Second-Order Time to Collision With Non-Static Acceleration
Abstract
We propose a second-order time to collision (TTC) considering non-static acceleration and turning with realistic assumptions. This is equivalent to considering that the steering wheel is held at a fixed angle with constant pressure on the gas or brake pedal and matches the well-known bicycle model. Past works that use acceleration to compute TTC consider only longitudinally aligned acceleration. We additionally develop and present the Second-Order Time-to-Collision Algorithm using Region-based search (STAR) to efficiently compute the proposed second-order TTC and overcome the current limitations of the existing built-in functions. The evaluation of the algorithm in terms of error and computation time is conducted through statistical analysis. Through numerical simulations and publicly accessible real-world trajectory datasets, we show that the proposed second-order TTC with non-static acceleration is superior at reflecting accurate collision times, especially when turning is involved.
Cite
@article{arxiv.2502.08066,
title = {Second-Order Time to Collision With Non-Static Acceleration},
author = {Hossein Nick Zinat Matin and Yuneil Yeo and Amelie Ju-Kang Ngo and Antonio R. Paiva and Jean Utke and Maria Laura Delle Monache},
journal= {arXiv preprint arXiv:2502.08066},
year = {2025}
}
Comments
37 pages, 41 Figures