1 / 24

Business Logistics 420 Public Transportation

Business Logistics 420 Public Transportation. Lecture 20: Transit System Design. Lecture Objectives. To understand the basic elements of transit system design To appreciate the different transit system route configurations To know the basic principles of good route design

nariko
Download Presentation

Business Logistics 420 Public Transportation

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Business Logistics 420Public Transportation Lecture 20: Transit System Design

  2. Lecture Objectives • To understand the basic elements of transit system design • To appreciate the different transit system route configurations • To know the basic principles of good route design • To understand other aspects of system design such as schedules, stop location

  3. Elements of Transit System Design • Overall system -- route interrelationship • Individual route design • Scheduling • Stop locations • Vehicle Selection

  4. System Considerations • Service area definition • Location of major generators • Route pattern -- network • Radial -- circumferential • Grid -- rectangular • Combination • Irregular • Route spacing • Transfers -- inter and intra modal • Marketing considerations

  5. Chicago Loop -- Grid Network

  6. Washington Metro -- Radial

  7. CATA -- Radial System

  8. ATA -- Bradford, Pa -- Irregular

  9. Route Design Guidelines • Use direct routing where possible • Through routing is preferred to cycle routing • Reverse or loop routing should be used sparingly • Routes should begin and end at major generators

  10. Route Design Guidelines (Continued) • Routes should be spaced about 1/2 mile apart • Routes should provide direct service -- circuity ratio (actual route miles/direct auto travel) should not exceed 1.33 • Initial route design assumes average speed of 12 miles per hour

  11. CATA - P Route -- Through Routing

  12. CATA C Route -- Poor Circuity

  13. CATA -- CS Route --Reverse or Loop Routing

  14. Factors Influencing Route Design • Demand • spatial arrangement • special generators • Urban environment • street network (one-way streets) • congestion • Management Considerations • driver scheduling • labor rules

  15. Factors Influencing Route Design (Continued) • Intermodal Coordination • Rail/bus/paratransit • Intercity facilities (rail, bus, air) • Political Considerations • Equity • Pressure

  16. Scheduling Considerations • Two major issues • Headway – time between vehicles Ex: 15 minuteheadway represents four buses per hour • Timing of arrivals at points along the route • Factors to consider • quality of service (frequency) • transfers • easy memorization • driver labor requirements

  17. Scheduling Considerations (Continued) • Setting headways • Maximum headway (fewest minutes between vehicles) set based on capacity needed to meet demand • Minimum headway based on policy decisions, e.g., all routes should have no less frequent service than 30 minutes in the peak and 60 minutes off peak

  18. Scheduling Considerations (Continued) • Setting arrival times • Independent scheduling • Most common approach • OK if short headways, but may cause transfer problems if long headways • Pulse scheduling – timed transfers • Attractive approach for systems with long headways • Improves service quality • Hard to implement due to space constraints at stops and variability of travel times

  19. Stop Locations • Operations • location (Near side, far side, mid block) • peak number of buses at stop at any given time • Quality of service • near destinations • spaced 750 ft or more apart to maintain operating speed • adequate waiting area -- shelter

  20. Stop Locations (Continued) • The urban environment • parking restrictions • turns • Special concerns in “Edge City,” “big box” environment • bus stop near store entrances rather than across sea of parking • circuity concerns if store too far from road

  21. Vehicle Selection • Size of vehicle • Peak loads (goal to provide 5 sq ft/psgr so 8 x 40 ft bus = 320 sq ft or 64 passengers max. • Traffic conditions • street width • turning radius • Number of vehicles • Peak hour requirement plus 10% spares

  22. Miscellaneous System Design Issues • Special service types • “freeway flyers” • skip stop operation • local vs express • New service types • service routes (fixed-route with deviations) • paratransit feeder services

  23. Study Questions • What are the major aspects of transit system design? • What are the basic types of transit route network configurations? • What are the basic route design guidelines? • What are “good” route designs? What are “poor” designs? • What factors influence scheduling decisions?

  24. Study Questions (Continued) • What factors are important when selecting vehicle size and numbers? • Pick up a CATA Ride Guide in the HUB, Kern, or inside the doors to Willard (“new” building side on Pollock Rd.) to serve as reference for this lecture

More Related