High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region

Juliette Ugirumurera; Joseph Severino; Qichao Wang; Harry Sorensen; Austin Todd; Ambarish Nag; Kristin Potter; Wesley Jones; Srinath Ravulaparthy; Anne Berres; Philip Nugent; Alex Moore; Sarah Tennille; Steven Peterson; Haowen Xu; Jibonananda Sanyal

High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region

Juliette Ugirumurera
, Joseph Severino
, Qichao Wang
, Harry Sorensen
, Austin Todd
, Ambarish Nag
, Kristin Potter
, Wesley Jones
, Srinath Ravulaparthy
, Anne Berres
, Philip Nugent
, Alex Moore
, Sarah Tennille
, Steven Peterson
, Haowen Xu
, Jibonananda Sanyal

Computational Science

Oak Ridge National Laboratory

Research output: NLR › Poster

Abstract

In 2019, highway congestion wasted over 3 billion gallons of fuel and caused 8.8 billion hours of lost productivity.1 Research has shown that introducing near-real time traffic controls can significantly reduce congestion. Validated and calibrated traffic simulations enable the modeling of transportation systems and the evaluation of different traffic control actions and schemes given a variety of circumstances that represent likely future scenarios. The developed scenarios can inform the deployment of controls in near real-time to improve freight and passenger vehicle congestion and energy use. In this work, we present simulations used to model the traffic in the Chattanooga, Tennessee, metropolitan area. Simulations were constructed and calibrated using a variety of local, data science enhanced, data sources utilizing open source software including the Simulation of Urban Mobility (SUMO) simulator. High-Performance Computing (HPC) provides a scalable platform with enough computing for the high-fidelity simulation of many scenarios and the application of advance data science especially for large-scale systems. Our simulations include microscopic simulations at a corridor level for traffic signal control, and mesoscopic simulations to evaluate regional operational controls and infrastructure.

Original language	American English
Publisher	National Laboratory of the Rockies (NLR)
State	Published - 2019

Publication series

Name	Presented at the 2019 Tennessee Sustainable Transportation Forum & Expo, 1-2 October 2019, Knoxville, Tennessee

NLR Publication Number

NREL/PO-2C00-75009

Keywords

high performance computing
HPC
real-time traffic control
traffic simulation

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Ugirumurera, J., Severino, J., Wang, Q., Sorensen, H., Todd, A., Nag, A., Potter, K., Jones, W., Ravulaparthy, S., Berres, A., Nugent, P., Moore, A., Tennille, S., Peterson, S., Xu, H., & Sanyal, J. (2019). High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region. National Laboratory of the Rockies (NLR). https://www.nlr.gov/docs/fy20osti/75009.pdf

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title = "High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region",

abstract = "In 2019, highway congestion wasted over 3 billion gallons of fuel and caused 8.8 billion hours of lost productivity.1 Research has shown that introducing near-real time traffic controls can significantly reduce congestion. Validated and calibrated traffic simulations enable the modeling of transportation systems and the evaluation of different traffic control actions and schemes given a variety of circumstances that represent likely future scenarios. The developed scenarios can inform the deployment of controls in near real-time to improve freight and passenger vehicle congestion and energy use. In this work, we present simulations used to model the traffic in the Chattanooga, Tennessee, metropolitan area. Simulations were constructed and calibrated using a variety of local, data science enhanced, data sources utilizing open source software including the Simulation of Urban Mobility (SUMO) simulator. High-Performance Computing (HPC) provides a scalable platform with enough computing for the high-fidelity simulation of many scenarios and the application of advance data science especially for large-scale systems. Our simulations include microscopic simulations at a corridor level for traffic signal control, and mesoscopic simulations to evaluate regional operational controls and infrastructure.",

keywords = "high performance computing, HPC, real-time traffic control, traffic simulation",

author = "Juliette Ugirumurera and Joseph Severino and Qichao Wang and Harry Sorensen and Austin Todd and Ambarish Nag and Kristin Potter and Wesley Jones and Srinath Ravulaparthy and Anne Berres and Philip Nugent and Alex Moore and Sarah Tennille and Steven Peterson and Haowen Xu and Jibonananda Sanyal",

year = "2019",

language = "American English",

series = "Presented at the 2019 Tennessee Sustainable Transportation Forum \& Expo, 1-2 October 2019, Knoxville, Tennessee",

publisher = "National Laboratory of the Rockies (NLR)",

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Ugirumurera, J , Severino, J , Wang, Q , Sorensen, H, Todd, A, Nag, A, Potter, K , Jones, W, Ravulaparthy, S, Berres, A, Nugent, P, Moore, A, Tennille, S, Peterson, S, Xu, H & Sanyal, J 2019, High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region. National Laboratory of the Rockies (NLR). <https://www.nlr.gov/docs/fy20osti/75009.pdf>

TY - GEN

T1 - High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region

AU - Ugirumurera, Juliette

AU - Severino, Joseph

AU - Wang, Qichao

AU - Sorensen, Harry

AU - Todd, Austin

AU - Nag, Ambarish

AU - Potter, Kristin

AU - Jones, Wesley

AU - Ravulaparthy, Srinath

AU - Berres, Anne

AU - Nugent, Philip

AU - Moore, Alex

AU - Tennille, Sarah

AU - Peterson, Steven

AU - Xu, Haowen

AU - Sanyal, Jibonananda

PY - 2019

Y1 - 2019

N2 - In 2019, highway congestion wasted over 3 billion gallons of fuel and caused 8.8 billion hours of lost productivity.1 Research has shown that introducing near-real time traffic controls can significantly reduce congestion. Validated and calibrated traffic simulations enable the modeling of transportation systems and the evaluation of different traffic control actions and schemes given a variety of circumstances that represent likely future scenarios. The developed scenarios can inform the deployment of controls in near real-time to improve freight and passenger vehicle congestion and energy use. In this work, we present simulations used to model the traffic in the Chattanooga, Tennessee, metropolitan area. Simulations were constructed and calibrated using a variety of local, data science enhanced, data sources utilizing open source software including the Simulation of Urban Mobility (SUMO) simulator. High-Performance Computing (HPC) provides a scalable platform with enough computing for the high-fidelity simulation of many scenarios and the application of advance data science especially for large-scale systems. Our simulations include microscopic simulations at a corridor level for traffic signal control, and mesoscopic simulations to evaluate regional operational controls and infrastructure.

AB - In 2019, highway congestion wasted over 3 billion gallons of fuel and caused 8.8 billion hours of lost productivity.1 Research has shown that introducing near-real time traffic controls can significantly reduce congestion. Validated and calibrated traffic simulations enable the modeling of transportation systems and the evaluation of different traffic control actions and schemes given a variety of circumstances that represent likely future scenarios. The developed scenarios can inform the deployment of controls in near real-time to improve freight and passenger vehicle congestion and energy use. In this work, we present simulations used to model the traffic in the Chattanooga, Tennessee, metropolitan area. Simulations were constructed and calibrated using a variety of local, data science enhanced, data sources utilizing open source software including the Simulation of Urban Mobility (SUMO) simulator. High-Performance Computing (HPC) provides a scalable platform with enough computing for the high-fidelity simulation of many scenarios and the application of advance data science especially for large-scale systems. Our simulations include microscopic simulations at a corridor level for traffic signal control, and mesoscopic simulations to evaluate regional operational controls and infrastructure.

KW - high performance computing

KW - HPC

KW - real-time traffic control

KW - traffic simulation

M3 - Poster

T3 - Presented at the 2019 Tennessee Sustainable Transportation Forum & Expo, 1-2 October 2019, Knoxville, Tennessee

PB - National Laboratory of the Rockies (NLR)

ER -

High Performance Computing Traffic Simulations for Real-Time Traffic Control of Mobility in Chattanooga Region

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