Your search keyword '"tsp optimization"' showing total 4 results

1. An Improved Transit Signal Priority Strategy for Real-World Signal Controllers that Considers the Number of Bus Arrivals

Author

Jiangang Guo, Zhenlong Li, Yiyuan Wu, Jack Keel, Yaling Kang, and Peikun Lian

Subjects

early green strategy, Computer science, tsp optimization, Geography, Planning and Development, Real-time computing, lcsh:TJ807-830, lcsh:Renewable energy sources, Management, Monitoring, Policy and Law, Field (computer science), Control theory, 0502 economics and business, active priority, Transit (satellite), lcsh:Environmental sciences, lcsh:GE1-350, 050210 logistics & transportation, Renewable Energy, Sustainability and the Environment, Intersection (set theory), green extension strategy, lcsh:Environmental effects of industries and plants, 05 social sciences, SIGNAL (programming language), cnob tsp strategy, transit signal priority, lcsh:TD194-195, Rush hour, signal controller, 050203 business & management

Abstract

Active transit signal priority (TSP) is used more conveniently and widely than the other strategies for real-world signal controllers. However, the active TSP strategies of real-world signal controllers use the first-come-first-served rule to respond to any active TSP request and are not effective at responding to the number of bus arrivals. With or without the green extension strategy, the active TSP has little impact on the final green time of priority phase, even in the case where more buses arrive during the priority phase. The reduced green time of early green strategy is relatively large when a bus arrives, and it would be worse when more buses arrive, the active TSP has a big adverse impact on the final green time of the non-priority phase. Therefore, the active TSP strategies of real-world signal controllers cannot handle the downtown intersection where many bus lines converge or where many buses arrive in a signal cycle during the evening rush hour. Traffic engineers need to do much work to optimize the TSP parameters before field application. Consequently, it is necessary to improve the TSP strategy of the real-world signal controllers for the intersections with a lot of bus arrivals. In order to achieve that objective, the authors present the CNOB (cumulative number of buses) TSP strategy based on the Siemens 2070 signal controller. The TSP strategy extends the max call time according to the number of buses in the arrival section when priority phases are active. The TSP strategy truncates the green time according to the number of buses in the storage section when non-priority phases are active. The experiment&rsquo, s result shows that the CNOB TSP strategy can not only significantly reduce the average delay per person without using TSP optimization but can also reduce the adverse impact on the general vehicles of non-bus-priority approaches for the intersections with a lot of bus arrivals. Additionally, because the system dynamically adjusts, traffic engineers do not need to do much optimization work before the TSP implementation.

Published

2019

2. An Improved Transit Signal Priority Strategy for Real-World Signal Controllers that Considers the Number of Bus Arrivals.

Author

Lian, Peikun, Wu, Yiyuan, Li, Zhenlong, Keel, Jack, Guo, Jiangang, and Kang, Yaling

Abstract

Active transit signal priority (TSP) is used more conveniently and widely than the other strategies for real-world signal controllers. However, the active TSP strategies of real-world signal controllers use the first-come-first-served rule to respond to any active TSP request and are not effective at responding to the number of bus arrivals. With or without the green extension strategy, the active TSP has little impact on the final green time of priority phase, even in the case where more buses arrive during the priority phase. The reduced green time of early green strategy is relatively large when a bus arrives, and it would be worse when more buses arrive, the active TSP has a big adverse impact on the final green time of the non-priority phase. Therefore, the active TSP strategies of real-world signal controllers cannot handle the downtown intersection where many bus lines converge or where many buses arrive in a signal cycle during the evening rush hour. Traffic engineers need to do much work to optimize the TSP parameters before field application. Consequently, it is necessary to improve the TSP strategy of the real-world signal controllers for the intersections with a lot of bus arrivals. In order to achieve that objective, the authors present the CNOB (cumulative number of buses) TSP strategy based on the Siemens 2070 signal controller. The TSP strategy extends the max call time according to the number of buses in the arrival section when priority phases are active. The TSP strategy truncates the green time according to the number of buses in the storage section when non-priority phases are active. The experiment's result shows that the CNOB TSP strategy can not only significantly reduce the average delay per person without using TSP optimization but can also reduce the adverse impact on the general vehicles of non-bus-priority approaches for the intersections with a lot of bus arrivals. Additionally, because the system dynamically adjusts, traffic engineers do not need to do much optimization work before the TSP implementation. [ABSTRACT FROM AUTHOR]

Published

2020

3. Exploiting Quantum Entanglement and Quantum Superposition for Nature-Inspired Optimization

Author

Panella, Massimo

Subjects

exhaustive quantum search, nonlinear quantum processing, tsp optimization

Published

2012

4. Quantum Dynamic Mechanism-based Parallel Ant Colony Optimization Algorithm

Author

Sheng Liu, Xiao-ming You, and Yu-ming Wang

Subjects

Extremal optimization, Mathematical optimization, General Computer Science, business.industry, Ant system, Ant colony optimization algorithms, Quantum Dynamic Mechanism, Parallelization, QA75.5-76.95, Travelling salesman problem, lcsh:QA75.5-76.95, Computational Mathematics, Operator (computer programming), TSP optimization, Electronic computers. Computer science, Benchmark (computing), Local search (optimization), lcsh:Electronic computers. Computer science, business, Algorithm, Quantum, Metaheuristic, Self-adaptive strategy, Mathematics

Abstract

A novel Parallel Ant Colony Optimization Algorithm based on Quantum dynamic mechanism for travelling salesman problem (PQACO) is proposed. The use of the improved 3-opt operator provides this methodology with superior local search ability; several antibody diversification schemes were incorporated into the PQACO in order to improve the balance between exploitation and exploration. We describe the quantum dynamic mechanism and analysis the technology of improving performance, the efficiency of the approach has been illustrated by applying to TSP benchmark instances Chn144.

Published

2010