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1. Enhancing Transferability of Adversarial Attacks with GE-AdvGAN+: A Comprehensive Framework for Gradient Editing

Author

Jin, Zhibo, Zhang, Jiayu, Zhu, Zhiyu, Zhang, Chenyu, Huang, Jiahao, Zhou, Jianlong, and Chen, Fang

Subjects
Computer Science - Artificial Intelligence
Abstract

Transferable adversarial attacks pose significant threats to deep neural networks, particularly in black-box scenarios where internal model information is inaccessible. Studying adversarial attack methods helps advance the performance of defense mechanisms and explore model vulnerabilities. These methods can uncover and exploit weaknesses in models, promoting the development of more robust architectures. However, current methods for transferable attacks often come with substantial computational costs, limiting their deployment and application, especially in edge computing scenarios. Adversarial generative models, such as Generative Adversarial Networks (GANs), are characterized by their ability to generate samples without the need for retraining after an initial training phase. GE-AdvGAN, a recent method for transferable adversarial attacks, is based on this principle. In this paper, we propose a novel general framework for gradient editing-based transferable attacks, named GE-AdvGAN+, which integrates nearly all mainstream attack methods to enhance transferability while significantly reducing computational resource consumption. Our experiments demonstrate the compatibility and effectiveness of our framework. Compared to the baseline AdvGAN, our best-performing method, GE-AdvGAN++, achieves an average ASR improvement of 47.8. Additionally, it surpasses the latest competing algorithm, GE-AdvGAN, with an average ASR increase of 5.9. The framework also exhibits enhanced computational efficiency, achieving 2217.7 FPS, outperforming traditional methods such as BIM and MI-FGSM. The implementation code for our GE-AdvGAN+ framework is available at https://github.com/GEAdvGANP

Published
2024

2. Leveraging Information Consistency in Frequency and Spatial Domain for Adversarial Attacks

Author

Jin, Zhibo, Zhang, Jiayu, Zhu, Zhiyu, Wang, Xinyi, Huang, Yiyun, and Chen, Huaming

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Adversarial examples are a key method to exploit deep neural networks. Using gradient information, such examples can be generated in an efficient way without altering the victim model. Recent frequency domain transformation has further enhanced the transferability of such adversarial examples, such as spectrum simulation attack. In this work, we investigate the effectiveness of frequency domain-based attacks, aligning with similar findings in the spatial domain. Furthermore, such consistency between the frequency and spatial domains provides insights into how gradient-based adversarial attacks induce perturbations across different domains, which is yet to be explored. Hence, we propose a simple, effective, and scalable gradient-based adversarial attack algorithm leveraging the information consistency in both frequency and spatial domains. We evaluate the algorithm for its effectiveness against different models. Extensive experiments demonstrate that our algorithm achieves state-of-the-art results compared to other gradient-based algorithms. Our code is available at: https://github.com/LMBTough/FSA., Comment: Accepted by PRICAI 2024

Published
2024

3. Enhancing Model Interpretability with Local Attribution over Global Exploration

Author

Zhu, Zhiyu, Jin, Zhibo, Zhang, Jiayu, and Chen, Huaming

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

In the field of artificial intelligence, AI models are frequently described as `black boxes' due to the obscurity of their internal mechanisms. It has ignited research interest on model interpretability, especially in attribution methods that offers precise explanations of model decisions. Current attribution algorithms typically evaluate the importance of each parameter by exploring the sample space. A large number of intermediate states are introduced during the exploration process, which may reach the model's Out-of-Distribution (OOD) space. Such intermediate states will impact the attribution results, making it challenging to grasp the relative importance of features. In this paper, we firstly define the local space and its relevant properties, and we propose the Local Attribution (LA) algorithm that leverages these properties. The LA algorithm comprises both targeted and untargeted exploration phases, which are designed to effectively generate intermediate states for attribution that thoroughly encompass the local space. Compared to the state-of-the-art attribution methods, our approach achieves an average improvement of 38.21\% in attribution effectiveness. Extensive ablation studies in our experiments also validate the significance of each component in our algorithm. Our code is available at: https://github.com/LMBTough/LA/, Comment: Accepted by ACMMM 2024

Published
2024

4. Enhancing Adversarial Attacks via Parameter Adaptive Adversarial Attack

Author

Jin, Zhibo, Zhang, Jiayu, Zhu, Zhiyu, Zhang, Chenyu, Huang, Jiahao, Zhou, Jianlong, and Chen, Fang

Subjects
Computer Science - Machine Learning, Computer Science - Cryptography and Security
Abstract

In recent times, the swift evolution of adversarial attacks has captured widespread attention, particularly concerning their transferability and other performance attributes. These techniques are primarily executed at the sample level, frequently overlooking the intrinsic parameters of models. Such neglect suggests that the perturbations introduced in adversarial samples might have the potential for further reduction. Given the essence of adversarial attacks is to impair model integrity with minimal noise on original samples, exploring avenues to maximize the utility of such perturbations is imperative. Against this backdrop, we have delved into the complexities of adversarial attack algorithms, dissecting the adversarial process into two critical phases: the Directional Supervision Process (DSP) and the Directional Optimization Process (DOP). While DSP determines the direction of updates based on the current samples and model parameters, it has been observed that existing model parameters may not always be conducive to adversarial attacks. The impact of models on adversarial efficacy is often overlooked in current research, leading to the neglect of DSP. We propose that under certain conditions, fine-tuning model parameters can significantly enhance the quality of DSP. For the first time, we propose that under certain conditions, fine-tuning model parameters can significantly improve the quality of the DSP. We provide, for the first time, rigorous mathematical definitions and proofs for these conditions, and introduce multiple methods for fine-tuning model parameters within DSP. Our extensive experiments substantiate the effectiveness of the proposed P3A method. Our code is accessible at: https://anonymous.4open.science/r/P3A-A12C/

Published
2024

5. DMS: Addressing Information Loss with More Steps for Pragmatic Adversarial Attacks

Author

Zhu, Zhiyu, Zhang, Jiayu, Wang, Xinyi, Jin, Zhibo, and Chen, Huaming

Subjects
Computer Science - Cryptography and Security, Computer Science - Machine Learning
Abstract

Despite the exceptional performance of deep neural networks (DNNs) across different domains, they are vulnerable to adversarial samples, in particular for tasks related to computer vision. Such vulnerability is further influenced by the digital container formats used in computers, where the discrete numerical values are commonly used for storing the pixel values. This paper examines how information loss in file formats impacts the effectiveness of adversarial attacks. Notably, we observe a pronounced hindrance to the adversarial attack performance due to the information loss of the non-integer pixel values. To address this issue, we explore to leverage the gradient information of the attack samples within the model to mitigate the information loss. We introduce the Do More Steps (DMS) algorithm, which hinges on two core techniques: gradient ascent-based \textit{adversarial integerization} (DMS-AI) and integrated gradients-based \textit{attribution selection} (DMS-AS). Our goal is to alleviate such lossy process to retain the attack performance when storing these adversarial samples digitally. In particular, DMS-AI integerizes the non-integer pixel values according to the gradient direction, and DMS-AS selects the non-integer pixels by comparing attribution results. We conduct thorough experiments to assess the effectiveness of our approach, including the implementations of the DMS-AI and DMS-AS on two large-scale datasets with various latest gradient-based attack methods. Our empirical findings conclusively demonstrate the superiority of our proposed DMS-AI and DMS-AS pixel integerization methods over the standardised methods, such as rounding, truncating and upper approaches, in maintaining attack integrity.

Published
2024

9. A pathology foundation model for cancer diagnosis and prognosis prediction

Author

Wang, Xiyue, Zhao, Junhan, Marostica, Eliana, Yuan, Wei, Jin, Jietian, Zhang, Jiayu, Li, Ruijiang, Tang, Hongping, Wang, Kanran, Li, Yu, Wang, Fang, Peng, Yulong, Zhu, Junyou, Zhang, Jing, Jackson, Christopher R., Zhang, Jun, Dillon, Deborah, Lin, Nancy U., Sholl, Lynette, Denize, Thomas, Meredith, David, Ligon, Keith L., Signoretti, Sabina, Ogino, Shuji, Golden, Jeffrey A., Nasrallah, MacLean P., Han, Xiao, Yang, Sen, and Yu, Kun-Hsing

Published
2024
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17. Benchmarking Transferable Adversarial Attacks

Author

Jin, Zhibo, Zhang, Jiayu, Zhu, Zhiyu, and Chen, Huaming

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

The robustness of deep learning models against adversarial attacks remains a pivotal concern. This study presents, for the first time, an exhaustive review of the transferability aspect of adversarial attacks. It systematically categorizes and critically evaluates various methodologies developed to augment the transferability of adversarial attacks. This study encompasses a spectrum of techniques, including Generative Structure, Semantic Similarity, Gradient Editing, Target Modification, and Ensemble Approach. Concurrently, this paper introduces a benchmark framework \textit{TAA-Bench}, integrating ten leading methodologies for adversarial attack transferability, thereby providing a standardized and systematic platform for comparative analysis across diverse model architectures. Through comprehensive scrutiny, we delineate the efficacy and constraints of each method, shedding light on their underlying operational principles and practical utility. This review endeavors to be a quintessential resource for both scholars and practitioners in the field, charting the complex terrain of adversarial transferability and setting a foundation for future explorations in this vital sector. The associated codebase is accessible at: https://github.com/KxPlaug/TAA-Bench, Comment: Accepted by NDSS 2024 Workshop

Published
2024

18. GE-AdvGAN: Improving the transferability of adversarial samples by gradient editing-based adversarial generative model

Author

Zhu, Zhiyu, Chen, Huaming, Wang, Xinyi, Zhang, Jiayu, Jin, Zhibo, Choo, Kim-Kwang Raymond, Shen, Jun, and Yuan, Dong

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Adversarial generative models, such as Generative Adversarial Networks (GANs), are widely applied for generating various types of data, i.e., images, text, and audio. Accordingly, its promising performance has led to the GAN-based adversarial attack methods in the white-box and black-box attack scenarios. The importance of transferable black-box attacks lies in their ability to be effective across different models and settings, more closely aligning with real-world applications. However, it remains challenging to retain the performance in terms of transferable adversarial examples for such methods. Meanwhile, we observe that some enhanced gradient-based transferable adversarial attack algorithms require prolonged time for adversarial sample generation. Thus, in this work, we propose a novel algorithm named GE-AdvGAN to enhance the transferability of adversarial samples whilst improving the algorithm's efficiency. The main approach is via optimising the training process of the generator parameters. With the functional and characteristic similarity analysis, we introduce a novel gradient editing (GE) mechanism and verify its feasibility in generating transferable samples on various models. Moreover, by exploring the frequency domain information to determine the gradient editing direction, GE-AdvGAN can generate highly transferable adversarial samples while minimizing the execution time in comparison to the state-of-the-art transferable adversarial attack algorithms. The performance of GE-AdvGAN is comprehensively evaluated by large-scale experiments on different datasets, which results demonstrate the superiority of our algorithm. The code for our algorithm is available at: https://github.com/LMBTough/GE-advGAN, Comment: Accepted by SIAM International Conference on Data Mining (SDM24)

Published
2024

19. MFABA: A More Faithful and Accelerated Boundary-based Attribution Method for Deep Neural Networks

Author

Zhu, Zhiyu, Chen, Huaming, Zhang, Jiayu, Wang, Xinyi, Jin, Zhibo, Xue, Minhui, Zhu, Dongxiao, and Choo, Kim-Kwang Raymond

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

To better understand the output of deep neural networks (DNN), attribution based methods have been an important approach for model interpretability, which assign a score for each input dimension to indicate its importance towards the model outcome. Notably, the attribution methods use the axioms of sensitivity and implementation invariance to ensure the validity and reliability of attribution results. Yet, the existing attribution methods present challenges for effective interpretation and efficient computation. In this work, we introduce MFABA, an attribution algorithm that adheres to axioms, as a novel method for interpreting DNN. Additionally, we provide the theoretical proof and in-depth analysis for MFABA algorithm, and conduct a large scale experiment. The results demonstrate its superiority by achieving over 101.5142 times faster speed than the state-of-the-art attribution algorithms. The effectiveness of MFABA is thoroughly evaluated through the statistical analysis in comparison to other methods, and the full implementation package is open-source at: https://github.com/LMBTough/MFABA, Comment: Accepted by The 38th Annual AAAI Conference on Artificial Intelligence (AAAI-24)

Published
2023

20. Leveraging Information Consistency in Frequency and Spatial Domain for Adversarial Attacks

Author

Jin, Zhibo, Zhang, Jiayu, Zhu, Zhiyu, Wang, Xinyi, Huang, Yiyun, Chen, Huaming, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Hadfi, Rafik, editor, Anthony, Patricia, editor, Sharma, Alok, editor, Ito, Takayuki, editor, and Bai, Quan, editor

Published
2025
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24. DANAA: Towards transferable attacks with double adversarial neuron attribution

Author

Jin, Zhibo, Zhu, Zhiyu, Wang, Xinyi, Zhang, Jiayu, Shen, Jun, and Chen, Huaming

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

While deep neural networks have excellent results in many fields, they are susceptible to interference from attacking samples resulting in erroneous judgments. Feature-level attacks are one of the effective attack types, which targets the learnt features in the hidden layers to improve its transferability across different models. Yet it is observed that the transferability has been largely impacted by the neuron importance estimation results. In this paper, a double adversarial neuron attribution attack method, termed `DANAA', is proposed to obtain more accurate feature importance estimation. In our method, the model outputs are attributed to the middle layer based on an adversarial non-linear path. The goal is to measure the weight of individual neurons and retain the features that are more important towards transferability. We have conducted extensive experiments on the benchmark datasets to demonstrate the state-of-the-art performance of our method. Our code is available at: https://github.com/Davidjinzb/DANAA, Comment: Accepted by 19th International Conference on Advanced Data Mining and Applications. (ADMA 2023)

Published
2023

25. Formulations and Constructions of Remote State Preparation with Verifiability, with Applications

Author

Zhang, Jiayu

Subjects
Quantum Physics
Abstract

Remote state preparation with verifiability (RSPV) is an important quantum cryptographic primitive [GV19,Zha22]. In this primitive, a client would like to prepare a quantum state (sampled or chosen from a state family) on the server side, such that ideally the client knows its full description, while the server holds and only holds the state itself. In this work we make several contributions on its formulations, constructions and applications. In more detail: - We first work on the definitions and abstract properties of the RSPV problem. We select and compare different variants of definitions [GV19,GMP22,Zha22], and study their basic properties (like composability and amplification). - We also study a closely related question of how to certify the server's operations (instead of solely the states). We introduce a new notion named remote operator application with verifiability (ROAV). We compare this notion with related existing definitions [SW87,MY04,MV21,NZ23] and study its abstract properties. - Building on the abstract properties and existing results [BGKPV23], we construct a series of new RSPV protocols. Our constructions not only simplify existing results [GV19] but also cover new state families, for example, states in the form of $\frac{1}{\sqrt{2}}(|0\rangle|x_0\rangle+|1\rangle|x_1\rangle)$. All these constructions rely only on the existence of weak NTCF [BKVV,AMR22], without additional requirements like the adaptive hardcore bit property [BCMVV,AMR22]. - As a further application, we show that the classical verification of quantum computations (CVQC) problem [ABEM,Mah18] could be constructed from assumptions on group actions [ADMP20]. This is achieved by combining our results on RSPV with group-action-based instantiation of weak NTCF [AMR22], and then with the quantum-gadget-assisted quantum verification protocol [FKD18]., Comment: Accepted by ITCS 2025. 70 pages, 2 figures

Published
2023

26. A Quantum Approach for Reducing Communications in Classical Cryptographic Primitives

Author

Zhang, Jiayu

Subjects
Quantum Physics, Computer Science - Cryptography and Security
Abstract

How could quantum cryptography help us achieve what are not achievable in classical cryptography? In this work we consider the following problem, which we call succinct RSPV for classical functions (SRC). Suppose $f$ is a function described by a polynomial time classical Turing machine, which is public; the client would like to sample a random $x$ as the function input and use a protocol to send $f(x)$ to the server. What's more, (1) when the server is malicious, what it knows in the passing space should be no more than $f(x)$; (2) the communication should be succinct (that is, independent to the running time of evaluating $f$). Solving this problem in classical cryptography seems to require strong cryptographic assumptions. We show that, perhaps surprisingly, it's possible to solve this problem with quantum techniques under much weaker assumptions. By allowing for quantum communication and computations, we give a protocol for this problem assuming only collapsing hash functions [Unr16]. Our work conveys an interesting message that quantum cryptography could outperform classical cryptography in a new type of problems, that is, to reduce communications in meaningful primitives without using heavy classical cryptographic assumptions., Comment: 29 pages

Published
2023

28. Blessing of High-Order Dimensionality: from Non-Convex to Convex Optimization for Sensor Network Localization

Author

Lei, Mingyu, Zhang, Jiayu, and Ye, Yinyu

Subjects
Mathematics - Optimization and Control
Abstract

This paper investigates the Sensor Network Localization (SNL) problem, which seeks to determine sensor locations based on known anchor locations and partially given anchors-sensors and sensors-sensors distances. Two primary methods for solving the SNL problem are analyzed: the low-dimensional method that directly minimizes a loss function, and the high-dimensional semi-definite relaxation (SDR) method that reformulates the SNL problem as an SDP (semi-definite programming) problem. The paper primarily focuses on the intrinsic non-convexity of the loss function of the low-dimensional method, which is shown in our main theorem. The SDR method, via second-order dimension augmentation, is discussed in the context of its ability to transform non-convex problems into convex ones; while the first-order direct dimension augmentation fails. Additionally, we will show that more edges don't necessarily contribute to the better convexity of the loss function. Moreover, we provide an explanation for the success of the SDR+GD (gradient descent) method which uses the SDR solution as a warm-start of the minimization of the loss function by gradient descent. The paper also explores the parallels among SNL, max-cut, and neural networks in terms of the blessing of high-order dimension augmentation., Comment: 25 pages, 9 figures. References in arxiv. arXiv:1801.06146, arXiv:1810.04805, arXiv preprint arXiv:1906.05474, arXiv preprint arXiv:1801.06146

Published
2023

40. Psychological health status and influencing factors of patients with moderate-to-severe acne

Author

Guo Qiong, Ren Hu, Zhong Tingting, Chen Yi, Zhang Jiayu, and Liao Qiaoyun

Subjects
acne, psychological health problems, influencing factor, Psychology, BF1-990, Psychiatry, RC435-571
Abstract

BackgroundAcne treatment cycle lasts long and will cause facial appearance damage. Many patients are prone to psychological problems and severe patients may even experience suicidal ideation.However, the influencing factors of psychological health problems in acne patients are still unclear.ObjectiveTo investigate the mental health status of patients with moderate-to-severe acne and to analyze the influencing factors of their psychological health problems, so as to provide references for improving their mental health.MethodsA total of 120 patients with moderate-to-severe acne of grades II-IV were selected as the research subjects, who were treated in the dermatology outpatient department of the Third Hospital of Mianyang from June 2021 to June 2023. All subjects were evaluated by using the Acne-Specific Quality of Life Questionnaire(Acne-QoL), Self-rating Depression Scale (SDS), Self-rating Anxiety Scale (SAS), Rosenberg Self-Esteem Scale (RSES) and Social Phobia Inventory (SPIN). According to the evaluation results of SDS, SAS, RSES, SPIN, subjects were divided into a group with mental health problems (n=21) and a group without mental health problems (n=99). Binary Logistic regression anaylsis was adopted to explore the influencing factors of psychological health problems in acne patients.ResultsA total of 21 patients (17.50%) were detected to have symptoms of depression, anxiety, inferiority or social dysfunction. Statistically significant difference was observed in comparison between two groups in gender, profession, acne classification, dietary habit, age, illness course as well as the factor scores of self perception, emotional function, social function and acne symptom in Acne-QoL (χ2=7.013, 23.123, 9.028, 11.327, t=9.913, 13.022, 4.081, 5.383, 5.361, 10.203,P

Published
2024
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41. Learning from Home: Widening Rural-Urban Educational Inequality and High School Students' Self-Control in China during the COVID-19 Pandemic and School Closure

Author

Ma, Gaoming, Zhang, Jiayu, and Hong, Liu

Abstract

Worldwide school closures and remote learning have been implemented during the COVID-19 pandemic. These measures' impact on young populations' academic achievements is unclear. This study (N = 1,736, ages 14-20 years, 53% female, and Chinese) analyzed academic examination scores for students at a high school in Eastern China between January and July 2020. Results showed that overall, students' academic achievements appeared to be negatively affected amid a school closure. More importantly, students' self-control was introduced as a moderating factor that partially accounted for this difference in the context of remote learning at home. These findings extended our understanding of school closures' unequal impact on young populations. Education and social policies should respond to these challenges during times of crisis.

Published
2023
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46. Analysis of Deformation in Aircraft Skin Vacuum Adsorption Clamping

Author

Xing, Wenhao, Wang, Aimin, Wu, Long, Xu, Baode, Zhang, Jiayu, Yu, Yuan, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Halgamuge, Saman K., editor, Zhang, Hao, editor, Zhao, Dingxuan, editor, and Bian, Yongming, editor

Published
2024
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