Saved in:
Bibliographic Details
Main Authors: Ward, Isaac R., Ho, Michelle, Liu, Houjun, Feldman, Aaron, Vincent, Joseph, Kruse, Liam, Cheong, Sean, Eddy, Duncan, Kochenderfer, Mykel J., Schwager, Mac
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.06987
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866908871504691200
author Ward, Isaac R.
Ho, Michelle
Liu, Houjun
Feldman, Aaron
Vincent, Joseph
Kruse, Liam
Cheong, Sean
Eddy, Duncan
Kochenderfer, Mykel J.
Schwager, Mac
author_facet Ward, Isaac R.
Ho, Michelle
Liu, Houjun
Feldman, Aaron
Vincent, Joseph
Kruse, Liam
Cheong, Sean
Eddy, Duncan
Kochenderfer, Mykel J.
Schwager, Mac
contents Deploying visuomotor robots at scale is challenging due to the potential for anomalous failures to degrade performance, cause damage, or endanger human life. Bimanual manipulators are no exception; these robots have vast state spaces comprised of high-dimensional images and proprioceptive signals. Explicitly defining failure modes within such state spaces is infeasible. In this work, we overcome these challenges by training a probabilistic, history informed, world model within the compressed latent space of a pretrained vision foundation model (NVIDIA's Cosmos Tokenizer). The model outputs uncertainty estimates alongside its predictions that serve as non-conformity scores within a conformal prediction framework. We use these scores to develop a runtime monitor, correlating periods of high uncertainty with anomalous failures. To test these methods, we use the simulated Push-T environment and the Bimanual Cable Manipulation dataset, the latter of which we introduce in this work. This new dataset features trajectories with multiple synchronized camera views, proprioceptive signals, and annotated failures from a challenging data center maintenance task. We benchmark our methods against baselines from the anomaly detection and out-of-distribution detection literature, and show that our approach considerably outperforms statistical techniques. Furthermore, we show that our approach requires approximately one twentieth of the trainable parameters as the next-best learning-based approach, yet outperforms it by 3.8% in terms of failure detection rate, paving the way toward safely deploying manipulator robots in real-world environments where reliability is non-negotiable.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06987
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Foundational World Models Accurately Detect Bimanual Manipulator Failures
Ward, Isaac R.
Ho, Michelle
Liu, Houjun
Feldman, Aaron
Vincent, Joseph
Kruse, Liam
Cheong, Sean
Eddy, Duncan
Kochenderfer, Mykel J.
Schwager, Mac
Robotics
Artificial Intelligence
Deploying visuomotor robots at scale is challenging due to the potential for anomalous failures to degrade performance, cause damage, or endanger human life. Bimanual manipulators are no exception; these robots have vast state spaces comprised of high-dimensional images and proprioceptive signals. Explicitly defining failure modes within such state spaces is infeasible. In this work, we overcome these challenges by training a probabilistic, history informed, world model within the compressed latent space of a pretrained vision foundation model (NVIDIA's Cosmos Tokenizer). The model outputs uncertainty estimates alongside its predictions that serve as non-conformity scores within a conformal prediction framework. We use these scores to develop a runtime monitor, correlating periods of high uncertainty with anomalous failures. To test these methods, we use the simulated Push-T environment and the Bimanual Cable Manipulation dataset, the latter of which we introduce in this work. This new dataset features trajectories with multiple synchronized camera views, proprioceptive signals, and annotated failures from a challenging data center maintenance task. We benchmark our methods against baselines from the anomaly detection and out-of-distribution detection literature, and show that our approach considerably outperforms statistical techniques. Furthermore, we show that our approach requires approximately one twentieth of the trainable parameters as the next-best learning-based approach, yet outperforms it by 3.8% in terms of failure detection rate, paving the way toward safely deploying manipulator robots in real-world environments where reliability is non-negotiable.
title Foundational World Models Accurately Detect Bimanual Manipulator Failures
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2603.06987