Quantized neural network for complex hologram generation

arXiv - CS - Graphics Pub Date : 2024-08-25 DOI:arxiv-2409.06711

Yutaka Endo, Minoru Oikawa, Timothy D. Wilkinson, Tomoyoshi Shimobaba, Tomoyoshi Ito

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Abstract

Computer-generated holography (CGH) is a promising technology for augmented reality displays, such as head-mounted or head-up displays. However, its high computational demand makes it impractical for implementation. Recent efforts to integrate neural networks into CGH have successfully accelerated computing speed, demonstrating the potential to overcome the trade-off between computational cost and image quality. Nevertheless, deploying neural network-based CGH algorithms on computationally limited embedded systems requires more efficient models with lower computational cost, memory footprint, and power consumption. In this study, we developed a lightweight model for complex hologram generation by introducing neural network quantization. Specifically, we built a model based on tensor holography and quantized it from 32-bit floating-point precision (FP32) to 8-bit integer precision (INT8). Our performance evaluation shows that the proposed INT8 model achieves hologram quality comparable to that of the FP32 model while reducing the model size by approximately 70% and increasing the speed fourfold. Additionally, we implemented the INT8 model on a system-on-module to demonstrate its deployability on embedded platforms and high power efficiency.

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用于生成复杂全息图的量化神经网络

计算机生成全息（CGH）是一种很有前途的增强现实显示技术，例如头戴式或平视显示器。然而，它对计算能力的高要求使其无法付诸实施。最近，将神经网络集成到 CGH 中的努力成功地加快了计算速度，证明了克服计算成本与图像质量之间权衡的潜力。然而，在计算能力有限的嵌入式系统上部署基于神经网络的 CGH 算法需要更高效的模型、更低的计算成本、内存占用和功耗。具体来说，我们建立了一个基于张量全息的模型，并将其从 32 位浮点精度（FP32）量化为 8 位整数精度（INT8）。我们的性能评估结果表明，所提出的 INT8 模型实现了与 FP32 模型相当的全息质量，同时将模型大小减少了约 70%，速度提高了四倍。此外，我们还在一个系统模块上实现了 INT8 模型，以证明它在嵌入式平台上的可部署性和高能效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Graphics

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