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Hauptverfasser: Jiang, Songtao, Song, Sibo, Zhou, Chenyi, Wang, Yuan, Chen, Ruizhe, Guan, Tongkun, Luo, Ruilin, Zhang, Yan, Tang, Zhihang, Sun, Yuchong, Zhang, Hang, Yang, Zhibo, Bai, Shuai, Lin, Junyang, Liu, Zuozhu
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.17693
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author Jiang, Songtao
Song, Sibo
Zhou, Chenyi
Wang, Yuan
Chen, Ruizhe
Guan, Tongkun
Luo, Ruilin
Zhang, Yan
Tang, Zhihang
Sun, Yuchong
Zhang, Hang
Yang, Zhibo
Bai, Shuai
Lin, Junyang
Liu, Zuozhu
author_facet Jiang, Songtao
Song, Sibo
Zhou, Chenyi
Wang, Yuan
Chen, Ruizhe
Guan, Tongkun
Luo, Ruilin
Zhang, Yan
Tang, Zhihang
Sun, Yuchong
Zhang, Hang
Yang, Zhibo
Bai, Shuai
Lin, Junyang
Liu, Zuozhu
contents The transition from image to video understanding requires vision-language models (VLMs) to shift from recognizing static patterns to reasoning over temporal dynamics such as motion trajectories, speed changes, and state transitions. Yet current post-training methods fall short due to two critical limitations: (1) existing datasets often lack temporal-centricity, where answers can be inferred from isolated keyframes rather than requiring holistic temporal integration; and (2) training data generated by proprietary models contains systematic errors in fundamental temporal perception, such as confusing motion directions or misjudging speeds. We introduce SynRL, a post-training framework that teaches models temporal primitives, the fundamental building blocks of temporal understanding including direction, speed, and state tracking. Our key insight is that these abstract primitives, learned from programmatically generated synthetic videos, transfer effectively to real-world scenarios. We decompose temporal understanding into short-term perceptual primitives (speed, direction) and long-term cognitive primitives, constructing 7.7K CoT and 7K RL samples with ground-truth frame-level annotations through code-based video generation. Despite training on simple geometric shapes, SynRL achieves substantial improvements across 15 benchmarks spanning temporal grounding, complex reasoning, and general video understanding. Remarkably, our 7.7K synthetic CoT samples outperform Video-R1 with 165K real-world samples. We attribute this to fundamental temporal skills, such as tracking frame by frame changes and comparing velocity, that transfer effectively from abstract synthetic patterns to complex real-world scenarios. This establishes a new paradigm for video post-training: video temporal learning through carefully designed synthetic data provides a more cost efficient scaling path.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17693
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning Transferable Temporal Primitives for Video Reasoning via Synthetic Videos
Jiang, Songtao
Song, Sibo
Zhou, Chenyi
Wang, Yuan
Chen, Ruizhe
Guan, Tongkun
Luo, Ruilin
Zhang, Yan
Tang, Zhihang
Sun, Yuchong
Zhang, Hang
Yang, Zhibo
Bai, Shuai
Lin, Junyang
Liu, Zuozhu
Computer Vision and Pattern Recognition
The transition from image to video understanding requires vision-language models (VLMs) to shift from recognizing static patterns to reasoning over temporal dynamics such as motion trajectories, speed changes, and state transitions. Yet current post-training methods fall short due to two critical limitations: (1) existing datasets often lack temporal-centricity, where answers can be inferred from isolated keyframes rather than requiring holistic temporal integration; and (2) training data generated by proprietary models contains systematic errors in fundamental temporal perception, such as confusing motion directions or misjudging speeds. We introduce SynRL, a post-training framework that teaches models temporal primitives, the fundamental building blocks of temporal understanding including direction, speed, and state tracking. Our key insight is that these abstract primitives, learned from programmatically generated synthetic videos, transfer effectively to real-world scenarios. We decompose temporal understanding into short-term perceptual primitives (speed, direction) and long-term cognitive primitives, constructing 7.7K CoT and 7K RL samples with ground-truth frame-level annotations through code-based video generation. Despite training on simple geometric shapes, SynRL achieves substantial improvements across 15 benchmarks spanning temporal grounding, complex reasoning, and general video understanding. Remarkably, our 7.7K synthetic CoT samples outperform Video-R1 with 165K real-world samples. We attribute this to fundamental temporal skills, such as tracking frame by frame changes and comparing velocity, that transfer effectively from abstract synthetic patterns to complex real-world scenarios. This establishes a new paradigm for video post-training: video temporal learning through carefully designed synthetic data provides a more cost efficient scaling path.
title Learning Transferable Temporal Primitives for Video Reasoning via Synthetic Videos
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.17693