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Autori principali: Kim, Donghoon, Lee, Dongyoung, Chang, Ik Joon, Bae, Sung-Ho
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2509.26436
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author Kim, Donghoon
Lee, Dongyoung
Chang, Ik Joon
Bae, Sung-Ho
author_facet Kim, Donghoon
Lee, Dongyoung
Chang, Ik Joon
Bae, Sung-Ho
contents Diffusion models achieve high-quality image generation but face deployment challenges due to their high computational requirements. Although 8-bit outlier-aware post-training quantization (PTQ) matches full-precision performance, extending PTQ to 4 bits remains challenging. Larger step sizes in 4-bit quantization amplify rounding errors in dense, low-magnitude activations, leading to the loss of fine-grained textures. We hypothesize that not only outliers but also small activations are critical for texture fidelity. To this end, we propose Quantization via Residual Truncation and Zero Suppression (QuaRTZ), a 4-bit PTQ scheme for diffusion models. QuaRTZ applies 8-bit min-max quantization for outlier handling and compresses to 4 bits via leading-zero suppression to retain LSBs, thereby preserving texture details. Our approach reduces rounding errors and improves quantization efficiency by balancing outlier preservation and LSB precision. Both theoretical derivations and empirical evaluations demonstrate the generalizability of QuaRTZ across diverse activation distributions. Notably, 4-bit QuaRTZ achieves an FID of 6.98 on FLUX.1-schnell, outperforming SVDQuant that requires auxiliary FP16 branches.
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publishDate 2025
record_format arxiv
spellingShingle Post-Training Quantization via Residual Truncation and Zero Suppression for Diffusion Models
Kim, Donghoon
Lee, Dongyoung
Chang, Ik Joon
Bae, Sung-Ho
Computer Vision and Pattern Recognition
Diffusion models achieve high-quality image generation but face deployment challenges due to their high computational requirements. Although 8-bit outlier-aware post-training quantization (PTQ) matches full-precision performance, extending PTQ to 4 bits remains challenging. Larger step sizes in 4-bit quantization amplify rounding errors in dense, low-magnitude activations, leading to the loss of fine-grained textures. We hypothesize that not only outliers but also small activations are critical for texture fidelity. To this end, we propose Quantization via Residual Truncation and Zero Suppression (QuaRTZ), a 4-bit PTQ scheme for diffusion models. QuaRTZ applies 8-bit min-max quantization for outlier handling and compresses to 4 bits via leading-zero suppression to retain LSBs, thereby preserving texture details. Our approach reduces rounding errors and improves quantization efficiency by balancing outlier preservation and LSB precision. Both theoretical derivations and empirical evaluations demonstrate the generalizability of QuaRTZ across diverse activation distributions. Notably, 4-bit QuaRTZ achieves an FID of 6.98 on FLUX.1-schnell, outperforming SVDQuant that requires auxiliary FP16 branches.
title Post-Training Quantization via Residual Truncation and Zero Suppression for Diffusion Models
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2509.26436