Salvato in:
Dettagli Bibliografici
Autori principali: Agarwal, Naaisha, Wu, Yihan, Jian, Yichang, Hu, Yikuan, Mansoor, Nishad, Li, Mohan, Peng, Yifei, Dai, Wang-Zhou, Ding, Yao-Xiang, Sansone, Emanuele
Natura: Preprint
Pubblicazione: 2026
Soggetti:
Accesso online:https://arxiv.org/abs/2603.13856
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866912970614767616
author Agarwal, Naaisha
Wu, Yihan
Jian, Yichang
Hu, Yikuan
Mansoor, Nishad
Li, Mohan
Peng, Yifei
Dai, Wang-Zhou
Ding, Yao-Xiang
Sansone, Emanuele
author_facet Agarwal, Naaisha
Wu, Yihan
Jian, Yichang
Hu, Yikuan
Mansoor, Nishad
Li, Mohan
Peng, Yifei
Dai, Wang-Zhou
Ding, Yao-Xiang
Sansone, Emanuele
contents Building AI systems that can plan, act, and create in the physical world requires more than pattern recognition. Such systems must understand the causal mechanisms and constraints governing physical processes in order to guide sequential decisions. This capability relies on internal representations, analogous to an internal language model, that relate observations, actions, and resulting environmental changes. However, many existing benchmarks treat visual perception and programmatic reasoning as separate problems, focusing either on visual recognition or on symbolic tasks. The domain of origami provides a natural testbed that integrates these modalities. Constructing shapes through folding operations requires visual perception, reasoning about geometric and physical constraints, and sequential planning, while remaining sufficiently structured for systematic evaluation. We introduce OrigamiBench, an interactive benchmark in which models iteratively propose folds and receive feedback on physical validity and similarity to a target configuration. Experiments with modern vision-language models show that scaling model size alone does not reliably produce causal reasoning about physical transformations. Models fail to generate coherent multi-step folding strategies, suggesting that visual and language representations remain weakly integrated.
format Preprint
id arxiv_https___arxiv_org_abs_2603_13856
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle OrigamiBench: An Interactive Environment to Synthesize Flat-Foldable Origamis
Agarwal, Naaisha
Wu, Yihan
Jian, Yichang
Hu, Yikuan
Mansoor, Nishad
Li, Mohan
Peng, Yifei
Dai, Wang-Zhou
Ding, Yao-Xiang
Sansone, Emanuele
Machine Learning
Computer Vision and Pattern Recognition
Building AI systems that can plan, act, and create in the physical world requires more than pattern recognition. Such systems must understand the causal mechanisms and constraints governing physical processes in order to guide sequential decisions. This capability relies on internal representations, analogous to an internal language model, that relate observations, actions, and resulting environmental changes. However, many existing benchmarks treat visual perception and programmatic reasoning as separate problems, focusing either on visual recognition or on symbolic tasks. The domain of origami provides a natural testbed that integrates these modalities. Constructing shapes through folding operations requires visual perception, reasoning about geometric and physical constraints, and sequential planning, while remaining sufficiently structured for systematic evaluation. We introduce OrigamiBench, an interactive benchmark in which models iteratively propose folds and receive feedback on physical validity and similarity to a target configuration. Experiments with modern vision-language models show that scaling model size alone does not reliably produce causal reasoning about physical transformations. Models fail to generate coherent multi-step folding strategies, suggesting that visual and language representations remain weakly integrated.
title OrigamiBench: An Interactive Environment to Synthesize Flat-Foldable Origamis
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.13856