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A Distributed Smart Signal Architecture for Traffic Signal Controls

A Distributed Smart Signal Architecture for Traffic Signal Controls. Dustin DeVoe Richard Wall, PhD University of Idaho Moscow, ID USA. Motivation for Distributed Control. Reduce Complexity Enabling technologies Promotes open architecture

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A Distributed Smart Signal Architecture for Traffic Signal Controls

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  1. A Distributed Smart Signal Architecture for Traffic Signal Controls Dustin DeVoe Richard Wall, PhD University of Idaho Moscow, ID USA

  2. Motivation for Distributed Control • Reduce Complexity • Enabling technologies • Promotes open architecture • Encourages development of new technologies and services • Overcome legacy technology and practices • Less expensive installation • Easier to tune • Reduce misinformation • Improve service to all users Univerity of Idaho Engineering

  3. Research Goals • Identify Suitability • New control devices • New instrumentation • Identify Advantages • Access • Safety • Reconfigurable • Upgrades Univerity of Idaho Engineering

  4. Evolution of Traffic Control Mechanical Switch Traffic Controllers of 1924 Univerity of Idaho Engineering

  5. Evolution of Traffic Control NEMA TS1 Standard - 1976 Univerity of Idaho Engineering

  6. US Approach - Distributed Control? NEMA TS2 Standard - 1992

  7. Application of Distributed Standard • Implementation of IEEE 1451: Plug and Play Arbitrary Network Univerity of Idaho Engineering

  8. Current Traffic Control Design NEMA TS2 Controller System NTCIP: National Transportation Committee for Intelligent Transportation Systems Protocol Web Based Configuration Interface Univerity of Idaho Engineering

  9. Smart Signals Traffic Control Design NEMA TS2 Controller System Advanced Controller System NTCIP: National Transportation Committee for Intelligent Transportation Systems Protocol Univerity of Idaho Engineering

  10. Communication of Information NTCIP – Traffic Communication Standard Pedestrian Call Plug and Play Network Traffic Controller Encrypted Power-line Ethernet Communications Univerity of Idaho Engineering

  11. Results • Able to implement IEEE 1451 • Allowed dynamic signaling • Easy implementation of innovative devices • Enabled Plug n’ Play • Resolved inaccuracy issues with distribution of information • Required translation of standards • Did not comply with accepted industry practices • Proprietary interface Univerity of Idaho Engineering

  12. Project Progression Univerity of Idaho Engineering

  13. Work in Progress Univerity of Idaho Engineering

  14. Conclusion • Increased flow of information can improve level of service at the signal • Distributed architecture increases system functionality • IEEE 1451 is implementable for an traffic control environment • Required translation of information between protocols Univerity of Idaho Engineering

  15. Future Work • Network Security • Intrusion • Reliability • Performance recording • Educating the Industry • Field Tests • Human Factors • Smart Vehicle Signals • Integrate with Federal Initiatives Univerity of Idaho Engineering

  16. Long Term Goals Univerity of Idaho Engineering

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