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Main Authors: Zhang, Yu, Zhou, Jialei, Li, Xinchen, Zhang, Qi, Wan, Zhongwei, Wang, Tianyu, Miao, Duoqian, Wang, Changwei, Cao, Longbing
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.19261
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author Zhang, Yu
Zhou, Jialei
Li, Xinchen
Zhang, Qi
Wan, Zhongwei
Wang, Tianyu
Miao, Duoqian
Wang, Changwei
Cao, Longbing
author_facet Zhang, Yu
Zhou, Jialei
Li, Xinchen
Zhang, Qi
Wan, Zhongwei
Wang, Tianyu
Miao, Duoqian
Wang, Changwei
Cao, Longbing
contents Current text-to-image diffusion generation typically employs complete-text conditioning. Due to the intricate syntax, diffusion transformers (DiTs) inherently suffer from a comprehension defect of complete-text captions. One-fly complete-text input either overlooks critical semantic details or causes semantic confusion by simultaneously modeling diverse semantic primitive types. To mitigate this defect of DiTs, we propose a novel split-text conditioning framework named DiT-ST. This framework converts a complete-text caption into a split-text caption, a collection of simplified sentences, to explicitly express various semantic primitives and their interconnections. The split-text caption is then injected into different denoising stages of DiT-ST in a hierarchical and incremental manner. Specifically, DiT-ST leverages Large Language Models to parse captions, extracting diverse primitives and hierarchically sorting out and constructing these primitives into a split-text input. Moreover, we partition the diffusion denoising process according to its differential sensitivities to diverse semantic primitive types and determine the appropriate timesteps to incrementally inject tokens of diverse semantic primitive types into input tokens via cross-attention. In this way, DiT-ST enhances the representation learning of specific semantic primitive types across different stages. Extensive experiments validate the effectiveness of our proposed DiT-ST in mitigating the complete-text comprehension defect.
format Preprint
id arxiv_https___arxiv_org_abs_2505_19261
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publishDate 2025
record_format arxiv
spellingShingle Enhancing Text-to-Image Diffusion Transformer via Split-Text Conditioning
Zhang, Yu
Zhou, Jialei
Li, Xinchen
Zhang, Qi
Wan, Zhongwei
Wang, Tianyu
Miao, Duoqian
Wang, Changwei
Cao, Longbing
Computer Vision and Pattern Recognition
Artificial Intelligence
Current text-to-image diffusion generation typically employs complete-text conditioning. Due to the intricate syntax, diffusion transformers (DiTs) inherently suffer from a comprehension defect of complete-text captions. One-fly complete-text input either overlooks critical semantic details or causes semantic confusion by simultaneously modeling diverse semantic primitive types. To mitigate this defect of DiTs, we propose a novel split-text conditioning framework named DiT-ST. This framework converts a complete-text caption into a split-text caption, a collection of simplified sentences, to explicitly express various semantic primitives and their interconnections. The split-text caption is then injected into different denoising stages of DiT-ST in a hierarchical and incremental manner. Specifically, DiT-ST leverages Large Language Models to parse captions, extracting diverse primitives and hierarchically sorting out and constructing these primitives into a split-text input. Moreover, we partition the diffusion denoising process according to its differential sensitivities to diverse semantic primitive types and determine the appropriate timesteps to incrementally inject tokens of diverse semantic primitive types into input tokens via cross-attention. In this way, DiT-ST enhances the representation learning of specific semantic primitive types across different stages. Extensive experiments validate the effectiveness of our proposed DiT-ST in mitigating the complete-text comprehension defect.
title Enhancing Text-to-Image Diffusion Transformer via Split-Text Conditioning
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2505.19261