Navigating New Mobility: policy approaches for cities October 2019 urbanism next center @urbanismnext urbanismnext.com city of gresham, or | city of Eugene, or Urbanism Next | University of Oregon ACKNOWLEDGMENTS Funding for this project was generously provided by the National Institute for Transportation and Communities (NITC; grant number 1249), the National Science Foundation (NSF; award number 1737645), the City of Gresham, and the City of Eugene. Special thanks to City of Eugene staff Terri Harding, Chris Henry, Rob Inerfeld, Jeff Petry, Shane Rhodes, Lacey Risdal, Matt Rodrigues, and Larisa Varela. From the City of Gresham, we’d like to thank Katherine Kelly, Amanda Lunsford, John Heili, and Carly Rice. The primary author of this report is Becky Steckler, AICP, Urbanism Next Program Director. This report could not have been completed without the efforts of the following people: Jennifer Davidson Amanda Howell Nico Larco, AIA Rebecca Lewis, PhD Michelle Montiel Marsie Surguine Huijun Tan Navigating New Mobility | October 2019 | 3 Urbanism Next | University of Oregon TABLE OF CONTENTs 01| Introduction 3 02| The Potential Impacts of 7 Technology on Mobility 03| New Mobility Policies and Strategies 15 04| Implications for Gresham and Eugene 35 Aa| Appendix A: Bibliography 61 AB| Appendix B: The Multilevel Impacts 66 of Emerging Technologies on City Form and Development, Chapter 2 Navigating New Mobility | October 2019 | 1 Urbanism Next | University of Oregon 01 | Introduction Navigating New Mobility | October 2019 | 3 Congestion is a common occurrence for urban commuters. Source: Nabeel Syed, for Unsplash. Background Over the past few years, it would not be unusual to wake up and notice a fleet of bright yellow or green bikes all over town, electric scooters on the sidewalk, or see people getting into cars with strangers for a ride. The introduction of dockless bikes, e-scooters, and ride hailing services like Uber and Lyft has been relatively smooth in some locations. In others, it has felt more like a major conflict, such as Santa Cruz and San Francisco (Brinklow, 2018; Cabanatuan, 2018; Men, 2018). Even if new passenger services haven’t yet been introduced in a city, the vast majority of people in the US have made an online purchase. The resulting deliveries from “ ...These new these purchases are potentially increasing traffic throughout our cities as goods are delivered to more homes and businesses. Our digital devices are forms of mobility changing how people and goods move. create new Increasingly, city leaders are coming to the realization that new mobility services create novel and complex issues they must address to ensure issues... that they complement the existing transportation system and don’t create new problems. Government agencies across North America are ” beginning to create strategies and regulations to manage the challenges, realize the opportunities, and ensure that these new mobility services help communities achieve their goals. These efforts are being led primarily by cities, but transit agencies, coalitions of cities, regional governments, and increasingly states are also developing new mobility strategies and policies. This purpose of this report is to help the cities of Gresham, Oregon and Eugene, Oregon understand the potential impacts of new mobility technologies – with an emphasis on autonomous vehicles (AVs) – and prepare a policy response. While Gresham and Eugene are case studies, it provides communities of all sizes information on how new mobility services could impact their communities and what they can do about it, from broad strategies to specific policy responses. While this work focuses on the various new mobility and goods delivery services that currently exist, the framework that is discussed here is also applicable to emerging technologies that haven’t yet been introduced, such as AVs. 4 | Navigating New Mobility | October 2019 | Section 1 - Introduction Urbanism Next | University of Oregon What was once purely science fiction is starting to materialize on streets across the country. Being prepared for these changes is what makes the difference between a community achieving its goals or being plagued with negative impacts. Cities that think ahead, stay ahead. methods The University of Oregon has been at the forefront of thinking about the secondary impacts of emerging technologies on city form and development. This document relies in part on extensive literature and policy reviews conducted in 2018 and 2019 for the Carbon Neutral Cities Alliance at the Urban Sustainability Directors Network (CNCA/USDN) and funded by the Bullitt Foundation, and the National Science Foundation. This report builds upon the policy review conducted as part of the CNCA/USDN work that compiled information from existing playbooks, policies, and strategies for new mobility and emerging transportation technologies. Some cities, such as Seattle, WA; Los Angeles, CA; and Austin, TX have created or adopted new mobility policies or strategies. Other cities, such as Atlanta, GA and St. Louis, MO are incorporating elements of new mobility topics into current planning documents or regulations. They all have something to teach other cities that are contemplating how to respond to the challenges of new mobility technology. This report focuses on new mobility and how it might affect city policies, programs, and budgets. report organization The rest of this document is organized in the following sections: section 2 Potential impacts of technology on mobility. This section describes how technology is changing how people and goods move. It briefly describes “new mobility” modes, including anticipated changes from the deployment of autonomous vehicles (AVs). It then discusses some of the possible first order impacts of new mobility, such as reduced demand for parking and increase in vehicle miles traveled (VMT) and congestion. This section then explores some of the potential secondary impacts of new mobility. section 3 New mobility policies and strategies. Government agencies at the federal, state, and local level are just beginning to address the challenges and opportunities presented by emerging technologies. This section will describe the roles of regulations at the federal, state, and local level, focusing on North American jurisdictions. It then describes in greater detail the ten most common topics included in new mobility policies and strategies from plans across the country. section 4 What does this mean for Gresham and Eugene? This section includes a scan of Gresham and Eugene’s transportation and other plans and highlights exisiting strengths, opportunities, and gaps. Appendix a Bibliography Appendix B The Multilevel Impacts of Emerging Technologies on City Form and Development Report, Chapter 2. Urbanism Next | University of Oregon Section 1 - Introduction | Navigating New Mobility | October 2019 | 5 Urbanism Next | University of Oregon 02 | the potential impacts of technology ON MOBILITY Navigating New Mobility | October 2019 | 7 Source: Fred Joe Photo NEW MOBILITY: HOW TECHNOLOGY IS CHANGING HOW PEOPLE AND GOODS MOVE It may be hard to understand how a digital device changes how people and goods move. One critical difference is that access to a wide range of mobility services has the potential to make transportation much more accessible. For example, a city that has a variety of services – from transit, to e-scooters, to TNCs – multiplies the possible modes and routes that a person can take throughout a day to get where they need to go. No longer is a person required to drive if they need to go somewhere inconvenient to transit. The new suite of options vastly expands the menu of options that people have to get around. Another critical difference is that by accessing transportation via a smartphone means that people can leave their cars at home. If people are leaving cars at home, then the demand for parking goes down. At the same time, the demand for space for drop-off and pick-up goes up. In addition, people make different choices about how many trips they take and what mode they use. For example, women going out at night might take public transit early in the evening when service is more frequent and more people are out, but feel less safe later at night waiting for the bus or train and decide to take an Uber or Lyft home instead. A recent report by the Rudin Center for Transportation estimated that women surveyed in New York pay $26-$50 more than men per month for safe transportation (Kaufman, Polack, & Campbell, 2018). Another study found that the majority of trips made by people taking TNCs would either not have been taken at all, or the trips would have been made by walking, biking, or transit (R. R. Clewlow & Mishra, 2017) had TNCs not been available. In other words, most TNC trips are not replacing driving trips. 8 | Navigating New Mobility | October 2019 | Section 2 - Potential Impacts of Technology Urbanism Next | University of Oregon Change is not limited to passenger movement. The growth of e-commerce as well as food, grocery, and other types of local delivery (also referred to as courier services in this report) is rapidly changing the retail economy and impacting transportation systems. While there is some data on passenger movement and heavy freight moving to and through cities, very few (if any) cities require companies to provide data on deliveries to homes and businesses. Given the rapid growth in e-commerce – the US Census Bureau reported that e-commerce increased from 4.5% in 2010 of total retail sales to 8.9% in 2017 – cities should expect to see increased delivery on city streets and increased demand for commercial loading and unloading zones. While demands from deliveries are felt first in larger metropolitan areas, it is expected to increase in suburban and rural areas over time. In addition to deliveries made by commercial trucks (like UPS, FedEx, and USPS), cities need to consider deliveries made in personal vehicles. There is very limited data about the communities served, number of deliveries, total miles traveled for companies like UberEats, GrubHub, Postmates, or Amazon Flex. As these services increase, communities need to understand the impact on the transportation system and the demand for curb space. The Urbanism Next Center completed research on how emerging technologies are disrupting land use, urban design, transportation, and real estate markets. This section briefly summarizes some of the work from the Multilevel Impacts of Emerging Technologies on City Form and Development. Appendix B includes Chapter 2 from that report that describes shifting paradigms and how they are leading to forces for change and the implications of those forces of change on equity, health, the economy, the environment, and governance. The next four pages describe new mobility, new mobility services, and new mobility as a service. It then defines new mobility services for moving people and moving goods. Finally, it lists the forces of change and 1st level impacts of new mobility technologies, the growth of e-commerce, and the anticipated deployment of AVs. The median extra transportation cost per month for men, due to safety reasons, is $0. $0 On the other hand, the median extra cost per month for women is $26-$50. Conclusion: Women are more likely than men to change their behavior in order to avoid harassment. Source: The Pink Tax on Transportation | Rudin Center for Transportation | November 2018 Graphic: Urbanism Next Urbanism Next | University of Oregon Section 2 - Potential Impacts of Technology | Navigating New Mobility | October 2019 | 9 $26-50/MO defining terminology New Mobility New Mobility Services (NMS) The term used to describe transportation that is The term used to describe the types of transportation newly enabled by digital technology, primarily the services of New Mobility. use of smartphone apps. Examples include: ridehailing, microtransit, and car and Examples include: ridehailing transportation network bike shares, which operate using smartphones and companies (TNC) (e.g. Uber and Lyft), autonomous other emerging technologies. (See additional NMS types vehicles, micro-transit (e.g. Via), bikeshare, and e-scooters. on the next page.) Mobility as a Service (MaaS) Describes both a change in how mobility is viewed as well as how New Mobility Services are consumed. The mobility paradigm shift is a shift from thinking of mobility as something one individually owns (e.g. owning a car or bike) to approaching mobility as a suite of pay-as-you-use transportation services. Mobility as a Service (MaaS) is the consumption of New Mobility Services (NMS) via the integration of various forms of transportation services into a single mobility service accessible on demand, such as a smartphone app. Through digital technology and a single end-to-end charge, consumers can choose their “own adventure” when deciding travel routes by selecting from a suite of New Mobility Services, choosing their mode(s) of transportation based on availability and preferences in price and total trip duration. (Below is the ideal MaaS situation: using a smartphone app, choosing desired modes of mobility, and paying through the app.) arrive: 10:31a (37 min) total: $2.75 2min $0 Maa S 10min $0.25 25min $2.50 10 | Navigating New Mobility | October 2019 | Section 2 - Potential Impacts of Technology Urbanism Next | University of Oregon arrive: 10:31a (37 min) total: $2.75 2min $0 aaSM 10min $0.25 25min $2.50 BIKESHARE eSCOOTER SHARE MOPED SHARE CARSHARING Services providing fleets of Services providing fleets of Services providing fleets of Services providing access bicycles for short-term electric scooters for mopeds for short-term to shared vehicles for trips rental. Pay at kiosk/ short-term rental within a rental. Typically dockless: where users only pay for smartphone app. Docked: time used. Stationary: defined service area. pick-up/return anywhere pick-up/return at fixed pick-up/return to same stations. Dockless: Pick-up/leave anywhere within a defined area. parking spot. Free-floating: pick-up/leave anywhere within a defined area. pick-up/leave anywhere within a defined area. within a defined area. Peer-to-peer: rent from individuals. RIDEHAILING MICROTRANSIT PUBLIC TRANSIT AUTONOMOUS VEHICLE Use of smartphone apps Privately operated Use of public transit as it Vehicles use sensors and to connect passengers passenger vans and currently exists, but using advanced control systems with drivers who provide shuttle buses offer newer technologies like to operate independently rides in their personal transit-like service on a smaller scale. Routes may smartphone apps to look from a human driver and vehicles. Also known as be fixed or dynamic, but up routes and/or pay for may be used to transport transportation network typically use ride. passengers as well as companies (TNCs). Can predetermined pick-up and freight. be single or shared drop off points for occupancy. passengers. COURIER SERVICES AUTONOMOUS DELIVERY SELF-DRIVING ROBOTIC AERIAL DRONE DELIVERY The use of an app to The delivery of goods by DELIVERY Not a focus of report/or in connect people using their driverless autonomous Fleets of small autonomous the scope of Urbanism personal vehicles to make vehicles, from larger delivery vehicles that may Next... but a technology on restaurant, grocery, or freight vehicles to smaller be used on sidewalks or on the near horizon. other package deliveries. passenger vehicles. roads depending on size and speed. Urbanism Next | University of Oregon Section 2 - Potential Impacts of Technology | Navigating New Mobility | October 2019 | 11 m o v i n g p e o p l e m o v i n g G O O D S m o v i n g p e o p l e m o v i n g G O O D S Shifting Paradigms 1st order impacts I m p l i c at i o n s These two pages summarize Congestion and/or VMT change Equity Chapter 2 from the report, The Rates of congestion and/or VMT have been changing in recent New mobility technologies could have positive equity implications, but they may Multilevel Impacts of Emerging years due to a variety of factors, including the introduction of also exacerbate existing inequities. On the positive side, technology may improve Technologies on City Form and TNCs. Congestion and/or VMT could increase with the mobility access for underserved populations, increase opportunities for wealth Development, included in Appendix introduction of AVs if they expand mobility options, address issues creation, and create jobs. However, technology can also have negative impacts: B. This report includes research on of latent demand, induce travel, and/or change travel behavior. from excluding those without credit or smart phone access from services; to three forces of change—new mobility However, congestion and/or VMT could decrease if people shift displacement of workers by automation; to disproportionately benefiting technologies, e-commerce, and from cars to micromobility devices, microtransit, or transit. higher-income earners furthering income disparity. autonomous vehicles (AVs). It also identifies the first order impacts, or impacts that are being caused by, at least in Change in parking demand part, the forces of change. Many of the these Some places, such as airports and areas with are already underway and will be further concentrated nightlife, are seeing demand for Health impacted by the commercial deployment of AVs. parking change. The continued adoption of TNCs, Emerging technologies could make us healthier—AVs have the micromobility, and eventually AVs will likely have potential to significantly decrease car crashes and lower exposure to increasing impacts on demand, which has pollution and greenhouse gas (GHG) emissions. New mobility could 1. implications for street space allocation and land use. improve mental health if travel becomes less stressful and food delivery could improve access to healthy food. Active transportation Ease of travel may become more or less attractive depending on the future safety New mobility and comfort engendered by AVs; depending on the safety, cost, and AVs may make longer commutes The Multilevel Impacts of Emerging potential effects on the built environment, AVs may either help boost more tolerable as people can work or Technologies on City Form and bicycling and walking, or could undermine them. technologies be entertained while traveling. That may increase the willingness of some Development explores how the 1st to live farther away from work or other destinations. order impacts could change land use, urban design, transportation, and real 2. estate and the implications of these EconomyTravel mode shifts The gig economy is significantly increasing the number of impacts on equity, health, the economy, New mobility services are changing people that are working as contractors instead of Growth of travel behavior. There may be a shift the environment, and governance. employees. Additionally, AVs may put millions of people from walking, biking, and transit to out of work who drive as part of their job. Government modes like TNCs and AVs. finance and budgets will likely change as people pay for E-Commerce less parking, or less in gas taxes if electric AVs proliferate. Curb/street competition Demand for limited space has been increasing 3. with the introduction of TNCs, the increase in urban delivery, the expansion of bikesharing programs, Environment and the deployment of e-scooters, to name a few. If AVs are primarily electric or hybrid vehicles, there is the potential to greatly Anticipated If AVs proliferate, an increasing number of pick-up reduce GHG and other air pollutants with widespread adoption. However, if and drop-off areas may become necessary. the transition is slow, and all those AVs significantly increase congestion, we may see increases in GHG and pollution as gas-powered vehicles get stuck deployment in traffic. AVs could also encourage sprawling development, resulting in loss Changes in delivery and freight of habitat and natural systems as they are developed. The growth of e-commerce and the introduction of services of AVs like GrubHub and Uber Eats are changing how, and how often, goods, food, and other items are delivered. These changes increase demands on the transportation system, and AVs could have significant impacts on the freight industry. Governance Emerging technologies could have profound impacts on local, regional, and national Changes in land use government budgeting, financing, operations, and business practices. Regulating emerging technology may enable cities to take advantage of the benefits and mitigate the Some brick-and mortar retail establishments are seeing demand risks. Regulations that are not flexible or adaptive to swift changes in technology could be decrease while demand for experiential retail is increasing. The need a barrier to city growth, safety of community members, the management of the for warehousing and distribution centers is changing the use of technologies, and city priorities. Information from new mobility providers will help commercial and industrial land as a result of shifting demand patterns. governments make informed decisions. 12 | Navigating New Mobility | October 2019 | Section 2 - Potential Impacts of Technology Urbanism Next | University of Oregon FORCES of CHANGE Shifting Paradigms 1st order impacts I m p l i c at i o n s These two pages summarize Congestion and/or VMT change Equity Chapter 2 from the report, The Rates of congestion and/or VMT have been changing in recent New mobility technologies could have positive equity implications, but they may Multilevel Impacts of Emerging years due to a variety of factors, including the introduction of also exacerbate existing inequities. On the positive side, technology may improve Technologies on City Form and TNCs. Congestion and/or VMT could increase with the mobility access for underserved populations, increase opportunities for wealth Development, included in Appendix introduction of AVs if they expand mobility options, address issues creation, and create jobs. However, technology can also have negative impacts: B. This report includes research on of latent demand, induce travel, and/or change travel behavior. from excluding those without credit or smart phone access from services; to three forces of change—new mobility However, congestion and/or VMT could decrease if people shift displacement of workers by automation; to disproportionately benefiting technologies, e-commerce, and from cars to micromobility devices, microtransit, or transit. higher-income earners furthering income disparity. autonomous vehicles (AVs). It also identifies the first order impacts, or impacts that are being caused by, at least in Change in parking demand part, the forces of change. Many of the these Some places, such as airports and areas with are already underway and will be further concentrated nightlife, are seeing demand for Health impacted by the commercial deployment of AVs. parking change. The continued adoption of TNCs, Emerging technologies could make us healthier—AVs have the micromobility, and eventually AVs will likely have potential to significantly decrease car crashes and lower exposure to increasing impacts on demand, which has pollution and greenhouse gas (GHG) emissions. New mobility could 1. implications for street space allocation and land use. improve mental health if travel becomes less stressful and food delivery could improve access to healthy food. Active transportation Ease of travel may become more or less attractive depending on the future safety New mobility and comfort engendered by AVs; depending on the safety, cost, and AVs may make longer commutes The Multilevel Impacts of Emerging potential effects on the built environment, AVs may either help boost more tolerable as people can work or Technologies on City Form and bicycling and walking, or could undermine them. technologies be entertained while traveling. That may increase the willingness of some Development explores how the 1st to live farther away from work or other destinations. order impacts could change land use, urban design, transportation, and real 2. estate and the implications of these EconomyTravel mode shifts The gig economy is significantly increasing the number of impacts on equity, health, the economy, New mobility services are changing people that are working as contractors instead of Growth of travel behavior. There may be a shift the environment, and governance. employees. Additionally, AVs may put millions of people from walking, biking, and transit to out of work who drive as part of their job. Government modes like TNCs and AVs. finance and budgets will likely change as people pay for E-Commerce less parking, or less in gas taxes if electric AVs proliferate. Curb/street competition Demand for limited space has been increasing 3. with the introduction of TNCs, the increase in urban delivery, the expansion of bikesharing programs, Environment and the deployment of e-scooters, to name a few. If AVs are primarily electric or hybrid vehicles, there is the potential to greatly Anticipated If AVs proliferate, an increasing number of pick-up reduce GHG and other air pollutants with widespread adoption. However, if and drop-off areas may become necessary. the transition is slow, and all those AVs significantly increase congestion, we may see increases in GHG and pollution as gas-powered vehicles get stuck deployment in traffic. AVs could also encourage sprawling development, resulting in loss Changes in delivery and freight of habitat and natural systems as they are developed. The growth of e-commerce and the introduction of services of AVs like GrubHub and Uber Eats are changing how, and how often, goods, food, and other items are delivered. These changes increase demands on the transportation system, and AVs could have significant impacts on the freight industry. Governance Emerging technologies could have profound impacts on local, regional, and national Changes in land use government budgeting, financing, operations, and business practices. Regulating emerging technology may enable cities to take advantage of the benefits and mitigate the Some brick-and mortar retail establishments are seeing demand risks. Regulations that are not flexible or adaptive to swift changes in technology could be decrease while demand for experiential retail is increasing. The need a barrier to city growth, safety of community members, the management of the for warehousing and distribution centers is changing the use of technologies, and city priorities. Information from new mobility providers will help commercial and industrial land as a result of shifting demand patterns. governments make informed decisions. Urbanism Next | University of Oregon Section 2 - Potential Impacts of Technology | Navigating New Mobility | October 2019 | 13 FORCES of CHANGE Urbanism Next | University of Oregon 03|NEW MOBILITY POLICIES AND STRATEGIES Navigating New Mobility | October 2019 | 15 the Shared Mobility Principles for Livable Cities The Shared Mobility Principles for Livable Cities is an effort initiated by Robin Chase, the founder of Zipcar. She worked with a consortium of transportation experts to create 10 mobility principles to help guide urban decision-makers and stakeholders towards the best outcome for all. Hundreds of organizations, companies, and governments (and counting) have signed on to the principles. Source: Unsplash. The 10 Mobility Principles: Overview 1. We plan our cities and their Government agencies at the federal, state, and local level are just beginning mobility together to address the challenges and opportunities presented by emerging 2. We prioritize people over technologies and new mobility services described in Section 2. Cities vehicles are considering these impacts and framing their new mobility policies within existing transportation, land use, sustainability, social equity, and 3. We support the shared and other goals. Some cities and organizations developed or are developing efficient use of vehicles, lanes, strategies and guidance first, such as the City of Seattle’s New Mobility curbs, and land Playbook or the Shared Mobility Principles for Livable Cities (see sidebar), others are using existing land use, transportation, or other documents 4. We engage with stakeholders and updating elements of these policies to accommodate new mobility. 5. We promote equity This section describes some of the most common topics included in new mobility strategies and implementation regulations across the country, such 6. We lead the transition towards as improving safety, prioritizing active transportation, and improving social a zero-emission future and equity. This section breaks it down into ten topic areas: renewable energy 1. safety 7. We support fair user fees across all modes 2. social equity 8. We aim for public benefits via 3. active transportation open data 4. Congestion and vehicle miles traveled 9. We work towards integration and seamless connectivity 5. Sustainability and environmental impacts 10. We support that autonomous 6. Design and management of the right-of-way (ROW) vehicles AVs) in dense urban areas should be operated only in 7. land use and metropolitan footprint shared fleets 8. Informed decision making (Shared Mobility Principles for Livable Cities, 2017) 9. ManageD innovation 10. Fiscal impacts and new mobility revenue 16 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon These ten topic areas were chosen not just because they were commonly found in new mobility policy documents listed in Table 3-1. They were also chosen in part because of the community goals in the City of Gresham and Eugene’s land use, transportation, economic development, and environmental plans, discussed in greater detail in Section 4. Urbanism Next researchers scanned the cities’ policy documents and found that they identified goals, objectives, and action items related to these topics. For example, both cities have multiple goals related to promoting active transportation–walking, biking, and transit. Coupled with the fact that most new mobility policy documents and implementing measures also support active transportation made it logical to include it in this section and provide examples from the policy documents listed in Table 3-1. This list of documents and the sample policies should not be considered exhaustive, but is designed to provide an example of the types of policies that other jurisdictions are considering. Jurisdiction Name Date Agency/Group Description Atlanta, GA Regional Transportation Dec 2016 Atlanta Regional Policy and strategy Technology Policy Document Commission recommendations Smart Mobility Roadmap Oct 2017 City of Austin and Policy and strategy Capital Metro recommendations Austin, TX Austin Strategic Mobility Plan No Date City of Austin Draft policies Ridesharing and Autonomous Chandler, AZ Vehicles Zoning Code May 2018 City of Chandler Adopted parking to passenger Amendments loading ratio zoning code updates Denver November Policy and strategy Metropolitan Region 2030 Mobility Choice Blueprint 2018 Denver Region recommendations Urban Mobility in a Digital Age 2016 LA Dept. of Policy and strategy Transportation recommendations Los Angeles, CA Mobility Plan 2035 Sept 2016 Dept. of City Planning Adopted as part of the General Plan in 2016 Draft Emerging Technology Policy and strategy plan, Metro Region, OR Strategy June 2018 Metro incorporated into the Regional Transportation Plan Miami-Dade County Miami-Dade County Urban Mobility Playbook March and City Innovate Policy and strategy 2016 Foundation recommendations New Mobility: AVs and the Region Policy and strategy recom- NY/NJ/CT Region (Component of Fourth Regional Oct 2017 Regional Plan Plan) Association mendations included in the Fourth Regional Plan (Nov 2017) Portland, OR Portland 2035 Transportation MaySystem Plan 2018 City of Portland Policies and strategies Seattle, WA New Mobility Playbook Sept 2017 Seattle Department of Policy and strategy Transportation recommendations St. Louis, MO Region Emerging Transportation June 2017 East-West Gateway Policy and strategy Technology Strategic Plan COG recommendations Toronto, ON Preparing the City of Toronto for Report on steps taken and AVs Jan 2018 Transportation Services proposed next steps Table 3-1. Sample of new mobility policies and implementing regulations Source: Links compiled by the Urbanism Next Center, 2019. Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 17 nacto’s principles for autonomous urbanism Source: Nacto’s Blueprint for Autonomous Urbanism, pp12-13. 18 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon Safety common Equity approaches adopted by cities Cities with Vision Zero policies (or their equivalents) must now consider how new mobility services could help them achieve community safety Provide a seat at the table. goals. Examples of cities incorporating Vision Zero goals into new mobility strategies and policies: Ensure all areas are covered by the service. City of Portland. The City of Portland’s Transportation Plan was updated in 2018. Policy 9.68.a. states that the city should “[e]nsure that Require diverse payment all levels of automated vehicles advance Vision Zero by operating safely options. for all users, especially vulnerable road users.” (City of Portland, Bureau Ensure that companies promote of Transportation, 2018) equitable workforce policies. City of Seattle. New Mobility Playbook, Strategy 2.2 states the city Accommodate people with will, “Ensure that new mobility advances our Vision Zero goal of ending disabilities. traffic deaths and serious injuries on city streets by 2030.” (Seattle Department of Transportation, 2017) (Also see Social Equity Examples.) City of San Francisco. San Francisco’s Guiding Principles for Emerging Technologies state, “Emerging Mobility Services and Technologies must be consistent with the City and County of San Francisco’s goal for achieving Vision Zero, reducing conflicts, and ensuring public safety and security.”1 social equity Cities are adopting a number of approaches to include equity issues. Some of the most common are: Provide a seat at the table. Include a diversity of people to ensure that equity is addressed in plans and strategies as well as implementing regulations. The City of Austin is proposing a policy to partner with the public and private sectors to create new mobility solutions for historically underserved communities (City of Austin, n.d.). Ensure all areas are covered by the service. Some cities require new mobility services be available to all residents, regardless of where they live. More and more, cities are requiring companies to disperse their vehicles (bike, e-scooter, or other vehicles) in low- income or underserved neighborhoods or across the entire city. During Portland’s e-scooter pilot that ran from July to November 2018, the permit required that each of the three companies participating in the pilot deploy 100 e-scooters in the historically underserved neighborhoods of East Portland. Only one company regularly complied with this requirement. The report found that, “many Black Portlanders and East Portlanders expressed enthusiasm and support for e-scooters, focus group participants also expressed an overall concern with traffic safety and being targeted for racial profiling and harassment. The prohibitive cost of renting and a lack of knowledge of e-scooter laws and low- income plans also presented barriers to use.” (Portland Bureau of Transportation, 2019, p 25). Other cities require a minimum number 1 San Francisco Municipal Transportation Agency (SFMTA) (no date), Guiding Principles for Emerging Mobility Services and Technology. Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 19 of vehicles in each neighborhood or designated zone. Washington, DC requires companies to put e-scooters in every ward, though companies complained that the capping of the total number of e-scooters makes this difficult (Dalgadillo, 2018). Require diverse payment options. Some jurisdictions require companies to provide a payment option that does not include a smartphone or credit card, or that waives deposits for low-income people. Washington, DC requires companies to offer unlimited 30-minute trips to customers that are at 200% of the federal poverty level. Ensure that companies promote equitable workforce policies. Ensure that companies reflect the community they serve and offer fair pay, labor policies, and practices. Accommodate people with disabilities. Several cities encourage companies to provide options for people with disabilities, such as Washington, DC’s adaptive e-scooters. Examples of cities incorporating equity into new mobility strategies and policies: City of Seattle. Seattle’s New Mobility Playbook includes principles, plays, and actions to improve safety. The Principles put people and safety first, “Safety is paramount, no matter how you get around Seattle. Our streets should be comfortable and intuitive for our most vulnerable travelers (people walking and biking). Shared, automated, and other new mobility models should not only advance our Vision Zero safety goals, they should also maintain consumer protections.” (City of Seattle, 2018, p 32). Play 1 is to ensure a fair and just transportation system for all. The strategies in this play includes enhancing transportation services for vulnerable groups such as the LGBTQ community, youth, seniors, people with disabilities, and many others; ensure everyone can access smartphone services; ensure a wide array of payment options; make sure new mobility services are ADA accessible, and more. Washington, DC. The District adopted a new e-scooter and motorized bicycle permit (effective January 1, 2019) that requires e-scooter coverage in every ward (eight total), and allows up to 600 e-scooters per company with the potential to increase that amount by 25% every three months. In addition, companies are encouraged to offer adaptive vehicles that can accommodate people with mobility devices (like wheelchairs). These vehicles are not counted towards the total allowed (District Department of Transportation, 2018). active transportation (walk/bike/ e-scooter/transit) Cities and transit agencies are considering the impact new mobility services are having on active transportation systems. While many cities include goals related to promoting pedestrian, bicycle, and transit systems and reducing reliance on single-occupancy vehicles, some cities are taking the next step to prioritize walking, biking, transit, over vehicles with a focus on reducing 20 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon single-occupancy and zero-occupancy vehicles. Table 3-2 shows the prioritization of modes for the City of Portland. priority portland Prioritizing active transportation draws a direct connection between policy goals related to safety, health, reducing greenhouse gases, 1 Walking complete streets, and sustainable and livable cities that support 2 Cycling higher-intensity uses and guides infrastructure investments. It also informs the implementation of complete streets and curb 3 Transit management policies to reduce conflicts between new mobility 4 Fleet automated vehicles that are service providers and vehicles and pedestrians, bicyclists, and electric and shared (FAVES) transit riders, as well as goods delivery and courier services. It 5 Other shared vehicles clearly states that implementation strategies that prioritize walking, biking, and transit will take precedence over vehicles. Examples of 6 Low or no occupancy vehicles, fossil-fueled non-transit vehicles how cities are incorporating these concepts into policies: Table 3-2. Prioritization by mode, Portland, OR City of Portland. Portland recently updated its Transportation Source: City of Portland, Portland 2035 Transportation System Plan (TSP) and identifies reducing GHG emissions by System Plan (2018). reducing low occupancy “empty miles” as well as prioritizing electric and other zero emission vehicles. (TSP Policy 9.68.b.) City of San Francisco. San Francisco’s SFMTA has the Transit First policy, which prioritizes pedestrian modes. The city is attempting to evaluate its curb management approach by using data collection and implementing a “decongestion pricing and incentives system” with either cordons or roadway user fees. The SFMTA has also embarked on “Powered E-Scooter Share Permit Program” and is attempting to regulate e-scooter clutter in the ROW. An evaluation of restricted parking curb location data determined that approximately 20% of microtransit stops are located in unauthorized zones. The report has a number of recommendations related to congestion and curb pricing but there’s not a lot of specific deliverables on precise ordinance or pilot suggestions. NY/NJ/CT Regional Plan Association. The NY/NJ/CT Regional Plan Association identified the need to prioritize street space for public transit, pedestrians, bikes, and freight in the 2017 New Mobility report. Source: Photo by Ryoji Iwata on Unsplash. congestion and vehicle miles traveled Almost every new mobility strategy or plan includes a goal to keep people and goods moving. The potential for TNCs and AVs to dramatically increase congestion and VMT is concerning. Numerous reports have documented an increase in TNCs and the corresponding increase in congestion and reduced traffic speeds (Schaller, 2018; SFCTA, 2017; Fehr & Peers, 2018) as well as a reduction in transit use (Graehler et al., 2018). Given the potential for increased congestion and VMT, cities are considering efforts that reduce congestion and promote shared vehicles. NACTO’s report Blueprint for an Autonomous Future (2017) provides a vision for how cities can design streets to increase throughput while promoting active transportation and autonomous transit. Figure 3-1 shows that streets designed for high-capacity AV transit service could move over 47,000 more people per hour than auto-oriented streets (NACTO, 2017). At the policy guidance level, the cities of Portland, OR; Seattle, WA; and Vancouver, BC have all indicated they will prioritize shared, electric, autonomous vehicles. Other potential strategies are to price single-occupancy or zero-occupancy vehicles at a higher rate than shared vehicles. To our knowledge, this idea is conceptual as of early 2019 as most cities and airports charge TNCs by the ride, and the only company offering commercial AV services is Waymo in Chandler, AZ (as of December 2018) and does not charge a city fee for each ride. Another tactic is to price the curb higher at the most desirable pick-up/ drop-off locations. For example, the San Francisco Airport charges TNCs $5 to pick-up/drop-off passengers in front of the terminals (the most convenient location) or $3.60 to get picked-up/dropped-off on the top level of the parking garage. Figure 3-1. Conceptual street capacity of different modes, NACTO, 2017 Source: NACTO, Blueprint for an Autonomous Future, 2017 22 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon City of Portland. The City of Portland’s Transportation System Plan states that to “ensure that connected and automated vehicles improve travel time reliability and system efficiency by: (1) maintaining or reducing the number of vehicle trips during peak congestion periods; (2) reducing low occupancy vehicle trips during peak congestion periods; (3) paying for use of, and impact on, Portland’s transportation system including factors such as congestion level, vehicle miles traveled, vehicle occupancy, and vehicle energy efficiency; and (4) supporting and encouraging use of public transportation.” (TSP Policy 9.68.b.) Sustainability and environmental impacts Cities across the country understand that new mobility services provide a new opportunity to decrease greenhouse gas emissions, air pollution, and possibly improve storm water management. Example policies are: City of Portland. Transportation System Plan Policy 9.68.c. is “Cut vehicle carbon pollution by reducing low occupancy ‘empty miles’ traveled by passenger vehicles with zero or one passengers. Prioritize electric and other zero direct emission vehicles operated by fleets and carrying multiple passengers.” (City of Portland, Bureau of Transportation, 2018). denver region. The Mobility Choice Blueprint identified promotion of electrification of vehicles as one of its strategies to reduce GHG emissions and air pollution. The tactical actions are: “5.1. Incentivize TNCs to use electric vehicles. Develop a goal, create a policy and incentivize the deployment and use of electric and other zero-emission vehicles by TNCs. 5.2. Create an electrified mobility development program. Identify regulatory hurdles and develop recommendations to encourage the adoption of electrified vehicles by public and private fleets. 5.3. Transition government fleets to electric and other zero-emission vehicles. Work with public agencies to create an aggressive and agreed-upon goal for converting a portion of their fleets to zero- emission vehicles. The goals may be tailored to fleet types as well as available vehicle technology.” (Colorado Department of Transportation, Denver Regional Council of Governments, Regional Transportation District, & Denver Metro Chamber, 2018). Source: Photo by John Cameron on Unsplash Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 23 Spotlight on the curb design and management of the row Curb management is an important tool that cities Emerging technologies and new mobility services are disrupting how can use to reduce GHG the right-of-way – the space from sidewalk to sidewalk – is being used. emissions. Free on-street Researchers from the Association of Pacific Rim Universities (APRU) and parking, which has historically the University of Oregon through the Sustainable Cities and Landscapes been plentiful, induces auto Research Hub identified two ways that AVs (and some new mobility travel, and encourages drivers services) may free up street space (Schlossberg & Riggs, 2018): to “cruise” for parking. This 1. Lanes. Both the number of lanes and the amount of space needed increases VMT/VKT and can may shrink as AVs are “right-sized” to fit the need and more vehicles increase congestion. Cities are shared, as well as the ability of AVs to travel close together in a can encourage mode shifts platoon. by dedicating curb space to transit, bike lanes, and other 2. Parking. As more people rent or share the ride and fewer use low-carbon uses. However, personally owned vehicles, the demand for parking should go down. many cities do not know how much demand there is for Both of these trends allow for cities to reclaim space in the ROW for other their curbs—how much space uses. The authors of the report imagine regaining approximately 24’ on exists, where it is, where it is a typical urban arterial by removing one lane of parking and reducing regulated and where it is not, lane widths to 8’. The reclaimed space could be used for loading zones, and how the space is currently widened sidewalks, dedicated transit, or increased bike/e-scooter lanes. being used. As a result, cities The National Association of City Transportation Officials’ (NACTO) Blueprint should map and inventory for Autonomous Urbanism provides even more detail about how cities curb space and collect data about current usage patterns. This information can inform GREENING decisions about how space should be allocated, and personal vehicles puBLIC TRANSPORTATION what regulatory or pricing mechanisms may need to be implemented. (More information about curb management can be found in the New Mobility in the Right-of-Way report at www.urbanismnext.com). bikeshare/e-scooter storage active transportation TNC FREE RKINGPA The Cost of igh rkingH ree P a F UP NALD SHO DO TNC electric car charging ride-hailing COURIER SERVICES parking utilities freight/goods delivery Figure 3-1. Multiple uses of the right-of-way (ROW) Streeteries Source: Michelle Montiel. 24 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon Figure 3-2. Vehicles and People by Mode, per hour, San Francisco Curb Study, Five Case Study Sites, 2018 Source: Fehr and Peers, San Francisco Curb Study prepared for Uber Technologies, September 2018. p 39. should think about autonomous vehicles (NACTO, 2017). NACTO envisions a future where streets are prioritized for pedestrians, bicyclists, and transit riders. The City of Portland’s hierarchy of modes sets an overarching policy that prioritizes streets and street networks for pedestrians, bikes, transit, and freight above private vehicles or single-occupancy vehicles. A similar policy is identified in the NY/NJ/CT Regional Plan Association New Mobility (p 3) and Seattle’s New Mobility Playbook (Appendix C, p 5). From adjacent store owners advocating for free parking for customers and employees, to commercial delivery companies demanding parking for trucks, to active transportation advocates requesting protected space to walk, bike, and take transit, battles over the curb are nothing new. What is new is the explosion of dockless bikes and e-scooters where they’ve been introduced and TNC services, along with the anticipation of AVs, that is convincing cities that they must develop new systems to manage, and price, the curb. Cities rarely have a comprehensive picture of how the curb is being used. Data requirements for new mobility providers helps cities understand the demand for the curb, but not all cities require data sharing. A study completed in 2018 by Uber and Fehr & Peers quantified the demand for the curb in five locations with significant TNC drop-off/pick-up in San Francisco. Figure 3-2 highlights the most efficient mode for moving people is by bus, with 481 people observed dropped-off or picked up by 69 vehicles, compared to 432 people in 370 vehicles for TNCs or private vehicles. Twenty-three parked cars transported 23 people. As the demand for the curb increases, cities are increasingly accepting that they may need to change how they manage the right of way and curb space. For example, some cities that have neighborhoods with a lot of nightlife, are removing on-street parking and replacing it with loading zones. Cities are also starting to rethink the condition of their bikelanes as Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 25 e-scooters descend on cities and riders that are uncomfortable riding on the street (often due to poor conditions or unprotected bike lanes) and instead are riding on the sidewalk. Some e-scooter companies are advocating for better bike infrastructure (Sisson, 2018a) and cities are starting to think about and plan for e-scooter parking (see Figure 3-3). Some cities are considering removing on-street parking, designing dockless e-scooter and bike parking, and eventually regulating the use of sidewalks and streets for terrestrial drones, such as those by Starship (see Figure 3-4). Only a few cities have developed a comprehensive ROW and curb management system and of those, they are still adapting their systems for new mobility modes. For example, the City of Seattle has identified six functions of the ROW as storage, greening, activation, access for commerce, access for people, and mobility, as shown in Figure 3-5. Figure 3-6 describes the pedestrian zone, the flex zone, and the travel way. The regulatory approach to managing the curb is in transition. Many jurisdictions understand that how curbs were managed in the past won’t work in the future. One tool cities are using to better understand this change is by conducting pilot projects. The Cities of Washington, DC, New York, and others are actively working on curb management pilot projects. This is an area of policy that continues to evolve, however several cities Figure 3-4. Starship terrestrial drone have begun to think of overarching policies. Examples from plans include: Source: Starship, 2018. Accessed at https:// www.starship.xyz/kit/ on December 18, 2018. city of austin. The draft Austin Strategic Mobility Plan includes a section on curb Management with three policies: “Policy 1: Use context to determine mobility and non-mobility curb uses. Identify the most appropriate uses for curbs by considering mobility, safety, street type, surrounding land use, and location. Policy 2: Manage curb space dynamically. Flexibly allocate curb space to adapt to different uses and users. Figure 3-3. Dockless bike and e-scooter parking, City of Santa Monica, 2018 Source: City of Santa Monica, 2018. Accessed at https://www.santamonica.gov/blog/5-things-to-know-before-you-ride-an-electric-scooter on December 18, 2018. 26 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon Figure 3-5. Primary functions of the Right-of-Way as defined by the Seattle Department of Transportation, 2016 Source: City of Seattle. Accessed at http://streetsillustrated.seattle.gov/street-types/row-allocation/ on December 18, 2018. Figure 3-6. Street Right-of-Way (ROW) Zones as Designated by SDOT Source: Seattle Department of Transportation Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 27 Policy 3: Streamline objects at the curb to improve safety and mobility. Coordinate the placement, number, and use of objects at the curb with natural features to realize multiple community benefits.” Denver region. The Denver Region Mobility Choice Blueprint’s 2nd objective is to integrate shared mobility. Tactical Action 2.4 is to implement curbside management standards “for passenger loading and freight delivery by developing policies and employing technologies to monitor, enforce, and monetize curbside operations.” (Colorado Department of Transportation, Denver Regional Council of Governments, Regional Transportation District, & Denver Metro Chamber, 2018). city of portland. TSP Policy 9.69.b is “Design and manage the mobility zone, Curb Zone, and traffic control devices to limit speeds to increase safety, to minimize cut-through traffic, evaluate future demand for pick-up and drop-off zones, and to prioritize automated electric vehicles carrying more passengers in congested times and locations.” (City of Portland, Bureau of Transportation, 2018). Figure 3-7. City of Gresham Parking Lots Source: Google Maps and Urbanism Next consider changes in land use and metropolitan footprint On the one hand, new mobility modes, especially autonomous vehicles, have the potential to both increase the intensity of land uses in urban centers and corridors by reducing the demand for parking. On the other hand, new mobility and especially AVs could increase sprawl by reducing the friction of driving through decreasing cost and allowing passengers to do more pleasant and productive things other than drive. Government policy could help shape how much infill occurs on existing parking lots, and how much farm, forest, and rural land is consumed up by sprawl. It’s hard to say exactly how much land is dedicated to parking, though there have been numerous estimates that range from 100 million to two billion parking spaces across the US (Kimmelman, 2012). New mobility services are dependent on people not using their personally-owned vehicles and parking them at their destination. This presents a significant opportunity to reclaim that space for more productive uses, from housing to employment to parks or open space. Cities should begin to plan for this 28 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon opportunity and consider the steps that will aid the transition and ensure city codes do not continue to require developers to provide even more parking that likely will not be used in the future. There is additional work to do to convince banks and others that financing parking will be increasingly risky as the demand for parking goes down. Cities may want to be thinking and planning now for how they can more productively use reclaimed parking spaces. On-street parking can be used for drop-off/pick-up zones, or for transit, bikes, e-scooters, and other micromobility uses. It can also be used for landscaping and to manage storm water. When it comes time to consider what to do with off-street parking, cities will need to determine if the current zoning is adequate for the demand for that use, or if it should re-zone the land for other uses. It is likely that the areas with the greatest potential for redevelopment are in downtowns and corridors with high-capacity transit. Some cities, like the City of Austin, considering changes to parking focus on on-street parking and how use of the ROW could evolve. The City of Chandler is one of the few places that has changed its zoning code to reduce minimum parking requirements, though it remains to be seen if this policy results in reduced off-street parking. Example policies are: City of Austin. The draft Austin Strategic Mobility Plan parking policy 3 is “Coordinate on-street parking and curb management strategies for flexibility and adaptability with future parking and mobility technology.” (City of Austin, n.d.) City of Chandler. To date, the City of Chandler is the only jurisdiction that has adopted minimum parking requirement reductions if a development includes loading zones for AVs. The objectives of the policy are to: “(1) Provide the City with more flexibility to reduce minimum parking requirements as parking demand changes, and, (2) Encourage develo9pments to install passenger loading zones.” (City of Data is replacing Chandler, 2018). concrete, asphalt and steel as the foundation make informed decisions “ of 21st-century urban transportation planning and It’s particularly true that it is difficult to manage what you don’t measure, management. New technologies especially in relation to managing a city or regional transportation system. have the potential to radically As new mobility services continue to disrupt how people and goods move improve the efficiency, cost, across a region, decision-makers must better understand those changes and inclusiveness of our and model how movement will change in the future to make sure they transport system. can wisely invest millions (or billions) of dollars in transportation funds. New mobility companies and others are collecting movement data, but jurisdictions aren’t likely to get that information from private companies ” unless they require it. Historically it has been difficult to get information – John Ellis (via Nacto) from TNC companies and even when they do share data, it is sometimes protected from the public by non-disclosure agreements. Cities have been more successful requiring data of e-scooter companies. It remains to be seen if cities are successful in requiring data of all new mobility providers in the future. The City of Los Angeles is a leader in this area and is striving to develop the idea of “Data as a Service.” Data as a Service is the “...rapid exchange of real-time conditions and service information between service providers, Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 29 customers and the supporting infrastructure. This requires a seamless data exchange with a variety of partners and stakeholders, privacy and security data and transportation protections, the capacity to analyze data from a variety of resources, “The real question is: can LADOT and the ability to integrate this insight into a data-driven decision-making manage the transportation process (as opposed to an anecdotal one) for both system managers network similar to a data network and city leaders. Data sharing is a relatively cost-effective way to enhance or a telecommunications connectivity and system efficiency without constructing new physical network? Should we consider infrastructure. With better data, LADOT will be in a position to become any vehicle like any other “data more responsive to the transportation needs of Angelenos as both a packets” that need to transverse service provider and regulator of transportation in Los Angeles.” (Hand, across a complex network? Can 2016, p ii). we use technology to change our Los Angeles’ data policy recommendations (Hand, 2016) are: first-come, first-served system into a fully managed system 1. Define what can be shared using software? The answer to 2. Adopt privacy principles all of these questions is yes.” 3. Develop a standard data sharing agreement 4. Create a regional blueprint for system integration 5. Establish design guidelines for digital infrastructure The City of portland noted in its e-scooter report that not all companies defined terms in the same way, which resulted in underreported vehicles for one company. Given the rapidly evolving nature of both the technology as well as the learning curve, cities have multiple reasons to ensure the data they get from companies is accurate, from enforcing vehicle distribution to collection of fees. Standardization and experience will likely help improve Source: LADOT Strategic Implementation, p4. compliance over time. The City of Portland joined with 15 other jurisdictions and six companies to create the Open Mobility Foundation (OMF) . OMF’s goal is to create a governance structure around open-source mobility tools, with a focus on Mobility Data Specification (MDS). manage innovation Changes in mobility have been happening so fast that it’s been difficult for cities to keep up. Many new mobility companies have taken the “grenade launching” approach to the introduction of new services by putting them on the street without operating permits. Commercial e-scooter services, first introduced in Santa Monica, epitomizes what can go wrong with a deployment. In an interview for Curbed, Rick Cole, Santa Monica’s City Manager characterized the initial deployment of e-scooters in 2017 as a “punishing experiment.” He joked that when e-scooters were first introduced, “he spent a third of his time running the city, a third of his time answering emails from those who thought e-scooters represented the end of Western civilization, and a third of his time responding to Twitter posts that he was clamping down on the best invention since the iPhone – one that would save the planet” (Sisson, 2018b). While many cities have been caught without a permitting process for new mobility technologies, they are starting to catch up. That said, they are finding that many city procurement policies may not be the best way to provide services to citizens, given the rapidly evolving technological landscape. Cities across the country are embracing the use of pilot projects to introduce new mobility services or try to manage mobility services in a 30 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon small, controlled area. Examples in Oregon include the Portland E-Scooter Pilot project and Metro’s Partnerships and Innovative Learning Opportunities in Transportation (PILOT) program. Pilot projects can be a cost-effective way to better understand how the technology operates, costs, its utility, and other intended and unintended consequences. Most pilot projects include the following elements: Time frame. Pilot projects generally last from several months to one year. Limited number of vehicles. There are no set criteria for how many vehicles are the right number for a pilot project. Cities need to allow enough to be able to determine the potential impacts as well as provide adequate coverage for the city and for the companies, but not so many that they overwhelm the city. This could mean limiting the total number of vehicles per company, limiting the total number of vehicles, regardless of company, or gradually increasing the total number of vehicles over time. Enforcement. Cities should include a plan to monitor service provisions and budget for enforcement of permit requirements. This could mean ensuring that users are not going in restricted areas (like e-scooters on sidewalks) or that companies are placing vehicles in required locations. Outreach plan. While companies will have a marketing plan or strategy to let customers know about their service, cities need to develop an outreach plan to let residents know that a service is coming, educate them about the rules of the road, parking guidelines (for dockless e-scooters or bikes), and safety considerations for all services. In addition, some pilots include user surveys to understand who is using the service, the socio-economics of users, and their attitudes about the service. Industry partners. Cities will need to work with technology companies and industry partners to provide transportation services. Sometimes the partner is identified first, or the project is identified and companies competitively bid on the opportunity to provide the service. Different approaches may be required for different circumstances. Created by ProSymbols from the Noun Project Data sharing. All pilots should include data to understand the measurable outcomes of the pilot project. Data sharing should ensure protection of user privacy and proprietary company data. Evaluation. All pilots should include an evaluation stage to understand what happened and determine what changes the city would like to make before rolling out a larger pilot or an on-going permit process. Budget. Finally, cities should consider the resources necessary to conduct a pilot project. Significant staff resources may be necessary, along with enforcement, outreach, surveys and other activities that must be paid for with limited funds. Some pilots charge a fee (such as a fee per ride) to help pay for the city cost of the pilot. Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 31 Consider the fiscal impacts New mobility technologies are already disrupting how cities and other jurisdictions pay for transportation infrastructure as well as operations and maintenance. Some agencies are seeing a benefit from charging for TNC rides, such as the Los Angeles Airport that saw TNC revenues of $24.8 million in 2017, offsetting a decrease in revenues of $3.4 million from bus, limousine, and taxi services (Department of Airports, Los Angeles, CA, 2017). However, many other jurisdictions will need to plan for changes in revenue from parking and parking citations, vehicle registration, moving vehicle citations, and most significantly, reductions in the fuels tax. Most of the major car companies developing autonomous vehicles are testing hybrid and electric vehicles. A 2017 article in the Verge reported that General Motors, Ford, Tesla, and Waymo have committed to creating AVs in hybrid or electric vehicles (Hawkins, 2017). One reason is that the electronics on AVs require significant battery power. The need for power increases as automation increases. In addition, car manufacturers are ramping up production of zero-emission vehicles to comply with California’s GHG reduction targets. As more people and goods are transported in hybrid and electric vehicles, less money will be spent on fuel taxes. According to the Tax Policy Center, over $43.8 billion in motor fuel tax revenue was collected in the United states in 2015, including $540 million in Oregon.1 Fuel taxes are one of the primary sources of transportation funding. On one hand, cities will need to think about how they will replace funding for transportation infrastructure. On the other hand, emerging technologies are a powerful new tool that can be used to price for congestion. Currently, some cities and other jurisdictions are charging a per ride fee, a % of the total fee, or a vehicle per day fee for new mobility services. While no city in the United States currently charges for congestion, Oregon is one of a few states that is piloting a road usage charge that has the potential to collect a per mile fee. This may be another model for charging for the use of roads. Another option is to convert on-street parking to drop-off/pick-up pricing (especially for high demand locations). Of course, there are many 1 https://www.taxpolicycenter.org/statistics/motor-fuel-tax-revenue. Accessed 12/17/18. 32 | Navigating New Mobility | October 2019 | Section 3 - New Mobility Polices & Strategies Urbanism Next | University of Oregon other ways to charge vehicles for traveling in the most congested locations at the most popular times, such as cordon pricing. Cities should consider a full suite of options to determine the methods that are best to achieve community goals. Cities should make sure their policies include the right to charge new mobility companies a fee to operate in their city, whether or not they actually collect the fee or not. Examples: City of Portland. The Transportation System Plan (2018) 9.68.b includes language to “ensure that connected and automated vehicles improve travel time reliability and system efficiency by…(3) paying for use of, and impact on, Portland’s transportation system including factors such as congestion level, vehicle miles traveled, vehicle occupancy, and vehicle energy efficiency.” Denver Region. The Mobility Choice Blueprint identifies several tactical actions to help fund transportation infrastructure including exploring a road usage charge for the state of Colorado as well as supporting legislation to ensure that AVs generate funding from new user fees, registration fees, and other revenue streams to help fund the transportation system (Colorado Department of Transportation et al., 2018). City of Los Angeles. The City of Los Angeles envisions a suite of transportation financing options in its Urban Mobility in a Digital Age including charging by the mile, sales tax, public/private partnerships, infrastructure banks, different ownership models, and municipal bonds (Hand, 2016). Below: Some agencies are seeing a benefit from charging for TNC rides, such as the Los Angeles Airport that saw TNC revenues of $24.8 million in 2017, offsetting a decrease in revenues of $3.4 million from bus, limousine, and taxi services (Department of Airports, Los Angeles, CA, 2017). Source: Photo by Thought Content on Unsplash Urbanism Next | University of Oregon Section 3 - New Mobility Polices & Strategies | Navigating New Mobility | October 2019 | 33 Urbanism Next | University of Oregon 04 | Implications for Gresham and Eugene Navigating New Mobility | October 2019 | 35 Left: Gresham, OR. Right: Eugene, OR Source: University of Oregon, University Communications section Overview Now that we’ve discussed some of the first and second level impacts and common policy topics and approaches taken around the country to address these impacts, the Cities of Gresham and Eugene will need to decide what types of policies they will need to consider and adopt. This final section discusses the existing statewide conditions, as well as the unique attributes of each city, the policy plans to consider, and recommends next steps for each city. STATE OF OREGON New mobility regulations Oregon has few statewide policies or regulations specific to new mobility. Oregon is the only state that does not have statewide TNC regulations, though several bills were introduced in the 2019 Oregon Legislature and failed to pass. In the meantime, jurisdictions must negotiate on a city- by-city basis with TNC service providers. Cities that have adopted TNC regulations are Portland, Eugene, Medford, Salem, Ashland, Bend, and Redmond, among others. The state has no regulations for micromobility (e-scooters or bikeshare) beyond helmet requirements and no riding e-scooters on sidewalks. Planning for Autonomous Vehicles The Oregon Department of Transportation’s (ODOT) Office of Innovation is studying the impacts of autonomous and connected vehicles and released the Emerging Technology Impact Assessment Final Report in March of 2019 (Jacobs, 2019). ODOT plans to engage stakeholders, including Area Commissions on Transportation (ACTs), Metropolitan Planning Organizations (MPOs), and peer state agencies next. 36 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon The Oregon Legislature created the Oregon Automated Vehicle Task Force1 with the passage of HB 4063 in the 2018 legislative session with the purpose of making recommendations on autonomous vehicles to the Legislature. The Task Force was created in May 2018 and its first report focused on licensing and registration, law enforcement and crash reporting, cybersecurity, and insurance and liability was completed in September 2018 (Task Force on Autonomous Vehicles, 2018). The Task Force is planning on submitting a second report to the Legislature in September 2019 that focuses on land use, road and infrastructure design, public transit, workforce changes, and state responsibilities relating to cybersecurity and privacy. Figure 4-1. OreGo tracks mileage–users pay a road usage charge for the amount of miles they drive instead of the fuel tax. Source: OreGo, http://www.myorego.org/ The gas tax and OreGo The University of Oregon and others have conducted research regarding the potential impact of autonomous vehicles on transportation revenues, especially the gas tax. The state of Oregon has one of the longest running road usage charge pilot projects in the country – OreGo. While the pilot project appears to have successfully considered many of the logistical challenges of charging drivers for the vehicle miles traveled, the political will to do something with that information has stalled. That said, HB 2017, a transportation funding bill passed in the 2017 Oregon Legislative session directed the Oregon Transportation Commission to develop a congestion pricing proposal. 1 Note that one of the authors of this report, Becky Steckler, is a member of the AV Task Force. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 37 Gresham, OR Source: https://en.wikipedia.org/wiki/Gresham,_Oregon CITY OF GRESHAM Regional context The City of Gresham is located on the east side of the Portland metropolitan region. Located within Multnomah County and the Metro regional boundaries, it must comply with Metro’s Regional Framework Plan, Urban Growth Management Functional Plan, and the Regional Transportation Plan, as well as applicable statewide policies. Metro has drafted an Emerging Technology Strategy that focuses on issues related to equity, choices, information, and innovation (Metro, 2018). The strategy also discusses the need to convene partners and establish new mobility policies that align with the strategy. The City of Gresham currently has no operating regulations for new mobility services. TNCs operate without a permit, and there is no bikeshare program (docked or dockless) that requires regulations. During the 2018 Portland E-Scooter Pilot, Gresham ordered the e-scooter companies to remove any e-scooters that ended up in Gresham. The rationale for requesting e-scooter vendors to remove them was that Gresham was concerned about how the e-scooters would operate and the possibility they could impede access for people with disabilities or create unsafe conditions in the right-of-way. Because Gresham did not have guidelines or standards developed to address this issue, City officials requested removal of e-scooters that ended up in Gresham. 38 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Policy Scan: Relevant goals, policies, and actions; opportunities, gaps, and recommendations key The City of Gresham’s long-range policies for transportation and land TSP - Transportation System Plan (2014) use currently include many supportive goals, objectives, strategies, and action items that should be considered when developing new mobility ATP - Active Transportation Plan (2018) policies. Urbanism Next researchers conducted a preliminary scan of Gresham’s plans, including the Transportation System Plan (2014), the CP - Comprehensive Plan Active Transportation Plan (2018), and the Comprehensive Plan. Table 4-1 shows the policies, actions, and implementation measures in the plans that are relevant to new mobility. These plans are generally supportive of safety, social equity, active transportation, reducing congestion and VMT, sustainability and environment, design and management of the ROW, and changes in land use and metropolitan footprint that should be incorporated into policies and regulations for new mobility services. As the City considers new mobility goals, policies, and actions, it should make sure that they are designed to achieve city goals. In addition, there are a number of opportunities to expand some specific city policies to address new mobility issues. These are: Active Transportation: Mobility Hubs Opportunity: TSP: Transit System, Policy 3, Action 7 states the City will “Work with TriMet to provide secure and convenient bicycle parking at light rail station and transit centers…” Recommendation: The City may want to consider working with TriMet to develop multimodal mobility hubs similar to Seattle and other jurisdictions that include bikes, e-scooters, and other modes to ease the transition from one mode to the next. Active Transportation: Conflict between modes Opportunity: TSP: Bicycle Network, Policy 2, Action 1 directly supports the need for new mobility services to prioritize active transportation and reduce potential conflicts. Recommendation: The City of Gresham could consider adopting a policy that prioritizes funding for walking, biking, transit, microtransit, and electric modes over conventional gas single- or zero-occupancy modes of travel. Active Transportation: Conflict between modes Opportunity: TSP: Pedestrian System, Policy 1, Action 1 guides Gresham to “design and build sidewalks…free of hazards…” directs the City to ensure sidewalks are unobstructed. Recommendation: This policy language could be expanded to also support new mobility policies which ensure that parked or moving dockless vehicles (like e-scooters) do not obstruct or impede pedestrians. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 39 o p p o r t u n i t i e s & r e c o m m e n d a t i o n s Design and Management of the Right of Way: Street design for new technologies Opportunity: CP: Street System, Policy 4, Action 6 calls for the City of Gresham to consider national guidelines for streets. Recommendation: NACTO created guidance for street design for autonomous vehicles in their publication, Blueprint for an Autonomous Future (2018). The City may want to consider including references to national guidance from this document and other new mobility and AV guides as they are developed. Informed Decision Making: Requiring information Opportunity: CP: Transportation System Management Operations / Intelligent Transportation Systems policy is, “(i)mplement transportation system management operations and intelligent transportation systems programs and strategies that reduce the need for single occupant vehicle (SOV) travel and make walking, bicycling and taking transit more convenient for all trips to and within Gresham.” The City identified technology as one way to gather information and craft strategies to reduce SOVs. Recommendation: This policy is directly applicable to new mobility policies and could be the basis for the City to consider information requirements from the new mobility companies as well as explore opportunities to coordinate with Metro, TriMet, and other public agencies on data collection and analysis to reduce single- and zero- occupancy vehicles, increase active transportation modes, and eventually manage the transportation system based on current, real- time conditions. The City should consider how the data can be used to inform City policies and programs, as well as explore opportunities to share real-time data with the public so they can make informed transportation choices. The most significant policy gaps that are not identified in existing plans that the City could consider are: Social Equity: gap: While the City has numerous goals, policies, and action items related to providing transportation access to communities of concern, there is no specific guidance for access in specific neighborhoods or across the city, payment options for the unbanked, equitable workforce policies, or accommodating people with disabilities. Recommendation: Determine if the City wants to create policies that specifically address equity, and if so (1) identify the geography (specific neighborhoods or the entire city) to focus on for either pilot projects or for deployment of services, (2) determine if the City wants to require new mobility providers to provide non-smartphone/credit card options for payment, (3) determine if the City will require equitable workforce policies (for example, related to contractors that provide services to companies), and accommodating people with disabilities. Given rapidly 40 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon g a p s & r e c o m m e n d a t i o n s o p p o r t u n i t i e s & r e c o m m e n d a t i o n s changing socio-economic trends, the City should develop flexible policies or revisit them regularly to ensure they continue to address the needs of communities of concern. Sustainability and Environment: gap: The City does not have explicit sustainability or environmental policies related to new mobility services, specifically the reduction of GHG emissions. Recommendation: Even absent a Climate Action Plan, the City of Gresham adopted numerous policies and actions items that could result in lower GHG emissions, such as promoting low-carbon modes like walking, biking, and transit, reducing dependence on vehicles, and encouraging compact development close to transit. The City could also consider how these activities could reduce air pollution from vehicles. Finally, the City could take advantage of the opportunities presented by the potential to decrease parking and consider strategies and activities that result in a reduction of on-street parking and improve water quality through stormwater management. Design and management of the right-of-way: gap: The City does not have any regulations related to management of new mobility in the right-of-way, specifically the curb and sidewalk. Recommendation: New mobility impacts suggest that the City will need to take a new approach to managing the ROW and especially the curb, specifically in high demand locations like downtown and MAX stations. The City will need to understand changes in demand for the curb for both passengers and freight and goods delivery. The City should prepare residents and adjacent property owners that changes are likely and work with them, as well as continue to monitor promising practices from across the country, to prepare policies that improve the throughput of people and goods. Changes in land use and metropolitan footprint: gap: The City of Gresham’s policies assume that driving a personally- owned vehicle will be the primary mode of movement in the City. Recommendation: If new mobility does reduce reliance on personally- owned vehicles, then this assumption would need to be updated in transportation and land use plans. The City may need to reevaluate the amount of land zoned for residential, retial, office, and commercial, as well as industrial land to determine if the supply of land is adequate for the demand (especially if much more of the land is available for development instead of parking). The City may want to consider focusing redevelopment and development of parking lots in key districts/neighborhoods and along high-capacity transit routes. In addition, the City should closely monitor e-commerce and experiential retail trends to determine if it needs to re-evaluate the demand for commercial and retail land in the next update of its Comprehensive Plan. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 41 g a p s & r e c o m m e n d a t i o n s Informed decision making: gap: The City of Gresham currently has no goals, policies, or action measures directly related to the collection of data or information from new mobility providers. This information would help the City better understand how the transportation system is being used, as well as how safe the services are, if they are providing affordable services to all Gresham residents, impacts on active transportation, demand for the curb, and other issues. This information is also critical for enforcement of requirements and fees (if applied). Recommendation: The City of Gresham should review the Los Angeles Data Mobility Specifications and work with regional partners (as well as the City of Portland which has adapted this standard to collect data from e-scooter companies), to adopt a data standard for the City. Managing innovation: gap: While the City of Gresham has formal relationships with regional partners (TriMet, Metro, and surrounding jurisdictions), coordination on new mobility services is still evolving. Many larger cities where new mobility deployments are happening first are trying to better manage impacts by conducting pilot projects. The City of Gresham does not have a pilot project process. Recommendation: Gresham’s plans reference the coordination between its policies and regional and state policies, as well as activities to coordinate those activities. Gresham and regional leaders have an opportunity to coordinate more closely and formally on the collection and analysis of data, coordination on policies regulating new mobility providers, as well as coordination and payment standards for new mobility services. It is unclear if there will be enough demand for pilot projects in Gresham, but if there is, the City may want to consider creating a pilot project framework. That said, the City may want to initiate pilot projects to better understand new mobility services on the City of Gresham. It may be appropriate to recruit companies for public/private partnerships to test these services. Fiscal impacts and new mobility revenue: gap: Gresham has no adopted policies that specifically require that new mobility services fund transportation infrastructure and its impact on the transportation system. Recommendation: The City should evaluate different fee options to create a funding mechanism that helps the City achieve its goals, including paying city costs for managing new mobility (permitting, enforcement, evaluation, etc.), paying for the impact on transportation infrastructure and the transportation system, and investments that increase capacity and throughput of people and goods. 42 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon g a p s & r e c o m m e n d a t i o n s Table 4-1. City of Gresham scan of Policies relevant for new mobility key Table 4-1 shows existing policies in the Transportation System Plan, the Active Transportation Plan, and the Comprehensive Plan for the City of Gresham that TSP - Transportation System Plan (2014) relate to new mobility services and should inform policies developed for the operation of those services in Gresham. ATP - Active Transportation Plan (2018) CP - Comprehensive Plan New Mobility City of Gresham policies and Actions Policy Topics TSP: Transportation System Policy 1, Action 1, 4 Policy 2, Action 5 Policy 4, Action 1, 2 The TSP policies related to safety call for providing and promoting a transportation TSP: Street System Policy 1, Action 4, 7 system and options that are safe, Policy 2, Action 4 convenient, and comfortable. Investments Policy 3, Action 5 should focus in part on pedestrian and Policy 4, Action 4 bicycle improvements that connect to Safety TSP: Transit System Policy 4, Action 1, 2 transit and schools. It calls for investments in high-crash locations. The ATP also TSP: Pedestrian System Policy 1, all Actions, 1 calls for increasing safety for walkers and bikers. The Comprehensive Plan calls ATP Revised TSP Policy 1 for using design to reduce speeds and CP: Transportation System Policy 4, Action 1, 2 crashes as well as ensuring the street system supports healthy, active living. CP: Street System Policy 4, Action 3, 4, 5, 6 TSP: Transportation System Policy 1, Action 2 The TSP policies and actions focus on Policy 2, Action 5 responding to “all communities’ needs” TSP: Transit System Policy 2, Action 1 including those identified by residents. The Social Equity Policy 3, Action 3 TSP Transit policies and actions include paratransit service and addressing the TSP: TDM Policy 1, Action 2 needs of the transit dependent such as the elderly, low-income, and people with ATP Revised TSP Policy 7, 8, 9, 10 disabilities. TSP: Transportation System Policy 1, Action 1, 3, 5, 7 Policy 2, Action 2, 4 TSP: Street System Policy 1, Action 1, 2, 3, 4, 5, 7 Policy 2, Action 8, 9 Policy 3, Action 2, 6 Policy 4, Action 4 TSP: Transit System Policy 2, Action 1 Policy 3, Action 4, 6, 7 TSP: Bicycle Network Policy 1, all Actions Policy 2, all Actions, 1 TSP: Pedestrian system Policies 1, 2, 3, all Actions All of the plans identify policies and Active TSP: TDM Policy 1, Action 1, 3 activities to invest in, promote, and Transportation ATP All revised TSP Policies, p 18. otherwise make walking, biking, and transit use safe, convenient, and more CP: Downtown Plan Dist Urban Design Policy 8 accessible in almost all areas of the city. Transp & Con Policy 1, 2; Action 1 CP: Transportation System Policy 1, all Actions CP: Street System Policy 1, all Actions Policy 2, Actions 1, 2 CP: Transit All Policies and Actions CP: Bicycle System All Policies and Actions CP: Pedestrian System All Policies and Actions CP: Community Health and the All Policies and Actions Built Environment Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 43 Table 4-1. City of Gresham scan of Policies relevant for new mobility [cont.] key TSP - Transportation System Plan (2014) ATP - Active Transportation Plan (2018) CP - Comprehensive Plan New Mobility City of Gresham policies and Actions Policy Topics TSP: Transportation System Policy 1, Action 4, 5, 7, 8 TSP: Street System Policy 2, Action 5 The TSP identifies policies and actions Policy 3, Action 2 to reduce automobile dependence Congestion and through support and investment in other TSP: Transit System Policy 1, Action 3 modes. The TDM policies and actions vehicle miles TSP: TDM Policy 1, Action 1 in the TSP and the Comprehensive Plan traveled are designed to reduce congestion and TSP: Truck and Freight System Action 1, 2 VMT. Regarding freight, the TSP identifies the need to design streets to provide for CP: Transportation System Policy 2, Action 6 efficient and safe movements of trucks. CP: TDM All Policies and Actions TSP: Transportation System Policy 1, Action 6 Policy 2, Action 3, 7 TSP: Street System Policy 4, Action 1 The TSP calls for protecting natural resources, improving air and water quality, TSP: Transit System Policy 1, Action 3 promoting energy-efficient or low- and Sustainability zero-emissions vehicles and bicycling, TSP: TDM Policy 1, Action 10 and the transit, and pedestrian modes. The only Environment CP: Air Quality Policy 3, 4 action directly related to GHG emission Action 3, 7 reductions is TSP: TDM Policy 1, Action 10: “Support state and regional programs CP: Water Quality Policy 6 aimed at reducing greenhouse gases and CP: Transportation System Policy 2, Action 7 other harmful emissions.” CP: Street System Policy 4, Action 1 TSP: Transportation System Policy 2, Action 1, 2 TSP: Street System Policy 2, Action 5 Policy 4, Action 4 TSP: Transit System Policy 3, Action 3, 10 Most of the policies and actions in these Design and TSP: Truck and Freight System Policy 1, Action 1 sections refer to multi-modal street design management of and ensuring an “efficient” transportation CP: Comm Design, Trees and Policy 1, 11 system that takes advantage of the the right of way Veg Action 9, 10 existing capacity and makes it more CP: Downtown Plan Dist Urban Design Action 4 efficient. CP: Transportation System Policy 2, Actions 1, 2 CP: Street System Policy 2, Action 5, 7, 8 Policy 3, Actions 3, 4 TSP: Transit System Policy 3, Action 5, 8, 9, 10 CP: Commercial Land Use Policy 1, Implementation 2 Policy 2, Implementation 1, 3 Changes in Most of the policies, actions, and implementation items identified here land use and CP: Industrial Land Use Action 9, 11, 14 are for densities of housing and jobs metropolitan CP: Downtown Plan District Trans & Connection Policy 6; that support transit and the efficient Action 2 development of land, especially in footprint Parks & People Policy 1 downtown and other residential and Economic Development Policy 4 employment districts. Downtown Housing Policy 1, 6 CP: Street System Policy 3, Action 1 44 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Table 4-1. City of Gresham scan of Policies relevant for new mobility [cont.] key TSP - Transportation System Plan (2014) ATP - Active Transportation Plan (2018) CP - Comprehensive Plan New Mobility City of Gresham policies and Actions Policy Topics TSP: Transportation System Policy 4, Action 2 This action is to “monitor high crash Informed locations and types and develop decision making appropriate programs and projects to address problems.” TSP: Transportation System Policy 2, Action 5 TSP: Transit System Policy 1, Action 2 Policy 1, Action 7 Policy 2, Action 1 The TSP identifies the need to “identify creative, non-traditional funding” for TSP: TDM Policy 1, Action 1, 6, 7 transportation, as well as maintaining “the Managing City’s flexibility to take advantage of new CP: Land Use Policy 13 funding opportunities, including public/ innovation private partnerships.” Other policies CP: Transportation System Policy and all Actions Management Operations / highlight working with jurisdictions and Intelligent Transportation Systems TriMet to come up with strategies to increase access to transportation. CP: Political Environment Policy and all Implementation Strategies Fiscal impacts TSP: Transportation System Policy 2, Action 5 and new CP: Land Use Action 7 This policy and action item is to create a Transportation Finance Plan to pay for mobility CP: Transportation System Policy 2, Action 5 transportation in Gresham. revenue Source: Preliminary scan by Urbanism Next of the Transportation System Plan (2014); Active Transportation Plan (2018); and the Gresham Comprehensive Plan. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 45 Eugene, OR Source: University of Oregon, University Communications CITY OF EUGENE Regional context The City of Eugene is located in the Southern Willamette Valley and is the regional center, surrounded by Springfield, Coburg, Veneta, Cottage Grove and other smaller cities. Located within Lane County and a member of the Lane Council of Governments, it actively coordinates with the surrounding jurisdictions and the Lane Transit District on the Regional Transportation Plan and other policy documents. Two new mobility services are available in Eugene: transportation network companies and bikeshare. Uber first started operations in Eugene in 2014 but was forced to stop operations in April 2015 when the city ruled that it must secure a vehicle-for-hire license to continue operations (Hill, 2018). It took until September 2018 for Uber to get back on city streets. Lyft also operates in Eugene. The City of Eugene adopted revised regulations for the operation of TNCs and other public passenger vehicles in the city. Eugene introduced a docked bikeshare system – PeaceHealth Rides – in 2018. Figure 4-2 is a map of bikeshare stations and bikes in Eugene. 46 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Figure 4-2. Eugene bikeshare map, 2019. Note that green dots are bike share stations and blue dots are bikes that are not at stations. Source: PeaceHealth Rides (screenshot from: https://www.peacehealthrides.com/) Policy Scan: Relevant goals, policies, and actions; opportunities, gaps, and recommendations Eugene has a number of long-term plans which contain goals, policies, guidelines, and action items that shape ways transportation services serve and interact with the city. Many of these policies already provide useful guidance on how new mobility services can be incorporated into existing service frameworks, but there are also policies which will need to be changed or updated to ensure they continue to meet the community’s goals in the future. Urbanism Next researchers identified the following plans that will likely be impacted by the introduction of new mobility services, or could be used to influence policies to allow these services in Eugene: Transportation Policies: Eugene 2035 Transportation System Plan (2017) Eugene Vision Zero Action Plan (2019) MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) land use Policies: Envision Eugene Comprehensive Plan (2017) DRAFT Community Design Handbook (2017) environmental Policies: A Community Climate and Energy Action Plan for Eugene (2010) (The City of Eugene is currently updating its Climate Action Plan.) economic Policies: Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 47 Eugene policies These plans articulate goals to improve safety, equity, support and promote active transportation, reduce congestion, vehicle miles traveled, and GHG emissions. The City of Eugene drafted an Urban Design Handbook and has a vision for the urban design of streets that are focused on people, not cars. Any new mobility plans, strategies, and actions the City of Eugene adopts should support these community goals. Table 4-2 summarizes an initial scan of these plans to help highlight current policies and action items that new mobility policies should support. Included in the list are policies and action items that represent opportunities for expansion or elaboration that could help address new mobility policies. These opportunities are: Active Transportation: Modal prioritization Opportunity: TSP: Roadway and Parking Policy 1, the “Complete Streets Policy,” states that “(a) ‘complete street’ allows safe travel for automobiles and emergency responders, bicycles, walking, transit, and freight” but does not specify which of these uses has priority in the street. Recommendation: Establishing a street usage prioritization that caters to the needs of pedestrians, cyclists, transit, and emergency vehicles over personal automobiles could help support safety, active transportation, sustainability, and community livability goals. Design and Management of the Right of Way: Local deliveries Opportunity: The Community Climate and Energy Action Plan for Eugene’s High Priority Action 16.1c calls for a freight transportation system that “(f)acilitates efficient local deliveries” in order to reduce GHG emissions. Recommendation: Given the trend toward increased numbers of local deliveries with the rise in e-commerce orders and courier network service deliveries, this action could be updated to focus on both efficiency in terms of fuel usage and GHG emissions as well as efficiency in terms of facilitating delivery ease via curb management techniques. 48 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon o p p o r t u n i t i e s & r e c o m m e n d a t i o n s Changes in Land Use and Metropolitan Footprint: Park-and- Ride facilities Opportunity: TSP: Transit Policies Potential Action B suggests that the City “(c)oordinate with Lane Transit District (LTD) to expand the park- and-ride system within Eugene’s commute shed with an emphasis in developing partnerships to share existing parking facilities.” The City of Eugene’s policies assume that driving a personally-owned vehicle will be one of the primary modes of movement in the City. Recommendation: If new mobility does reduce reliance on personally- owned vehicles, then this assumption would need to be updated in transportation and land use plans. The City may want to reassess the need for park-and-ride facilities in the long term. The City may want to consider phasing out close-in park-and-rides as personally-owned vehicle use decreases and new mobility services and transit increase. Changes in Land Use and Metropolitan Footprint: Street parking Opportunity: The DRAFT Community Design Handbook Design Smart Parking and Circulation Guideline 1 calls for the City to “(p)rioritize on-street parking” while Guideline 2 encourages the City to “(u)tilize shared-parking strategies within development sites and at the district scale.” Recommendation: New mobility services have the potential to decrease the demand for parking, meaning that prioritizing on-street and shared parking strategies over surface lots will continue to be smart land use strategies. However, the changing nature and increasing demand of curb space by new mobility services could change the demand for spaces currently allocated to on-street parking. Maintaining a mix of parking, loading zones, transit access, and micromobility access along the curb could help balance the demands for these spaces. Informed Decision Making: Data collection Opportunity: TSP: System-Wide Policies Potential Action S calls for the City to “Collect and report crash data for all travel modes…”. Recommendation: Expanding this policy to include broader information about new mobility services, such as trip start and end locations, timing, and other ridership details, could provide the City with the information they need to make their current transportation and transit systems much more efficient and thus better serve their users. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 49 o p p o r t u n i t i e s & r e c o m m e n d a t i o n s The most significant gaps or policy areas that are not identified in existing plans that the City could consider are: Social Equity: gap: While the City has goals, policies, and action items related to providing transportation access to low income, vulnerable, and underserved populations, there is no specific guidance for access, payment options for the unbanked, equitable workforce policies, or accommodating people with disabilities. Recommendation: Determine if the City wants to create policies that specifically address equity. Transportation equity policies can address specific geographic areas or the city as a whole. Policies requiring cash payment options for the unbanked, outlining accessibility requirements for people with disabilities, and equitable workforce conditions for those working as contractors with new mobility service providers are all examples of ways the City can promote equitable practices in a changing transportation landscape. Reduce congestion and vehicle miles traveled: gap: Eugene’s current policies related to congestion do address alternatives to personal automobiles, such as transit and active transportation modes, but lack a way to establish quantitative data on baseline or future use. Recommendation: Adding VMT as a metric for assessing modal split and transportation efficiency would provide a quantifiable means for formulating transportation-related goals and measuring their progress while also promoting non-vehicular modes of travel. Design and management of the right of way: gap: The impacts of newly emerging mobility trends suggest that the City will need to take a new approach to managing the ROW and especially the curb, specifically in high demand locations like downtown and BRT stations. Recommendation: The City will need to understand changes in demand for the curb for both passengers and freight and goods delivery. Accommodating this increased demand can also pair with projected decreases in parking demand, allowing the City to take a fresh look at space allocation throughout the ROW and reassign less efficient uses to those which meet these new and growing demands. Changes in land use and metropolitan footprint: gap: Many of Eugene’s policies already encourage compact urban form, transit-oriented development, and a pedestrian-friendly downtown area, however, these plans assume that personally-owned vehicles will be one of the primary modes of transportation for residents. 50 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon g a p s & r e c o m m e n d a t i o n s Recommendation: New mobility services increase the uncertainty of the demand for parking in the future, which could increase the risk of publicly financed parking structures. The City should conduct a full-risk assessment of any new parking structures, using pricing strategies to help manage the demand for parking in high demand locations, and invest in alternative modes more aggressively to accommodate the demand for access. In addition, the City may want to reconsider minimum parking requirements and consider redevelopment strategies to redevelop parking lots and structures in the future if new mobility services decrease the demand for parking in the future. Informed decision making: gap: The City of Eugene currently does not have any policies that require new mobility service providers to share data with the City. Recommendation: In addition to collecting crash data as suggested under its Vision Zero policies, gathering usage data from new mobility providers will also help Eugene’s City staff understand how they can meet transportation-related safety, mode share, equity, and GHG emissions reduction goals. This information is also critical for enforcement of requirements and fees for new mobility service providers (if applied). The City of Eugene should review the Los Angeles Data Mobility Specifications and review the work of the City of Portland which adapted this standard to collect data from e-scooter companies, to adopt a data standard for the City. Managing innovation: gap: While the City of Eugene has formal relationships with regional partners (Lane Council of Governments, Lane Transit District, and surrounding jusidictions), coordination on new mobility issues is nascent. Many larger cities where new mobility deployments are happening first are trying to better manage impacts by conducting pilot projects. The City of Eugene does not have a pilot project process, but instead has rolled out projects for implementation (bikeshare and TNCs). Recommendation: The City of Eugene should consider if they want to formally coordinate with regional partners. At a minimum, the City should work closely with Lane Transit District as a key partner to achieving community goals. Fiscal impacts and new mobility revenue: gap: Eugene has no adopted policies that specifically require new mobility services fund transportation infrastructure and assess its impact on the transportation system. Recommendation: The City should evaluate different fee options to create a funding mechanism that helps the City achieve its goals, including paying city costs for managing new mobility (permitting, enforcement, evaluation, etc.), paying for the impact on transportation infrastructure and the transportation system, and investments that increase capacity and throughput of people and goods. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 51 g a p s & r e c o m m e n d a t i o n s Table 4-2. City of eugene scan of Policies relevant for new mobility Eugene currently has a wide range of policies that can help shape the growth of new mobility services in ways that meet the goals of its key community, although the strength and approaches of these policies vary by plan document. By reprioritizing and reframing policy language to prioritize TSP - Eugene 2035 Transportation System active transportation, transit, and equitable transportation access, the City Plan (2017) of Eugene could ensure that potentially disruptive new mobility technologies continue to align with the City’s core values pertaining to transportation, VZ - Eugene Vision Zero Action Plan (2019) safety, land use, and GHG emissions reductions. ATS - MoveEUG: Eugene’s Active As the City of Eugene updates and revises its planning documents, Transportation Strategy (2017-2021) establishing a hierarchical transportation mode prioritization could help CP - Envision Eugene Comprehensive Plan unify goals, policies, and actions across the City’s different plans. It will (2017) also be helpful to keep in mind emerging technology trends and how they could impact land use, transportation, urban design, and real estate. The CDH - Draft Community Design Handbook potential reductions in demand for parking, changes in the ways people (2007) shop for and receive goods, and increases in demand for curb space will CCEAP - Community Climate and Energy Action all affect how communities interact with their urban infrastructure. Allowing Plan for Eugene (2010). a degree of regulatory flexibility that does not compromise on established EDP - Regional Prosperity Economic community goals can help the City navigate these changes in ways that are Development Plan: Eugene, Springfield, Lane beneficial for Eugene’s community both in the short and the long term. County (2010) New Mobility City of Eugene Policies and Actions Policy Topics TSP: Transportation System System-Wide Policy 2 System-Wide Potential Actions E, F, G, K, P, S, W TSP: Transit Policies Potential Action A, Item 5 Potential Action C TSP: Roadway and Parking Action B Policies Potential Actions F, K, M TSP: Pedestrian Policies Policy 2 Potential Action B, C Eugene’s policies relating to safety are TSP: Bicycle Policies Policy 2, 3 shaped by the City’s adoption of the Vision Zero program, which strives to TSP: Rail, Freight, and Pipeline Policy 1, 5, 7 reduce injuries and eliminate deaths due Policies Potential Action G to crashes. While the plan is designed to VZ: Strategies All Strategies protect and promote safe walking and bicycling, these modes are not explicitly prioritized over automobiles in the policy Safety VZ: Street Design All Two-year Actions language. Potential Action F within the All Five-year Actions ‘Roadway and Parking Policies’ section VZ: Impairment 2nd Two-year Action of the TSP does note that “plans that state a preference for a mode of travel in a specific location” are “integral parts of VZ: Dangerous Behaviors All Two-year Actions the planning, design, and programming for public streets and rights-of-way” ATS: Action 1 - Education Actions 1.1-1.4, 1.6-1.7, 1.10 and notes bicycles as an example of a designated mode, but does not apply this ATS: Action 2 - Encouragement Actions 2.1, 2.3*, 2.7, 2.9 modal preference within policy language. ATS: Action 3 - Enforcement Actions 3.1-3.4, 3.6, 3.8-3.11 ATS: Action 4 - Engineering Actions 4.1, 4.4, 4.6, 4.12-4.18 ATS: Action 5 - Evaluation & Actions 5.3-5.6, 5.7 Planning CDH: Create a Network of Guidelines 5-8 Complete Streets 52 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Table 4-2. City of eugene scan of Policies relevant for new mobility [cont.] key TSP - Eugene 2035 Transportation System Plan (2017) VZ - Vision Zero Eugene (2017) ATS - MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) CP - Envision Eugene Comprehensive Plan (2017) CDH - Draft Community Design Handbook (2007) CCEAP - Community Climate and Energy Action Plan for Eugene (2010). EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) New Mobility City of Eugene Policies and Actions Policy Topics TSP: Transportation System System-Wide Potential Actions I, Q TSP: Transit Policies Policy 3 Potential Action A, Item 3 TSP: Roadway and Parking Potential Actions F, L Policies TSP: Equity, Economy, and All Policies and Potential Actions Community Engagement Policies VZ: Street Design 7th Two-year Action The City’s TSP features a section entitled Equity, Economy, and Community Engagement Practices that addresses VZ: Dangerous Behaviors 3rd Five-year Action many aspects of social equity in transportation planning. Other TSP Social Equity ATS: Action 1 - Education Actions 1.5, 1.9 sections address ADA requirements, community engagement practices, and ATS: Action 2 - Encouragement Actions 2.9-2.11 the creation of context sensitive solutions, while other documents discuss age- ATS: Action 3 - Enforcement Action 3.7 based transportation needs and the need for fair economies. ATS: Action 4 - Engineering Actions 4.8, 4.12 ATS: Action 5 - Evaluation & Actions 5.4-5.5, 5.8 Planning CDH: Create a Network of Guideline 7 Complete Streets EDP: Strategy 2 Tactic 2.5 Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 53 Table 4-2. City of eugene scan of Policies relevant for new mobility [cont.] key TSP - Eugene 2035 Transportation System Plan (2017) VZ - Vision Zero Eugene (2017) ATS - MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) CP - Envision Eugene Comprehensive Plan (2017) CDH - Draft Community Design Handbook (2007) CCEAP - Community Climate and Energy Action Plan for Eugene (2010). EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) New Mobility City of Eugene Policies and Actions Policy Topics TSP: Transportation System System-Wide Policies 1, 3, 4 System-Wide Potential Actions B, C, E, K, M, O, Q TSP: Transit Policies Policy 1 Potential Action A, Item 5 Potential Action C TSP: Roadway and Parking Potential Actions B, F, K, L, S Policies TSP: Pedestrian Policies Policies 1, 2 All Potential Actions TSP: Bicycle Policies All Policies and Potential Actions TSP: Greenhouse Gas, Climate Policies 3, 4 Change, and Natural Environment Potential Action I Policies Eugene had a robust selection of active transportation policies, actions, and VZ: Strategies All Strategies guidelines. Supporting pedestrian and cyclist activity is an integral part of the VZ: Street Design 1st, 4th, and 7th Two-year City’s TSP and Vision Zero programs Actions and is the basis for MoveEUG: Eugene’s Active Active Transportation Strategy. Support Transportation VZ: Engagement and 5th Two-year Action for active transportation is also found in Accountability 6th Five-year Action the City’s Community Design Handbook and Community Climate and Energy ATS: Action 1 - Education All subactions Action Plan for Eugene, where walking and biking are recognized as key ATS: Action 2 - Encouragement All subactions components in healthy, livable, low- carbon communities. ATS: Action 3 - Enforcement All subactions ATS: Action 4 - Engineering All subactions CDH: Promote Outdoor Lifestyles Guideline 4 CDH: Create a Netowrk of Guidelines 1, 3, 5-9 Complete Streets CDH: Emphasize Walking, Biking, All Guidelines and Riding Transit CCEAP: Objective 13 All High Priority Actions CCEAP: Objective 15 High Priority Action 15.1 54 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Table 4-2. City of eugene scan of Policies relevant for new mobility [cont.] key TSP - Eugene 2035 Transportation System Plan (2017) VZ - Vision Zero Eugene (2017) ATS - MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) CP - Envision Eugene Comprehensive Plan (2017) CDH - Draft Community Design Handbook (2007) CCEAP - Community Climate and Energy Action Plan for Eugene (2010). EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) New Mobility City of Eugene Policies and Actions Policy Topics TSP: Transportation System System-Wide Potential Actions D, M, N TSP: Transit Policies Policy 1 Potential Actions B, C Eugene’s policies related to congestion TSP: Roadway and Parking Policy 5, 6, 7 and VMT are primarily focused on Policies Action A congestion management strategies and Congestion and Potential Actions F, L, M GHG reduction. VMT is not mentioned as vehicle miles TSP: Rail, Freight, and Pipeline Policy 2, 3, 4 a metric for measuring or assessment. The TSP does have language around traveled Policies Potential Action E reducing single-occupancy vehicles and TSP: Greenhouse Gas, Climate Policies 1, 2 promoting non-gasoline powered vehicles Change, and Natural Environment Potential Action A, F in its ‘Greenhouse Gas, Climate Change, Policies and Natural Environment Policies’ section. CCEAP: Objective 14 High Priority Actions 14.2-14.3 CCEAP: Objective 16 High Priority Actions 16.1a, 16.1c TSP: Rail, Freight, and Pipeline Potential Action K Existing policies that relate to Policies transportation and its effects on the environment are found in Eugene’s TSP TSP: Greenhouse Gas, Climate All Policies and Potential Actions and Climate Action plans. The Regional Change, and Natural Environment Prosperity Economic Development Plan Policies Sustainability that applies to Lane County also calls for CCEAP: Objective 10 High Priority Action 10 the support of “of sustainable businesses and that work toward building economies Environment CCEAP: Objective 15 All High Priority Actions that are green, local, and fair.” While the City’s TSP does have a full section entitled ‘Greenhouse Gas, Climate Change, and CCEAP: Objective 17 All High Priority Actions Natural Environment Policies’, there is no metric established for assessing baseline EDP: Strategy 2 Tactic 2.5 and future rates of GHG emissions related to vehicles and transportation. Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 55 Table 4-2. New Mobility Policy Scan, Eugene [cont.] key TSP - Eugene 2035 Transportation System Plan (2017) VZ - Vision Zero Eugene (2017) ATS - MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) CP - Envision Eugene Comprehensive Plan (2017) CDH - Draft Community Design Handbook (2007) CCEAP - Community Climate and Energy Action Plan for Eugene (2010). EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) New Mobility City of Eugene Policies and Actions Policy Topics TSP: Transportation System System-Wide Policy 3 TSP: Roadway and Parking Policy 1 Policies TSP: Transit Policies Potential Action A, Item 5 TSP: Roadway and Parking Potential Action F Policies Many of Eugene’s current planning TSP: Bicycle Policies Potential Action H documents touch on various aspects of street and right of way design. However, Design and VZ: Strategies 1st Strategy, 2nd Strategy, 4th there is no language that addresses Strategy future mobility types or potential changes management of in ROW usage, such as increased curb the right of way VZ: Street Design 1st-8th Two-year Actions demand. Within these policies and 1st-4th Five-year Actions strategies, active transportation modes ATS: Action 1 - Education Actions 1.3-1.4, 1.7 are specifically addressed, but there is no hierarchical assignment of modal priority to guide ROW design and management. ATS: Action 3 - Enforcement Actions 3.6, 3.10-3.11 ATS: Action 4 - Engineering Actions 4.1-4.8, 4.12-4.13, 4.15- 4.18 CDH: Design Smart Parking and Guidelines 1-2, 5, 11-12 Circulation CCEAP: Objective 14 High Priority Action 14.2b TSP: Transportation System System-Wide Potential Action D Eugene’s TSP does recommend the development of local metrics for Changes in CCEAP: Objective 10 High Priority Action 10 assessing changes in land use and the transportation system as a potential land use and action when local trends differ from metropolitan predictions based on national standards. The Community Climate and Energy footprint Action Plan for Eugene establishes the creation of “20-minute neighborhoods” as a land use objective. 56 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon Table 4-2. New Mobility Policy Scan, Eugene [cont.] key TSP - Eugene 2035 Transportation System Plan (2017) VZ - Vision Zero Eugene (2017) ATS - MoveEUG: Eugene’s Active Transportation Strategy (2017-2021) CP - Envision Eugene Comprehensive Plan (2017) CDH - Draft Community Design Handbook (2007) CCEAP - Community Climate and Energy Action Plan for Eugene (2010). EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010) New Mobility City of Eugene Policies and Actions Policy Topics VZ: Strategies 5th Strategy Many of Eugene’s Vision Zero sections VZ: Street Design 8th Two-year Action discuss the need for establishing 4th Five-year Action measurable metrics to assess and monitor current transportation safety Informed VZ: Impairment 3rd Two-year Action as well as inform future decision making. The ‘Evaluation and Planning’ decision making VZ: Engagement and 1st and 3rd Two-year Actions section of MoveEUG: Eugene’s Active Accountability 7th Five-year Action Transportation Strategy also discusses the same as a means of monitoring and ATS: Action 5 All subactions developing safe and viable pedestrian and bicycle networks. CP: Administration Policy 10.8 TSP: Roadway and Parking Potential Action H, I Policies TSP: Pedestrian Policies Potential Action A Eugene’s TSP does recommend different types of user-oriented and VZ: Street Design 3rd Two-year Action system-based technologies to improve traffic safety and encourage transit and CP: Overall Economic Policy 3.6, 3.29 rideshare use as potential actions. The Development Objectives ‘Street Design’ section of the City’s CP: Administration Policy 10.8 Vision Zero program recommends the Managing use of pilot projects for testing and innovation CDH: Design Smart Parking and Guidelines 5, 11-12 assessing potential transportation safety Circulation interventions. More broadly, the Envision Eugene Comprehensive Plan calls for EDP: Strategy 1 Tactic 1.3 responsible economic development that EDP: Strategy 2 Tactic 2.5 aligns with community goals and for the development of a means of assessing how development is aligning with the EDP: Strategy 4 Tactics 4.2, 4.4 city’s more qualitative quality of life goals. EDP: Strategy 6 Tactic 6.1 TSP: Cost Effectiveness and All Policies and Potential Actions The City’s ‘Cost Effectiveness and Fiscal impacts Finance Policies Finance Policies’ section of their TSP calls for looking at full lifecycle costs and new of potential facilities and favoring cost mobility efficiency in transportation systems. Preserving the existing system is a priority, revenue followed by improving efficiency and adding capacity to the system. Source: Preliminary scan by Urbanism Next of the Eugene 2035 Transportation System Plan (2017), Vision Zero Eugene (2017), MoveEUG: Eugene’s Active Transportation Strategy (2017-2021), Envision Eugene Comprehensive Plan (2017), DRAFT Community Design Handbook (2007), Community Climate and Energy Action Plan for Eugene (2010), and EDP - Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County (2010). Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 57 Eugene, OR Source: University of Oregon, University Communications NEXT STEPS The University of Oregon recommends the following next steps for both Gresham and Eugene: Conduct additional research. The University of Oregon’s Urbanism Next and Sustainable City Year Program is conducting a wide variety of research on the potential impacts of new mobility services on city form and development. This research is designed to inform the Cities of Gresham and Eugene as they consider policy responses to new mobility services and in preparation for autonomous vehicle deployment. Staying abreast of the most recent research and promising practices will likely be an ongoing activity for the cities of Gresham and Eugene as the technology evolves. Create new mobility policies. Be prepared to update them frequently. This report lists ten of the most common issues that are addressed in new mobility policies. Neither the City of Eugene’s or the City of Gresham’s land use, transportation, or other policy plans address these issues specifically. Both cities should consider creating overarching new mobility policies to address these ten issues comprehensively. A logical place to start would be to develop new mobility policies and incorporate them into each city’s transportation system plan. These policies would then guide operational and other regulations and inform the development or update of future land use, environmental, economic development long-range plans as well as short-term implementation regulations and programs. Given the rapid pace of technological change, it may be necessary for the Cities to update these policies on a regular basis. Create or amend existing operational regulations. Once the cities have considered and adopted new mobility policies, the next logical step is to create or amend existing operational regulations, such as operating permits. Given the quickly evolving technology for new mobility, operating time frames should be relatively short (one to three years) to allow the cities to adapt to changing circumstances. Track new mobility pilot projects and AV testing. Given that most of the new mobility services and AVs are likely to be introduced in other cities first, there is a lot that can be learned from pilot projects, testing, and new mobility evaluations from other jurisdictions. City staff should track these projects and studies to better understand lessons learned and promising practices that could inform future policy development in the future. Work with regional partners to coordinate and leverage activities with private companies. While the City of Gresham must consider the best policies for the city, it should consider that it may be in a better position to negotiate with private service providers if it coordinates with the City of Portland or, 58 | Navigating New Mobility | October 2019 | Section 4 - Gresham & Eugene Urbanism Next | University of Oregon ideally, the region. The City of Portland is taking the lead in the region to create new mobility strategies and policies that help it achieve its equity, mobility, and other goals. They have been relatively successful at requiring and obtaining information and service from new mobility companies. Working in coordination with Portland and Metro may result in better outcomes for the City of Gresham than they could potentially obtain negotiating on their own. At a minimum, the City of Portland is setting a precedent in the region that Gresham can look to when working with some of the same companies that operate in Portland. The City of Eugene should consider working with its regional partners, including Lane Transit District, Lane Council of Governments, Lane County, and surrounding cities to coordinate on data collection and analysis and to negotiate with private service providers. Activities in the Portland region, as well as other regions across the country such as Denver, may provide lessons learned and useful models. Educate and involve the public and stakeholder groups. New mobility services represent a new way for people and goods to move and will bring change to our neighborhoods and downtowns. Residents need to understand how this could impact their lives and have an opportunity to shape the policies and programs that are developed to address new mobility issues. It is important that lower-income and vulnerable populations are part of the policy making process. Consider studying and updating parking management and regulations. While the demand for parking is likely to change, exactly how and when that change will play out in cities like Gresham or Eugene is unknown. Given this disruption, the Cities could evaluate their current policies and consider steps that will encourage redevelopment near transit. The Cities could also consider how street design could change to accommodate active transportation and new mobility modes, as well as future automation of vehicles. This will require the cities to work closely with their transit agencies and regional partners. Consider changes to design and management of the right-of-way. The cities of Gresham and Eugene should identify some of the neighborhoods and streets with the highest demand for pick-up/drop-off and be prepared to study and adopt management regulations in these areas first. This will likely require the cities to work closely with TNC and taxi companies to ensure their drivers comply with the regulations. In addition, the cities should consider changes at the curb necessary for urban goods and freight and commercial delivery. Begin planning for a significant change in how transportation is funded. It remains to be seen how disruptive new mobility services will be for cities and other governmental agencies that depend on parking revenue, parking and traffic infractions, gas tax, and registration. Cities should monitor changes at airports and larger cities around the United States (such as San Francisco, Seattle, New York, Washington, DC, and others) to see how new mobility services disrupt revenues and expenses as well as policy responses to this disruption. Source: https://www.seattlebikeblog.com/2015/08/25/5th-ave-has-a-new-protected-bike-lane-for-one-block/ Urbanism Next | University of Oregon Section 4 - Gresham & Eugene | Navigating New Mobility | October 2019 | 59 Urbanism Next | University of Oregon A |Appendicies A + B Appendix A: Bibliography Appendix B: The Multilevel Impacts of Emerging Technologies on City Form and Development, Urbanism Next Center, Chapter 2 Navigating New Mobility | October 2019 | 61 Appendix A: Bibliography Brinklow, A. (2018, October 16). City blames half of new congestion on Lyft, Uber. Retrieved December 15, 2018, from https://sf.curbed.com/2018/10/16/17984366/tnc-ride-hailing-uber-lyft-sfcta-report Cabanatuan, M. (2018, April 13). SF scooter problem: City impounds dozens of the two-wheelers - SFGate. Retrieved December 14, 2018, from https://www.sfgate.com/bayarea/article/SF-scooter-problem-City-impounds-dozens-of- the-12832354.php City of Austin. (n.d.). Austin Strategic Mobility Plan: Developing the Draft Policies. Retrieved December 5, 2018, from https:// austin.maps.arcgis.com/apps/Cascade/index.html?appid=66856e8c95244e3b927253fd85878043 City of Chandler. (2018, April 4). ZCA18-0001 City of Chandler/Ride Sharing and Autonomous Vehicles Zoning Code Amendment. City of Chandler. Retrieved from https://www.chandleraz.gov/sites/default/files/documents/imported/ ZCA180001.pdf City of Eugene. (2010a, February 26) Regional Prosperity Economic Development Plan: Eugene, Springfield, Lane County. Retrieved from https://www.eugene-or.gov/DocumentCenter/View/3649/Regional-Prosperity-Economic-Development- Plan?bidId= City of Eugene. (2010b, September) Community Climate and Energy Action Plan for Eugene. Retrieved from https://www. eugene-or.gov/DocumentCenter/View/44051/Community-Climate-and-Energy-Action-Plan-for-Eugene City of Eugene. (2017a, February) Eugene 2035 Transportation System Plan. Retrieved from https://www.eugene-or. gov/3941/Transportation-System-Plan City of Eugene. (2017b, March) Draft Community Design Handbook. Retreived from https://www.eugene-or.gov/2977/ Community-Design-Handbook City of Eugene. (2017c, July) Envision Eugene Comprehensive Plan. Retrieved from https://www.eugene-or.gov/3009/The- Envision-Eugene-Comprehensive-Plan City of Eugene. (2017d) MoveEug: Eugene’ Active Transportation Strategy (2017-2021). Retrieved from https://www.eugene- or.gov/2594/MoveEug-Active-Transportation-Strategy City of Eugene. (2017e) Vision Zero Eugene. Retrieved from https://www.eugene-or.gov/3239/Vision-Zero City of Gresham. (2014) Transporation System Plan. Retrieved from https://greshamoregon.gov/Transportation-System-Plan/ City of Gresham. (2018) Active Transportation Plan. City of Gresham. City of Gresham. (na) Comprehensive Plan. Retrieved December 19, 2018, from https://greshamoregon.gov/Comprehensive- Plan/ City of Portland, Bureau of Transportation. (2018, May). Portland 2035 Transportation System Plan. City of Portland. Retrieved from https://www.portlandoregon.gov/transportation/67263 Clewlow, R., & Mishra, G. (2017). Disruptive Transportation: The Adoption, Utilization, and Impacts of Ride-Hailing in the United States. Institute of Transportation Studies, University of California, Davis. Retrieved from https://steps.ucdavis.edu/ new-research-ride-hailing-impacts-travel-behavior/ Colorado Department of Transportation, Denver Regional Council of Governments, Regional Transportatin District, & Denver Metro Chamber. (2018, November 26). DRAFT Mobility Choice Blueprint. Retrieved from http://www. mobilitychoiceblueprintstudy.com/assets/resources/Mobility_Choice_Blueprint_document_DRAFT_11.26.18.pdf Dalgadillo, N. (2018, November 12). Bird Says New Scooter Regulations Make It “Impossible” to Serve D.C. Retrieved December 5, 2018, from https://dcist.com/story/18/11/12/bird-says-new-scooter-regulations-make-it-impossible-to-serve- d-c/ 62 | Navigating New Mobility | October 2019 | Appendix Urbanism Next | University of Oregon Department of Airports, Los Angeles, CA. (2017). Los Angeles International Airport Annual Financial Report. Department of Airports, Los Angeles, CA. Retrieved from https://www.lawa.org/-/media/lawa-web/lawa-investor-relations/files/2017_lax_ annual_report.ashx?la=en&hash=302D0ECEE68148C6B164ED70D40036814FA58271 District Department of Transportation. (2018, November 5). DDOT Releases New Permit Application for Dockless Vehicles [Government]. Retrieved December 19, 2018, from https://ddot.dc.gov/release/ddot-releases-new-permit-application- dockless-vehicles%C2%A0 Fehr & Peers. (2018). How will autonomous vehicles influence the future of travel? Retrieved December 10, 2018, from http:// www.fehrandpeers.com/autonomous-vehicle-research/ Graehler, M., Mucci, R. A., & Erhardt, G. D. (2018). Understanding the Recent Transit Ridership Decline in Major US Cities: Service Cuts or Emerging Modes? (p. 19). University of Kentucky. Retrieved from http://usa.streetsblog.org/wp-content/ uploads/sites/5/2019/01/19-04931-Transit-Trends.pdf Hand, A. Z., AIA, LEED AP BD+C. (2016, August). Urban Mobility in a Digital Age: A Transportation Technology Strategy for Los Angeles. City of Los Angeles, Office of the Mayor and the Department of Transportation. Hawkins, A. J. (2017, December 12). Not all of our self-driving cars will be electrically powered — here’s why. Retrieved September 7, 2018, from https://www.theverge.com/2017/12/12/16748024/self-driving-electric-hybrid-ev-av-gm-ford Hill, C. (2018, September 4). Uber set to launch in Eugene next Thursday. The Register Guard. Retrieved from https://www. registerguard.com/news/20180830/uber-set-to-launch-in-eugene-next-thursday Jacobs (2019, March). Emerging Technology Impact Assessment Final Report. Prepared for the Oregon Department of Transportation. Kaufman, S. M., Polack, C. F., & Campbell, G. A. (2018). The Pink Tax on Transportation: Women’s Challenges in Mobility (p. 9). NYU Wagner Rudin Center for Transportation. Retrieved from https://wagner.nyu.edu/files/faculty/publications/Pink%20 Tax%20Report%2011_13_18.pdf Kimmelman, M. (2012, January 6). Paved, but Still Alive. The New York Times. Retrieved from https://www.nytimes. com/2012/01/08/arts/design/taking-parking-lots-seriously-as-public-spaces.html Larco, N., Howell, A., Lewis, R., & Steckler, B. (2018). AVs in the Pacific Northwest: Reducing Greenhouse Gas Emissions in a TIme of Automation, 119. Men, C. (2018, September 17). Bird scooters impounded by Santa Cruz, following cease and desist order – Santa Cruz Sentinel. Retrieved December 15, 2018, from https://www.santacruzsentinel.com/2018/09/17/bird-scooters-impounded-by- santa-cruz-following-cease-and-desist-order/ Metro. (2018, June 25). 2018 Regional Transportation Plan - Emerging Technology Strategy (Public Review Draft). Metro. Retrieved from https://www.oregonmetro.gov/sites/default/files/2018/07/02/Metro-Emerging-Tech-Strategy-06-2018-Public- Review-Draft.pdf NACTO. (2017). Blueprint for Autonomous Urbanism (p. 60). National Association of City Transportation Officials. Retrieved from https://nacto.org/wp-content/uploads/2017/11/BAU_Mod1_raster-sm.pdf Portland Bureau of Transportation. (2019). 2018 E-Scooter Findings Report. City of Portland, Bureau of Transportation. Retrieved from https://www.portlandoregon.gov/transportation/article/709719 Schaller, B. (2018). The new automobility: Lyft, Uber and the future of American cities. Retrieved from http://www. schallerconsult.com/rideservices/automobility.htm Schlossberg, M., & Riggs, W. (2018). Rethinking the street in an era of driverless cars. Retrieved from https://cpb-us-e1. wpmucdn.com/blogs.uoregon.edu/dist/f/13615/files/2018/01/Rethinking_Streets_AVs_012618-27hcyr6.pdf Urbanism Next | University of Oregon Appendix | Navigating New Mobility | October 2019 | 63 Seattle Department of Transportation. (2017, September). New Mobility Playbook. City of Seattle. SFCTA. (2017). TNCs today: A profile of San Francisco Transportation Newok company activity. Retrieved from https://www. sfmta.com/sites/default/files/agendaitems/2017/6-20-17%20Item%2014%20Transportation%20Network%20Company%20 Actvity%20Report.pdf Shared Mobility Principles for Livable Cities. (2017, October 17). Shared Mobility Principles for Livable Cities. Retrieved December 4, 2018, from https://www.sharedmobilityprinciples.org/ Sisson, P. (2018a, August 2). Scooter startup Bird plans to fund protected bike lanes. Retrieved from https://www.curbed. com/2018/8/2/17641604/bird-scooter-safety-bike-lane Sisson, P. (2018b, December 7). Scooter City: How Santa Monica, the birthplace of dockless electric scooters, is shaping the multibillion-dollar industry [News]. Retrieved December 13, 2018, from https://www.curbed.com/2018/12/7/18130247/santa- monica-uber-lyft-bird-lime-scooter-bike-app Task Force on Autonomous Vehicles. (2018). 2018 Final Report to the Oregon State Legislature House Bill 4063 Task Force. State of Oregon. 64 | Navigating New Mobility | October 2019 | Appendix Urbanism Next | University of Oregon Urbanism Next | University of Oregon Appendix | Navigating New Mobility | October 2019 | 65 Appendix B: The Multilevel Impacts of Emerging Technologies on City Form and Development, Urbanism Next Center, Chapter 2 In 2018, the University of Oregon’s Urbanism Next Center received a grant from the National Science Foundation to convene experts from around the country to better understand how new mobility, autonomous vehicles, and e-commerce are changing and/or may change city form and development. The goal was to: 1) understand the immediacy of the technology; 2) research the scale of impact from these technological innovations; 3) determine how a diverse range of issues may be connected and impacted; and 4) delineate the important policy and research questions we need to be asking related to city design and municipal administration to maximize the benefits of this new technology while minimizing the negative externalities. As part of this work, Urbanism Next researchers and contributors created the report, Multilevel Impacts of Emerging Technologies on City Form and Development (Urbanism Next Center, 2019). Chapter 2 of Multilevel Impacts summarizes the forces of change, assumptions, first order impacts, and the implications of the forces of change. It forms a baseline of knowledge which this report draws from. 66 | Navigating New Mobility | October 2019 | Appendix Urbanism Next | University of Oregon National Science Foundation Planning Grant Multilevel Impacts of Emerging Technologies on City Form and Development OCTOBER 2019 urbanism next center @urbanismnext urbanismnext.com 6 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 02 | Forces Of Change, Assumptions, First Order Impacts, AND IMPLICATIONS Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 7 02|forces of change Description of forces assumptions Identifying the Forces of Change The proliferation of the smart phone has changed many facets of urban, suburban, and rural life, including how we travel, where we go, and how we make purchases. More specifically, there are three fundamentally disruptive technological forces undergoing simultaneous rapid development and/or deployment: 1. The introduction of new mobility technologies and the associated paradigm shift to thinking of mobility as a service; 2. The continued growth of e-commerce and the related rise in goods delivery; and 3. The anticipated deployment of autonomous vehicles. Source: Fred Joe for Urbanism Next 8 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Introduction of New Mobility Technologies and Shifting Paradigms The introduction of new mobility technol- To illustrate the rapid development of ogies over the past ten years has contrib- new mobility, the International Council uted to an ongoing paradigm shift on Clean Transportation (ICCT) from thinking about mobility as created a timeline to display something we own, such as the milestones achieved between a vehicle, to thinking about mobility 1995 and 2016 (Figure 1) mobility as something we with the pace of change purchase as a service. paradigm shift is accelerating in 2009 with According to the Seattle a shift from thinking the introduction of on- Department of Trans- demand ride services or portation, the term “new about mobility as transportation network mobility” is defined as something we own to companies (TNCs) like the “emerging elements Uber and Lyft. A second of our transportation sys- thinking about it timeline (Figure 2) shows tem that are enabled by as a service we anticipated developments digital technology, shared, driven by real-time and often purchase. and milestones based on announcements from providing curb-to-curb transporta- companies, providers, and other tion,” which entirely changes how people entities. According to projections made and goods move from point A to point B by a variety of companies, the rate of (Seattle Department of Transportation, change we have witnessed over the past n.d.). The intersections of innovation in ten years will continue, although the vehicle and device sharing—spurred by anticipated date of deployment of fully the growth of mobile technology and app automated vehicles remains a moving development—in vehicle automation and target. For instance, Ford, Honda, and electrification is facilitating and amplifying Nissan previously announced that they innovations in mobility (Grosse-Ophoff, plan to have a fully autonomous vehicle Hausler, Heineke, & Möller, 2017). commercially available by 2020; by 2030, IHS Automotive predicts 10.5 million fully autonomous vehicles will have been deployed globally. Whether or not those predictions will come to pass remains to be seen. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 9 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Figure 1. International Council on Clean Transportation’s New Mobility Timeline from 1995 to 2016 (Political Milestones in Blue) Reprinted from “New Mobility: Today’s Technology and Policy Landscape,” by P. Slowik and F. Kamaketé, 2017, Retrieved from https://www.theicct.org/sites/default/files/publications/New-mobility-landscape_ICCT-white-paper_27072017_vF.pdf. Copy- right 2017 by International Council on Clean Transportation. Reprinted from “The New Automobility: Lyft, Uber and the Future of American Cities,” by B. Schaller, 2018, Retrieved from http://www. schallerconsult.com/rideservices/automobility.htm. Copyright 2018 by Schaller Consult Inc. 10 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Figure 1. International Council on Clean Transportation’s New Mobility Timeline from 1995 to 2016 (Political Milestones in Blue) Reprinted from “New Mobility: Today’s Technology and Policy Landscape,” by P. Slowik and F. Kamaketé, 2017, Retrieved from https://www.theicct.org/sites/default/files/publications/New-mobility-landscape_ICCT-white-paper_27072017_vF.pdf. Copy- right 2017 by International Council on Clean Transportation. Reprinted from “The New Automobility: Lyft, Uber and the Future of American Cities,” by B. Schaller, 2018, Retrieved from http://www. schallerconsult.com/rideservices/automobility.htm. Copyright 2018 by Schaller Consult Inc. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 11 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Figure 2. International Council on Clean Transportation’s New Mobility Timeline from 2016 to 2030 Reprinted from “New Mobility: Today’s Technology and Policy Landscape,” by P. Slowik and F. Kamaketé, 2017, Retrieved from https://www.theicct.org/sites/default/files/publications/New-mobility-landscape_ICCT-white-paper_27072017_vF.pdf. Copy- right 2017 by International Council on Clean Transportation. 12 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Figure 2. International Council on Clean Transportation’s New Mobility Timeline from 2016 to 2030 Reprinted from “New Mobility: Today’s Technology and Policy Landscape,” by P. Slowik and F. Kamaketé, 2017, Retrieved from https://www.theicct.org/sites/default/files/publications/New-mobility-landscape_ICCT-white-paper_27072017_vF.pdf. Copy- right 2017 by International Council on Clean Transportation. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 13 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Evolution of Shared Mobility Shared mobility, which refers to it now encompasses not only transit, but transportation services and resources also carsharing, bikesharing, microtransit, that are shared amongst various users ridesharing, and ridesourcing (Federal (Shared-Use Mobility Center, 2019), is Transit Administration, 2016) as well as not a new concept. For instance, public the newest entrant to the field, shared transit is a vital and widespread form electric scooters. McKinsey reported that of shared mobility. However, emerging the shared mobility market in three core technologies that enable the renting markets—China, Europe, and the U.S.— or borrowing of a broader range of was nearly $54 billion in 2016, and in an goods and services instead of owning aggressive growth scenario, the market them are driving an evolution of shared could experience 28 percent annual mobility. According to the Federal Transit growth from 2015 to 2030 (Grosse-Ophoff Administration’s scope on shared mobility, et al., 2017). Figure 4. Locations of Large Station-Based Bikeshare Systems in the U.S. in 2018 (NACTO) Source. Reprint from “Shared Micromobility in the U.S.:2018”, by NACTO.org, 2019, Retrieved from https://nacto.org/wp-con- tent/uploads/2019/04/NACTO_Shared-Micromobility-in-2018_Web.pdf / Copyright 2019 by National Association of City Transpor- tation Officials. 14 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Bikesharing (Dockless and shared bike. Figure 4 shows the locations Docked) of station-based bikeshare systems with 1,000 or more bikes in the U.S. as of 2018 and Figure 5 shows bikeshare ridership in Bikesharing has been in existence for the U.S. from 2010-2019. The majority of over 24 years in North America, and even the increase in bikeshare between 2010- longer in Europe. The earliest bikeshare 2017 was from new dockless systems, programs, which enabled users to access which comprised 44% of all bikeshare a shared bicycle as needed, were part bikes in the U.S in 2017. Dockless bikes of the “first generation of bikeshare” continued to be a popular option through and were free to use. The first bikeshare 2018, but saw a slow in growth due to program to launch in the U.S. was in the introduction of dockless e-scooters Portland, OR in 1994, and two years later, in 2018, which likely replaced some the twin cities of Minneapolis and St. Paul dockless bike trips (NACTO, 2019). launched the first Coin-Deposit system, the first of the “second generation” Electric bikes or e-bikes have also grown bikeshare programs (S. A. Shaheen, significantly in popularity. According to Guzman, & Zhang, 2010). Second a 2018 NACTO report on micromobility, generation bikeshare programs were “cities that added e-bikes to their station categorized, in part, by the incorporation fleets report that, on average, e-bikes are of docking stations, setting them apart used twice as frequently as pedal bikes” from the first generation bikeshare (NACTO, 2019). Global e-bike sales are programs where bikes could be picked up expected to grow from over $15.7 billion and left anywhere. in revenue in 2016 to $24.4 billion by 2025 (Navigant Research, 2016). Since e-bikes Bikeshare has grown rapidly in the can provide a boost to riders by making U.S. since 2010. From 2010 to 2016, it easier to travel further, e-bikes could over 88 million trips were made on a increase the amount of cycling (both bikeshare bike in the U.S., according to number of trips and total distance) and NACTO, or the National Association of affect both commuter and leisure travel City Transportation Officials (NACTO, time (Fyhri & Fearnley, 2015). 2017a). Bikeshare continued growing with 35 million trips in 2017, 25% more than in 2016, and the number of bikes Figure 5. Bike Share Ridership in the U.S. Since 2010 (NACTO) at the end of 2017 (100,000) more than doubled compared to 2016 (NACTO, 2018). Bikeshare further grew in 2018, with a total of 52 million trips on docked, dockless, pedal, and e-bikes combined (NACTO, 2019). Interestingly, dockless systems are somewhat of a return to first generation bikeshare programs since bikes can be deployed with more Source. Reprint from “Shared Micromobility in the U.S.:2018”, by NACTO. flexibility, providing users more leeway org, 2019, Retrieved from https://nacto.org/wp-content/uploads/2019/04/NACTO_Shared-Micromobility-in-2018_Web.pdf / Copyright 2019 by in where they pick up and drop off a National Association of City Transportation Officials. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 15 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Source: car2go Carsharing Similar to bikesharing, it has been over decade, largely due to advancements 20 years since carsharing was first in smartphone technology, and has introduced as an innovative transportation experienced an evolution in the types mode in North America. Carsharing of operational models available. Newer is based on the idea that users can carsharing models include one-way or enjoy the benefits of access to a point-to-point carsharing, peer-to-peer private car without the fixed costs and carsharing where individuals access a responsibilities of owning a car. Most privately owned vehicle fleet through carsharing programs are “a membership- a third party, and fractional ownership based, self-service, short-term car- where individuals co-lease a vehicle access system with a network of vehicles (Shaheen, 2018). for which members pay by time and/or distance” (Lane et al., 2015). The early Free-floating carshare, which enables days of North American carsharing in users to pick up a vehicle and end the the late 1990s grew out of the “station trip anywhere on permitted streets or car” idea where vehicles were made company-marked parking locations, has available at passenger rail stations, and also grown in the past few years. Car2go by 1999 there were nine carsharing was one of first players to try out free- organizations in existence—five in Canada floating carsharing, and by 2018, it had and four in the U.S. (Shaheen, Sperling, grown to over 2 million members across & Wagner, 1999). For more than 15 years, North America, Europe, and Asia with carsharing was run almost exclusively as 14,000 vehicles in 30 locations worldwide roundtrip carsharing, requiring members (Navy, 2018). Traditional automakers such to pick up and return a vehicle from the as BMW entered the U.S. and European same location. However, the carsharing markets with carsharing models such as industry has expanded over the past DriveNow and ReachNow. 16 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Ridehailing or Transportation Network Companies (TNCs) Since 2010, a growing number of private projected to surpass local bus ridership companies have entered the for-hire by the end of 2018 (Schaller, 2018). Their transportation services market offering overall growth is the result of a number new travel options that use app-based of factors, including, of course, the technology to provide on-demand comfort and convenience of direct point- mobility, known collectively as ridehailing to-point service. While TNC ridership or transportation network companies has increased dramatically over the (TNCs). Previously, for-hire vehicles were past few years, taxi ridership has been primarily taxis and users would call a steadily decreasing (Figure 6). TNC wait dispatcher to request a ride. TNCs enable times tend to be substantially shorter passengers to request rides directly than for conventional taxis (Wang, 2015), from drivers who generally use their contributing to their increasing popularity own personal, non-commercial vehicles compared to taxis. Importantly, TNC to transport passengers. TNC services drivers have been found to be significantly generally follow a point-to-point route less discriminatory than taxi drivers and can be dynamically priced based (Brown, 2018). A study of ridehailing in on supply and demand of vehicles, Los Angeles County also revealed that customers, and roadway congestion. TNCs served neighborhoods home to 99.8% of the population (Brown, 2018), TNCs, such as Uber and Lyft, have had providing increased mobility options a dramatic impact on mobility in cities. across all geographies. For example, in the U.S., TNCs were Figure 6. TNC and Taxi Ridership in the U.S., 1990-2017. Reprinted from “The New Automobility: Lyft, Uber and the Future of American Cities,” by B. Schaller, 2018, Retrieved from http://www.schallerconsult.com/rideservices/automo- bility.htm. Copyright 2018 by Schaller Consult Inc. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 17 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Microtransit Microtransit is a relatively new entrant passengers unlike TNCs wherein drivers in shared mobility and mobility on use their personal vehicles. Microtransit demand. It is a form of technology- shuttle services have been offered by enabled “alternative transit” and can have providers such as Bridj, Chariot, and either flexible or fixed routes and flexible Via, although Bridj and Chariot have scheduling. Microtransit vehicles are both ceased their U.S. operations. Via typically smaller than traditional transit continues to operate in the U.S. and has vehicles. Other common features include partnered with cities and agencies to help limited routes or service areas, more fill gaps in the transportation system. Los amenities (i.e., Wi-Fi, and USB outlets), Angeles Metro, for instance, announced in and the integration of big data into their January 2019 that they would partner with operating systems (Fehr & Peers, 2015). Via on a year-long pilot using the private Microtransit service providers typically mictrotransit service with first- and last- own and manage their own fleet of mile connections to major transit stops vehicles and employ drivers to transport (Chiland, 2019). Source: ridewithvia.com/news 18 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Electric Scooters Shared electric scooters, or e-scooters, deployed the micromobility devices in San are among the most recent shared Francisco by April. By the end of 2018, use mobility innovations and were first over 85,000 e-scooters were available introduced in late 2017 in Santa Monica, in over 100 U.S. cities (NACTO, 2019). CA by the operator Bird (Walker, 2018). The market has continued to grow since Like privately owned automobiles and they were first introduced, and the major some bikeshare systems, e-scooters are providers now include Bird, Lime, Spin, another form of dockless mobility. The Skip, Bolt, and Jump, which was acquired momentum for e-scooters ramped up by Uber in 2018. quickly in early 2018, and providers Bird, Lime (formerly LimeBike), and Spin had all Figure 7. E-Scooter Share System Sizes and Locations as of 2018 (NACTO) Reprint from “Shared Micromobility in the U.S.: 2018”, by NACTO.org, 2019, Retrieved from https://nacto.org/shared-micromobili- ty-2018/. Copyright 2019 by National Association of City Transportation Officials. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 19 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Mobility as a Service (Concept and Platform) Mobility as a service (MaaS), or the a bikeshare membership in one payment notion that we purchase transportation rather than having to pay for each service as rides rather than as commodities such separately. Another example of an as cars, is certainly not a new concept integrated service platform is the Whim unto itself—mass transit is a longstanding App, which was created by MaaS Global, and well-established example of MaaS. a company based in Helsinki, Finland. However, the emergence of technology- MaaS Global worked with agencies in enabled new mobility options such as Helsinki to develop an integrated platform ridehailing, microtransit, and e-scooters that enables residents to purchase has helped bring about a paradigm shift mobility service subscriptions that in how we think of mobility. Instead of correspond to their mobility needs. Users one in which vehicles are purchased and who need fewer mobility options (e.g., used for a majority of trips, now rides are modes) can pay a lower fee that provides purchased with the mode of travel chosen unlimited transit and bikeshare rides, but on a trip-by-trip basis. The term MaaS access to carshare and taxis requires an can also be used to refer to a service additional fee. People who need more platform where a trip can be routed, options can pay a higher monthly fee that reserved, and paid for using one app that provides unlimited access to transit and integrates information from a variety of bikeshare, as well as a limited number of services providers. carshare and taxi rides. The Whim App has also been adopted in West Midlands, MaaS can take different forms, including U.K. the opportunity in many cities to choose from among different public and private Paying a flat monthly fee for a suite of mobility providers. Hypothetically, the mobility services is the most advanced range of mobility options could be MaaS platform to date. Another provided by a single entity, public or application of MaaS is a platform that private, offering “transportation services enables users to get information about within a given regional environment that all the ways that a particular trip could provide holistic, preferred and optimal be made, how long each option would travel solutions, to enable end-to-end take, and what the cost would be. In journeys paid for by the user as a single that application, a user could potentially charge” (CUBIC, 2018). There are not yet opt to pick and choose multiple modes many instances where public agencies to reach their final destination instead have integrated multiple services into of just selecting one mode for the entire a single charge, but there are a few trip. More cities have started to pilot examples. TriMet in Portland, OR versions of this type of MaaS platform. launched the Transportation Wallet in Denver, CO launched the Go Denver 2018, which enables users to access an platform in 2017, where users are able annual transit pass, streetcar pass, and to create a profile that matches their 20 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Mobility as a Service (MaaS) The mobility paradigm shift is a shift from thinking of mobility as something one invdividually owns (e.g. owning a vehicle or a bike) to approach mobility as a suite of pay-as-you-use transportation services. arrive: 10:31a (37 min) total: $2.75 The ideal MaaS plataform enables 2min $0 users to get information about all the ways that a particular trip could be made, how long each SMaa 10min $0.25 option would take, what the cost would be, and pay through the app. 25min $2.50 Source: Marsie Surguine for Urbanism Next transportation needs and preferences instance, the Uber app allows users to (International Transportation Service, request a ride in a vehicle, or reserve a 2017). For example, users can select bicycle or an e-scooter by partnering with all their preferred modes and filter out bikeshare operator Jump and e-scooter modes they would prefer not to take, and operator Lime (Siddiqui, 2018a). In this then plan their trips accordingly. LA Metro instance, multiple modes may be utilized announced in August 2018 that they were to complete a single trip, but all of the working on developing a MaaS platform modes are being operated and managed for the Transit Access Pass (TAP) Smart by a single private entity. Card program to make it a one-stop shop for a variety of mobility services, including It is estimated that the MaaS market transit, bikeshare, and ridehailing, with the is expected to grow nearly tenfold option to pay using credit cards or cash from $38.76 billion in 2017 to $358.35 (Musulin, 2018). billion by 2025 (Research and Market, 2018). The acceleration of MaaS and Some private mobility companies have the development of automated services also started to vertically integrate more may help with consumer decision- services for their users. Unlike some making, make travel more seamless of the applications discussed above, and straightforward, and facilitate more such as the Portland Transportation efficient movement by combining various Wallet or the Go Denver platform which modes to form a holistic transport service include multiple service providers, some ecosystem (KPMG, 2017). applications are company specific. For Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 21 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Growth of E-Commerce and Rise of Goods Delivery Another significant force of change supply chains, logistics, the customer is the continued growth of the experience, and last mile delivery (Reddy, e-commerce market, and by extension, 2018). the rise in goods delivery. Like the growth of new mobility technologies, With the growth of e-commerce, the the growth of e-commerce in recent rate of package delivery has increased years is also related to the evolution of substantially, and e-commerce businesses mobile technology. U.S. e-commerce have identified last-mile services as a sales reportedly grew by 16% in 2017 key factor in maintaining a competitive (Ecommerce Foundation, 2017) and advantage. Many retailers have started e-commerce represented 13% of total offering faster delivery service, such as retail sales and approximately 49% of same-day and even hour-based delivery all retail sales growth in 2017 (Zaroban, in order to compete for e-commerce 2018). Figure 7 shows the growth of market share (Bliss, 2018a). According e-commerce between 2000 and 2015. to a report published by McKinsey in More broadly, technological developments 2016, 20-25% of consumers are willing such as Big Data, Internet of Things to pay significant premiums or same-day (IoT), Virtual Reality (VR), Augmented delivery, and by 2020, it is anticipated that Reality (AR), Artificial Intelligence (AI), same-day and instant delivery will reach and automation are also shaping various a combined share of 15 percent of the aspects of e-commerce, changing market (Joerss et al., 2016). Figure 7. E-commerce Sales and Their Share in Total Retail Sales from 2000-2015 (Deloitte) Reprint from “Ring in the new: Holiday season e-commerce sales poised for strong growth”, by Bachman and Barua, 2016, Re- trieved from https://www2.deloitte.com/insights/us/en/economy/behind-the-numbers/holiday-ecommerce-sales-growth-forecast. html 22 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Source: Postmates Courier Network Services In order to meet increasing customer and Deliveroo, have proliferated. These demand for delivery and to expand their services have created an inexpensive market, businesses are using a variety of option for last mile delivery and turned new delivery strategies. Courier network delivery from a small segment of the food services (CNS), or flexible goods delivery, industry (i.e., pizza) to a growing new enable for-hire delivery by connecting source of sales for different types of food couriers with businesses via mobile establishments. apps or online platforms (Shaheen, Chan, Bansal, & Cohen, 2015b). Courier Amazon has also expanded into network services operate similarly to courier service delivery, moving beyond TNCs in that couriers are considered traditional carriers like FedEx and UPS in independent contractors and they order to keep up with growing delivery use their own vehicles or devices to demand. Amazon Flex leverages local, deliver goods and/or food. In the past nonprofessional couriers for package several years, on-demand food delivery delivery. Amazon Flex drivers typically use services, such as Grubhub/Seamless, their own vehicles, similar to other courier Postmates, Doordash, Caviar, UberEats, network services. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 23 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Autonomous Vehicles on the Horizon The force of changes described above are already underway, including the limited deployment of autonomous vehicles. While many factors contribute to the adoption, deployment, and acceptance of autonomous vehicles, it is likely that this next decade will see autonomous ridehailing-type passenger services rolled out, such as those that exist in Phoenix, Arizona. Deployment will not be ubiquitous in all cities, however, as technological challenges will need to be overcome regionally. While the exact speed and scale of AV deployment is uncertain, it is clear their development and use will be disruptive to the existing transportation, real estate, design, and financial structures of cities. Passenger Mobility integrated MaaS strategy, including AVs (Bomey, 2016). Many also believe that Transportation network companies like ridehailing companies like Uber and Lyft Uber and Lyft provide a good model of are currently fighting for market share how autonomous vehicles are likely to and survival as driverless vehicles may be used given their on-demand nature, be key to their profitability (Lekach, point-to-point service, ease in pooling 2019; Siddiqui & Bensinger, 2019). Other customers if desired, and ability to companies, such as Tesla, are betting dynamically price trips. Accordingly, that AVs will simply represent the next understanding the use patterns and generation of the current model of private municipal impacts of TNCs can help vehicle ownership. The future is likely to provide initial insights about anticipated be a mix of these options, varying by city changes. size, location within a metropolitan area, topography, or other factors, but what There is some evidence that AV operators is likely different than what many cities will adopt a MaaS approach rather than a experience currently is that the increase in private vehicle ownership model, although ridehailing with the introduction of AVs is the exact mix of personally-owned versus likely to be significant. fleet-based trip-making is hard to predict at this time. For example, Waymo, the AV technology could allow for the self-driving unit under Alphabet, Google’s emergence of shared autonomous parent company, ordered over 60,000 vehicles (SAVs), which are likely be AVs to be used in its own ridehailing cheaper to take a ride in than human- application in May of 2018 (Boudette, operated ridehailing and taxi services 2018). Ford launched a Smart Mobility since the labor cost of the driver would Unit in 2016, expanding its offerings be eliminated (Litman, 2018)driverless beyond personally-owned vehicles and or robotic. Ford plans to release fully is also heavily investing in a vertically automated vehicles designed for ‘high- 24 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Source: Waymo volume’ commercial uses such as ride- Automation may also have a substantial hailing services by 2021, and General impact on the development of microtransit Motors plans to provide ridehailing initiatives. Many cities are already testing vehicles to its partner Lyft in the form AV shuttles, partnering with operators of fully autonomous Chevy Bolts (Bliss, like EasyMile, Transdev, Navya, and 2017). Audi’s “Own the experience, not May Mobility. Most of these pilots have the car” or Volvo’s “You used to buy occurred on closed courses and private music … the car you can subscribe to” campuses, but some cities are beginning on-demand programs can be seen as to pilot AV shuttles on public streets. OEM’s beta-testing what a shared AV Eventually, autonomous microtransit future could look like. may be able to operate independently of predefined routes just like pooled services The concept of SAVs combines elements in Uber or Lyft, or the algorithms created of conventional car-sharing and taxi/ by microtransit service providers like Via, TNC services, which are known as calculating nearby pickup and drop-off autonomous taxis, “aTaxis,” or “robo- points for passengers (Lang et al., 2017). taxis” (Krueger, Rashidi & Rose, 2016). In addition, autonomous microtransit SAVs may help to facilitate accessibility could help redevelop specialized transit for different sociodemographic groups to potentially reduce travel costs and and for those cannot drive (such as those possibly optimize the efficiency of with disabilities) in either suburban or transport services, making the system urban areas (Litman, 2018)driverless or more convenient, effective, and efficient. robotic. Therefore, autonomous microtransit could increase the demand for and potential to deliver more on-demand products and services (MaRS, 2016). Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 25 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Goods Delivery Both long-haul freight and last-mile as well as food. Amazon has also been delivery may prove to be natural developing its own self-driving delivery applications for driverless vehicles. robot, Scout, which it has been testing Autonomous trucking is already in in neighborhoods around Seattle, WA development and Otto, an autonomous (Vincent, 2019). trucking company now owned by Uber, made the first automated truck delivery Goods delivery also will likely not be using public roads in the United States in limited to ground transportation in 2016 (Isaac, 2017). Companies, such as the future. The U.S. Department of Daimler, Volvo, and others, are developing Transportation announced in 2018 that it autonomous trucks and long-haul freight had chosen a combination of 10 states, will likely be among the first widely local, and tribal governments and a deployed use cases of autonomous handful of companies, including Alphabet, technology. FedEx, Intel and Uber to work together on commercial drone testing (Bloomberg, Last-mile delivery is also a natural 2018). Chinese e-commerce business application of autonomous technology, JD.com has been starting same-day and the self-driving startup Nuro has delivery of online orders in 100 rural already partnered with the grocery chain villages in China using 40 teleoperated Kroger to pilot small, self-driving vehicles drones, which are 70% cheaper and for grocery deliveries in Scottsdale, AZ faster than the manned vehicle alternative (Dickey, 2018). The City of Scottsdale has (Smart, 2018). Additionally, in April 2019, allowed Nuro to utilize public roads for the U.S. Federal Aviation Administration their delivery vehicles. Other companies (F.A.A.) issued its first approval to Wing, have also been working to develop Alphabet’s drone-delivery unit, to pilot small, self-driving robots for last-mile package delivery in parts of Virginia. As delivery that travel on sidewalks. Starship autonomous vehicle technology continues Technologies is one such company that to advance, it is estimated that they will has been piloting its robots in places like be used in up to 80% of parcel delivery, Washington, D.C., Redwood City, CA, and saving nearly 40% in delivery costs Milton Keynes, U.K. to deliver packages (Joerss et al., 2016). 26 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Demographic Shifts There are many simultaneous changes In addition to this, young people, happening in society that will have especially Millennials, are less likely than significant impacts on the form and older generations to become licensed function of cities. In tandem with the drivers (Cortright, 2016a), and they tend technological advancements described to live in more walkable areas or areas above, we are also seeing demographic equipped with more active transportation shifts in household preferences for options. Also, emerging technologies housing and transportation. Young people are providing new ways of experiencing aged 20 to 30 are less likely to move from information in urban space. Young central cities to suburbs than a decade people tend to adopt technologies (i.e., ago (Cortright, 2016b; Dutzik, Inglis, & smartphones, ridehailing) faster than Baxandall, 2014). As we move more and other age cohorts: research shows that more towards a “knowledge economy” it people age between 25 and 34 have the is worth noting what Richard Florida wrote highest usage of TNCs compared to other in 2017: age groups (Schaller, 2018). According to Pew Research Center, 92% of Millennials Today, clustering, not dispersal, own smartphones, compared with 85% powers innovation and economic of Gen Xers, 67% of Baby Boomers, growth. Many people still like living and 30% of the Silent Generation (Jiang, in suburbs, of course, but suburban 2018). As the younger generations age growth has fallen out of sync with and the newest generation, Generation the demands of the urbanized Z, grows into adulthood, we will likely see knowledge economy …. The suburbs greater adoption rates as a share of the aren’t going away, but they are total population because the technology no longer the apotheosis of the needed to hail new mobility services will American Dream and the engine of be more ubiquitous. economic growth (Florida, 2017). Young people aged 20 to 30 are less likely to move from central cities to suburbs than a decade ago. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 27 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Assumptions About Autonomous Vehicles Two key assumptions underpin much of previous studies’ estimations, private this report: 1) AVs are much more likely vehicle ownership rates for AVs could be to be deployed as MaaS fleets than as dramatically reduced if fleets of AVs are privately-owned vehicles; and 2) the owned and operated by TNCs (Fagnant majority of these vehicles will quickly & Kockelman, 2014; Pofuk, 2017). In a become electric. simulated model, researchers found that a shared fleet of AVs could incur 11% more At this point in time, fleet ownership of travel compared to non-shared vehicles AVs appears more likely than widespread because they would be more consistently personal ownership, at least in the in service, but they also suggest that near-term. While a ride in an AV may be the fleet could save participating users cheaper than a ride in a TNC today, AVs ten times the number of private vehicles will likely be expensive to purchase due they would otherwise need (Fagnant & to the high cost of production, as well as Kockelman, 2014). Also, low-cost SAVs the need to maintain some control over in urban areas might encourage people, updates needed by the vehicle’s operating especially younger urbanites, to reduce system. While private vehicle ownership personal vehicle ownership. Therefore, rates may stay close to the same for the carmakers may be more committed to foreseeable future, it is likely that rates ridehailing and carsharing services today, will fall once fully autonomous vehicles prioritizing fleets over personal vehicle become readily available and people ownership (The Economist, 2018). increasingly favor on-demand automated ridehailing-type services over private ownership (Pofuk, 2017). According to Source: Waymo 28 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Source: Electric Vehicles Only by Mary and Angus Hogg https://ccsearch.creativecommons.org/photos/cef90bee-0423-40ce-803a-61b3afc1129c Our second assumption is that AVs will be electric or gas will likely depend on will likely be electric, though whether their continued technological development they will be all-electric is still uncertain. and their overall market penetration. Steffen Hoffmann, Bosch’s U.K. president projected that by 2025, 15% of vehicles Automakers such as Volkswagen (VW) are worldwide will an electric component (an developing battery electric EVs capable all-electric vehicle, a plug-in hybrid, or of super-fast charging by plugging into full hybrid; J. Silver, 2017). Companies machines that provide 250-450 kw/h will likely adopt electric cars faster than as opposed to the current 150 kw/h individual owners and using electricity machines. Additionally, researchers are instead of gasoline could have significant pursuing commercially viable inductive fuel cost savings. For instance, an electric charging, which would allow a vehicle to vehicle can save $750 -$1,200 per year park over a pad and receive the charge in fueling costs compared to a gasoline- through the air. This second innovation powered vehicle (averaging 27 miles per is seen as important to the future of AVs gallon and $3.5 per gallon for fuel cost; allowing the vehicles to pull into a parking Anair & Mahmassani, 2012). Whether AVs area and charge themselves. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 29 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions First Order Impacts The following discussion describes the broad ways that the form and function of cities are being impacted by the forces of change identified above. This section provides a foundation for the following chapters, which dive into the cascading impacts that the forces of change may have more specifically on land use, urban design, transportation, and real estate, and the resulting implications of those impacts for equity, health, the environment, the economy, and governance. Change in Parking Demand In the United States, it is estimated that of the two most common reasons TNC the average car is parked 95% of the users give for taking a TNC is because time (Shoup, 2011), and while estimates destination-area parking is difficult of the total number of parking spots (Clewlow & Mishra, 2017). differ, they generally agree that we have far more parking than we need. In 2018, Airports, in particular, have seen parking one researcher used a combination of demand change since the introduction data sources, including satellite data, of TNCs. According to a 2018 study to calculate exactly how many parking that analyzed data from four regional spaces exist in five U.S. cities—New U.S. airports, including Portland, San York, NY; Philadelphia, PA; Des Moines, Francisco, Denver, and Kansas City, IA; Seattle, WA; and Jackson, WY—and airport parking revenue per passenger found that only in New York City were peaked approximately 12-24 months there more homes than parking spaces after the introduction of TNCs and has (Peters, 2018). Seattle, however, averages since steadily declined (Henao, Sperling, more than five spaces per household Garikapati, Hou, & Young, 2018). The and Jackson averages more than 27 data suggest that, taken together, the spaces per household. Increasingly airports show an annualized declining cities are recognizing that parking has rate of 3-7%. At that rate, parking been overbuilt and underpriced, and demand at these airports could be cut the emergence of TNCs and other new in half in approximately 14 years. In mobility services are already impacting order to manage the increased demand parking demand in some places, such for curbside pick-up and drop-off many as dense downtown areas and areas airports have created designated TNC with concentrated nightlife (Morris, passenger loading zones and have 2018; Steele, 2018; Zipkin, 2017). One instituted trip fees. 30 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change The introduction of AVs could further it is also expected that AVs will be able reduce the demand for parking and will to park more efficiently than conventional likely impact a greater variety of place vehicles. A 2018 study estimated that AV types beyond heavily urbanized areas and car-parks, which could have multiple rows airports. The use of SAVs in the future of stacked vehicles, could decrease the could further diminish parking demand need for parking space by an average of since it is anticipated that SAVs will spend 62% and potentially up to a maximum of more time transporting passengers and 87% of the space that’s designated for much less time parked than conventional parking today. (Nourinejad, Bahrami, & vehicles. Not only will AVs/SAVs be able Roorda, 2018). to spend more time on the road overall, Airport parking revenue per passenger peaked approximately 12-24 months after the introduction of TNCs and has since steadily declined. This suggest that, taken together, the airports show an annualized declining rate of 3-7%. At that rate, parking demand at these airports could be cut in half in approximately 14 years. Henao, A., Sperling, J., Garikapati, V., Hou, Y., & Young, S. (2018). Airport Analyses Informing New Mobility Shifts: Opportunities to Adapt Energy-Efficient Mobility Services and Infrastructure (No. NREL/CP-5400-71036). Retrieved from National Renewable Energy Laboratory website: https://www.nrel.gov/docs/fy18osti/71036.pdf Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 31 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Change in Vehicle Miles Traveled Recent studies have found that vehicle Based on existing studies, AVs could miles/kilometers traveled (VMT) has in- contribute to an increase in travel demand creased over the past several years and due to a variety of factors including, some of that growth has been attributed but not limited to: increased mobility to the rise of TNCs. In a 2017 UC Davis options for certain populations (people study on ridehailing, researchers Clewlow with disabilities, elderly, etc.); induced and Mishra asked respondents to answer demand (people choosing to take trips the question, “If Uber and Lyft were they otherwise may not have taken); unavailable, which transporta- and people choosing to travel tion alternatives would you to destinations that are use for the trips that you At 5% market further away because the make using Uber and penetration mode of travel is more Lyft?” Twenty-two per- AVs comfortable. These cent of respondents could increase VMT factors could potentially said they would have depending yield additional VMT just made fewer trips from 5-20% if they hadn’t used a on facility class, and because more trips may be generated TNC (Clewlow & Mish- could reach as high and more locations/ ra, 2017). Since Uber destinations may be and Lyft were an option, as 35% with 95% accessible (Childress et however, these respondents penetration. al., 2015; Correia et al., opted to take a vehicle trip 2016). Gucwa (2014) reported that they would otherwise would that VMT could increase between not have made. This is not necessarily a 4-8% by applying different scenarios of bad thing since it may be that TNCs are road capacity and value of time changes filling transportation gaps and addressing through the introduction of AVs. Bierstedt issues of latent demand by expanding and colleagues (2014) estimated that at mobility for underserved populations, as 5% market penetration AVs could increase research findings suggest (Brown, 2018). VMT from 5-20% depending on facility class, and could reach as high as 35% with 95% penetration. 32 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Even if SAVs function as a form of public & Kockelman, 2014). In another simulation transportation and replace conventional, study of SAVs in a mid-sized U.S. city, the private vehicles, some studies have also author found that overall VMT (for SAVs) suggested that SAVs may still increase would increase due to the need to detour VMT and generate more congestion in and reposition vehicles for drop-off and urban areas. One study found that SAVs pick-up (Schaller, 2017b). could increase travel distance by 10% compared to non-SAVs and also suggest that total VMT would increase in part because of the number of out-of-service trips (e.g., zero-occupancy trips; Fagnant Source: Maximilian Watcher for Unsplash. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 33 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Change in Congestion Note: This section pulls from the AVs could contribute to increased Urbansm Next report “AVs in the Pacific congestion resulting from a combination Northwest: Reducing Greenhouse of induced and latent demand, and mode Gases in a Time of Automation” (August replacement (e.g., a person choosing 2018). Several studies examining the to take an AV instead of walking or impacts of TNCs on congestion have biking). However, the potential exists for concluded that TNCs are contributing to AVs to help decrease congestion since increased congestion (Gehrke, Reardon, AVs have the ability to travel in closer & Felix, 2018; San Francisco County proximity than human-driven vehicles Transportation Authority, 2017; Schaller, can today, resulting in shorter headways 2017a). Researchers at the Metropolitan and narrower travel lanes. Such an Area Planning Council in Boston found improvement of free-flow capacity and that 15% of ride-hailing trips are adding flow stability could decrease congestion, cars to regional roadways during morning though such efficiency gains will depend and afternoon rush hours (Gehrke et upon the penetration rates of connected al., 2018). In San Francisco, researchers and autonomous vehicles (Talebpour & concluded that on a typical weekday Mahmassani, 2016). However, in planning TNCs are averaging 570,000 VMT, which for a fully autonomous environment we they consider to be a conservative will be presented with the option of seeing estimate. In comparison, they estimate these potential efficiency gains directed that taxis in San Francisco generate towards either: 1) using the same amount 66,000 VMT on a typical weekday of roadway as today to allow for greater (San Francisco County Transportation vehicle throughput, or 2) keeping current Authority, 2017). There are two important vehicle throughput and directing the contributing factors: in-service VMT, or “efficiency gains” towards other modes the distance traveled while transporting such as transit, walking, and biking a passenger, and out-of-service VMT, or through the reallocation of space. the distance traveled during circulation periods. With the current model of TNCs, If AVs are able to travel more efficiently those circulation periods represent single- than conventional vehicles, delays and occupancy trips but with fully automated travel costs could be reduced. This vehicles, those same trips are likely to be could make travel more affordable and/ zero-occupancy, or “zombie” trips, with or attractive to those whose trips were no people in the vehicle. previously suppressed, thus generating additional traffic. A simulation study in Of course, levels of traffic congestion Boston found that introducing AVs and vary from place to place and city to city, SAVs into the city could improve travel and relate to a variety of factors including time for the city overall, but could still “population density, road capacity, increase congestion, as well as travel time choice of alternative modes of travel, in the downtown area (World Economic and traffic management technologies Forum, 2018). use” (Metz, 2018). On the one hand, 34 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Change in Ease of Travel While AVs are predicted to induce trips could shift as commute time is liberated and increase congestion within central from needing to focus on driving. cities (Fagnant & Kockelman, 2014; 2018), studies have predicted that AVs might The National Association of Realtors increase the speed of travel to and from yearly survey of housing preferences suburban and exurban areas (International (Dill, 2015) has consistently reported Transport Forum, 2015; Patel, Levin & a dominant preference for larger lots, Boyles, 2016) as they take advantage of proximity to open space, and proximity to the potential speed increases on low- nature. If it becomes easier to reach areas conflict roads such as suburban arterials, further in the periphery that have these highways and freeways. This would properties, individuals—without the limits allow travelers to reach further into the imposed by our current transportation periphery of cities while maintaining their system— may preference these properties current commute time. over ones closer to the center. If commute times become less important and travel Currently, average commute time in the speeds increase, the need for labor to United States is approximately 26 minutes be near employment, and vice versa, each direction per day (U.S. Census may be reduced. This could free up Bureau, 2017). Although this number has both residential and employment lands remained fairly consistent in recent years, for development based on other criteria this might change with the usage of AVs such as lower land costs, limited land as this new technology allows comuuters use constraints, and limited neighbor to shift our use of time from driving to a opposition. range of activities such as social media, working, eating, or sleeping. Thus, it Set against this, however, are the is conceivable that individuals might preferences, described in Richard accept a slightly longer commute time Florida’s book “The Rise of the Creative than they have now as travel time gains Class” (2002), that knowledge economy utility and is not seen as a lost part of the workers consistently prefer environments day (Harb, Xiao, Circella, Mokhtarian, & with a “vibrant quality of place” and Walker, 2018). While there are conceivable “an abundance of things to do,” which absolute limits to the time individuals will typically favors denser urban areas. spend on their commute, a slight increase Recent trends point to Millennials in acceptable travel time, combined with (those born between 1981 – 1997), as the increased travel speeds offered by AV a demographic that is more diverse suburban commutes, could allow travelers than previous generations, less likely to to reach even further into the periphery be homeowners, and more interested of cities. Marchetti’s Constant, or the in intergenerational housing typology, notion that approximately 30 minutes of which is typically not found in outer travel time has remained the consistently suburbia (Choi, Zhu, Goodman, Ganesh, acceptable range across modes, eras, or & Strochak, 2018; Y. Lee, Lee, & Shubho, geographic locations (Marchetti, 1994), 2019). Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 35 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Shift in Modes Travel behavior theory suggests that the have seen transit ridership grow in the last decision to use one mode over another is year because they have invested in tran- informed by a variety of factors including, sit focusing on core high-capacity routes but not limited to, socioeconomic status, (Lindblom, 2018; Kerr, 2018). age, the price of gas, urban form, and the availability of transportation options. In a The growth of TNCs in the last several 2016 white paper published by Circella years has impacted travel behavior and and colleagues, researchers analyzed the preliminary research suggests that TNCs National Household Travel Survey (NHTS) are among the factors impacting transit and found that while the total number of ridership (Graehler Jr., Mucci, & Erhardt, person trips increased between 2019; Manville et al., 2018). In a 1995 and 2009, mode distri- Boston-area study conducted bution shifted away from by the Metropolitan Area vehicles and the per- Planning Council (MAPC), centage of person trips those who ride researchers found that made by car decreased (Circella, Tiedeman, transit more often are weekly or monthly transit pass holders are Handy, Alemi, & more likely to drop it for substituting TNCs for Mokhtarian, 2016). ride hailing, even while transit more frequently, Buehler and Hamre and that those “who found that Americans doing so at a huge cost ride transit more often became increasingly multimodal during that differential. are more likely to drop it for ride hailing, even while same time period (Buehler doing so at a huge cost & Hamre, 2015). However, differential, and even when several more recent reports they have already paid for the found that transit ridership is de- transit” (Gehrke et al., 2018). creasing in most major U.S. cities, which may be attributed to a variety of factors TNCs may also be replacing trips that including, but not limited to: a sustained otherwise would have been made by period of economic growth following the walking and biking. Using weighted data, Great Recession; the rise of transporta- Clewlow and Mishra found that only 39% tion network companies; higher rates of of trips made using Uber and Lyft would car ownership; neighborhood change and otherwise have been made by car (i.e. migration patterns related to displace- drive alone, carpool, or taxi; Clewlow & ment and gentrification; and declining gas Mishra, 2017). The majority of trips would prices (Manville, Taylor, & Blumenberg, otherwise not have been made at all, or 2018; Siddiqui, 2018b). There are a few would have been made by walking, biking, notable exceptions, including both Seat- or transit. Transit services being too slow, tle, WA and Vancouver, B.C.; both cities not having enough stops or stations, 36 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change and not having service at times needed SAVs or on-demand driverless shuttles were the primary reasons respondents could dramatically reduce costs cited for substituting ridehailing for transit associated with the first- and last-mile (Clewlow & Mishra, 2017). These findings portions of a trip, which could serve to are corroborated by MAPC in Boston. complement transit use. But a shift to According to MAPC researchers, 42% of SAVs could impact mode choice and the people they surveyed indicated they spur some to switch from an active would otherwise have taken public transit mode to an SAV. Research findings on for their trip and an additional 12% said this topic suggest that up to 10% of they would have walked or biked (Gehrke travelers could switch from walking and et al., 2018). cycling to AVs (Childress et al., 2015; Davidson & Spinoulas, 2015). Also, If AVs offer lower travel costs, potential researchers project that if AV operating modal shifts may occur depending on trip costs decrease by 50% and perceived distances and purposes (LaMondia et al., travel time costs decrease by 10-50%, 2016). According to LaMondia’s study, at public transportation and walking and certain AV travel time valuations, the cost cycling would decrease by 14% and 11% of travel may not be a significant factor respectively. Truong and colleagues (2017) and as the perceived travel time benefits assume that if vehicle occupancy rates from driverless cars rise, monetary costs remain unchanged and mode shifts from may become less important. Lower public transportation and active modes to operating costs, lower costs of parking, AVs occur, vehicle trips would increase by increased roadway capacity, and a over 7%. reduced perceived cost of travel could incentivize a mode shift to AVs (Fulton, Mason, & Meroux, 2017). This assumes, however, that other elements of the transportation system, such as transit frequency and reliability, remain similar to or the same as they are today. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 37 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Competition for the Right-of-Way (ROW) The public right-of-way, which need to consider several components, encompasses the sidewalk, curb, and including loading zones, paratransit and street, plays a vital role in creating an accessibility loading, metered parking efficient transport system. Demand for spots, bus stops, and passenger drop- this limited space has been increasing off zones (NACTO, 2017c). Because AVs over the past several years with the may be able to travel more efficiently than introduction of TNCs, the increase conventional vehicles, ROW could be in urban delivery, the expansion reallocated to other modes. Street design of bikesharing programs, and the in an autonomous future could place more deployment of e-scooters. As a result, emphasis on walking, biking, and transit, managing the competing demands for as well as helping to establish safer this space is increasingly complicated. If speed limits, and allowing the curbside AVs proliferate, an increasing number of to be flexible for public and private uses pick-up and drop-off areas may become (NACTO, 2017b). necessary. Curb management for AVs will GREENING PERSONAL VEHICLES PUBLIC TRANSPORTATION BIKESHARE/E-SCOOTER ACTIVE TRANSPORTATION STORAGE TNC FREE G PARKIN The t of gh C os i n g H e Pa rki Fre PALD SH OU DON TNC ELECTRIC CAR RIDE-HAILING CHARGING PARKING COURIER SERVICES UTILITIES FREIGHT/GOODS DELIVERY STREETERIES Multiple uses of the right-of-way (ROW). Source: Michelle Montiel for Urbanism Next. 38 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Changes in Goods and Meal Delivery With the continued growth of e-commerce and restaurants may choose to deliver coupled with the advent of AV their products via driverless methods to technologies, goods delivery will likely cut down on last-mile delivery costs. It continue to increase to meet consumer also seems likely that the demand for demand. The automation of technology restaurant delivery will continue to grow. will make it easier to haul goods over UberEats, for example, has expanded to long distances by road, air, and sea. In 280 cities in a four-year period between a recent survey, 49% of shoppers said 2014 and 2018 (Kludt & Geneen, 2018). that same day shipping would make them Some restaurants now operate as more likely to shop online; however, only delivery-only in order to reduce the 15% of global retailers offer same-day costs associated with running an eat-in delivery (Asper, 2017). Therefore, on- establishment, or use shared commissary demand delivery provided by AVs may kitchens for food preparation for delivery- help to grow current and future goods only meals. delivery. More brick-and-mortar retailers Source: Starship Technologies Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 39 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Shifting Nature of Freight AV technologies have the potential to tethered electronically and overseen by profoundly impact many aspects of the one driver could significantly reduce the freight industry and may help to tackle cost of point-to-point linehaul journeys current issues that the industry faces, (Gibbs, 2017). Several companies that such as labor shortages and high rates are working on developing autonomous of driver turnover. With new technology trucks, including Uber’s advanced platforms, autonomous trucks could Technologies Group, are relying on a become integrated into the logistics “transfer hub” model. In this model, chain, potentially providing players across long-haul autonomous trucks stop at the supply chain with more transparent transfer stations in order to exchange information about the status of goods trailers with conventional trucks, which shipments and movements. Highly are then operated by local drivers automated, driverless, or fully-automated to their final destinations (Clevenger, trucks may also help increase the speed 2018). Automation could improve freight of delivery, since the need for driver rest efficiency and capacity, which would periods would be reduced or nullified, reduce transportation costs, and possibly, and distribution routes could be planned the cost of the goods themselves. Further differently (Flämig, 2016). Also, the ability reductions in the cost of delivery could to have autonomous trucks operate also lead to an increase in the demand for in a “platoon” with multiple vehicles goods delivery. Changes in Demand for Warehousing Space Package and parcel volumes have Industrial Forecast Report predicts that by continued to accelerate year-over-year the end of 2019, 782 million square feet of with the continued growth of e-commerce new warehouse space will have entered (Synchrony Finance, 2016). As a result, the North American market (Cushman companies are choosing to localize & Wakefield, 2017). Technological warehousing construction so that supply developments provide opportunities chains and logistics are moving closer to for businesses to make efficiency consumers in order to increase efficiency improvements, and smart warehousing (Cerasis, 2018). The North American solutions may become the core model. 40 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Reduction of Certain Types of Brick and Mortar Stores As e-commerce business has expanded, shuttering: Payless announced that it more mall retailers and department stores planned to close more than 2,500 stores have shuttered around the country. U.S. after filing for bankruptcy in February stores closings totaled over 5,000 in 2017, 2019 (Peterson, 2019). In order to stay and there were nearly 4,100 store closures competitive, traditional brick-and-mortar in the first half of 2018 alone, more than retailers have started or expanded their double the 2,000 openings in the same own e-commerce operations. Wal-Mart timeframe (Cheng, 2018; Timmermann, Stores, Inc. spent $3.3 billion to take over 2018). More than 8,000 stores are e-commerce start-up Jet.com and Wal- expected to close in the U.S. by the end Mart’s U.S. e-commerce sales climbed of 2019 (Peterson, 2019). Chains like 63% in the second quarter in 2017 Macy’s, Best Buy, and Payless have been (Bowman, 2017). Increasing Interest in Experiential Retail While some types of brick-and-mortar Experience-driven retail appeals to retail have been struggling to compete consumers who strongly favor in-store with e-commerce, other types of retail, shopping experiences to online shopping. especially “experiential retail,” have They prefer a unique experience that been flourishing. Experiential retail differentiates their spending and they favors immersive, interactive, and often, are willing to pay 32% more (on average) technology-enhanced experiences for for that experience (Synchrony Finance, consumers (Ruff, 2019). The most familiar 2016). With the introduction of AVs, the “experiential retail” environment is likely need for parking will likely be reduced, the Apple Store. Apple Stores emphasize and delivery costs may go down, further the “experience” with the physical exacerbating these retail trends. Auto- environment replicating the sleekness of oriented strip malls and big-box stores its product. Since the first Apple Store may face more shrinkage as consumers opened in 2001, other retailers have opt to travel to experiential retail but seen the value of this retail model, which order household goods and other items typically requires a smaller footprint, online. According to one study, customer and are gradually using it to replace experience will overtake price and the traditional large footprint big-box product as the key brand differentiator experience. by 2020 and 86% of consumers will pay more for a better experience (Walker Consultants, 2013). Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 41 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Implications of the Forces of Change and First Order Impacts The forces of change and first order impacts previously described are largely focused on the built environment and how city form and function is changing. The following section explores what the implications of these changes may be for equity, health, the environment, the economy, and governance. Equity Access to Mobility Income Disparity New mobility technologies and the other Today’s income disparities are at an forces of change discussed above could outsize level, with the richest 0.1% holding have positive equity implications, but it is the same amount of wealth as the bottom also possible that these changes could 90% of the population (National League further exacerbate existing inequities in of Cities, 2017). The emergence of new transportation and mobility access (Asenjo transport technologies may exacerbate et al., 2017). On the one hand, AVs have the geographic inequality as higher-income potential to expand mobility for people who populations have more opportunities to have been underserved, such as people choose where they live, and AVs could with disabilities, seniors, low-income contribute to further stratification. Also, populations, and people living in areas higher-income earners stand to gain with limited modal options. On the other greater financial benefits from adopting hand, many new mobility technologies time-saving modes of transport, such require access to smartphones, data as AVs, and they will likely be early and plans, and credit/debit cards, and have more widespread adopters (McLaughlin, very few, if any, language options. Lower- 2017). Additionally, AVs could potentially income populations may not have the eliminate some middle- and low-wage same access to technology and credit as jobs, such as in the trucking industry, higher-income populations. According to and may displace workers who drive a Federal Deposit Insurance Corporation for a living, further exacerbating income survey (2018), 8.4 million U.S. households disparity. were unbanked in 2017, and an additional 24.2 million were underbanked, meaning that they obtained some financial services outside of the banking system. As a result, new mobility technologies including AVs could further widen the gap of access to mobility across different income groups and geographical areas. 42 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Wealth Creation Workforce Impacts Mobility is a crucial component of The commercial deployment of AVs may employment access, which is inextricably have serious and far-reaching workforce linked to wealth creation. A lack of reliable impacts. One group of workers that may and efficient transportation options is a be displaced by AVs are truckers and significant barrier to upward economic for-hire drivers. The World Economic mobility (Chetty, Hendren, Kline, & Saez, Forum estimates that the confluence of 2014). New mobility technologies have the automation technology could displace potential to improve services, efficiency, approximately 5.1 million jobs across and quality of life if they are implemented 15 major economies by 2020 (World equitably (National League of Cities, Economic Forum, 2018). Depending on 2017). the rate of adoption, autonomous trucks and cars could directly eliminate 1.3 to Displacement 2.3 million workers’ jobs over the next 30 years in the United States (Groshen, Helper, MacDuffie, & Carson, 2018). New mobility can accelerate growth in Groshen and colleagues estimate that a city. However, if services are limited this could raise the annual unemployment to certain areas, they may contribute to rate by 0.1% and lower the overall increasingly expensive housing in those labor participation rate annually. Even if areas as demand increases, potentially technological advancements have the resulting in displacement of certain potential to create thousands of new jobs, populations. There has been some many of the new roles that are created will evidence to suggest that this been the require higher skills and education, which case around transit stations, with property can be a barrier to retraining displaced values increasing in these areas (Buyahar, employees for those positions. 2019). New transportation technology, along with redevelopment of space and urban design, may mainly attract— and focus on serving—higher income populations who can afford to live in the places with those services. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 43 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Health Level of Physical Activity Safety AVs and other new mobility technologies AVs could dramatically reduce the number could have positive and/or negative of automobile-related injuries and fatalities implications for public health depending that occur annually. Since human error on a variety of factors, including the rate contributes to 90% of crashes, AVs could and manner of AV deployment, as well as significantly reduce crash rates (Fagnant decisions made by city officials regarding & Kockelman, 2014). AV technology will the built environment. Some cities may allow vehicles to incorporate machine use the introduction of AVs to modify their learning, such as safety data, and urban and street design to make cities comprehensive risk predictions through more encouraging of active transportation sensors, cameras, radars, etc., which modes, such as walking and biking. This could help increase safety. In addition, would increase the levels of physical the potential for increased road capacity activity and its associated health benefits. and flow stability, as is anticipated by Moreover, a dramatically reduced demand AVs, may be conducive to improving road for parking may result in parking lots safety. However, it is difficult to assess being redeveloped in ways that could how safe autonomous vehicles are or make streets and cities become more will be given limited data about those compact, which would promote active currently in deployment, as well as the transportation (Richland, Lee, & Butto, relative nascence of the technology. There 2016a). However, if AVs reduce the cost are also varying levels of automation. of travel to the point where the reliance Automated vehicles that share some on the automobile for travel further responsibility with human operators, such increases, this could negatively impact as Level 3 AVs, may require intervention physical activity and increase sedentary in emergency situations. This could make behaviors (Ding et al., 2014). With AVs, decision-making more as opposed to less people may also be willing to commute complex and could negatively impact road longer distances, which could exacerbate safety (International Transport Forum, sprawl, reduce physical activity, and 2018). expand built form that lacks access to active transportation. 44 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Exposure to Pollution Mental Health AVs may help reduce dependence on There are several ways that AVs may fossil fuels if they are primarily electric, as impact mental health. First, the potential anticipated. Compared to current driving improvement of road safety could possibly patterns, AVs will likely be able to drive lessen the stress experienced by road more efficiently, with less stopping and users. For people in vehicles, they may starting and fewer crash-induced traffic be less likely to stress about common jams (Richland et al., 2016a). Reduced commuting woes such as congestion if emissions would positively impact AVs free up that time for activities other public health and could lower rates of than driving. AVs could also increase respiratory-related illnesses and deaths. access to places for social interaction and However, as discussed previously, AVs social support by increasing access to may also increase VMT/VKT which may mobility, particularly for populations that not offset pollution reduction even if the are currently underserved by the current efficiency of driving is improved, in part transportation system, such as elderly because they will share the road with populations and people with disabilities. conventional vehicles for many years. In a study that simulated potential AV use by providing 13 households with an on- demand chauffeur for a week, researchers found that the retiree cohort increased their VMT, the number of long trips taken, and the number of evening trips taken the most compared to the other cohorts (Harb, Xiao, Circella, Mokhtarian, & Walker, 2018). Additionally, the potential opportunities for placemaking due to a reduction in parking (e.g., more parks and green space), and the potential for air quality improvements due to the adoption of electric AVs could be conducive to mental health (Rojas- Rueda, 2017). However, another study suggests that isolated travel periods could limit social interaction, which could have negative impacts on mental health (Boniface et al., 2015). Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 45 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Access to Healthy Food Access to Health Care In addition to cities assisting with the AVs also have the potential to provision of access to healthy food increase access to health care if they through spot zoning, AVs may increase provide expanded mobility options, access to healthy foods. New delivery particularly for low-income populations, models could decrease the time and cost seniors, and people with disabilities. of delivery services, which may benefit Transportation barriers can result in those who cannot afford cars or other missed appointments and poor health types of mobility, or who are unable to management (Cronk, 2015). Researchers travel. However, whether AVs will be in New York surveyed nearly 700 low- transformational for these populations income people living in suburban areas in need will depend, in part, on how and found that nearly one-quarter the cost of accessing AVs compares to had missed a medical appointment other transportation options, such as or been forced to reschedule due to mass transit or emerging on-demand taxi transportation difficulties (D. Silver, services, as well as the physical proximity Blustein, & Weitzman, 2012). Limited to goods and services (Richland, Lee, & transit schedules and routes can be Butto, 2016b). barriers to accessing health care. On- demand transportation services that are characterized by more flexible routing may help to mitigate some of these barriers. A pilot project conducted from June through November 2019 in Columbus, OH will provide free, on-demand rides to health care appointments for low-income expectant mothers (Bliss, 2018b). The extent to which AVs are able to increase access to health care will, of course, depend on their affordability and other factors. 46 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Economy Shift in Industries/Labor the restaurant industry. Additionally, a reduction in parking demand could Many industries may face upheaval if they reshape the urban landscape, which will are not able to adapt to the changes that likely impact those involved in real estate. AVs will bring to the market. According AVs will most likely be deployed as fleets to CB Insights, fast food, real estate, rather than private vehicles, at least early military operations, and even industries on, which may have the effect of turning like home improvement (approximately car dealerships into AV fleet support and 33 industries), will shift their strategies service centers. Autonomous technology in the wake of driverless cars (CB also requires data centers and high-speed Insights Research, 2018). The demand connections to support the infrastructure for insurance may decrease as the risk of AV systems, potentially generating new of car crashes drop, and insurance jobs in information technology and data companies may shift business strategies, analysis. such as charging based on the number of miles are driven. Driverless technology may also further expand food delivery services and make delivery operations more efficient, which could further impact Many industries may face upheaval if ther are not able to adapt to the changes AVs will bring to the market. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 47 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Environment Greenhouse Gas Emissions Particulate Pollution The broad deployment of AVs has the Studies examining the environmental potential to reduce greenhouse gas benefits of electric vehicles compared emissions (GHG) if AVs are primarily to conventional vehicles have generally electric, as anticipated. One study found found that EVs offer net positive benefits that AVs with electric power-trains have (Requia, Mohamed, Higgins, Arain, lifetime greenhouse gas emissions that & Ferguson, 2018) which could help are 40% lower than vehicles powered policymakers in the objective of making by internal-combustion engines (Gawron road transportation more sustainable et al., 2018). Replacing conventional, and environmental friendly. This study gasoline-powered vehicles with electric provides a comprehensive review of the AVs will likely reduce GHGs, but the effects of EVs adoption on air quality, deployment of AVs will also likely happen greenhouse gas emissions, and human in stages. As a result, AVs are expected to health. Specifically, we (i. However, EVs share the road with conventional vehicles have been shown to have a greater for years. If the cost of traveling is lowered impact on ground-level ozone (O3) than by AVs and VMT/VKT increases, as fine particulate matter (PM2.5; Schnell previously discussed, this could have the et al., 2019). Additionally, Schnell and effect of increasing GHGs since there colleagues found that the source of would be more vehicles on the road electricity for EVs exhibits greater control overall. over PM2.5, which suggests the impacts of electric AVs on particulate pollution could be more regional and dependent on the local fuel mix. 48 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Quality and Extent of Habitat The potential positive and negative impacts of AVs on air quality and ecosystems are based on the assumptions mentioned above. AVs also have the potential to change and reshape urban areas and how people use space. More people may choose to live further from cities because the travel (monetary and time) costs may be reduced, which could further exacerbate sprawl. This may affect biodiversity and other species’ habitats without land use planning policies to protect natural/farmland areas and restrict development. However, should the potential for improvements to streets and the public realm in cities be realized this could make urban living more attractive, thus offsetting some of the potential induced sprawl. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 49 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Governance Government Structure and Municipal Revenues and Hierarchy Finance Different levels of government have AVs could have profound impacts on different roles in the regulation of AVs. government revenues. According to a The federal government is responsible survey by Governing of the 25 largest U.S for regulating motor vehicle design, cities, cities took in a total of nearly $5 safety, and equipment. According to billion in the 2016 fiscal year from parking- USDOT, the role of the U.S. Department related activities (56%), camera and traffic of Transportation is “acting as a convener citations (12%), gas taxes (14%), towing and facilitator, partnering with a broad (2%), and vehicle registration and licensing coalition of industry, academic, states and fees (13%; Governing, 2018). These local, safety advocacy to support the safe revenue streams could be immediately development, testing, and deployment and directly affected by AVs as a result of automated vehicle technology” of decreasing car ownership, reduction in (USDOT, 2018). The National Highway sales tax revenue from local auto dealers, and Transportation Safety Administration the proliferation of hybrid and electric (NHTSA) released guidelines that offer vehicles, reduced demand for parking, best practices for state legislatures about and a decrease in the number of citations incorporating standard safety-related issued. The loss of municipal revenue elements regarding AV systems into due to the pervasive effects of AVs will their legislation (NHTSA, 2017). At the likely impact policy, planning, investment, state level, the role includes regulating and design decisions by public agencies, other aspects such as insurance and private business, investors and the public liability, enacting new traffic laws (e.g., at large (Clark, Larco, & Mann, 2017; Clark speed limits), licensing requirements, & Lewis, 2018; Clements & Kockelman, vehicle registrations, safety inspections, 2017). Faced with potentially significant etc. Local government is responsible reductions in revenue due to EVs, AVs, for dealing with the immediate, on-the- and new mobility in general, cities will ground effects of autonomous vehicles, likely need to strategize on how to recover such as parking, street design, and curb those revenue holes. management. 50 | Multilevel Impacts of Emerging Technology | Chapter 02 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change AVs could lead to entirely new mechanisms for collecting revenue from transportation. Governments may enact strategies to develop alternative revenue streams to offset the loss of fuel tax, such as introducing a VMT tax to replace revenue lost from gas taxes and parking (T. Lee, 2016), taxing SAVs, pricing the curb, etc. A new regulatory structure may pose different privacy and data concerns compared to the current structure. Data and information from TNCs and logistics industries can help cities adjust pricing regulations by managing the supply and demand spatially and temporally. The flip side may be that the potential for greater efficiencies of AVs could reduce current projected needs for infrastructure. Urbanism Next | University of Oregon Chapter 02 | Multilevel Impacts of Emerging Technology | 51 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 52 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 08 | CITATIONS Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 53 02|forces of change Description of forces assumptions Anair, D., & Mahmassani, A. (2012, June). Anair_2012_State of charge-EV’s global warm- ing emissions and fuel-cost savings across the US.pdf. Retrieved from https:// www.ucsusa.org/clean-vehicles/electric-vehicles/emissions-and-charging-costs- electric-cars Asenjo, I., Dively, C., Edwards, M., Ettensohn, Z., Goldstein, J., Gupte, G., … Matvey, D. (2017). Autonomous Vehicles and Transportation Equity in Pittsburgh. Asper, D. (2017). Daniel_2017_The timely guide to on-demand delivery.pdf. Retrieved from https://www.shopify.com/guides/on-demand-delivery/same-day-delivery Bachman, D., & Barua, A. (2016). Ring in the new: Holiday season e-commerce sales poised for strong growth. Retrieved August 24, 2018, from Deloitte Insights web- site: https://www2.deloitte.com/insights/us/en/economy/behind-the-numbers/holi- day-ecommerce-sales-growth-forecast.html Bierstedt, J., Gooze, A., Gray, C., Peterman, J., Raykin, L., & Walters, J. (2014). Effects of next-generation vehicles on travel demand and highway capacity. 31. Bliss, L. (2017). Self-driving cars will be for sharing. Retrieved August 8, 2018, from CityL- ab website: http://www.citylab.com/tech/2017/01/the-future-of-autonomous-vehi- cles-is-shared/512417/ Bliss, L. (2018a). The future of suburban retail looks worse than you realize. Retrieved August 9, 2018, from CityLab website: https://www.citylab.com/transporta- tion/2018/03/a-ticking-time-bomb-for-suburban-retail/554882/ Bliss, L. (2018b, December 27). An Uber for Expectant Mothers Is Coming to Columbus. Retrieved July 22, 2019, from CityLab website: https://www.citylab.com/transpor- tation/2018/12/smart-city-columbus-prenatal-ride-hailing/579082/ Bloomberg. (2018, May). Uber Plans to Test Food Delivery by Drone. Retrieved August 16, 2018, from Fortune website: http://fortune.com/2018/05/10/uber-food-delivery- drone/ Bomey, N. (2016, March 11). Ford forms “smart mobility” division. USA TODAY. Retrieved from https://www.usatoday.com/story/money/cars/2016/03/11/ford-smart-mobility- ride-sharing-self-driving-cars/81636682/ Boniface, S., Scantlebury, R., Watkins, S. J., & Mindell, J. S. (2015). Health implications of transport: Evidence of effects of transport on social interactions. Journal of Trans- port & Health, 2(3), 441–446. https://doi.org/10.1016/j.jth.2015.05.005 54 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Boudette, N. (2018, May 31). Waymo to Buy Up to 62,000 Chrysler Minivans for Ride-Hailing Service—The New York Times. Retrieved from https://www.nytimes. com/2018/05/31/business/waymo-chrysler-minivans.html Bowman, J. (2017). 1 Year Later, Wal-Mart’s Jet.com Acquisition Is an Undeniable Suc- cess. Retrieved August 9, 2018, from The Motley Fool website: https://www.fool. com/investing/2017/10/03/1-year-later-wal-marts-jetcom-acquisition-is-an-un.aspx Brown, A. (2018). Ridehail Revolution: Ridehail Travel and Equity in Los Angeles [Disserta- tion]. University of California Los Angeles. Buehler, R., & Hamre, A. (2015). The multimodal majority? Driving, walking, cycling, and public transportation use among American adults. Transportation, 42(6), 1081– 1101. https://doi.org/10.1007/s11116-014-9556-z Buyahar, N. (2019, May 2). L.A. homes near mass transit often sell for more, a study finds. Retrieved August 23, 2019, from Los Angeles Times website: https://www.latimes. com/business/realestate/hot-property/la-fi-hp-transit-homes-premium-price- 20190502-story.html CB Insights Research. (2018, May 24). 33 Industries Other Than Auto That Driverless Cars Could Turn Upside Down. Retrieved August 29, 2018, from CB Insights Research website: /research/13-industries-disrupted-driverless-cars/ Cerasis. (2018). The top logistics trends that will impact logistics management in 2018. Retrieved from Cerasis website: https://cerasis.com/wp-content/uploads/2018/02/ The-Top-Logistics-Trends-that-Will-Impact-Logistics-Management-in-2018.pdf Cheng, A. (2018). Brick-And-Mortar Retail Isn’t Dead: Just Look At Who’s Moving Into Empty Toys “R” Us Stores. Retrieved August 9, 2018, from Forbes website: https:// www.forbes.com/sites/andriacheng/2018/07/08/brick-and-mortar-retail-is-far-from- dead-just-look-at-whos-moving-in-to-replace-toys-r-us/ Chetty, R., Hendren, N., Kline, P., & Saez, E. (2014). Where is the Land of Opportunity: The Geography of Intergenerational Mobility in the United States. Quarterly Journal of Economics, 129(4), 1553–1623. Chiland, E. (2019, January 28). Metro tests Uber-like service to get riders to and from stations. Retrieved June 4, 2019, from Curbed LA website: https://la.curbed. com/2019/1/28/18201146/metro-via-microtransit-ride-app Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 55 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Childress, S., Nichols, B., Charlton, B., & Coe, S. (2015). Using an activity-based model to explore the potential impacts of automated vehicles. Transportation Research Record: Journal of the Transportation Research Board, (2493), 99–106. Choi, J. H., Zhu, J., Goodman, L., Ganesh, B., & Strochak, S. (2018). Millennial Home- ownership: Why Is It So Low, and How Can We Increase It? Retrieved from Urban Institute website: https://www.urban.org/research/publication/millennial-homeown- ership/view/full_report Circella, G., Tiedeman, K., Handy, S., Alemi, F., & Mokhtarian, P. (2016). What Affects U.S. Passenger Travel? Current Trends and Future Perspectives. National Center for Sustainable Transportation, UC Davis. Retrieved from https://escholarship.org/uc/ item/2w16b8bf Clark, B., Larco, N., & Mann, R. F. (2017). The Impacts of Autonomous Vehicles and E-Commerce on Local Government Budgeting and Finance. University of Oregon. Clark, B., & Lewis, R. (2018). Future Transport and City Budgets: Getting Bottom-Line Savvy In An Uncertain Future. In Toward Just and Sustainable Mobilities: Driverless Cars, Transport Innovation, and the City of Tomorrow (Edited by William Riggs). Routledge. Clements, L. M., & Kockelman, K. M. (2017). Economic Effects of Automated Vehicles. Transportation Research Record: Journal of the Transportation Research Board, 2606(1), 106–114. https://doi.org/10.3141/2606-14 Clevenger, S. (2018, June 8). How Drivers and Autonomous Trucks Could Work Together to Move Freight | Transport Topics. Transport Topics. Retrieved from https://www. ttnews.com/articles/how-drivers-and-autonomous-trucks-could-work-together- move-freight Clewlow, R., & Mishra, G. (2017). Disruptive Transportation: The Adoption, Utilization, and Impacts of Ride-Hailing in the United States. Retrieved from https://steps.ucdavis. edu/new-research-ride-hailing-impacts-travel-behavior/ Correia, C., Milakis, D., van Arem, B., & Hoogendoorn, R. (2016). Handbook on Transport and Urban Planning in the Developed World. https://doi. org/10.4337/9781783471393 Cortright, J. (2016a). Are Millennials Racing to Buy Cars? Nope. Retrieved August 9, 2018, from Streetsblog USA website: https://usa.streetsblog.org/2016/04/25/are-millenni- als-racing-to-buy-cars-again-nope/ 56 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Cortright, J. (2016b, October 18). City Observatory—The price of parking. Retrieved Au- gust 6, 2018, from City Observatory website: http://cityobservatory.org/the-price- of-parking/ Cronk, I. (2015, August 9). The Transportation Barrier. The Atlantic. Retrieved from https:// www.theatlantic.com/health/archive/2015/08/the-transportation-barrier/399728/ CUBIC. (2018). Mobility-as-a-Service (MaaS). Retrieved August 14, 2018, from https:// www.cubic.com/innovation/insights/mobility-service-maas Cushman&Wakefield. (2017). North American Industrial Forecast Report 2018-2019. Re- trieved August 9, 2018, from http://www.cushmanwakefield.us/en/research-and-in- sight/2017/na-industrial-forecast-report Davidson, P., & Spinoulas, A. (2015). Autonomous vehicles: What could this mean for the future of transport. Proceedings of the Australian Institute of Traffic Planning and Management (AITPM) National Conference, Brisbane, Australia. Dickey, M. (2018, August). Nuro and Kroger are deploying self-driving cars for grocery delivery in Arizona today. Retrieved August 16, 2018, from TechCrunch website: http://social.techcrunch.com/2018/08/16/nuro-and-kroger-are-deploying-self-driv- ing-cars-for-grocery-delivery-in-arizona-today/ Dill, J. (2015). 2015 National Community and Transportation Preference Survey. Nation- al Association of Realtors and Transportation Research and Education Center at Portland State University. Ding, D., Gebel, K., Phongsavan, P., Bauman, A. E., & Merom, D. (2014). Driving: A Road to Unhealthy Lifestyles and Poor Health Outcomes. PLOS ONE, 9(6), e94602. https://doi.org/10.1371/journal.pone.0094602 Dutzik, T., Inglis, J., & Baxandall, P. (2014). Millennials in motion: Changing travel habits of young Americans and the implications for public policy (p. 51). Retrieved from https://uspirg.org/sites/pirg/files/reports/Millennials%20in%20Motion%20USPIRG. pdf Ecommerce Foundation. (2017). Global E-commerce Report 2017. Retrieved August 9, 2018, from https://www.mazars.com/Home/News/Our-publications/Sur- veys-and-studies/Global-E-commerce-Report-2017 Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 57 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Fagnant, D. J., & Kockelman, K. M. (2014). The travel and environmental implications of shared autonomous vehicles, using agent-based model scenarios. Transporta- tion Research Part C: Emerging Technologies, 40, 1–13. https://doi.org/10.1016/j. trc.2013.12.001 Fagnant, D. J., & Kockelman, K. M. (2018). Dynamic ride-sharing and fleet sizing for a system of shared autonomous vehicles in Austin, Texas. Transportation, 45(1), 143–158. https://doi.org/10.1007/s11116-016-9729-z Federal Deposit Insurance Corporation. (2018). 2017 FDIC National Survey of Unbanked and Underbanked Households Executive Summary. Retrieved from Federal Depos- it Insurance Corporation website: https://www.fdic.gov/householdsurvey/ Federal Transit Administration. (2016). Shared Mobility Definitions [Text]. Retrieved from FTA website: https://www.transit.dot.gov/regulations-and-guidance/shared-mobili- ty-definitions Fehr & Peers. (2015). Microtransit. Retrieved August 8, 2018, from Fehr & Peers website: http://www.fehrandpeers.com/microtransit/ Flämig, H. (2016). Autonomous Vehicles and Autonomous Driving in Freight Transport. In M. Maurer, J. C. Gerdes, B. Lenz, & H. Winner (Eds.), Autonomous Driving: Tech- nical, Legal and Social Aspects (pp. 365–385). https://doi.org/10.1007/978-3-662- 48847-8_18 Florida, R. (2002). The Rise of the Creative Class. New York: Basic Books. Florida, R. (2017, May 2). The New Suburban Crisis. Retrieved June 6, 2019, from CityL- ab website: https://www.citylab.com/housing/2017/05/the-new-suburban-cri- sis/521709/ Fulton, L., Mason, J., & Meroux, D. (2017). Three revolutions in transportation: How to achieve the full potential of vehicle electrification, automation and shared mobility in urban transportation systems around the world by 2050. Retrieved from Institute for Transportation & Development Policy website: https://www.itdp.org/wp-content/ uploads/2017/04/UCD-ITDP-3R-Report-FINAL.pdf Gawron, J. H., Keoleian, G. A., De Kleine, R. D., Wallington, T. J., & Kim, H. C. (2018). Life Cycle Assessment of Connected and Automated Vehicles: Sensing and Computing Subsystem and Vehicle Level Effects. Environmental Science & Technology, 52(5), 3249–3256. https://doi.org/10.1021/acs.est.7b04576 58 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Gehrke, S., Reardon, T., & Felix, A. (2018). Fare Choices: A Survey of Ride-Hailing Pas- sengers in Metro Boston. Boston: Metropolitan Area Planning Council. Gibbs, P. (2017). How autonomous vehicles will impact on the supply chain. Retrieved from Automotive Logistics website: https://automotivelogistics.media/opinion/au- tonomous-vehicles-will-impact-supply-chain Governing. (2018). Special Report: How Autonomous Vehicles Could Constrain City Budgets. Retrieved August 13, 2018, from http://www.governing.com/gov-data/ gov-how-autonomous-vehicles-could-effect-city-budgets.html Graehler Jr., M., Mucci, R. A., & Erhardt, G. D. (2019, January 13). Understanding the Recent Transit Ridership Decline in Major U.S. Cities: Service Cuts or Emerging Modes? Presented at the 98th Annual Meeting of the Transportation Research Board, Washington, DC. Retrieved from https://uknow.uky.edu/research/under- standing-traffic-impacts-uber-lyft-greg-erhardt Groshen, E. L., Helper, S., MacDuffie, J. P., & Carson, C. (2018). Preparing U.S. Work- ers and Employers for an Autonomous Future. Retrieved from Securing America’s Future Energy website: https://www.google.com/url?sa=t&rct=j&q=&esrc=s&- source=web&cd=1&cad=rja&uact=8&ved=2ahUKEwjb9sbK7MHjAhVLwVQKHTyYB- k8QFjAAegQIARAC&url=https%3A%2F%2Favworkforce.secureenergy.org%2F- wp-content%2Fuploads%2F2018%2F06%2FGroshen-et-al-Report-June-2018-1. pdf&usg=AOvVaw1-g4-p0dh7w3Rg-z3tkmc_ Grosse-Ophoff, A., Hausler, S., Heineke, K., & Möller, T. (2017). How shared mobility will change the automotive industry | McKinsey. Retrieved August 23, 2018, from https://www.mckinsey.com/industries/automotive-and-assembly/our-insights/ how-shared-mobility-will-change-the-automotive-industry Gucwa, M. (2014). Mobility and energy impact of automated cars. Retrieved from https:// higherlogicdownload.s3.amazonaws.com/AUVSI/c2a3ac12-b178-4f9c-a654- 78576a33e081/UploadedImages/documents/pdfs/7-16-14%20AVS%20presenta- tions/Michael%20Gucwa.pdf Harb, M., Xiao, Y., Circella, G., Mokhtarian, P. L., & Walker, J. L. (2018). Projecting travel- ers into a world of self-driving vehicles: Estimating travel behavior implications via a naturalistic experiment. Transportation, 45(6), 1671–1685. https://doi.org/10.1007/ s11116-018-9937-9 Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 59 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Henao, A., Sperling, J., Garikapati, V., Hou, Y., & Young, S. (2018). Airport Analyses In- forming New Mobility Shifts: Opportunities to Adapt Energy-Efficient Mobility Services and Infrastructure (No. NREL/CP-5400-71036). Retrieved from National Renewable Energy Laboratory website: https://www.nrel.gov/docs/fy18osti/71036. pdf Hsu, J. (2017). Cargo Industry Tests Seaplane Drones to Deliver Freight. Retrieved from IEEE Spectrum: Technology, Engineering, and Science News website: https://spec- trum.ieee.org/aerospace/aviation/cargo-industry-tests-seaplane-drones-to-deliver- freight International Transport Forum. (2015). Automated and Autonomous Driving: Regulation Under Uncertainty [Text]. Retrieved from International Transport Forum website: https://www.itf-oecd.org/automated-and-autonomous-driving International Transport Forum. (2018). Safer roads with autonomous vehicles? Retrieved from https://www.itf-oecd.org/sites/default/files/docs/safer-roads-automated-vehi- cles.pdf International Transportation Service. (2017). ITS International—Go Denver opens up a world of seamless mobility and better data-driven decisions. Retrieved August 15, 2018, from http://www.itsinternational.com/sections/nafta/features/go-denver- opens-up-a-world-of-seamless-mobility-and-better-data-driven-decisions/ Isaac, M. (2017, December 21). Self-Driving Truck’s First Mission: A 120-Mile Beer Run. The New York Times. Retrieved from https://www.nytimes.com/2016/10/26/tech- nology/self-driving-trucks-first-mission-a-beer-run.html Jiang, J. (2018, May 2). Millennials stand out for their technology use. Retrieved June 6, 2019, from Pew Research Center website: https://www.pewresearch.org/fact- tank/2018/05/02/millennials-stand-out-for-their-technology-use-but-older-genera- tions-also-embrace-digital-life/ Joerss, M., Schröder, J., Neuhaus, F., Klink, C., & Mann, F. (2016). Parcel delivery: The future of last mile. Retrieved from https://www.mckinsey.com/~/media/mckinsey/ industries/travel%20transport%20and%20logistics/our%20insights/how%20cus- tomer%20demands%20are%20reshaping%20last%20mile%20delivery/parcel_de- livery_the_future_of_last_mile.ashx Kludt, A., & Geneen, D. (2018, June 29). Inside the World’s Fastest-Growing Food De- livery Service. Retrieved August 27, 2018, from Eater website: https://www.eater. com/2018/6/29/17511590/uber-eats-jason-droege-eater-upsell-podcast-listen 60 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change KPMG. (2017). Reimagine places: Mobility as a Service (p. 32). Retrieved from https://as- sets.kpmg.com/content/dam/kpmg/uk/pdf/2017/08/reimagine_places_maas.pdf Krawiec, R., & White, V. (2017). Governing the future of mobility. Retrieved August 30, 2018, from Deloitte Insights website: https://www2.deloitte.com/insights/us/en/fo- cus/future-of-mobility/federal-government-and-transportation-of-the-future.html Krueger, R., Rashidi, T. H., & Rose, J. M. (2016). Preferences for shared autonomous vehicles. Transportation Research Part C: Emerging Technologies, 69, 343–355. https://doi.org/10.1016/j.trc.2016.06.015 LaMondia, J. J., Fagnant, D. J., Qu, H., Barrett, J., & Kockelman, K. (2016). Long-Distance Travel Mode Shifts Due to Automated Vehicles: A Statewide Mode-Shift Simulation Experiment and Travel Survey Analysis. Transportation Research Board 95th Annu- al Meeting, 11. Lane, C., Zeng, H., Dhingra, C., & Carrigan, A. (2015). Carsharing: A Vehicle for Sustain- able Mobility in Emerging Market? (p. 76). Retrieved from World Resource Institute website: https://www.wri.org/sites/default/files/WRI_Report_Carsharing.pdf Lang, N., Rüßmann, M., Chua, J., & Doubara, X. (2017). Making autonomous vehicles a reality: Lessons from Boston and beyond. Retrieved August 7, 2018, from Https:// www.bcg.com website: https://www.bcg.com/en-us/publications/2017/automo- tive-making-autonomous-vehicles-a-reality.aspx Lee, T. (2016, January 12). Self-driving cars will reduce government revenue. Retrieved August 13, 2018, from Financial Review website: https://www.afr.com/news/policy/ budget/selfdriving-cars-will-reduce-government-revenue-20160111-gm36tt Lee, Y., Lee, B., & Shubho, M. T. H. (2019). Urban revival by Millennials? Intraurban net migration patterns of young adults, 1980–2010. Journal of Regional Science, 59(3), 538–566. https://doi.org/10.1111/jors.12445 Lekach, S. (2019, March 29). Lyft investors are banking on self-driving cars, not ride-shar- ing. Retrieved June 5, 2019, from Mashable website: https://mashable.com/article/ lyft-ipo-self-driving-cars-investors/ Litman, T. (2018). Implications for transport planning. 39. Manville, M., Taylor, B. D., & Blumenberg, E. (2018). Falling Transit Ridership: California and Southern California. UCLA Institute of Transportation Studies. Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 61 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Marchetti, C. (1994). Anthropological invariants in travel behavior. Technological Forecast- ing and Social Change, 47(1), 75–88. https://doi.org/10.1016/0040-1625(94)90041-8 MaRS. (2016). Microtransit: An assessment of potential to drive greenhouse gas reduc- tion. Retrieved from https://www.marsdd.com/mars-library/microtransit-assess- ment-potential-drive-greenhouse-gas-reductions/ McLaughlin, R. (2017, November 6). How Driverless Cars Could Drive Even Deeper Eco- nomic Inequality. Retrieved August 28, 2018, from Fast Company website: https:// www.fastcompany.com/40490471/how-driverless-cars-could-drive-even-deep- er-economic-inequality Metz, D. (2018). Developing Policy for Urban Autonomous Vehicles: Impact on Conges- tion. Urban Science, 2(2), 33. https://doi.org/10.3390/urbansci2020033 Morris, D. (2018, February 24). Yes, Uber Really Is Killing The Parking Business. Fortune. Retrieved from http://fortune.com/2018/02/24/yes-uber-really-is-killing-the-parking- business/ Musulin, K. (2018, August). LA Metro to develop MaaS system for TAP smart card pro- gram. Retrieved August 15, 2018, from Smart Cities Dive website: https://www. smartcitiesdive.com/news/la-metro-to-develop-maas-system-for-tap-smart-card- program/529316/ NACTO. (2017a). Bike Share in the US: 2010-2016. Retrieved from National Association of City Transportation Officials website: https://nacto.org/bike-share-statistics-2016/ NACTO. (2017b). Blueprint for Autonomous Urbanism (p. 60). Retrieved from https://nacto. org/wp-content/uploads/2017/11/BAU_Mod1_raster-sm.pdf NACTO. (2017c). Curb appeal curbside management. Retrieved from https://nacto.org/ wp-content/uploads/2017/11/NACTO-Curb-Appeal-Curbside-Management.pdf NACTO. (2018). Bike Share in the U.S.: 2017. Retrieved from National Association of City Transportation Officials website: https://nacto.org/bike-share-statistics-2017/ NACTO. (2019). Shared Micromobility in the U.S.: 2018. Retrieved from National Associa- tion of City Transportation Officials website: https://nacto.org/shared-micromobili- ty-2018/ National League of Cities. (2017). Future of Equity in Cities. Retrieved from http://nlc.org/ sites/default/files/2017-11/Future%20of%20Equity%20in%20Cities%202017.pdf 62 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Navigant Research. (2016). Electric Bicycles. Retrieved August 20, 2018, from https:// www.navigantresearch.com/reports/electric-bicycles Navy, M. (2018, January 31). Shared Mobility Comprehensive Guide 2018 by Movmi. Re- trieved August 24, 2018, from Shared Mobility website: http://www.sharedmobility. news/shared-mobility-comprehensive-guide/ NHTSA. (2017). Automated Driving Systems: A Vision for Safety. Retrieved from https:// www.nhtsa.gov/press-releases/us-dot-releases-new-automated-driving-sys- tems-guidance Nourinejad, M., Bahrami, S., & Roorda, M. J. (2018). Designing parking facilities for auton- omous vehicles. Transportation Research Part B: Methodological, 109, 110–127. https://doi.org/10.1016/j.trb.2017.12.017 Patel, R., Levin, M. W., & Boyles, S. D. (2016). Effects of Autonomous Vehicle Behavior on Arterial and Freeway Networks. Transportation Research Record, 2561(1), 9–17. https://doi.org/10.3141/2561-02 Peters, A. (2018, July 17). Here’s how much space U.S. cities waste on parking. Re- trieved June 6, 2019, from Fast Company website: https://www.fastcompany. com/90202222/heres-how-much-space-u-s-cities-waste-on-parking Peterson, H. (2019, August 14). More than 8,000 stores are closing in 2019 as the retail apocalypse drags on—Here’s the full list. Retrieved August 23, 2019, from Busi- ness Insider website: https://www.businessinsider.com/stores-closing-in-2019- list-2019-3 Pofuk, T. (2017). Autonomous Vehicles and the Future of Private Vehicle Ownership. 13. Reddy, N. (2018). The future of e-commerce (p. 70). Retrieved from https://www.cbin- sights.com/reports/CB-Insights_Future-of-Ecommerce.pdf Requia, W. J., Mohamed, M., Higgins, C. D., Arain, A., & Ferguson, M. (2018). How clean are electric vehicles? Evidence-based review of the effects of electric mobility on air pollutants, greenhouse gas emissions and human health. Atmospheric Environ- ment, 185, 64–77. https://doi.org/10.1016/j.atmosenv.2018.04.040 Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 63 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Research and Market. (2018). Global Mobility as a Service (MaaS) Market Report 2018: Market is expected to grow to US$ 358.35 billion by 2025 from US$ 38.76 billion in 2017. Retrieved August 8, 2018, from https://www.prnewswire.com/news-releases/ global-mobility-as-a-service-maas-market-report-2018-market-is-expected-to- grow-to-us-358-35-billion-by-2025-from-us-38-76-billion-in-2017--300645453.html Richland, J., Lee, J., & Butto, E. D. (2016a). Steering Autonomous Vehicle Policy: The Role of Public Health (p. 29). Retrieved from Altarum Institute website: https://altarum. org/sites/default/files/uploaded-related-files/Autonomous%20Vehicles%20Report_ final031816.pdf Richland, J., Lee, J., & Butto, E. D. (2016b). Steering Autonomous Vehicle Policy: The Role of Public Health. 29. Rojas-Rueda, D. (2017). Autonomous Vehicles and Mental Health. Retrieved August 28, 2018, from Centre for Urban Design and Mental Health website: http://www.ur- bandesignmentalhealth.com/journal3-autonomous-vehicles.html Ruff, C. (2019, February 19). What does experiential retail even mean these days? Re- trieved June 7, 2019, from Retail Dive website: https://www.retaildive.com/news/ what-does-experiential-retail-even-mean-these-days/548666/ San Francisco County Transportation Authority. (2017). TNCs Today: A Profile of San Francisco Transportation Nework Company Activity. Retrieved from https://www. sfcta.org/projects/tncs-today Schaller, B. (2017a). Empty Seats, Full Streets: Fixing Manhattan’s Traffic Problem. Re- trieved from Schaller Consulting website: schallerconsult.com/rideservices/empty- seatsfullstreets.pdf Schaller, B. (2017b). Schaller_2017_Empty Seats Full Streets.pdf. Schaller, B. (2018). The new automobility: Lyft, Uber and the future of American cities. Retrieved from http://www.schallerconsult.com/rideservices/automobility.htm Schnell, J. L., Naik, V., Horowitz, L. W., Paulot, F., Ginoux, P., Zhao, M., & Horton, D. E. (2019). Air quality impacts from the electrification of light-duty passenger ve- hicles in the United States. Atmospheric Environment, 208, 95–102. https://doi. org/10.1016/j.atmosenv.2019.04.003 64 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Seattle Department of Transportation. (n.d.). New Mobility Program—Transportation | seattle.gov. Retrieved July 9, 2019, from http://www.seattle.gov/transportation/proj- ects-and-programs/programs/new-mobility-program Shaheen, S. (2018). Peer-To-Peer (P2P) Carsharing: Understanding Early Markets, Social Dynamics, and Behavioral Impacts. https://doi.org/10.7922/g2fn14bd Shaheen, S. A., Guzman, S., & Zhang, H. (2010). Bikesharing in Europe, the Americas, and Asia: Past, Present, and Future. Transportation Research Record: Journal of the Transportation Research Board, (2143). Retrieved from https://trid.trb.org/ view/911158 Shaheen, S., Chan, N., Bansal, A., & Cohen, A. (2015). Shared Mobility: Definitions, In- dustry Developments, and Early Understanding. Retrieved from The Transportation Sustainability Research Center at University of California, Berkeley website: http:// innovativemobility.org/?project=shared-mobility-definitions-industry-develop- ments-and-early-understanding Shaheen, S., Sperling, D., & Wagner, C. (1999). A Short History of Carsharing in the 90’s. The Journal of World Transport Policy & Practice, 5(3), 18–40. Shared-Use Mobility Center. (2019). What Is Shared Mobility? Retrieved August 23, 2019, from Shared-Use Mobility Center website: https://sharedusemobilitycenter.org/ what-is-shared-mobility/ Shoup, D. (2011). The High Cost of Free Parking (Revised edition). Planners Press. Siddiqui, F. (2018a). Uber is not just for ride hailing anymore. Retrieved August 15, 2018, from Washington Post website: https://www.washingtonpost.com/local/trafficand- commuting/in-the-district-uber-is-not-just-for-ride-hailing-anymore/2018/04/11/3e1f- d9ca-3dc7-11e8-974f-aacd97698cef_story.html Siddiqui, F. (2018b, March 24). Falling transit ridership poses an ‘emergency’ for cities, experts fear. Washington Post. Retrieved from https://www.washingtonpost.com/ local/trafficandcommuting/falling-transit-ridership-poses-an-emergency-for-cit- ies-experts-fear/2018/03/20/ffb67c28-2865-11e8-874b-d517e912f125_story.html Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 65 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS 02|forces of change Description of forces assumptions Siddiqui, F., & Bensinger, G. (2019, March 29). As IPO soars, can Uber and Lyft survive long enough to replace their drivers with computers? Washington Post. Retrieved from https://www.washingtonpost.com/technology/2019/03/29/even-with-ipo-bil- lions-can-uber-lyft-survive-long-enough-replace-their-drivers-with-machines/ Silver, D., Blustein, J., & Weitzman, B. C. (2012). Transportation to Clinic: Findings from a Pilot Clinic-Based Survey of Low-Income Suburbanites. Journal of Immigrant and Minority Health, 14(2), 350–355. https://doi.org/10.1007/s10903-010-9410-0 Silver, J. (2017, January 15). Twelve things you need to know about driverless cars. The Observer. Retrieved from https://www.theguardian.com/technology/2017/jan/15/ driverless-cars-12-things-you-need-to-know Smart, J. (2018, February 20). Our Amazing Aerial Future—How, When, and Why Air Taxis and Air Deliveries Will Change Our World. Retrieved August 27, 2018, from Medium website: https://medium.com/@johnsmart/our-amazing-aerial-future-how-when- and-why-air-taxis-and-air-deliveries-will-change-our-world-2fc67d6b669 Steele, J. (2018, February 22). Ace Parking says Uber, Lyft have cut parking business up to 50% in some venues. Retrieved June 6, 2019, from San Diego Union-Tribune website: https://www.sandiegouniontribune.com/business/growth-development/ sd-fi-ace-parking-uber-lyft-competition-20180222-story.html Synchrony Finance. (2016). Brick-and-mortar reborn: The future of retail in the era of urbanization. Retrieved from https://www.synchrony.com/Synchrony%20Finan- cial%20-%20Brick%20and%20Mortar%20Reborn%20-%20August%202016.pdf Talebpour, A., & Mahmassani, H. S. (2016). Influence of connected and autonomous vehicles on traffic flow stability and throughput. Transportation Research Part C: Emerging Technologies, 71, 143–163. https://doi.org/10.1016/j.trc.2016.07.007 The Economist. (2018, March 1). Self-driving cars will require new business models. The Economist. Retrieved from https://www.economist.com/special-report/2018/03/01/ self-driving-cars-will-require-new-business-models Timmermann, M. (2018). Retail alert: More than 100 malls are losing another specialty retailer. Retrieved August 9, 2018, from Clark Howard website: https://clark.com/ shopping-retail/major-retailers-closing-2018/ 66 | Multilevel Impacts of Emerging Technology | Chapter 08 Urbanism Next | University of Oregon 01|GRANT SUMMARY 02|forces of change 03|TRANSPORTATION 04|LAND USE 05|URBAN DESIGN first order impacts Implication of the forces of change Truong, L. T., De Gruyter, C., Currie, G., & Delbosc, A. (2017). Estimating the trip genera- tion impacts of autonomous vehicles on car travel in Victoria, Australia. Transporta- tion, 44(6), 1279–1292. https://doi.org/10.1007/s11116-017-9802-2 U.S. Census Bureau. (2017). Mean Travel Time to Work of Workers 16 Years and Over Who Did Not Work at Home (Minutes) No. GCT0801. Retrieved September 24, 2019, from https://factfinder.census.gov/faces/tableservices/jsf/pages/productview. xhtml?src=bkmk USDOT. (2018). USDOT Automated Vehicles Activities [Text]. Retrieved August 29, 2018, from US Department of Transportation website: https://www.transportation.gov/AV Vincent, J. (2019, January 23). Amazon has made its own autonomous six-wheeled deliv- ery robot. Retrieved June 5, 2019, from The Verge website: https://www.theverge. com/2019/1/23/18194566/amazon-scout-autonomous-six-wheeled-delivery-robot Walker, A. (2018, July 31). How to ride scooters and bikes in Los Angeles. Re- trieved November 30, 2018, from Curbed LA website: https://la.curbed. com/2018/7/31/17623336/bird-lime-scooter-bike-app-locations-cost-hours Walker Consultants. (2013). The future of B-to-B customer experience in 2020. Retrieved from Walker Consultants website: https://www.walkerinfo.com/Portals/0/Docu- ments/Knowledge%20Center/Featured%20Reports/WALKER-Customers2020.pdf Wang, A. (2015). The Economic Impact of Transportation Network Companies on the Taxi Industry. 39. World Economic Forum. (2018). Reshaping Urban Mobility with Autonomous Vehicles: Lessons from the City of Boston (No. REF 140518). Retrieved from World Econom- ic Forum website: http://www3.weforum.org/docs/WEF_Reshaping_Urban_Mobili- ty_with_Autonomous_Vehicles_2018.pdf Zaroban, S. (2018). U.S. e-commerce sales grow 16.0% in 2017. Retrieved August 9, 2018, from Digital Commerce 360 website: https://www.digitalcommerce360.com/ article/us-ecommerce-sales/ Zipkin, A. (2017, December 11). Airports Are Losing Money as Ride-Hailing Services Grow—The New York Times. New York Times. Retrieved from https://www.ny- times.com/2017/12/11/business/airports-ride-hailing-services.html Urbanism Next | University of Oregon Chapter 08 | Multilevel Impacts of Emerging Technology | 67 05|URBAN DESIGN 06|REAL ESTATE 07|CONcLUSION 08|CITATIONS Urbanism Next | University of Oregon