Deep recommendation with iteration directional adversarial training

IF 3.3 3区 计算机科学 Q2 COMPUTER SCIENCE, THEORY & METHODS
Agyemang Paul, Yuxuan Wan, Zhefu Wu, Boyu Chen, Shufeng Gong
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Abstract

Deep neural networks are vulnerable to attacks, posing significant security concerns across various applications, particularly in computer vision. Adversarial training has demonstrated effectiveness in improving the robustness of deep learning models by incorporating perturbations into the input space during training. Recently, adversarial training has been successfully applied to deep recommender systems. In these systems, user and item embeddings are perturbed through a minimax game, with constraints on perturbation directions, to enhance the model’s robustness and generalization. However, they still fail to defend against iterative attacks, which have shown an over 60% increase in effectiveness in the computer vision domain. Deep recommender systems may therefore be more susceptible to iterative attacks, which might lead to generalization failures. In this paper, we adapt iterative examples for deep recommender systems. Specifically, we propose a Deep Recommender with Iteration Directional Adversarial Training (DRIDAT) that combines attention mechanism and directional adversarial training for recommendations. Firstly, we establish a consumer-product collaborative attention to convey consumers different preferences on their interested products and the distinct preferences of different consumers on the same product they like. Secondly, we train the DRIDAT objective function using adversarial learning to minimize the impact of iterative attack. In addition, the maximum direction attack could push the embedding vector of input attacks towards instances with distinct labels. We mitigate this problem by implementing suitable constraints on the direction of the attack. Finally, we perform a series of evaluations on two prominent datasets. The findings show that our methodology outperforms all other methods for all metrics.

Abstract Image

利用迭代定向对抗训练进行深度推荐
深度神经网络很容易受到攻击,这给各种应用,尤其是计算机视觉应用带来了严重的安全问题。对抗训练通过在训练过程中将扰动纳入输入空间,在提高深度学习模型的鲁棒性方面表现出了有效性。最近,对抗训练已成功应用于深度推荐系统。在这些系统中,通过最小博弈(minimax game)对用户和项目嵌入进行扰动,并对扰动方向进行约束,以增强模型的鲁棒性和泛化能力。然而,它们仍然无法抵御迭代攻击,而在计算机视觉领域,迭代攻击的有效性提高了 60% 以上。因此,深度推荐系统可能更容易受到迭代攻击,从而导致泛化失败。在本文中,我们为深度推荐系统调整了迭代示例。具体来说,我们提出了一种具有迭代定向对抗训练的深度推荐系统(DRIDAT),它结合了注意力机制和定向对抗训练来进行推荐。首先,我们建立了消费者-产品协同关注机制,以传递消费者对其感兴趣产品的不同偏好,以及不同消费者对其喜欢的同一产品的不同偏好。其次,我们利用对抗学习来训练 DRIDAT 目标函数,以尽量减少迭代攻击的影响。此外,最大方向攻击可能会将输入攻击的嵌入向量推向具有不同标签的实例。我们通过对攻击方向实施适当的限制来缓解这一问题。最后,我们在两个著名的数据集上进行了一系列评估。结果表明,在所有指标上,我们的方法都优于所有其他方法。
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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来源期刊
Computing
Computing 工程技术-计算机:理论方法
CiteScore
8.20
自引率
2.70%
发文量
107
审稿时长
3 months
期刊介绍: Computing publishes original papers, short communications and surveys on all fields of computing. The contributions should be written in English and may be of theoretical or applied nature, the essential criteria are computational relevance and systematic foundation of results.
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