论用于验证说话人的神经模型量化

IF 4.1 2区计算机科学 Q1 ACOUSTICS

IEEE/ACM Transactions on Audio, Speech, and Language Processing Pub Date : 2024-09-20 DOI:10.1109/TASLP.2024.3463430

Vishal Kumar;Vinayak Abrol;Mathew Magamai Doss

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引用次数: 0

摘要

本文探讨了当前训练后量化（PTQ）和量化感知训练（QAT）方法对于具有复杂架构元素（如信道聚合和挤压激励模块）的最先进扬声器验证（SV）模型的次优化问题。为了解决这些局限性，我们提出了：1）一种与数据无关的 PTQ 技术，在预训练模型上采用迭代低精度校准；2）一种与数据无关的 QAT 方法，旨在缩小全精度模型和整数模型之间的性能差距。我们的 QAT 包括两个渐进阶段，首先将 FP-32 权重转换为 FP-8，根据梯度规范调整精度，然后学习量化器参数（标度和零点）以进行 INT8 转换。实验验证凸显了我们在模型量化方面的独创性，证明我们减少了浮点运算和 INT8 推理时间，同时保持了与全精度模型相同的性能。

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On the Quantization of Neural Models for Speaker Verification

This paper addresses the sub-optimality of current post-training quantization (PTQ) and quantization-aware training (QAT) methods for state-of-the-art speaker verification (SV) models featuring intricate architectural elements such as channel aggregation and squeeze excitation modules. To address these limitations, we propose 1) a data-independent PTQ technique employing iterative low-precision calibration on pre-trained models; and 2) a data-dependent QAT method designed to reduce the performance gap between full-precision and integer models. Our QAT involves two progressive stages where FP-32 weights are initially transformed into FP-8, adapting precision based on the gradient norm, followed by the learning of quantizer parameters (scale and zero-point) for INT8 conversion. Experimental validation underscores the ingenuity of our method in model quantization, demonstrating reduced floating-point operations and INT8 inference time, all while maintaining performance on par with full-precision models.

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来源期刊

IEEE/ACM Transactions on Audio, Speech, and Language Processing ACOUSTICS-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

11.30

自引率

11.10%

发文量

217

期刊介绍： The IEEE/ACM Transactions on Audio, Speech, and Language Processing covers audio, speech and language processing and the sciences that support them. In audio processing: transducers, room acoustics, active sound control, human audition, analysis/synthesis/coding of music, and consumer audio. In speech processing: areas such as speech analysis, synthesis, coding, speech and speaker recognition, speech production and perception, and speech enhancement. In language processing: speech and text analysis, understanding, generation, dialog management, translation, summarization, question answering and document indexing and retrieval, as well as general language modeling.