Saved in:
Bibliographic Details
Main Authors: Barboza, Pamela, Castelli, Víctor, Pereira, Belén, Grando, Ricardo, de Vargas, Bruna, Calfani, Augusto
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.08136
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909027988930560
author Barboza, Pamela
Castelli, Víctor
Pereira, Belén
Grando, Ricardo
de Vargas, Bruna
Calfani, Augusto
author_facet Barboza, Pamela
Castelli, Víctor
Pereira, Belén
Grando, Ricardo
de Vargas, Bruna
Calfani, Augusto
contents Visual perception plays a central role in competitive robotics, where environmental variations can directly affect real-time detection performance. The related literature on transformer-based detectors lack information regarding the impact of backbone scale and environmental settings on model performance. This work presents a comparative evaluation of RT-DETR for detecting round objects under environmental and hyperparameter variations relevant to competitive robotics. Four ResNet backbones (ResNet18, ResNet34, ResNet50, and ResNet101) were compared using dropout rates, analyzing their effect on confidence and accuracy. All models were trained under the same configuration and evaluated under changes in lighting and background contrast. Environmental conditions primarily impact prediction confidence, while inference latency remains largely unaffected and classification accuracy stays consistently high, approaching or above 1.00 in most cases. Two distinct behaviors were observed. Under illumination variation, ResNet50 achieves the best trade-off, combining near-perfect accuracy, confidence values up to approximately 0.869 and latency around 0.058-0.059 ms. Under background variation, ResNet34 provides the most balanced performance, reaching near-perfect accuracy and higher confidence values up to approximately 0.887. These results indicate that the optimal architecture depends on the type of environmental variation, with intermediate-depth models offering the best balance between performance and efficiency.
format Preprint
id arxiv_https___arxiv_org_abs_2605_08136
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Benchmarking ResNet Backbones in RT-DETR: Impact of Depth and Regularization under environmental conditions
Barboza, Pamela
Castelli, Víctor
Pereira, Belén
Grando, Ricardo
de Vargas, Bruna
Calfani, Augusto
Computer Vision and Pattern Recognition
Artificial Intelligence
Robotics
Visual perception plays a central role in competitive robotics, where environmental variations can directly affect real-time detection performance. The related literature on transformer-based detectors lack information regarding the impact of backbone scale and environmental settings on model performance. This work presents a comparative evaluation of RT-DETR for detecting round objects under environmental and hyperparameter variations relevant to competitive robotics. Four ResNet backbones (ResNet18, ResNet34, ResNet50, and ResNet101) were compared using dropout rates, analyzing their effect on confidence and accuracy. All models were trained under the same configuration and evaluated under changes in lighting and background contrast. Environmental conditions primarily impact prediction confidence, while inference latency remains largely unaffected and classification accuracy stays consistently high, approaching or above 1.00 in most cases. Two distinct behaviors were observed. Under illumination variation, ResNet50 achieves the best trade-off, combining near-perfect accuracy, confidence values up to approximately 0.869 and latency around 0.058-0.059 ms. Under background variation, ResNet34 provides the most balanced performance, reaching near-perfect accuracy and higher confidence values up to approximately 0.887. These results indicate that the optimal architecture depends on the type of environmental variation, with intermediate-depth models offering the best balance between performance and efficiency.
title Benchmarking ResNet Backbones in RT-DETR: Impact of Depth and Regularization under environmental conditions
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Robotics
url https://arxiv.org/abs/2605.08136