Smart traffic signal control for multi-junctions
Along with economic growth and more affluence of population, traffic congestion has become a severe and growing problem in modern cities since more and more vehicles enter urban public road network with limited capacities. Traffic signal management is recognized as one of the most efficient ways...
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sg-ntu-dr.10356-662672023-07-04T16:09:36Z Smart traffic signal control for multi-junctions Wang, Yu Wang Dan Wei School of Electrical and Electronic Engineering Singapore-MIT Alliance for Research and Technology DRNTU::Engineering Along with economic growth and more affluence of population, traffic congestion has become a severe and growing problem in modern cities since more and more vehicles enter urban public road network with limited capacities. Traffic signal management is recognized as one of the most efficient ways to improve urban network congestion. Various signal control strategies have been proposed and applied all over the world in the past decades, which greatly improve traffic conditions. Whereas most of these strategies may not be capable for saturated conditions. Once road is congested, the throughput capacity decreases and in turn causes further deterioration of network congestion. Therefore, intelligent urban traffic control is an urgent need for regulating urban traffic systems to satisfy large fluctuating traffic demands. Furthermore, new motivations for traffic signal control research are the coming of new technologies such as fast communication systems, accurate sensing and network systems etc. \\ This thesis investigates the phase-based repetitive characteristic of historical traffic flow patterns and proposes Iterative Tuning (IT) strategy with anticipation of traffic demand. In general, traffic signals comprise four parameters: phase split, offset, cycle time and phase specifications. For phase split, IT strategy balances the degree of saturations for all phases of every junction in the urban network iteratively and automatically by taking evolution of traffic patterns into consideration. Rigorous analysis provides the sufficient conditions for guaranteeing the convergence of IT strategy globally over repetitions with traffic variations. With respect to offset, traffic signals synchronizes neighboring junctions to ensure as few vehicles stopped by red signal as possible. Repetitive histograms of traffic demand are proposed to estimate the number of queued vehicles off-line and seek the offset to minimize total queued vehicles on two-way links between junctions. The IT strategy smartly integrates phase split and offset tuning to provide suitable signal schedules for the entire day. \\ To ensure the robustness against non-repetitive day-to-day variations, Junctionbased Model Predictive Control (JMPC) strategy is proposed. Traffic dynamics is modeled as lane-group-based Frequently and Regularly Initialized Difference Equation (FRIDE) to make short-term predictions, which decomposes an urban network into decentralized junction-based subsystems. Every subsystem has its own controller to work cooperatively towards system-wide control objectives by coordinating traffic signals of neighboring junctions. IT and JMPC are supplementary to each other for repetitive traffic flow patterns and traffic pattern variations, which effectively and efficiently control phase split in a pre-emptive and predictive manner.\\ In this thesis, aforementioned strategies are tested and validated based on real urban areas in Singapore. A test-bed is setup in simulation software named Vissim, to model an actual urban road network. According to real traffic demand, timesliced origin-destination pairs are estimated to simulate traffic conditions during morning peak hours, afternoon non-peak hours and evening peak hours. Simulation results reveal the efficiency and convergence of proposed signal control strategies on scenarios with small and large day-to-day variations, respectively. Doctor of Philosophy (EEE) 2016-03-22T11:12:29Z 2016-03-22T11:12:29Z 2016 Thesis http://hdl.handle.net/10356/66267 en 213 p.; 7 Chapters application/pdf |
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DRNTU::Engineering Wang, Yu Smart traffic signal control for multi-junctions |
| description |
Along with economic growth and more affluence of population, traffic congestion
has become a severe and growing problem in modern cities since more and
more vehicles enter urban public road network with limited capacities. Traffic signal
management is recognized as one of the most efficient ways to improve urban
network congestion. Various signal control strategies have been proposed and applied
all over the world in the past decades, which greatly improve traffic conditions.
Whereas most of these strategies may not be capable for saturated conditions. Once
road is congested, the throughput capacity decreases and in turn causes further deterioration
of network congestion. Therefore, intelligent urban traffic control is an
urgent need for regulating urban traffic systems to satisfy large fluctuating traffic
demands. Furthermore, new motivations for traffic signal control research are the
coming of new technologies such as fast communication systems, accurate sensing
and network systems etc. \\
This thesis investigates the phase-based repetitive characteristic of historical traffic
flow patterns and proposes Iterative Tuning (IT) strategy with anticipation of traffic
demand. In general, traffic signals comprise four parameters: phase split, offset,
cycle time and phase specifications. For phase split, IT strategy balances the degree
of saturations for all phases of every junction in the urban network iteratively and
automatically by taking evolution of traffic patterns into consideration. Rigorous
analysis provides the sufficient conditions for guaranteeing the convergence of IT strategy globally over repetitions with traffic variations. With respect to offset,
traffic signals synchronizes neighboring junctions to ensure as few vehicles stopped
by red signal as possible. Repetitive histograms of traffic demand are proposed
to estimate the number of queued vehicles off-line and seek the offset to minimize
total queued vehicles on two-way links between junctions. The IT strategy smartly
integrates phase split and offset tuning to provide suitable signal schedules for the
entire day. \\
To ensure the robustness against non-repetitive day-to-day variations, Junctionbased
Model Predictive Control (JMPC) strategy is proposed. Traffic dynamics is
modeled as lane-group-based Frequently and Regularly Initialized Difference Equation
(FRIDE) to make short-term predictions, which decomposes an urban network
into decentralized junction-based subsystems. Every subsystem has its own controller
to work cooperatively towards system-wide control objectives by coordinating
traffic signals of neighboring junctions. IT and JMPC are supplementary to
each other for repetitive traffic flow patterns and traffic pattern variations, which
effectively and efficiently control phase split in a pre-emptive and predictive manner.\\
In this thesis, aforementioned strategies are tested and validated based on real
urban areas in Singapore. A test-bed is setup in simulation software named Vissim,
to model an actual urban road network. According to real traffic demand, timesliced
origin-destination pairs are estimated to simulate traffic conditions during
morning peak hours, afternoon non-peak hours and evening peak hours. Simulation
results reveal the efficiency and convergence of proposed signal control strategies on
scenarios with small and large day-to-day variations, respectively. |
| author2 |
Wang Dan Wei |
| author_facet |
Wang Dan Wei Wang, Yu |
| format |
Theses and Dissertations |
| author |
Wang, Yu |
| author_sort |
Wang, Yu |
| title |
Smart traffic signal control for multi-junctions |
| title_short |
Smart traffic signal control for multi-junctions |
| title_full |
Smart traffic signal control for multi-junctions |
| title_fullStr |
Smart traffic signal control for multi-junctions |
| title_full_unstemmed |
Smart traffic signal control for multi-junctions |
| title_sort |
smart traffic signal control for multi-junctions |
| publishDate |
2016 |
| url |
http://hdl.handle.net/10356/66267 |
| _version_ |
1772828031217303552 |