Category Archives: Smart Cities

The Mobility Ecosystem: the changing landscape and the need for fresh, new ideas. (Part 5: Some Other Technology Advances)

13 Saturday Feb 2021

Posted by in 3D Printers, 5.9 GHz, 5G, Artificial Intelligence (AI), Augmented Reality (AR), Autonomous Vehicles, Cloud Services, Communications, Connected and Autonomous Vehicles (CAV), Cyber-security, Drones, Future, Global Positioning Systems (GPS), Intelligent Infrastructure, Internet of Things or IoT, Lidar, Machine Control, Materials, Mobility Ecosystem, Robotics, Safety, Smart Cities, Solar, Technology, Transportation, Vehicle-to-Vehicle (V2V), Virtual Reality (VR)

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There is a mounting need from city and road planners to evolve current ground-based infrastructure, especially across transportation networks (Deruytter, 2020). There are a number of technologies, and collections of technologies, that are changing and impacting the mobility space. In Part 4, this writer neglected to acknowledge one of these leading transportation technology centers that is bringing the industry together to develop transportation and mobility solutions—the Infrastructure Automotive Technology Laboratory, or iATL, and iATL Partner Alliance in Georgia. The Intelligent Transportation Society of America (ITSA)—Smarter, Greener, Safer—began in 1991 and has been a primary convention and driver for use of transportation technologies in the intervening 30 years. Below is a brief scan of some of these technologies, each of which could warrant a book to provide a complete coverage.

  • Vehicle-to-Vehicle (V2V) and Vehicle to Infrastructure (V2I): These are the two primary connected vehicle areas and encompass CAV (connected and automated vehicle). The advantage of V2V is to gain capacity from infrastructure and improve safety (NHTSA, n.d.). This technology may also enable increased speeds and reduce travel time. V2I is beginning to advance as a means of further advancing capacity, safety, and speed. Both V2V and V2I offer the potential to expand other technologies such as battery charging while moving, autonomous routing of vehicles, and providing intelligent infrastructure with the capability of autonomously sending condition and other reports back to a central office for planning and response for repair or replace (RoboticsBiz, 2020; 3M, n.d.).
  • Intelligent Infrastructure: In addition to being able to send condition and other reports for action to a central office, emerging AI technologies are allowing for self-healing materials that repair themselves (Flower, 2020; Mazzarol, 2012; McFarlane, 2015; McMillan, 2017; ScienceDirect, n.d.).
  • Internet of Things or IoT: Infrastructure and transportation agencies are leading the way in adopting many IoT technologies, and that will continue. Why? Because they provide tangible results (Center for Digital Government for Spectrum Enterprise, 2019).
  • 3D Printers: These printers have existed for some time but are expanding for construction. This includes the printing of the small 3D plastic models for completing concrete bridges to the printing of steel bridge models (U.S. Bridge, 2020). The basic limitation is only the size of the printing machine and whether that is cost effective.
  • Materials: Whereas 3D printers are limited by the size of the printing machine, new research is revealing the possibility of rationally designing materials to specification at the micro and macro scale and with broad engineering applications (Jenett et al, 2020). Plus, traditional materials continue to be improved such as ultra-high performance concrete (Carter, 2019).
  • Artificial Intelligence (AI): This is a leading technology of technologies, combining various technologies into new ones that can perform tasks thought to be science fiction. One of these is “robotic swarms” of meta materials that turn into buildings, vehicles, bridges—delivered in boxes by drones (Jenett, 2020; Wyss Institute, n.d.). The technology currently exists and the U. S. Army has initiated this development in partnership with the private sector including the Massachusetts Institute of Technology. Still others are in use such as Building Information Technology or BIM. Others include AI-driven asset management for bridges, monitoring the condition of assets on a real and near-real time basis (Stone, 2021). Yet another focuses on road maintenance (Holliday and Frick, 2021). Ford Motor Company has expanded to leverage AI and machine learning to predict and prevent traffic crashes (Mendoza, 2021). The future of AI is enormous in the transportation and mobility space, and society as a whole (The Washington Post, n.d).
  • Virtual (VR) and Augmented Reality (AR): Beginning in the gaming business, these technologies continue to rapidly develop, especially in the design and construction arenas. A recent augmented reality innovation by VW and Mercedes Benz enhances safe navigation through an AR blue line down the center line of the lane, allowing the driver to stay focused on the road ahead (Ligon 2021).
  • Robotics/Drones: These technologies have been in development and use for decades. Like other technologies that reduce the requirement for labor (typically the largest single cost for many organizations) within the mobility space these technologies are increasingly used for terrestrial and aquatic inspections of all kinds, vegetation planting, surveying, aerial photography, movement and delivery of materials, and others. There is continuing discussion on the use of drones, including the potential to lease air space above roads and perhaps generating a new revenue source (Skorup and Harland, 2020;  Pressgrove, 2021).
  • Machine Control: Expanding on robotics and drones that are currently used is the programming of autonomous earthmoving and other equipment, surveying, inspections, etc., on construction sites (TopCon, n.d.; UK Plant Operators, n.d.). These have been in use for some years and allow for greater efficiency at a lower cost. Using currently available technology, other systems are emerging for other activities such as hauling dirt, delivery and placement of materials. Expanding on this area, some years ago the University of Nebraska developed remotely controlled orange work zone barrels to move without the labor required for moving each barrel (Bauer, 2004). This technology could be adopted to other systems, such as the Lindsay Company Road Zipper which moves concrete Jersey barriers on a near-real time basis to adjust lanes and contra flows in conjunction with traffic flow needs, separate bicycle from vehicle traffic, adjust to the needs of construction zones, etc. In effect, this could be done remotely or autonomously. The options are endless and open to continued innovation.
  • Cloud services: There are a growing number of organizations that are leveraging the cloud for more efficient operations. Among them is Amazon Web Services (AWS) which has a growing presence in the transportation and mobility space (Silver, n.d.). Municipal and state agencies continue to expand use of cloud services for construction oversight and other activities (Yoders, 2021).
  • 5G: This technology holds tremendous promise as it increases the speed and capacity of communications essential to the mobility ecosystem (Abbosh and Downes, 2019). The Internet of Things or IoT is a driver of 5G with three broad categories of use: enhanced broadband, massive IoT sensing, and critical IoT. The massive IoT sensing alone will allow 10 times more devices to connect at 100 times the energy efficiency compared to LTE-Advanced (Little, 2019).  Smart cities are being advanced thanks to 5G and other technologies (CBS Interactive Inc., 2020; Abbosh and Downes, 2019). 5G and its capabilities are expanding as this is written. 5G and AI will continue to drive mobility development.
  • Lidar: This technology has been around for some years, allowing for rapid 3D surveying by law enforcement, surveying by drones, autonomous vehicles, improving safety, enhanced BIM (Building Information Modeling), and other diverse applications that go on and on (Shacklett, 2021). One recent application makes transportation infrastructure more efficient and safer (Clark, 2021).
  • Global Positioning Systems (GPS): Although around for decades, GPS is worth mentioning because of its importance in pinpointing locations, navigation, and its ease of use (available on smartphones and many other devices). This is critical for many technologies including autonomous vehicles.
  • 5.9 GHz: This bandwidth had been identified for public safety with important uses in the transportation arena. However, recently the Federal Communications Commission or FCC has given this bandwidth away for other commercial purposes. This sorely complicates an important safety tool for the transportation industry (Fisher, 2020).
  • Communications, integrated and interoperable-voice and data: The most common lesson-learned following disasters is the difficulty of communicating between all parties in both voice and data (FEMA, 2020; FEMA, 2014; OnSolve, n.d.; U.S. Fire Administration, 2015). As such, many states have developed more robust and interoperable communications systems. Nonetheless, effective communications is literally a key to success in responding to man-made or natural disasters and will need to be continually improved and maintained.
  • Solar: Solar power is developing slowly, but surely, as one of the most important renewable energies. For over 100 years, petroleum-based fuels and electricity generation have been separate industries. Oil was for vehicles, coal and water were for electric power. Drillers versus miners, petrostates versus power utilities. With EVs the distinction between petroleum-based fuels and power markets is blurring. Solar power is rapidly becoming the cheapest form of energy in much of the world, which means that as power markets grow to meet the new demand from EVs, oil is being largely displaced by power from the sun. For nearly 20 years, the International Energy Agency has underestimated the rise of solar power. Every year, their estimates expected the rate of solar growth to plateau, but every year it grew (Figure 7).
FIGURE 7. Sunshine may be the new oil. Every year solar was projected to plateau, and every year it set new records. (Sources: International Energy Agency, BloombergNEF, Auke Hoekstra, in “Peak Oil is Suddenly Upon Us” by Tom Randall and Hayley Warren, Bloomberg Green December 1, 2020)

Solar roadways have been developed in France these past few years. It was recently announced that the first solar roadway to come on line in the U. S. will be in Georgia (Cooke, 2017; Edelstein, 2020).

  • Cyber-security: There is an arms race going on to hack and secure data. As technology has developed so has the need for adequate cyber-security. It is wise to have one, if not at least two, backup systems to protect transportation/mobility systems, including autonomous vehicles. Every organization continues to struggle with enhancing security (Center for Digital Government, 2020).

There are literally thousands of other technologies and associated tools in the transportation/mobility industry, and other fields, that continue to be developed, some proprietary and some not, in an effort to increase sales/profits and benefit-cost. A scan of printed and electronic trade journals, conferences, proposals, and sales presentations reflects the stunning scale of these developments. A brief scan reveals advanced and integrated project and program management, data collection and workflow automation, big data and analysis, remote piloted aerial and aquatic vehicles or drones, machine learning, Lidar, ground penetrating radar, geomatics, geophysics, Reality Mesh Services (i.e. 3D models out of unordered photographs or laser scans), Building Information Modeling (BIM) across the project life cycle while incorporating Reality Capture for Digital Twins and integrated for Asset Management, and many, many others.

This also does not discount the importance and value of the myriad existing methodologies that continue to advance, have been around for years, and that can increase system efficiency. Just a few include data collection and analysis, signal timing, static signing, variable message signs, 511, video cameras, radar, roadway weather notifications, traffic operations centers and infrastructure sensors, materials, recycling, planning, design, construction, maintenance, operations, and so on.

Literature Cited

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Abbosh, O. and L. Downes. (2019, March 5). 5G’s potential, and why businesses should start preparing for it. Harvard Business Review. Retrieved February 13, 2021, from https://hbr.org/2019/03/5gs-potential-and-why-businesses-should-start-preparing-for-it

Bauer, S. (2004, April 30). Robotic traffic cones hit the road. ABC News. Retrieved February 13, 2021, from https://www.nbcnews.com/id/wbna4872379

Carter, T. (2019, May 2). Corps of Engineers grant Virginia company exclusive commercial license for Cor-Tuf ultra-high performance concrete. TechLink. Retrieved February 13, 2021 from https://techlinkcenter.org/news/corps-of-engineers-grant-virginia-company-exclusive-commercial-license-for-cor-tuf-ultra-high-performance-concrete/

Center for Digital Government. (2020). Delivering services citizens can trust: how the city of Seattle became a privacy-first organization. Active Network. Retrieved February 13, 2021, from https://media.erepublic.com/document/CDG19_CASE_STUDY_Active_Network_Seattle_V.pdf

CBS Interactive Inc. (2020). 5 Successful Smart City Projects. CBS Interactive Inc. Retrieved February 13, 2021, from https://static.cbsileads.com/direct/whitepapers/TR_5_successful_smart_cities.pdf

Center for Digital Government. (2019). Infrastructure and transportation: government finds its IoT footing. Spectrum Enterprise. Retrieved 13 February, 2021 from https://media.erepublic.com/document/CDG18_REPORT_Spectrum2_V.pdf

Clark, D. (2021, January 26). Analysis touts lidar sensor efficiency, safety. Transportation Today. Retrieved February 13, 2021, from https://transportationtodaynews.com/news/21212-analysis-touts-lidar-sensor-efficiency-safety/

Cooke, L. (2017, February 7). First Wattway solar road pilot in US pops up in rural Georgia. InHabitat. Retrieved February 13, 2021, from https://inhabitat.com/first-wattway-solar-road-pilot-in-us-pops-up-in-rural-georgia/#popup-898928

Deruytter, M. (2020, December 18). Intelligent infrastructure in transport & mobility: paving the way for a smarter and safer future. ITProPortal. Retrieved February 13, 2021 from https://www.itproportal.com/features/intelligent-infrastructure-in-transport-and-mobility-paving-the-way-for-a-smarter-and-safer-future/

Edelstein, S. (2020, December 6). Georgia gets first solar roadway in the US. Green Car Reports. Retrieved February 13, 2020, from https://www.greencarreports.com/news/1130542_georgia-gets-first-solar-roadway-in-the-us

FEMA. (2020, August 3). Disaster emergency communications. FEMA. Retrieved February 13, 2021, from https://www.fema.gov/about/offices/field-operations/disaster-emergency-communications

FEMA. (2014). Lesson 3. communicating in an emergency. FEMA. Retrieved February 13, 2021, from https://training.fema.gov/emiweb/is/is242b/student%20manual/sm_03.pdf

Fisher, T. (2020, November 23). 5.9 Ghz spectrum and transportation technology, explained) Land Line. Retrieved February 13, 2021, from https://landline.media/5-9-ghz-spectrum-and-transportation-technology-explained/

Flower, T. (2020, June 30). Intelligent infrastructure explained. RailUK. Retrieved February 13, 2021, from https://railuk.com/featured/intelligent-infrastructure-explained/

Holliday, J. and S. Frick. (2021, January 27). Podcast: The role of AI in the future of roads maintenance with FMConway and Roadbotics. The Engineers Collective. Retrieved February 13, 2021 from https://theengineerscollective.podbean.com/e/the-role-of-ai-in-the-future-of-roads-maintenance-with-fmconway-and-roadbotics/

Jenett, B, C. Cameron, F. Tourlonousis, A. Parra Rubio, M. Ochalek, N. Gershenfeld. (2020, November 18). Discretely assembled mechanical metamaterials. ScienceAdvances AAAS. Retrieved February 13, 2021, from https://advances.sciencemag.org/content/6/47/eabc9943

Ligon, L. (2021, January 12). Driver experience with augmented reality head-up display. Fox10 News. Retrieved February 13, 2021, from https://www.fox10tv.com/news/daily_dot_com/driver-experience-with-augmented-reality-head-up-display/article_7e8b7e62-553c-11eb-9a2d-a36148115811.html

Little, A. (2019, September). 5G and IoT: the time to act is now. Sprint Business. Retrieved February 13, 2021, from https://connect.bizjournals.com/rs/673-UWY-229/images/5G%20and%20IOT%20eBook.PDF

Mazzarol, T. (2012, June 23). Intelligent infrastructure: when roads and vehicles talk to each other. The Conversation. Retrieved February 13, 2013, from https://theconversation.com/intelligent-infrastructure-when-roads-and-vehicles-talk-to-each-other-7865

McFarlane, D. (2015, March 9). What makes an intelligent infrastructure asset. Infrastructure Intelligence. Retrieved February 13, 2021, from http://www.infrastructure-intelligence.com/article/mar-2015/what-makes-intelligent-infrastructure-asset

McMillan, F. (2017, December 21). The rise of self-healing materials. Forbes. Retrieved February 13, 2021, from https://www.forbes.com/sites/fionamcmillan/2017/12/21/the-rise-of-self-healing-materials/?sh=596e514f64c3

Mendoza, N.F. (2021, January 21). Smart city: Windsor is first Canadian city to launch Ford Safety Insights Platform to reduce crashes. Tech Republic. Retrieved February 13, 2021 from https://www.techrepublic.com/article/smart-city-windsor-is-first-canadian-city-to-launch-ford-safety-insights-platform-to-reduce-crashes/

NHTSA. (n.d.). Vehicle-to-Vehicle Communication. United States Department of Transportation. Retrieved February 13, 2021, from https://www.nhtsa.gov/technology-innovation/vehicle-vehicle-communication

OnSolve. (n.d.). Exploring how 9/11 impacted emergency communication. OnSolve. Retrieved February 13, 2021, from https://www.onsolve.com/blog/sept-11-impact-emergency-communication/

Pressgrove, J. (2021, January 29). Will ‘highway systems’ better prepare states for drones? Government Technology. Retrieved February 13, 2021, from https://www.govtech.com/products/Will-Highway-Systems-Better-Prepare-States-for-Drones.html

Randall, T. and H. Warren. (2020, November 30). Peak oil is suddenly upon us. Bloomberg. Retrieved February 13, 2021, from https://www.bloomberg.com/graphics/2020-peak-oil-era-is-suddenly-upon-us

RoboticsBiz. (2020, August 21). Vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) explained. RoboticsBiz. Retrieved February 13, 2021, from https://roboticsbiz.com/vehicle-to-vehicle-v2v-and-vehicle-to-infrastructure-v2i-explained/

ScienceDirect. (n.d.). Self-healing material. ScienceDirect. Retrieved February 13, 2021, from https://www.sciencedirect.com/topics/materials-science/self-healing-material

Shacklett, M. (2021, February 10). 3D scanning, lidar, and drones: Big data is helping law enforcement solve crimes. TechRepublic. Retrieved February 13, 2021, from https://www.techrepublic.com/article/3d-scanning-lidar-and-drones-big-data-is-helping-law-enforcement-solve-crimes/

Silver, P. (n.d.). Transportation. AWS. Retrieved February 13, 2021, from https://aws.amazon.com/stateandlocal/transportation/

Skorup, B. and C. Haaland. (2020, March). Which states are prepared for the drone industry? A 50-state report card. Mercatus Center, George Mason University. Retrieved February 13, 2021, from https://www.mercatus.org/system/files/skorup-drone-report-card-mercatus-research-v1_1.pdf

Stone, T. (2021, January 25). New AI-driven asset management for bridges to be used in Australia for first time. Traffic Technology International (TTI). Retrieved February 13, 2021, from https://www.traffictechnologytoday.com/news/asset-management/new-ai-driven-asset-management-for-bridges-to-be-used-in-australia-for-first-time.html

The Washington Post. (n.d.). The fast track to AI. DXC Technology. Retrieved February 13, 2021, from https://www.washingtonpost.com/brand-studio/dxc-technology-fast-track-to-ai/

TopCon. (n.d.). Machine control—the basics. TopCon. Retrieved February 13, 2021, from https://www.topconpositioning.com/gb/insights/machine-control-basics

UK Plant Operators. (n.d.). Guide to machine control. UK Plant Operators. Retrieved February 13, 2021, from https://ukplantoperators.com/guide-to-machine-control/

U.S. Bridge. (2020, March 24). The future of 3D printed bridges and construction. U.S. Bridge. Retrieved February 13, 2021 from https://usbridge.com/the-future-of-3d-printed-bridges-and-construction/

U.S. Fire Administration. (2015, June). Operational lessons learned in disaster response. FEMA. Retrieved February 13, 2021, from https://www.usfa.fema.gov/downloads/pdf/publications/operational_lessons_learned_in_disaster_response.pdf

Wyss Institute. (n.d.). Programmable robot swarms. Wyss Institute, Harvard University. Retrieved February 13, 2021, from https://wyss.harvard.edu/technology/programmable-robot-swarms/

Yoders, J. (2021, January 27). State and municipal agencies expand use of cloud construction oversight. Engineering News-Record. Retrieved February 13, 2021, from https://www.enr.com/articles/51122-state-and-municipal-agencies-expand-use-of-cloud-construction-oversight?oly_enc_id=8197J3323267G9M

The Mobility Ecosystem: the changing landscape and the need for fresh, new ideas. (Part 4: Economics of Autonomous Vehicles)

06 Saturday Feb 2021

Posted by in Autonomous Vehicles, Business Transformation, Clean Energy, Collaboration, Connected and Autonomous Vehicles (CAV), Dynamic Transportation Management, Economics, Electric Vehicles, Future, Government & Policy, Internet of Things or IoT, Mobility, Mobility as a Service, Mobility Ecosystem, Relationships, Ride Sharing, Safety, Smart Cities, Society, Strategic Planning, Technology, Transportation

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Motorized vehicles began with the advent of electric vehicles as evidenced by the first recorded powered vehicle fatality in the United States in 1899, from an electric taxi (see Part 2 of this series). Technology advances in the intervening 100 plus years have given rise to fully autonomous vehicles which are on the horizon.

The summary (abstract) provided by Clements and Kockelman (2017) is superb and provided in full.

“Connected and fully automated or autonomous vehicles (CAVs) may soon dominate the automotive industry. Once CAVs are sufficiently reliable and affordable, they will penetrate markets and thereby generate economic ripple effects throughout industries. This paper synthesizes and expands on existing analyses of the economic effects of CAVs in the United States across 13 industries and the overall economy. CAVs will soon be central to the automotive industry, with software composing a greater share of vehicle value than previously. The number of vehicles purchased each year may fall because of vehicle sharing, but rising travel distances may increase vehicle sales. The opportunity for heavy-truck drivers to do other work or rest during long drives may lower freight costs and increase capacity. Personal transport may shift toward shared autonomous vehicle fleet use, reducing that of taxis, buses, and other forms of group travel. Fewer collisions and more law-abiding vehicles will lower demand for auto repair, traffic police, medical, insurance, and legal services. CAVs will also lead to new methods for managing travel demand and the repurposing of curbside and off-street parking and will generate major savings from productivity gains during hands-free travel and reduction of pain and suffering costs from crashes. If CAVs eventually capture a large share of the automotive market, they are estimated to have economic impacts of $1.2 trillion or $3,800 per American per year. This paper presents important considerations for CAVs’ overall effects and quantifies those impacts.”

See Table 1 for a summary of the economic impacts of autonomous vehicles.

TABLE 1. Table 1. Summary of economic effects (industry- and economy-wide) (source: Clements, L. M. and Kockelman, K. M., “Economic effects of automated vehicles”, Transportation Research Record: Journal of the Transportation Research Board Volume 2606, Issue 1, January 2017, pages 106-114)

In the columns headed “Dollar Change in Industry” and “Percent Change in Industry,” signs “+” and “-”, respectively, denote a gain and a loss for the industry, whereas the industry-specific total for the dollar change in industry is the sum of their absolute values. Figures in the “$/Capita” columns and provided as overall total represent the sum of net economic benefits enjoyed by consumers.

According to an estimate by Intel Corporation and Strategy Analytics, announced in June 2017, the economic effects of autonomous vehicles will total $7 trillion in 2050 (Figure 6). The dollar amount represents a newly created value or a new ‘passenger economy’, calculated based on the assumption that fully automated Level 5 vehicles will be on the roads by 2050.

Figure 6. Global service revenue generated by autonomous driving in 2050 (US$ millions) (source: Lanctot, R. Strategy Analytics, Accelerating the Future: The Economic Impact of the Emerging Passenger Economy, June 2017)

They also assumed that consumers and businesses will use Mobility-as-a-Service (MaaS) offerings instead of owning cars, and those who had been commuting to work by car will become passengers and spend the commuting time doing something else. Furthermore, transportation companies suffering from a serious labour shortage – such as long-haul truck operators and home delivery service providers – will introduce autonomous driving services, thereby enabling them to change their business models drastically. As such, the estimate reflects a very broad range of potential effects, which also include a wide variety of new commercial services such as onboard dining and retailing (Tomita, 2017).

Advancements continue almost daily. CNN Business (Farland, 2020) reports a self-driving and electric robotaxi from Amazon’s Zoox can travel up to 75 mph and never has to turn around, reversing directions as needed to navigate crowded city streets. In an effort to become a leader in this sector, China is advancing autonomous vehicles quickly, including fully autonomous highways (Metha, 2019; KPMG International, 2019).

There are a myriad of challenges to realize fully automated vehicles and that will require an accumulation of massive quantities of data and learning processes to enable the development of AI capable of coping with navigating the rules, laws, traffic control devices, unique infrastructure, and nuances in each city, county, and state, not to mention internationally. Moreover, developing soft infrastructure, including laws and regulations, and setting rules for liability arising from accidents involving autonomous vehicles will be challenging. Similar to the open ITS architecture established by USDOT, there is a need to establish AV architecture within the U. S., if not internationally.

The advent of fully automated driverless vehicles will have a tremendous impact on our society, bringing fundamental changes to the entire economic and social systems. When fully automated vehicles come into operation, they will become a major means of mobility for the elderly and infirmed in rural areas, in addition to agriculture uses. Urban areas will likely experience the greatest changes, the number of cars owned for personal use will drop, eliminating congestion and the need for parking spaces, and car-sharing services will continue to grow.

Companies are investing enormous money in both electric and autonomous vehicles. For example, Microsoft is investing $2 billion in Cruise, that is majority owned by GM, for a valuation of over $30 billion (Colias, 2021). Apple and Hyundai-Kia are planning to start production of a fully autonomous electric car in 2024 (Lebeau, 2021). It is interesting to note that the smart phone market is about $500 billion annually of which Apple has roughly one-third of that market. By contrast, the mobility market is about $10 trillion annually so Apple would only need two percent of that market to match their iPhone business. It is little wonder the interest in the autonomous and electric vehicle space.

Although some estimates are that it will be at least 2040 before fully autonomous vehicles will be dominant, how should we cope with these forthcoming changes? How should we redesign and change the urban and rural infrastructure and landscapes, land use, and the economic and social systems?

There are test beds spreading around the nation in an effort to bring these and other technologies to market—Contra Costa County California formed a Transportation Authority (CCTA) and developed the leading facility in the nation—GoMentum (https://gomentumstation.net), the University of Michigan established Mcity some years ago (https://mcity.umich.edu), Waymo is planning a test facility in Ohio (Moderation Team, n.d.), and Missouri just formed a Missouri Center for Transportation Innovation (https://mcti.missouri.edu). These test beds, and other efforts, reflect the drive toward an autonomous and safe mobility ecosystem future. What do they have in common? They are built on partnerships and collaboration. Of course, the National Academies Transportation Research Board (https://www.nationalacademies.org/trb/transportation-research-board), U. S. Department of Transportation, state departments of transportation, universities, and the private sector represent the best minds around and continually add to our body of knowledge on all aspects of mobility and transportation.

Autonomous marine, freshwater, river, air, truck, and train vessels

This discussion does not even mention other modes and types of autonomous vehicles such as marine, riverine, freshwater, trucks, trains, planes, drones or unmanned aerial vehicles, aircraft, or space craft. Although they share many of the same challenges as cars and similar vehicles, many of these are likely years away before widespread use. Nonetheless, they are on the horizon. Of course, the elimination/reduction of operators will require careful planning to help people find other jobs in addition to negotiations with unions, changes in business models, and changes in society. The following links provide more information on these topics.

“What Will the Autonomous Ship of the Future Looks Like?” Smithsonian Magazine: https://www.smithsonianmag.com/innovation/what-will-autonomous-ship-future-look-180962236/

“The Marine Corps is eyeing a long-range robot boat that can nail targets with kamikaze drones” Task & Purpose: https://taskandpurpose.com/news/marine-corps-long-range-unmanned-surface-vessel-contract/

“A New Generation of Autonomous Vessels Is Looking to Catch Illegal Fishers” Smithsonian Magazine: https://www.smithsonianmag.com/innovation/new-generation-autonomous-vessels-looking-catch-illegal-fishers-180976336/

“Autonomous Shipping: Trends and Innovators in a Growing Industry” Nasdaq Technology: https://www.nasdaq.com/articles/autonomous-shipping%3A-trends-and-innovators-in-a-growing-industry-2020-02-18

“The Future of Autonomous Aircraft” TechXplore: https://techxplore.com/news/2020-12-future-autonomous-aircraft.html

“Xwing Unveils Autonomous Flight System for Regional Planes” VentureBeat: https://venturebeat.com/2020/08/20/xwing-unveils-autonomous-flight-system-for-regional-planes/

“Rail in on the way to autonomous trains” International Railway Journal: https://www.railjournal.com/opinion/rail-autonomous-trains

“Autonomous vessels on inland waterways” De Vlaamse Waterweg: https://ec.europa.eu/transparency/regexpert/index.cfm?do=groupDetail.groupMeetingDoc&docid=38717

“Automated Trucking, A Technical Milestone That Could Disrupt Hundreds of Thousands of Jobs, Hits the Road” CBS News 60 Minutes: https://www.cbsnews.com/news/driverless-trucks-could-disrupt-the-trucking-industry-as-soon-as-2021-60-minutes-2020-08-23/

“Robots exploring on their own and self-piloting spacecraft are a long way off, says NASA computer scientist” Arizona State University News: https://news.asu.edu/20200220-discoveries-autonomous-spacecraft-baby-steps

Citations

Clements, L.M. and K.M. Kockelman. (2017, January 1). Economic effects of automated vehicles. Research Record: Journal of the Transportation Research Board. Retrieved February 6, 2021, from https://journals.sagepub.com/doi/abs/10.3141/2606-14

Colias, M. (2021, January 19). Microsoft bets bigger on driverless-car space with investment in GM’s Cruise. The Wall Street Journal. Retrieved February 6, 2021, from https://www.wsj.com/articles/microsoft-bets-bigger-on-driverless-car-space-with-investment-ingms-cruise-11611064940#

KPMG International. (2019). 2019 autonomous vehicles readiness index: assessing countries’ preparedness for autonomous vehicles. KPMG International. Retrieved February 6, 2021, from https://assets.kpmg/content/dam/kpmg/xx/pdf/2019/02/2019-autonomous-vehicles-readiness-index.pdf

Korosec, K. (2017, June 1). Intel predicts a $7 trillion self-driving future. The Verge. Retrieved February 6, 2021, from https://www.theverge.com/2017/6/1/15725516/intel-7-trillion-dollar-self-driving-autonomous-cars

Lanctot, R. (2017, June). Accelerating the future: the economic impact of the emerging passenger economy. Strategy Analytics. Retrieved February 6, 2021, from https://newsroom.intel.com/newsroom/wp-content/uploads/sites/11/2017/05/passenger-economy.pdf

LeBeau, P. and Reeder, M. (2021, February 3). Apple and Hyundai-Kia pushing toward deal on Apple Car. CNBC. Retrieved February 6, 2021 from https://www.cnbc.com/2021/02/03/apple-and-hyundai-kia-driving-towards-deal-on-apple-car.html

McFarland, M. (2020, December 14). This robotaxi from Amazon’s Zoox has no reverse function. CNN Business. Retrieved February 6, 2021 from https://www.cnn.com/videos/business/2020/12/14/zoox-robotaxi-amazon-orig.cnn-business

Mehta, Ivan. (2019, April 15). How China’s new highway for self-driving cars will boost its AV ambitions. The Next Web. Retrieved February 6, 2021, from https://thenextweb.com/cars/2019/04/15/how-chinas-new-highway-for-self-driving-cars-will-boost-its-av-ambitions/

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Tomita, H. (2017, December 17). Awaiting the realization of fully automated vehicles: potential economic effects and the need for a new economic and social design. VOXEU CEPR. Retrieved February 6, 2021, from https://voxeu.org/article/potential-economic-and-social-effects-driverless-cars

The Mobility Ecosystem: the changing landscape and the need for fresh, new ideas (Part 2: Safety, Smart Cities)

18 Monday Jan 2021

Posted by in Biological Diversity, Clean Energy, Climate, Connected and Autonomous Vehicles (CAV), Economy, Electric Vehicles, Environment, Extinction of Species, Future, Internet of Things or IoT, Mobility as a Service, Mobility Ecosystem, Multimodal, Pedestrians, Resilience, Ride Sharing, Safety, Smart Cities, Society, Technology, Transportation

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Safety

There is likely not a transportation agency or company that does not consider safety as their number one priority. This is how it should be. The very first roadway powered vehicle fatality in the United States was on September 13, 1899, when Henry Hale Bliss, a 69-year-old local real estate dealer, was dismounting a southbound 8th Avenue trolley car in New York City when an electric-powered taxi cab struck him. Bliss hit the pavement, crushing his head and chest. Bliss died from his sustained injuries the next morning (Eschner, 2017). A plaque was dedicated at the site on September 13, 1999, to commemorate the centenary of this event. It reads:

Here at West 74th Street and Central Park West, Henry H. Bliss dismounted from a streetcar and was struck and knocked unconscious by an automobile on the evening of September 13, 1899. When Mr. Bliss, a New York real estate man, died the next morning from his injuries, he became the first recorded motor vehicle fatality in the Western Hemisphere. This sign was erected to remember Mr. Bliss on the centennial of his untimely death and to promote safety on our streets and highways.

Since then, it has been a continual challenge to reduce fatalities, injuries, and property damage. Entire industries have grown up during this time (insurance, roadway policing, etc.).

More recently, while technology and autonomous vehicles hold promise to reduce and perhaps eliminate crashes, it will be many years and probably decades before a significant impact occurs. The United States alone averages 30-40,000 roadway deaths a year. Globally there are 1.35 million people annually killed on roadways around the world (3,700/day) with a $1.8 trillion economic cost in 2010 U. S. dollars (Road Traffic Injuries and Deaths—A Global Problem, n.d.). In the meantime, efforts must continue to protect people. Within the past decade, many in the industry have set goals for zero fatalities. As an example, one of these is Houston’s Vision Zero Action Plan (Begley, 2020). The city’s plan identifies 13 “priority actions” the city is committing to take. Among them:

  • construct at least 50 miles of sidewalks annually
  • build at least 25 miles of dedicated bike lanes annually
  • evaluate road projects for options to include sidewalks, bike trails and other amenities
  • redesign 10 locations with high numbers of incidents every two years, and make those changes within the following calendar year

Additionally, the plan calls on the city to train its employees on how to talk about crashes to avoid victim-blaming or playing down safety issues. It also calls for a detailed analysis of Vision Zero’s progress to be made publicly available.

These are not particularly unique actions to improve safety, as professionals work every day—through planning, design, construction, operations, maintenance, education, and collaboration—to reduce, if not eliminate, crashes and the circumstances that lead to them in an effort to keep people safe. However, “action” is the operative word just as Houston is doing.

Smart Cities and Concepts

Advances in policy, planning, partnerships, and innovation are being developed at all governmental levels in an effort to provide a framework for the public and private sectors to work in unison within an architecture to increase effective and efficient mobility. An early example of this is the Intelligent Transportation System or ITS Architecture developed by the U. S. Department of Transportation in conjunction with many partners and issued in 2001.

There are a number of concepts that can and have been referred to as “Smart Cities” or “Smart City Concepts”. These have evolved especially during the technology revolution of the past two decades. This list is far from exhausting the myriad concepts or disciplines. The following discusses some of these disciplines and concepts, in no particular order, and none fit neatly within one topic.

Some disciplines in these concepts:

  • Strategic Planning. This is the starting point for virtually everything else. It is, of course, preceded by the necessary outreach, listening, team building, and collaboration needed to build a strategy.
  • Performance Metrics. Tracking progress toward meeting the goals imbedded within the strategic plan is equally important. Any plan becomes useless without progress toward obtaining it and performance metrics provide that tool to measure progress.
  • Connected and Automated Vehicles (CAV). Driven by rapidly developing technologies, CAV primarily provides more capacity from infrastructure, essentially reducing costs and improving safety.
  • Clean Energy—Maturing Alternative Fuel Technologies. The Industrial Age and resulting pollution and climate change that resulted have demanded clean energy in all its forms—solar, wind, hydrogen fuel cell, and electricity. Electricity is currently most dominant.
  • Electrification. As electricity emerges as the clean energy fuel, vehicle manufactures and governments are rapidly moving forward to increase electric vehicle use and reduce carbon-based vehicle use. The Governor of California has mandated no new internal combustion vehicle sales within California after 2035 while electric vehicle use continues to rise, and many states and communities are encouraging their use with supporting infrastructure. California has led many areas in the mobility space so this is one to watch.
  • Hydrogen Fuel Cells. Recently, the diesel engine manufacturer Cummins is developing hydrogen fuel cell engines that they believe will be efficient and compete favorably with electricity for heavy vehicles such as buses, heavy trucks, and trains.
  • Mobility as a Service/Mobility on Demand. Mobility as a Service, or MaaS, also known as Transportation as a Service, provides services typically with a joint digital channel that enables users to plan, book, and pay for trips. This is part of a more global shift from personally-owned vehicles to mobility provided as a service. Micro-mobility and micro-transit are also emerging (Regional transportation study suggests ‘’micro-transit’, 2020).
  • Car and Ride Sharing. Car and ride sharing has been around for decades, but the technology of recent years has allowed it to become much more effective and efficient as evidenced by the rise of Lyft and Uber.
  • Increasing Biking, Scooters, and Pedestrian Mobility. In recent years as a means to reduce car usage especially in metropolitan areas, bike lanes, trails, sidewalks, and scooter/bicycle rentals are increasing. These have the ability to also improve health while reducing congestion and increasing the capacity of infrastructure.
  • Big Data. This is the best of continuous improvement. Virtually every organization has legacy systems of data, physical (e.g. file cabinets) or electronic (e.g. servers or the cloud). For a variety of reasons, these data have resided in ”silos” and are not easily accessed and analyzed from broader, more complex perspectives. New technologies and related tools are now allowing “big data” to be accessed and analyzed with resulting increases in efficiency and performance.
  • Risk. Risk has always existed and is dominant in mega and giga projects as evidenced in projects such as the California High Speed Rail. While private companies have had risk management programs for years, the most recent federal transportation act (Fixing America’s Surface Transportation or “FAST Act,” 2015) requires states to have a risk management program. Using different tools to anticipate potential challenges (e.g. lost revenues) as well as opportunities (e.g. lost opportunities to increase revenues), these tools allow proactive development of strategies to mitigate and address the challenges as they occur vice the turmoil and problems associated with surprises. Of course this does not eliminate surprises termed “black swans” but these tools do significantly reduce most risks.
  • Resilience. Infrastructure is the backbone of our economy, connecting people, enhancing quality of life, and promoting health and safety. But climate change is revealing infrastructure vulnerabilities (Will infrastructure bend or break under climate change?, 2020). Like risks, resiliency or the lack of it, has always existed. As our built environment has increased, come into conflict with, and impacted the natural environment, the demand for protecting the built environment has increased. The National Oceanographic and Atmospheric Administration (NOAA) (Lindsey, 2020) estimates a sea level rise of one foot to 8.2 feet by 2100. The variables are such that it is impossible to project more precisely. These apparently man-induced climate changes have increased hurricanes, other storms, coastal erosion, flooding, and other events that erode or destroy man-made structures including roads and bridges. This has demanded more resilient infrastructure through better materials, protective structures, relocation to less exposed areas, improved construction practices, and others (Parsons, 2020). One of the more recent efforts to improve the built-natural environment coexistence is the U. S. Army Corps of Engineers initiative “Engineering with Nature” (https://ewn.el.erdc.dren.mil/).
  • Environment. This discipline, like other disciplines, interacts together. As living beings, we depend on and are part of the natural environment. Thus, while risk and resilience are critical to the built environment, the healthy functioning of the natural environment is essential to our well-being. There is general recognition that climate change, biological diversity, populations, species loss and other insidious environmental impacts are undermining the natural world on which life (including humans) depends. (Will infrastructure bend or break under climate change?, 2020; UN Report: Nature’s Dangerous Decline ‘Unprecedented’; Species Extinction Rates ‘Accelerating’, 2019; Bongaarts, 2019; Duckett, 2020; Sofia, et al, 2020; Kann, 2020). There are emerging lab cultured meats that may reduce greenhouse gases 20-30 percent, slaughtering of 80 billion animals a year, improve land use, and reduce creation and transmission of diseases such as coronavirus. In the end we must take care of our natural environment. There is an increasing demand for the transportation/mobility space to not only mitigate but improve the natural environment. While many techniques are not new, the U. S. Army Corps of Engineers initiative “Engineering with Nature” increases the attention to the importance and techniques to live well within and take care of the natural environment.
  • Internet of Things (IoT). This is technology taken to a high level. There is increasing demand for seamless mobility and IoT provides tools to achieve that future. As the title of this blog infers (The Mobility Ecosystem), the IoT allows an increasing emphasis on a “systems perspective” of our lives. Technology is allowing us to not only see the mobility ecosystem more clearly but how to improve its performance in all of its myriad impacts and relations…economic, social, environmental etc. (Joshi, 2020).

Some Smart City Concepts

  • Incentivize High Density Development. Our society has seen in an ebb and flow in regards to this concept—rural agriculture migrating to cities during industrialization, migrations to suburbs during metropolitan growth, migrations to more rural areas with increased opportunities for remote work, and a return to metropolitan areas primarily for work. This latter has dramatically increased traffic congestion and no one likes that. So, metropolitan areas are employing solutions to address this issue, such as providing incentives for high density development, not only of businesses, but housing and support services such as health care and  grocery stores that are within walking distance. Due to population densities in European and Asian metropolitan areas, high density development has been occurring for some time. The United States is a much younger country so, we can learn from looking at their experience.
  • Incentivize Core Downtown Development by Charging Fees for Increases in Traffic. This is more of a technique than a concept. Nonetheless, charging fees for development that results in traffic increases can be a powerful tool while developing downtown areas, reducing traffic congestion, and increasing pedestrian/bicycle/scooter traffic.
  • Electrify Transportation: While electrification is a discipline, its application to traffic is considerable and is rapidly occurring. The economics driving this are discussed in a later post in this series.
  • Use More Shared and Connected Transportation. While shared transportation providers such as Uber and Lyft are becoming increasingly ubiquitous and used by many, especially millennials, there is little question that these and other providers will continue to expand. Connected transportation is beginning to emerge essentially in two forms. One is connecting various modes into one seamless multimodal transportation system, largely through technology. The other is by linking buses, trucks and cars into essentially “trains of vehicles or platoons” with little or no separation (i.e. virtually or physically connected). This has the net effect of increasing the capacity of infrastructure and increasing the productivity (and safety) of vehicles.
  • Use Traffic Calming Devices that Slow Cars and Enhance Pedestrian, Bicycle, Scooter, and Transit Mobility. This is likely one of the less obvious smart city concepts. However, the use of traditional traffic lights, traffic circles, pavement markings, and signs can have the net impact of slowing cars and enhancing pedestrian, bicycle, scooter and transit mobility.
  • Adopt User-Friendly App(s) for Routing and Paying for Multimodal Trips. This may be more of a technique for increasing connected vehicle use by a user-friendly app that allows for routing and paying for multimodal trips. These are being developed in locations such as the Denver RTD.
  • Free Public Transportation. As population densities increase and the impacts are valued and assessed via more “systems thinking,” the results may be that free public transportation may be more advantageous and cost-effective than alternatives. Dunkirk France concluded that free public transportation was more advantageous and cost effective than other alternatives, and thus provide free public transportation. Kansas City, Missouri, is providing free public transportation in a one year test to determine whether to do the same.
  • Stay Healthy Streets. Making more use of streets has gone by various names including complete streets, but Stay Healthy Streets is a more recent terminology. Essentially, this concept increases the usage of roads from motorized vehicles to pedestrians, bicycles, and other micro-mobility. This can be accomplished by closing or limiting streets to vehicle access, pavement markings for bicycle lanes, etc. The cities of Seattle and Minneapolis saw increases in pedestrian and bicycle traffic during the COVID-19 Pandemic while other cities saw little or no change. The question now is whether to keep these Stay Healthy Streets or not.

The fDis Global cities of the future (fDiintelligence.com, a service of the Financial Times LTD) also offers a variety of great insights, including by competitions to identify the best practices for future global cities.

Smart Rural Concepts

In an effort to be holistic, it is appropriate to provide some discussion of Smart Rural Concepts. The needs in largely agriculture-based communities for access to hospitals, schools, jobs and other communities is equal to that of more urban communities although the challenges may vary, including longer travel distances. Nearly every element in the above discussion of Smart Cities also relate to rural areas, the need for strategic planning, clean energy, electrification, big data, resilience, 5G, ITS, variable message signs, CAV, GPS, IoT, user-friendly apps for routing, etc. One exception is that most rural communities are not burdened with traffic congestion in their downtowns so incentivizing high-density development downtown makes little sense. However, many rural communities strongly desire more downtown traffic as a perceived means of economic development. Traffic can be a two-edged sword depending on your perspective. Truck traffic routing is another area rural communities may struggle with more than more urban communities.

One of the more challenging aspects of rural areas is that 45 percent of the nation’s fatalities are on rural roads while only 19 percent of the nation’s population lives in rural areas (Rural/Urban Comparison of Traffic Fatalities, 2020). This warrants counter measures not usually used in more urban areas. With more than 30 people a day dying in roadway departure crashes on rural roads, inexpensive countermeasures like SafetyEdge, rumble strips, lane markings, signage, and edge lines can and are bringing that number down.

Literature Cited

Begley, Dug (2020, December 16). Houston has a plan to end road fatalities. Now the work to implement it begins. Houston Chronicle. Retrieved January 14, 2021, from https://www.houstonchronicle.com/news/houston-texas/transportation/article/Houston-has-a-plan-to-end-road-fatalities-Now-15809563.php

Bongaarts, J. (2019, September 4). IPBES, 2019. Summary for policy makers of the global assessment report on biodiversity and ecosystem services of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services. Wiley Online Library. Retrieved January 14, 2021 from https://onlinelibrary.wiley.com/doi/full/10.1111/padr.12283

Duckett, M.K. (2020, March 4). Nature needs us to act – now. National Geographic. Retrieved January 14 from https://www.nationalgeographic.com/science/2020/03/partner-content-nature-needs-us-to-act-now/

Eschner, K. (2017, September 13). Henry Bliss, America’s First Pedestrian Fatality, Was Hit By an Electric Taxi. Smithsonian Magazine. Retrieved January 18, 2021, from https://www.smithsonianmag.com/smart-news/henry-bliss-americas-first-pedestrian-fatality-was-hit-electric-taxi-180964852/

Fixing America’s Surface Transportation or “FAST Act.” (2015, December 4). U.S. Department of Transportation. Retrieved January 14, 2021 from https://www.transportation.gov/fastact

Joshi, N. (2020, December 16). How IoT Can Enhance Public Transportation. BBN Times. Retrieved January 14, 2021 from https://www.bbntimes.com/technology/how-iot-can-enhance-public-transportation

Kann, D. (2020, December 3). Salmon have been dying mysteriously on the West Coast for years. Scientists think a chemical in tires may be responsible. CNN. Retrieved January 14, 2021 from https://www.cnn.com/2020/12/03/us/microplastics-tire-rubber-chemicals-killing-coho-salmon-scn/index.html

Lindsey, R. (2020, August 14). Climate Change: Global Sea Level. NOAA. Retrieved January 14, 2021 from https://www.climate.gov/news-features/understanding-climate/climate-change-global-sea-level

Parsons, J. (2020, December 16). Shoring Up for Rising Sea Levels. Engineering News-Record. Retrieved January 18, 2021 from https://www.enr.com/articles/50899-shoring-up-for-rising-sea-levels

Regional transportation study suggests ‘micro-transit’. (2020, December 11). Mid Hudson News. Retrieved January 14, 2021 from https://midhudsonnews.com/2020/12/11/regional-transportation-study-suggests-micro-transit/

Road Traffic Injuries and Deaths—A Global Problem. (n.d.) Center for Disease Control and Prevention. Retrieved January 14, 2021 from https://www.cdc.gov/injury/features/global-road-safety/index.html

Rural/Urban Comparison of Traffic Fatalities. (2020, May). NHTSA Traffic Safety Facts 2018 Data. Retrieved January 14, 2021 from https://ruralsafetycenter.org/wp-content/uploads/2020/06/812957.pdf

Sofia, G., E.I. Nikolopoulos, L. Slater. (2020, March 16). It’s Time to Revise Estimates of River Flood Hazards. Eos. Retrieved January 14, 2021 from https://eos.org/opinions/its-time-to-revise-estimates-of-river-flood-hazards

UN Report: Nature’s Dangerous Decline ‘Unprecedented’; Species Extinction Rate ‘Accelerating.’ (2019, May 6). United Nations. Retrieved January 14, 2021 from https://www.un.org/sustainabledevelopment/blog/2019/05/nature-decline-unprecedented-report/

Will infrastructure bend or break under climate stress? (2020, June). McKinsey Global Institute. Retrieved January 18, 2021 from https://www.mckinsey.com/~/media/McKinsey/Business%20Functions/Sustainability/Our%20Insights/Will%20infrastructure%20bend%20or%20break%20under%20climate%20stress/Will-infrastructure-bend-or-break-under-climate-stress_case-study.pdf