Quantization-aware interval bound propagation for training certifiably robust quantized neural networks

We study the problem of training and certifying adversarially robust quantized neural networks (QNNs). Quantization is a technique for making neural networks more efficient by running them using low-bit integer arithmetic and is therefore commonly adopted in industry. Recent work has shown that floa...

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Main Authors: LECHNER, Mathias, ZIKELIC, Dorde, CHATTERJEE, Krishnendu, HENZINGER, A. Thomas, RUS, Daniela
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Language:English
Published: Institutional Knowledge at Singapore Management University 2023
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Online Access:https://ink.library.smu.edu.sg/sis_research/9082
https://ink.library.smu.edu.sg/context/sis_research/article/10085/viewcontent/26747_Article_Text_30810_1_2_20230626.pdf
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spelling sg-smu-ink.sis_research-100852024-08-01T15:17:02Z Quantization-aware interval bound propagation for training certifiably robust quantized neural networks LECHNER, Mathias ZIKELIC, Dorde CHATTERJEE, Krishnendu HENZINGER, A. Thomas RUS, Daniela We study the problem of training and certifying adversarially robust quantized neural networks (QNNs). Quantization is a technique for making neural networks more efficient by running them using low-bit integer arithmetic and is therefore commonly adopted in industry. Recent work has shown that floating-point neural networks that have been verified to be robust can become vulnerable to adversarial attacks after quantization, and certification of the quantized representation is necessary to guarantee robustness. In this work, we present quantization-aware interval bound propagation (QA-IBP), a novel method for training robust QNNs. Inspired by advances in robust learning of non-quantized networks, our training algorithm computes the gradient of an abstract representation of the actual network. Unlike existing approaches, our method can handle the discrete semantics of QNNs. Based on QA-IBP, we also develop a complete verification procedure for verifying the adversarial robustness of QNNs, which is guaranteed to terminate and produce a correct answer. Compared to existing approaches, the key advantage of our verification procedure is that it runs entirely on GPU or other accelerator devices. We demonstrate experimentally that our approach significantly outperforms existing methods and establish the new state-of-the-art for training and certifying the robustness of QNNs. 2023-02-01T08:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/9082 info:doi/10.1609/aaai.v37i12.26747 https://ink.library.smu.edu.sg/context/sis_research/article/10085/viewcontent/26747_Article_Text_30810_1_2_20230626.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University OS and Networks
institution Singapore Management University
building SMU Libraries
continent Asia
country Singapore
Singapore
content_provider SMU Libraries
collection InK@SMU
language English
topic OS and Networks
spellingShingle OS and Networks
LECHNER, Mathias
ZIKELIC, Dorde
CHATTERJEE, Krishnendu
HENZINGER, A. Thomas
RUS, Daniela
Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
description We study the problem of training and certifying adversarially robust quantized neural networks (QNNs). Quantization is a technique for making neural networks more efficient by running them using low-bit integer arithmetic and is therefore commonly adopted in industry. Recent work has shown that floating-point neural networks that have been verified to be robust can become vulnerable to adversarial attacks after quantization, and certification of the quantized representation is necessary to guarantee robustness. In this work, we present quantization-aware interval bound propagation (QA-IBP), a novel method for training robust QNNs. Inspired by advances in robust learning of non-quantized networks, our training algorithm computes the gradient of an abstract representation of the actual network. Unlike existing approaches, our method can handle the discrete semantics of QNNs. Based on QA-IBP, we also develop a complete verification procedure for verifying the adversarial robustness of QNNs, which is guaranteed to terminate and produce a correct answer. Compared to existing approaches, the key advantage of our verification procedure is that it runs entirely on GPU or other accelerator devices. We demonstrate experimentally that our approach significantly outperforms existing methods and establish the new state-of-the-art for training and certifying the robustness of QNNs.
format text
author LECHNER, Mathias
ZIKELIC, Dorde
CHATTERJEE, Krishnendu
HENZINGER, A. Thomas
RUS, Daniela
author_facet LECHNER, Mathias
ZIKELIC, Dorde
CHATTERJEE, Krishnendu
HENZINGER, A. Thomas
RUS, Daniela
author_sort LECHNER, Mathias
title Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
title_short Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
title_full Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
title_fullStr Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
title_full_unstemmed Quantization-aware interval bound propagation for training certifiably robust quantized neural networks
title_sort quantization-aware interval bound propagation for training certifiably robust quantized neural networks
publisher Institutional Knowledge at Singapore Management University
publishDate 2023
url https://ink.library.smu.edu.sg/sis_research/9082
https://ink.library.smu.edu.sg/context/sis_research/article/10085/viewcontent/26747_Article_Text_30810_1_2_20230626.pdf
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