Litcius/Paper detail

Sliding Mode Network Perimeter Control

Youssef Bichiou, Maha Elouni, Hossam M. Abdelghaffar, Hesham Rakha

2020IEEE Transactions on Intelligent Transportation Systems27 citationsDOIOpen Access PDF

Abstract

Urban traffic congestion is a chronic problem faced by many cities in the US and worldwide. It results in inefficient infrastructure use as well as increased vehicle fuel consumption and emission levels. Congestion is intertwined with delay, as road users waste precious hours on the road, which in turn reduces productivity. Researchers have developed, and continue to develop, tools and systems to alleviate this problem. Network perimeter control is one such tool that has been studied extensively. It attempts to control the flow of vehicles entering a protected area to ensure that the congested regime predetermined by the Network Fundamental Diagram (NFD) is not reached. In this paper, an approach derived from sliding mode control theory is presented. Its main advantages over proportional-integral controllers include (1) minimal tuning, (2) no linearization of the governing equations, (3) no assumptions with regard to the shape of the NFD, and (4) ability to handle various demand profiles without the need to retune the controller. A sliding mode controller was implemented and tested on a congested grid network. The results show that the proposed controller produces network-wide delay savings and disperses congestion effectively.

Topics & Concepts

Controller (irrigation)Fuel efficiencySliding mode controlLinearizationMode (computer interface)Computer scienceGridTraffic flow (computer networking)Control theory (sociology)Feedback linearizationNetwork congestionControl (management)EngineeringControl engineeringAutomotive engineeringComputer networkNonlinear systemMathematicsAgronomyQuantum mechanicsPhysicsArtificial intelligenceNetwork packetGeometryBiologyOperating systemTraffic control and managementTransportation Planning and OptimizationTraffic Prediction and Management Techniques