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Transportation Speed and Space

Transportation systems and the urban form are inextricably linked.

Space and Speed

There is generally a tradeoff between the space requirements for a mode of transportation and the geographic range of destinations. The following portrays the space requirements for various modes of transportation that are suitable for daily commuting.

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Space requirements per passenger for several commuting modes. Calculations assume 1.14 passengers on average per car, the average for commuting as per Litman 1, 42 for a bus, as per the Colorado Department of Transportation 2 and 5.7 for a vanpool, as per the American Public Transportation Association 3, three second stopping times, and lane widths of four meters. Area needs for other mass transit modes are adapted from Babadjanov 4. Vehicle speeds are adapted from the APTA 3, BRT Data 5, Johnson 6, and Litman 7. Space estimates only account for space required when a vehicle is in motion, and not for parking or maintenance facilities.

The following portrays the 45 minute travel range for different modes of commuter transportation.

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Commuting range by mode. For mass transit, we assume 10 minutes of waiting, transferring, and walking to and from transit stops. Circuity--the ratio between the actual distance traveled and the Euclidean distance between two points--is a parameter adapted from Giacomin and Levinson 8 for cars and Huang and Levinson 9 for transit buses, estimated to be 1.5 for other forms of mass transit, and estimated to be 1.2 for active transportation. For mass transit, we assume up to 300 meters of walking to the first stop and from the last.

How Transportation Shapes the Urban Form

Due to the space required by transportation infrastructure, there is a limit to the size and population density of a city before the roads, trains, or buses become too congested. In the following, we estimate, using a simplified urban model, the limits imposed by different transportation modes.

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Our simplified model assumes the following: each city is a 30 minute commutershed around a central business district, using the predominant form of transportation; uniform population density; 15% of surface area dedicated to roads or rail (not including parking, vehicle maintenance facilities, etc.); the road network must accomodate 25% of the population traveling at peak; personal space is 50 square meters per person; no allowance for freight and emergency vehicles. The floor area ratio is the ratio between the residential floor area and land dedicated to residences.

In a large, car-dependent city, population density is limited by traffic congestion rather than building space. Hence such cities tend to have large single-family homes on large lots.

The 30 minutes travel radius is based on Marchetti's constant 10, the observation that, historically, humans tend to spend on average one hour commuting each day (30 minutes each way). In practice, the largest metros exceed the estimates above by growing beyond the 30 minute travel radius.

Weight

For most motorized vehicles, the weight of the vehicle itself greatly exceeds the weight of the passengers or cargo being transported, with the major exception active transportation: walking and biking.

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Car weights reported by Miller-Wilson 11 and tank sizes from Harbid 12. Weights of buses and tractor trailers given by PennDot 13. The charter bus fuel tank size is estimated as the median of five values reported by GOGO 14. Light rail car weights are for a single car and taken from the FTA 15. The weight of the 747-400ER is given by a Boeing brochure 16, with fuel reported by Modern Airliners 17 and cargo capacity of the freighter also from Boeing 18. Bicycle weights are reported by Bicycle Universe 19. TransConnect Services reports typical truck cargo capacity 20, and the International Used Truck Centers reports fuel capacity 21. We take the median of their figures of 135 gallons. The values for freight rail are for a single car, the weight of which is estimated by Barkan 22.

Capacity of passenger vehicle is the same as used in our transportation safety analysis. We assume a person weighs 62 kilograms 23 and can comfortably carry 20 kg of cargo 24; 20 kg for each person is the total cargo capacity of passenger vehicles. Since fuel tanks are generally given as volumes, we take a density of gasoline to be 6 pounds/gallon 25, kerosene (jet fuel) to be 6.82 pounds/gallon 26, and diesel to be 8 pounds/gallon 25.

Automobile Dependency (PDF, low toner PDF)

As more cars are driven through urban areas, more space and resources are devoted to roads and parking, and less to public transit and walking/biking lanes, reducing their viability as primary transportation modes. In this manner, a feedback cycle causes automobiles to become the standard mode of transportation 27. Automobile alternatives are often stigmatized.

Overcoming this cycle can be difficult, as the more automobiles and the infrastructure that supports them become entrenched, the harder it is to institute reforms. It takes decades to alter transportation networks, and resistance to change is driven by the cycle of automobile dependency.

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One-page handout on automobile dependency (PDF)

One-page handout on automobile dependency (PDF, low toner version)

References

  1. Litman, T. "Transportation Land Valuation: Evaluating Policies and Practices that Affect the Amount of Land Devoted to Transportation Facilities". Victoria Transport Policy Institute. November 2018.

  2. Colorado Department of Transportation. "Overview of Transit Vehicles". Accessed June 22, 2019.

  3. American Public Transportation Association. "Public Transportation Fact Book". 2019. 2

  4. Babadjanov, A. "The Supply And Demand Of Street Space". The Urbanist. May 2016.

  5. BRT Data. "Operating Speed, Corridor". Accessed June 22, 2019.

  6. Johnson, M. "Average schedule speed: How does Metro compare?". Greater Greater Washington. March 2010.

  7. Litman, T. "Transportation Cost and Benefit Analysis Techniques, Estimates and Implications (Second Edition)". Victoria Transport Policy Institute. October 2016.

  8. Giacomin, D., Levinson, D. "Road network circuity in metropolitan areas". Environment and Planning B: Urban Analytics and City Science. January 2015.

  9. Huang, J., Levinson, D. "Circuity in urban transit networks". Journal of Transport Geography 48, pp. 145-153. 2015.

  10. Marchetti, C. "Anthropological Invariants in Travel Behavior". Technological Forecasting and Social Change 47, pp. 75-88. 1994.

  11. Miller-Wilson, K. "List of Car Weights". LoveToKnow. Accessed May 28, 2021.

  12. Harbit, T. "Gasoline Tank Capacity: What You Need to Know". Cash Cars Buyer. November 2020.

  13. Pennsylvania Department of Transportation. "Approximate Vehicle Weights". Accessed May 28, 2021.

  14. GOGO Charters. "Charter Bus Comparison Chart". Accessed May 28, 2021.

  15. Federan Transit Administration. "TCRP Report 57: Track Design Handbook for Light Rail Transit". Transportation Research Board, National Research Council. 1999.

  16. Boeing. "The right choice for the large airplane market". Accessed May 28, 2021.

  17. Modern Airliners. "Boeing 747 Specs". Accessed May 28, 2021.

  18. Boeing. "Introducing the 747ER and 747ER Freighter". January 2003.

  19. White, M. "How Much Does A Bike Weigh?". Bicycle Universe. Accessed May 28, 2021.

  20. Tarradell, M. "A Guide to Truck Weight, Classification, and Uses". TransConnect Services. June 2020.

  21. International Used Truck Centers. "How Many Gallons Does a Semi Truck Hold?". Accessed May 28, 2021.

  22. Barkan, C. "Introduction to Rail Transportation". University of Illinois at Urbana-Champaign. 2012.

  23. Rettner, R. "The Weight of the World: Researchers Weigh Human Population". Live Science. 2013.

  24. Wagner, N. "Carry That Load". The Doctor Will See You Now. October 2014.

  25. Blanco, S. "How does weight affect a vehicle's efficiency?". Auto Blog. November 2016. 2

  26. Cool Conversion. "1 gallon of kerosene in pounds". Accessed May 28, 2021.

  27. Litman, T. "Smarter Congestion Relief in Asian Cities: Win-Win Solutions to Urban Transport Problems". Transport and Communications Bulletin for Asia and the Pacific 82. 2013.