English

When World Models Dream Wrong: Physical-Conditioned Adversarial Attacks against World Models

Machine Learning 2026-02-24 v1

Abstract

Generative world models (WMs) are increasingly used to synthesize controllable, sensor-conditioned driving videos, yet their reliance on physical priors exposes novel attack surfaces. In this paper, we present Physical-Conditioned World Model Attack (PhysCond-WMA), the first white-box world model attack that perturbs physical-condition channels, such as HDMap embeddings and 3D-box features, to induce semantic, logic, or decision-level distortion while preserving perceptual fidelity. PhysCond-WMA is optimized in two stages: (1) a quality-preserving guidance stage that constrains reverse-diffusion loss below a calibrated threshold, and (2) a momentum-guided denoising stage that accumulates target-aligned gradients along the denoising trajectory for stable, temporally coherent semantic shifts. Extensive experimental results demonstrate that our approach remains effective while increasing FID by about 9% on average and FVD by about 3.9% on average. Under the targeted attack setting, the attack success rate (ASR) reaches 0.55. Downstream studies further show tangible risk, which using attacked videos for training decreases 3D detection performance by about 4%, and worsens open-loop planning performance by about 20%. These findings has for the first time revealed and quantified security vulnerabilities in generative world models, driving more comprehensive security checkers.

Keywords

Cite

@article{arxiv.2602.18739,
  title  = {When World Models Dream Wrong: Physical-Conditioned Adversarial Attacks against World Models},
  author = {Zhixiang Guo and Siyuan Liang and Andras Balogh and Noah Lunberry and Rong-Cheng Tu and Mark Jelasity and Dacheng Tao},
  journal= {arXiv preprint arXiv:2602.18739},
  year   = {2026}
}
R2 v1 2026-07-01T10:45:30.403Z