Saved in:
Bibliographic Details
Main Authors: Vassilev, Apostol, Hasan, Munawar, Griffor, Edward, Jin, Honglan, Piliptchak, Pavel, Arora, Mahima, Gamage, Thoshitha
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.00314
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912863981928448
author Vassilev, Apostol
Hasan, Munawar
Griffor, Edward
Jin, Honglan
Piliptchak, Pavel
Arora, Mahima
Gamage, Thoshitha
author_facet Vassilev, Apostol
Hasan, Munawar
Griffor, Edward
Jin, Honglan
Piliptchak, Pavel
Arora, Mahima
Gamage, Thoshitha
contents The viability of automated driving is heavily dependent on the performance of perception systems to provide real-time accurate and reliable information for robust decision-making and maneuvers. These systems must perform reliably not only under ideal conditions, but also when challenged by natural and adversarial driving factors. Both of these types of interference can lead to perception errors and delays in detection and classification. Hence, it is essential to assess the robustness of the perception systems of automated vehicles (AVs) and explore strategies for making perception more reliable. We approach this problem by evaluating perception performance using predictive sensitivity quantification based on an ensemble of models, capturing model disagreement and inference variability across multiple models, under adverse driving scenarios in both simulated environments and real-world conditions. A notional architecture for assessing perception performance is proposed. A perception assessment criterion is developed based on an AV's stopping distance at a stop sign on varying road surfaces, such as dry and wet asphalt, and vehicle speed. Five state-of-the-art computer vision models are used, including YOLO (v8-v9), DEtection TRansformer (DETR50, DETR101), Real-Time DEtection TRansformer (RT-DETR)in our experiments. Diminished lighting conditions, e.g., resulting from the presence of fog and low sun altitude, have the greatest impact on the performance of the perception models. Additionally, adversarial road conditions such as occlusions of roadway objects increase perception sensitivity and model performance drops when faced with a combination of adversarial road conditions and inclement weather conditions. Also, it is demonstrated that the greater the distance to a roadway object, the greater the impact on perception performance, hence diminished perception robustness.
format Preprint
id arxiv_https___arxiv_org_abs_2602_00314
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle On the Assessment of Sensitivity of Autonomous Vehicle Perception
Vassilev, Apostol
Hasan, Munawar
Griffor, Edward
Jin, Honglan
Piliptchak, Pavel
Arora, Mahima
Gamage, Thoshitha
Computer Vision and Pattern Recognition
The viability of automated driving is heavily dependent on the performance of perception systems to provide real-time accurate and reliable information for robust decision-making and maneuvers. These systems must perform reliably not only under ideal conditions, but also when challenged by natural and adversarial driving factors. Both of these types of interference can lead to perception errors and delays in detection and classification. Hence, it is essential to assess the robustness of the perception systems of automated vehicles (AVs) and explore strategies for making perception more reliable. We approach this problem by evaluating perception performance using predictive sensitivity quantification based on an ensemble of models, capturing model disagreement and inference variability across multiple models, under adverse driving scenarios in both simulated environments and real-world conditions. A notional architecture for assessing perception performance is proposed. A perception assessment criterion is developed based on an AV's stopping distance at a stop sign on varying road surfaces, such as dry and wet asphalt, and vehicle speed. Five state-of-the-art computer vision models are used, including YOLO (v8-v9), DEtection TRansformer (DETR50, DETR101), Real-Time DEtection TRansformer (RT-DETR)in our experiments. Diminished lighting conditions, e.g., resulting from the presence of fog and low sun altitude, have the greatest impact on the performance of the perception models. Additionally, adversarial road conditions such as occlusions of roadway objects increase perception sensitivity and model performance drops when faced with a combination of adversarial road conditions and inclement weather conditions. Also, it is demonstrated that the greater the distance to a roadway object, the greater the impact on perception performance, hence diminished perception robustness.
title On the Assessment of Sensitivity of Autonomous Vehicle Perception
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2602.00314