Abstract
Although the macroscopic volume-delay function (VDF) has been widely used in static traffic assignment for transportation planning, the planning community has long recognized its deficiencies as a static function in capturing traffic flow dynamics and queue evolution process. In the existing literature, many queueing-based and simulation-based dynamic traffic assignment (DTA) models involving various traffic flow parameters have been proposed to capture traffic system dynamics on different spatial scales; however, how to calibrate these DTA models could still be a challenging task in its own right, especially for real-world congested networks with complex traffic dynamics. By extending the fluid-based polynomial arrival queue (PAQ) model with quadratic inflow rates proposed by Newell (1982) and cubic inflow rates by Cheng et al. (2022), this paper attempts to propose a cross-resolution Queueing-based Volume-Delay Function (QVDF) to explicitly establish a coherent connection between (a) the macroscopic average travel delay performance function in a long-term planning horizon and (b) the mesoscopic dynamic queuing model during a single oversaturated period. By introducing two types of elasticity functional forms, this paper develops a relationship from the macroscopic inflow demand-to-capacity (D/C) ratio to the congestion duration of a bottleneck, from the congestion duration to the magnitude of speed reduction. The QVDF can be directly utilized to provide closed-form expressions for both average travel delay performance and the time-dependent speed profiles. The proposed cross-resolution QVDF provides a numerically reliable and theoretically rigorous performance function to characterize oversaturated bottlenecks at both macroscopic and mesoscopic scales.
Original language | English |
---|---|
Article number | 100017 |
Journal | Multimodal Transportation |
Volume | 1 |
Issue number | 2 |
DOIs | |
Publication status | Published - Jun 2022 |
Bibliographical note
Funding Information:The first author would like to thank the insightful discussions from Dr. Mohammed Hadi (Florida International University) and Dr. David Hale (Leidos, Inc.) about Congestion and Bottleneck Identification (CBI) Tool Software and multiresolution modeling in transportation systems analysis. The encouragements of Norman L Marshall (Smart Mobility Inc.) and Dr. Nagui M. Rouphail (NC State University) are gratefully acknowledged. We also appreciate the efforts and help from Dr. Arup Dutta, Dr. Wang Zhang, Haidong Zhu, and Dr. Vladimir Livshits from Maricopa Association of Governments in an early stage of this research direction.
Publisher Copyright:
© 2022 The Authors
Keywords
- Link performance function
- Mesoscopic to macroscopic modeling
- Multi-resolution approach
- Polynomial arrival queue model
- Time-dependent delay
- Volume-delay function