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Demonstration of Experiments Coordinated Signal Systems (Labs 6 through 7)

This demonstration showcases the experiments, terms, and key points learned in Labs 6 and 7 of the Coordinated Signal Systems course at Purdue University. It covers topics such as system controls, traffic control system coordination, timing plans, and capacity estimation.

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Demonstration of Experiments Coordinated Signal Systems (Labs 6 through 7)

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  1. Demonstration of Experiments Coordinated Signal Systems(Labs 6 through 7) Darcy Bullock (with extensive help from Anuj Sharma, Mike Inerowicz, Chris Day and Matt Wiesenfeld) Purdue University 15 April 2009

  2. Structure of Laboratory Introduction Introduction to “System Controls” Terms Experiments Closure: Summary of Key Points Learned

  3. Structure of Laboratory Introduction Terms Parameters impacting capacity Parameters impacting progression Experiments Closure: Summary of Key Points Learned

  4. Traffic Control System Coordination must Maintain a background Cycle to facilitate coordination

  5. Minimize stops • Offset How does coordinationinfluence system operation d: control delay to the lane group, s/veh; d1: uniform delay, s/veh; d2: incremental delay, s/veh; d3: initial queue delay, s/veh; PF: progression adjustment factor; Xi: volume to capacity ratio for the lane group i; C: cycle length, s; gi: effective green time for the lane group i, s; 2. Minimize Delay for Vehicles that do stop! Cycle 3. Provide Sufficient Capacity.. Split

  6. Split, Cycle, and Offset are the main levers for controlling the system..but there is more Sunday Sunday Saturday Saturday Weekday Weekday Engineering Judgment b) Discrete Design Volumes a) Typical 24-hr Flow Pattern Free Morning Plan Mid-day Plan Engineering Analysis Evening Plan Free Evening Timing Plan Mid-day Timing Plan Morning Timing Plan c) Morning Synchro Analysis Timing Report

  7. Elements of a Controller Database

  8. Entire Process Evening Timing Plan Mid-day Timing Plan Morning Timing Plan Signal Timing DB Good Default Objective of MOST CoordinationExperiments

  9. Structure of Laboratory Introduction Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system Terms Experiments Closure: Summary of Key Points Learned

  10. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  11. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  12. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  13. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  14. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  15. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  16. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  17. Table 17 Number of vehicles arriving on red in the EB TH Lanes Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  18. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system

  19. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system Programmed vs. Observed

  20. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system Evening Timing Plan Mid-day Timing Plan Morning Timing Plan

  21. Structure of Laboratory Introduction Terms Experiments Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system This is more then a direct mapping from a Synchro printout

  22. Structure of Laboratory Introduction Lab 6 Coordination Status Screens Detector Mapping Detector Extension Split Manipulation Split Tuning Split Allocation Strategies Cycle Length Adjustments Offset Adjustments Lead/Lag Capacity Estimation Synchro Mapping Lab 7 Pulling together the 270-300 parameters necessary to implement a functional 3 plan system Terms Experiments Closure: Summary of Key Points Learned

  23. Field Quality Experience…..without the risk Evening Timing Plan Mid-day Timing Plan Morning Timing Plan Signal Timing DB Good Default Objective of MOST CoordinationExperiments

  24. Overview of MOST: a hands-on approach to signal timing training: Michael Kyte, University of Idaho Demonstration of MOST simulation tools: Kiel Ova, PTV America Demonstration of experiments relating to isolated intersections: Michael Kyte, University of Idaho Demonstration of experiments relating to coordinated systems: Darcy Bullock, Purdue University Future of software-in-the-loop simulation training and research: Thomas Urbanik, University of Tennessee, Knoxville

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