Analyzing the impact of traffic congestion mitigation: From an explainable neural network learning framework to marginal effect analyses

Jianping Sun; Jifu Guo; Xin Wu; Qian Zhu; Danting Wu; Kai Xian; Xuesong Zhou

doi:10.3390/s19102254

Analyzing the impact of traffic congestion mitigation: From an explainable neural network learning framework to marginal effect analyses

Jianping Sun, Jifu Guo, Xin Wu, Qian Zhu, Danting Wu, Kai Xian, Xuesong Zhou

Engineering, Ira A. Fulton Schools of (IAFSE)

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

Computational graphs (CGs) have been widely utilized in numerical analysis and deep learning to represent directed forward networks of data flows between operations. This paper aims to develop an explainable learning framework that can fully integrate three major steps of decision support: Synthesis of diverse traffic data, multilayered traffic demand estimation, and marginal effect analyses for transport policies. Following the big data-driven transportation computational graph (BTCG) framework, which is an emerging framework for explainable neural networks, we map different external traffic measurements collected from household survey data, mobile phone data, floating car data, and sensor networks to multilayered demand variables in a CG. Furthermore, we extend the CG-based framework by mapping different congestion mitigation strategies to CG layers individually or in combination, allowing the marginal effects and potential migration magnitudes of the strategies to be reliably quantified. Using the TensorFlow architecture, we evaluate our framework on the Sioux Falls network and present a large-scale case study based on a subnetwork of Beijing using a data set from the metropolitan planning organization.

Original language	English (US)
Article number	2254
Journal	Sensors (Switzerland)
Volume	19
Issue number	10
DOIs	https://doi.org/10.3390/s19102254
State	Published - May 2 2019

Keywords

Computational graph
Congestion mitigation
Marginal analyses
TensorFlow
Traffic demand estimation

ASJC Scopus subject areas

Analytical Chemistry
Information Systems
Instrumentation
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering
Biochemistry

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10.3390/s19102254

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title = "Analyzing the impact of traffic congestion mitigation: From an explainable neural network learning framework to marginal effect analyses",

abstract = "Computational graphs (CGs) have been widely utilized in numerical analysis and deep learning to represent directed forward networks of data flows between operations. This paper aims to develop an explainable learning framework that can fully integrate three major steps of decision support: Synthesis of diverse traffic data, multilayered traffic demand estimation, and marginal effect analyses for transport policies. Following the big data-driven transportation computational graph (BTCG) framework, which is an emerging framework for explainable neural networks, we map different external traffic measurements collected from household survey data, mobile phone data, floating car data, and sensor networks to multilayered demand variables in a CG. Furthermore, we extend the CG-based framework by mapping different congestion mitigation strategies to CG layers individually or in combination, allowing the marginal effects and potential migration magnitudes of the strategies to be reliably quantified. Using the TensorFlow architecture, we evaluate our framework on the Sioux Falls network and present a large-scale case study based on a subnetwork of Beijing using a data set from the metropolitan planning organization.",

keywords = "Computational graph, Congestion mitigation, Marginal analyses, TensorFlow, Traffic demand estimation",

author = "Jianping Sun and Jifu Guo and Xin Wu and Qian Zhu and Danting Wu and Kai Xian and Xuesong Zhou",

note = "Funding Information: This research project, especially the acquisition of the large-scale Beijing test network and the various traffic data sets, has been supported through the Beijing International Cooperation Base for Science and Technology on Urban Transport and the Beijing Key Laboratory of Urban Traffic Operation Simulation and Decision Support (BZ0012). This work was also partially supported by the China Natural Science Funding under Grant 61731004 and was supported by the National Natural Science Foundation of China under project no. 71734004, titled “Research on advanced theories for urban transportation governance”. The authors from Arizona State University are partially funded by the National Science Foundation of the United States under NSF Grant No. CMMI 1538105 “Collaborative Research: Improving Spatial Observability of Dynamic Traffic Systems through Active Mobile Sensor Networks and Crowdsourced Data” and NSF Grant No. CMMI 1663657 “Real-time Management of Large Fleets of Self-Driving Vehicles Using Virtual Cyber Tracks”. Funding Information: Funding: This research project, especially the acquisition of the large-scale Beijing test network and the various traffic data sets, has been supported through the Beijing International Cooperation Base for Science and Technology on Urban Transport and the Beijing Key Laboratory of Urban Traffic Operation Simulation and Decision Support (BZ0012). This work was also partially supported by the China Natural Science Funding under Grant 61731004 and was supported by the National Natural Science Foundation of China under project no. 71734004, titled “Research on advanced theories for urban transportation governance”. The authors from Arizona State University are partially funded by the National Science Foundation of the United States under NSF Grant No. CMMI 1538105 “Collaborative Research: Improving Spatial Observability of Dynamic Traffic Systems through Active Mobile Sensor Networks and Crowdsourced Data” and NSF Grant No. CMMI 1663657 “Real-time Management of Large Fleets of Self-Driving Vehicles Using Virtual Cyber Tracks”. Publisher Copyright: {\textcopyright} 2019 by the authors. Licensee MDPI, Basel, Switzerland.",

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N1 - Funding Information: This research project, especially the acquisition of the large-scale Beijing test network and the various traffic data sets, has been supported through the Beijing International Cooperation Base for Science and Technology on Urban Transport and the Beijing Key Laboratory of Urban Traffic Operation Simulation and Decision Support (BZ0012). This work was also partially supported by the China Natural Science Funding under Grant 61731004 and was supported by the National Natural Science Foundation of China under project no. 71734004, titled “Research on advanced theories for urban transportation governance”. The authors from Arizona State University are partially funded by the National Science Foundation of the United States under NSF Grant No. CMMI 1538105 “Collaborative Research: Improving Spatial Observability of Dynamic Traffic Systems through Active Mobile Sensor Networks and Crowdsourced Data” and NSF Grant No. CMMI 1663657 “Real-time Management of Large Fleets of Self-Driving Vehicles Using Virtual Cyber Tracks”. Funding Information: Funding: This research project, especially the acquisition of the large-scale Beijing test network and the various traffic data sets, has been supported through the Beijing International Cooperation Base for Science and Technology on Urban Transport and the Beijing Key Laboratory of Urban Traffic Operation Simulation and Decision Support (BZ0012). This work was also partially supported by the China Natural Science Funding under Grant 61731004 and was supported by the National Natural Science Foundation of China under project no. 71734004, titled “Research on advanced theories for urban transportation governance”. The authors from Arizona State University are partially funded by the National Science Foundation of the United States under NSF Grant No. CMMI 1538105 “Collaborative Research: Improving Spatial Observability of Dynamic Traffic Systems through Active Mobile Sensor Networks and Crowdsourced Data” and NSF Grant No. CMMI 1663657 “Real-time Management of Large Fleets of Self-Driving Vehicles Using Virtual Cyber Tracks”. Publisher Copyright: © 2019 by the authors. Licensee MDPI, Basel, Switzerland.

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N2 - Computational graphs (CGs) have been widely utilized in numerical analysis and deep learning to represent directed forward networks of data flows between operations. This paper aims to develop an explainable learning framework that can fully integrate three major steps of decision support: Synthesis of diverse traffic data, multilayered traffic demand estimation, and marginal effect analyses for transport policies. Following the big data-driven transportation computational graph (BTCG) framework, which is an emerging framework for explainable neural networks, we map different external traffic measurements collected from household survey data, mobile phone data, floating car data, and sensor networks to multilayered demand variables in a CG. Furthermore, we extend the CG-based framework by mapping different congestion mitigation strategies to CG layers individually or in combination, allowing the marginal effects and potential migration magnitudes of the strategies to be reliably quantified. Using the TensorFlow architecture, we evaluate our framework on the Sioux Falls network and present a large-scale case study based on a subnetwork of Beijing using a data set from the metropolitan planning organization.

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Analyzing the impact of traffic congestion mitigation: From an explainable neural network learning framework to marginal effect analyses

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