Performance analysis and signal design for a stationary signalized ring road

Existing methods for traffic signal design are either too simplistic to capture realistic traffic characteristics or too complicated to be mathematically tractable. In this study, we attempts to fill the gap by presenting a new method based on the LWR model for performance analysis and signal design in a stationary signalized ring road. We first solve the link transmission model to obtain an equation for the boundary flow in stationary states, which are defined to be time-periodic solutions in both flow-rate and density with a period of the cycle length. We then derive an explicit macroscopic fundamental diagram (MFD), in which the average flow-rate in stationary states is a function of both traffic density and signal settings. Finally we present simple formulas for optimal cycle lengths under five levels of congestion with a start-up lost time. With numerical examples we verify our analytical results and discuss the existence of near-optimal cycle lengths. This study lays the foundation for future studies on performance analysis and signal design for more general urban networks based on the kinematic wave theory.