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Autori principali: Zeng, Xianming, Du, Sicong, Chen, Qifeng, Liu, Lizhe, Shu, Haoyu, Gao, Jiaxuan, Liu, Jiarun, Xu, Jiulong, Xu, Jianyun, Chen, Mingxia, Zhao, Yiru, Chen, Peng, Xue, Yapeng, Zhao, Chunming, Yang, Sheng, Li, Qiang
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2503.11731
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author Zeng, Xianming
Du, Sicong
Chen, Qifeng
Liu, Lizhe
Shu, Haoyu
Gao, Jiaxuan
Liu, Jiarun
Xu, Jiulong
Xu, Jianyun
Chen, Mingxia
Zhao, Yiru
Chen, Peng
Xue, Yapeng
Zhao, Chunming
Yang, Sheng
Li, Qiang
author_facet Zeng, Xianming
Du, Sicong
Chen, Qifeng
Liu, Lizhe
Shu, Haoyu
Gao, Jiaxuan
Liu, Jiarun
Xu, Jiulong
Xu, Jianyun
Chen, Mingxia
Zhao, Yiru
Chen, Peng
Xue, Yapeng
Zhao, Chunming
Yang, Sheng
Li, Qiang
contents Sensor simulation is pivotal for scalable validation of autonomous driving systems, yet existing Neural Radiance Fields (NeRF) based methods face applicability and efficiency challenges in industrial workflows. This paper introduces a Gaussian Splatting (GS) based system to address these challenges: We first break down sensor simulator components and analyze the possible advantages of GS over NeRF. Then in practice, we refactor three crucial components through GS, to leverage its explicit scene representation and real-time rendering: (1) choosing the 2D neural Gaussian representation for physics-compliant scene and sensor modeling, (2) proposing a scene editing pipeline to leverage Gaussian primitives library for data augmentation, and (3) coupling a controllable diffusion model for scene expansion and harmonization. We implement this framework on a proprietary autonomous driving dataset supporting cameras and LiDAR sensors. We demonstrate through ablation studies that our approach reduces frame-wise simulation latency, achieves better geometric and photometric consistency, and enables interpretable explicit scene editing and expansion. Furthermore, we showcase how integrating such a GS-based sensor simulator with traffic and dynamic simulators enables full-stack testing of end-to-end autonomy algorithms. Our work provides both algorithmic insights and practical validation, establishing GS as a cornerstone for industrial-grade sensor simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2503_11731
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Industrial-Grade Sensor Simulation via Gaussian Splatting: A Modular Framework for Scalable Editing and Full-Stack Validation
Zeng, Xianming
Du, Sicong
Chen, Qifeng
Liu, Lizhe
Shu, Haoyu
Gao, Jiaxuan
Liu, Jiarun
Xu, Jiulong
Xu, Jianyun
Chen, Mingxia
Zhao, Yiru
Chen, Peng
Xue, Yapeng
Zhao, Chunming
Yang, Sheng
Li, Qiang
Computer Vision and Pattern Recognition
Robotics
Sensor simulation is pivotal for scalable validation of autonomous driving systems, yet existing Neural Radiance Fields (NeRF) based methods face applicability and efficiency challenges in industrial workflows. This paper introduces a Gaussian Splatting (GS) based system to address these challenges: We first break down sensor simulator components and analyze the possible advantages of GS over NeRF. Then in practice, we refactor three crucial components through GS, to leverage its explicit scene representation and real-time rendering: (1) choosing the 2D neural Gaussian representation for physics-compliant scene and sensor modeling, (2) proposing a scene editing pipeline to leverage Gaussian primitives library for data augmentation, and (3) coupling a controllable diffusion model for scene expansion and harmonization. We implement this framework on a proprietary autonomous driving dataset supporting cameras and LiDAR sensors. We demonstrate through ablation studies that our approach reduces frame-wise simulation latency, achieves better geometric and photometric consistency, and enables interpretable explicit scene editing and expansion. Furthermore, we showcase how integrating such a GS-based sensor simulator with traffic and dynamic simulators enables full-stack testing of end-to-end autonomy algorithms. Our work provides both algorithmic insights and practical validation, establishing GS as a cornerstone for industrial-grade sensor simulation.
title Industrial-Grade Sensor Simulation via Gaussian Splatting: A Modular Framework for Scalable Editing and Full-Stack Validation
topic Computer Vision and Pattern Recognition
Robotics
url https://arxiv.org/abs/2503.11731