Time to equilibrium in a car-following scenario under local stable conditions
In traffic flow stability analysis, extensive research has been conducted on stability criteria, offering binary classifications of stability, that is, defining flow as stable or unstable. Despite being informative, this classification falls short of providing detailed characteristics of stability,...
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sg-ntu-dr.10356-1807882024-10-25T02:37:56Z Time to equilibrium in a car-following scenario under local stable conditions Zhuo, Junfan Zhu, Feng School of Civil and Environmental Engineering Engineering Traffic flow Time to equilibrium In traffic flow stability analysis, extensive research has been conducted on stability criteria, offering binary classifications of stability, that is, defining flow as stable or unstable. Despite being informative, this classification falls short of providing detailed characteristics of stability, such as the time required for a vehicle to regain equilibrium subject to a disturbance from a preceding vehicle. To address this problem, in this study, a quantitative metric, the time to equilibrium (TTE), is introduced under the condition of local stability. In a car-following scenario of two vehicles, considering that the preceding vehicle undergoes a short-term deceleration–acceleration change, an analytical formulation of the TTE is derived by employing linear stability analysis with the disturbance approximated using the Dirac delta function. The bisection method is then applied to approximate analytical solutions. Subsequent simulation experiments, utilizing various car-following parameters and disturbance settings, demonstrate the general validity of the proposed analytical TTE, barring some large errors in extreme scenarios (unlikely in real-world driving) and the intrinsic features of the Dirac delta function. We then provide applicable ranges for car-following parameters with different selection criteria. Lastly, by using real-world vehicle trajectory data, the proposed TTE is further validated. Ministry of Education (MOE) This study is supported by Singapore Ministry of Education Academic Research Fund Tier 1 RG79/21. 2024-10-25T02:37:55Z 2024-10-25T02:37:55Z 2024 Journal Article Zhuo, J. & Zhu, F. (2024). Time to equilibrium in a car-following scenario under local stable conditions. Transportation Research Record. https://dx.doi.org/10.1177/03611981241258986 0361-1981 https://hdl.handle.net/10356/180788 10.1177/03611981241258986 2-s2.0-85200012568 en RG79/21 Transportation Research Record © 2024 The Author(s). All rights reserved. |
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Engineering Traffic flow Time to equilibrium |
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Engineering Traffic flow Time to equilibrium Zhuo, Junfan Zhu, Feng Time to equilibrium in a car-following scenario under local stable conditions |
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In traffic flow stability analysis, extensive research has been conducted on stability criteria, offering binary classifications of stability, that is, defining flow as stable or unstable. Despite being informative, this classification falls short of providing detailed characteristics of stability, such as the time required for a vehicle to regain equilibrium subject to a disturbance from a preceding vehicle. To address this problem, in this study, a quantitative metric, the time to equilibrium (TTE), is introduced under the condition of local stability. In a car-following scenario of two vehicles, considering that the preceding vehicle undergoes a short-term deceleration–acceleration change, an analytical formulation of the TTE is derived by employing linear stability analysis with the disturbance approximated using the Dirac delta function. The bisection method is then applied to approximate analytical solutions. Subsequent simulation experiments, utilizing various car-following parameters and disturbance settings, demonstrate the general validity of the proposed analytical TTE, barring some large errors in extreme scenarios (unlikely in real-world driving) and the intrinsic features of the Dirac delta function. We then provide applicable ranges for car-following parameters with different selection criteria. Lastly, by using real-world vehicle trajectory data, the proposed TTE is further validated. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Zhuo, Junfan Zhu, Feng |
| format |
Article |
| author |
Zhuo, Junfan Zhu, Feng |
| author_sort |
Zhuo, Junfan |
| title |
Time to equilibrium in a car-following scenario under local stable conditions |
| title_short |
Time to equilibrium in a car-following scenario under local stable conditions |
| title_full |
Time to equilibrium in a car-following scenario under local stable conditions |
| title_fullStr |
Time to equilibrium in a car-following scenario under local stable conditions |
| title_full_unstemmed |
Time to equilibrium in a car-following scenario under local stable conditions |
| title_sort |
time to equilibrium in a car-following scenario under local stable conditions |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180788 |
| _version_ |
1814777762145107968 |