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    This study introduces VQCT-VLT, a framework that transfers codebooks from pretrained language models to vector quantization (VQ) for improved image synthesis. It addresses codebook collapse by leveraging semantic relationships and vision-language alignment for robust codebook learning.

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    Area of Science:

    • Computer Vision
    • Natural Language Processing
    • Machine Learning

    Background:

    • Vector quantization (VQ) is crucial for image synthesis, representing images as discrete tokens.
    • Current VQ methods struggle with codebook collapse due to learning from scratch and code-independent approaches.
    • Pretrained language models possess valuable, yet underutilized, codebook information.

    Purpose of the Study:

    • To propose a novel codebook transfer framework (VQCT-VLT) for robust vector quantization.
    • To leverage pretrained language models' codebooks to overcome challenges in VQ.
    • To enhance VQ by aligning vision and language semantics for superior image synthesis.

    Main Methods:

    • Developed a codebook transfer framework (VQCT-VLT) utilizing pretrained language models and part-of-speech knowledge.
    • Constructed a vision-related codebook using language model priors for effective codebook transfer.
    • Integrated a vision-to-language translation module with image captions for vision-language-aligned codebook learning.

    Main Results:

    • The VQCT-VLT method demonstrates superior performance in image synthesis tasks compared to state-of-the-art VQ methods.
    • Successfully transferred well-trained codebooks from language models, enhancing VQ robustness.
    • Achieved vision-language alignment in codebook learning, improving semantic relevance.

    Conclusions:

    • VQCT-VLT offers a robust approach to vector quantization by transferring knowledge from pretrained language models.
    • The framework effectively mitigates codebook collapse and improves image synthesis quality.
    • Vision-language alignment is key for developing semantically meaningful and high-performing VQ systems.