Optimizing Wildfire Evacuations through Scenario-Based Simulations with Autonomous Vehicles
Abstract
:1. Introduction
2. Materials and Methods
2.1. Case Study: Knolls Fire of 2020, Utah
2.2. Scenario Studies
2.2.1. Scenario 1—No Change
2.2.2. Scenario 2—Different Intersection Controls
2.2.3. Scenario 3—Lane Reversal
3. Results and Discussion
3.1. Scenario Results
3.2. Impact of AV Penetration
3.3. Travel Time Comparison
4. Conclusions
5. Recommendations
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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W99 Parameters Human-Driven | Definition | VISSIM Default | Adjusted Value |
---|---|---|---|
CC0 (m) | Standstill Distance | 1.5 | 1.6 |
CC1 (s) | Headway Time | 0.9 | 1.26 |
CC2 (m) | Following Variation | 4 | 19.4 |
CC3 (s) | Threshold for Entering Following | −8 | −5.37 |
CC4 (m/s) | Negative Following Threshold | −0.35 | −0.83 |
CC5 (m/s) | Positive Following Threshold | 0.35 | 0.83 |
CC6 (-) | Speed Dependency of Oscillation | 11.44 | 0.25 |
CC7 (m/s2) | Oscillation Acceleration | 0.25 | 0.34 |
CC8 (m/s2) | Standstill Acceleration | 3.5 | 1.18 |
CC9 (m/s2) | Acceleration at Speed of 80 km/h | 1.5 | 0.26 |
W99 Parameters Autonomous Vehicles | Definition | VISSIM Default Values for All Weather |
---|---|---|
CC0 (m) | Standstill Distance | 1.5 |
CC1 (s) | Headway Time | 0.9 |
CC2 (m) | Following Variation | 0 |
CC3 (s) | Threshold for Entering Following | −8 |
CC4 (m/s) | Negative Following Threshold | −0.1 |
CC5 (m/s) | Positive Following Threshold | 0.1 |
CC6 (-) | Speed Dependency of Oscillation | 0 |
CC7 (m/s2) | Oscillation Acceleration | 0.1 |
CC8 (m/s2) | Standstill Acceleration | 3.5 |
CC9 (m/s2) | Acceleration at Speed of 80 km/h | 1.5 |
Name | Start Link | Start Position (m) | End Link | End Position (m) | Distance (m) |
---|---|---|---|---|---|
Segment #1 | 1 | 79.287 | 1 | 403.991 | 324.7 |
Segment #2 | 1 | 404.898 | 6 | 243.026 | 535.39 |
Segment #3 | 6 | 243.75 | 19 | 278.559 | 767.23 |
Segment #4 | 19 | 278.631 | 23 | 315.229 | 824.05 |
Segment #5 | 23 | 314.837 | 23 | 875.286 | 560.45 |
Segment #6 | 23 | 874.729 | 23 | 1206.216 | 331.49 |
Segment #7 | 23 | 1205.496 | 41 | 183.039 | 509.21 |
Segment #8 | 41 | 183.067 | 41 | 559.107 | 376.04 |
Segment #9 | 41 | 559.87 | 57 | 163.05 | 437.03 |
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Ali, A.; Guo, M.; Ahmad, S.; Huang, Y.; Lu, P. Optimizing Wildfire Evacuations through Scenario-Based Simulations with Autonomous Vehicles. Fire 2024, 7, 340. https://doi.org/10.3390/fire7100340
Ali A, Guo M, Ahmad S, Huang Y, Lu P. Optimizing Wildfire Evacuations through Scenario-Based Simulations with Autonomous Vehicles. Fire. 2024; 7(10):340. https://doi.org/10.3390/fire7100340
Chicago/Turabian StyleAli, Asad, Mingwei Guo, Salman Ahmad, Ying Huang, and Pan Lu. 2024. "Optimizing Wildfire Evacuations through Scenario-Based Simulations with Autonomous Vehicles" Fire 7, no. 10: 340. https://doi.org/10.3390/fire7100340
APA StyleAli, A., Guo, M., Ahmad, S., Huang, Y., & Lu, P. (2024). Optimizing Wildfire Evacuations through Scenario-Based Simulations with Autonomous Vehicles. Fire, 7(10), 340. https://doi.org/10.3390/fire7100340