Your search keyword '"Koushanfar, Farinaz"' showing total 14 results

1. EveGuard: Defeating Vibration-based Side-Channel Eavesdropping with Audio Adversarial Perturbations

Author

Chang, Jung-Woo, Sun, Ke, Xia, David, Zhang, Xinyu, and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Multimedia, Computer Science - Sound, Electrical Engineering and Systems Science - Audio and Speech Processing

Abstract

Vibrometry-based side channels pose a significant privacy risk, exploiting sensors like mmWave radars, light sensors, and accelerometers to detect vibrations from sound sources or proximate objects, enabling speech eavesdropping. Despite various proposed defenses, these involve costly hardware solutions with inherent physical limitations. This paper presents EveGuard, a software-driven defense framework that creates adversarial audio, protecting voice privacy from side channels without compromising human perception. We leverage the distinct sensing capabilities of side channels and traditional microphones where side channels capture vibrations and microphones record changes in air pressure, resulting in different frequency responses. EveGuard first proposes a perturbation generator model (PGM) that effectively suppresses sensor-based eavesdropping while maintaining high audio quality. Second, to enable end-to-end training of PGM, we introduce a new domain translation task called Eve-GAN for inferring an eavesdropped signal from a given audio. We further apply few-shot learning to mitigate the data collection overhead for Eve-GAN training. Our extensive experiments show that EveGuard achieves a protection rate of more than 97 percent from audio classifiers and significantly hinders eavesdropped audio reconstruction. We further validate the performance of EveGuard across three adaptive attack mechanisms. We have conducted a user study to verify the perceptual quality of our perturbed audio.

Published

2024

2. AMAZE: Accelerated MiMC Hardware Architecture for Zero-Knowledge Applications on the Edge

Author

Ahmed, Anees, Sheybani, Nojan, Moreno, Davi, Njungle, Nges Brian, Gong, Tengkai, Kinsy, Michel, and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Hardware Architecture

Abstract

Collision-resistant, cryptographic hash (CRH) functions have long been an integral part of providing security and privacy in modern systems. Certain constructions of zero-knowledge proof (ZKP) protocols aim to utilize CRH functions to perform cryptographic hashing. Standard CRH functions, such as SHA2, are inefficient when employed in the ZKP domain, thus calling for ZK-friendly hashes, which are CRH functions built with ZKP efficiency in mind. The most mature ZK-friendly hash, MiMC, presents a block cipher and hash function with a simple algebraic structure that is well-suited, due to its achieved security and low complexity, for ZKP applications. Although ZK-friendly hashes have improved the performance of ZKP generation in software, the underlying computation of ZKPs, including CRH functions, must be optimized on hardware to enable practical applications. The challenge we address in this work is determining how to efficiently incorporate ZK-friendly hash functions, such as MiMC, into hardware accelerators, thus enabling more practical applications. In this work, we introduce AMAZE, a highly hardware-optimized open-source framework for computing the MiMC block cipher and hash function. Our solution has been primarily directed at resource-constrained edge devices; consequently, we provide several implementations of MiMC with varying power, resource, and latency profiles. Our extensive evaluations show that the AMAZE-powered implementation of MiMC outperforms standard CPU implementations by more than 13$\times$. In all settings, AMAZE enables efficient ZK-friendly hashing on resource-constrained devices. Finally, we highlight AMAZE's underlying open-source arithmetic backend as part of our end-to-end design, thus allowing developers to utilize the AMAZE framework for custom ZKP applications., Comment: Accepted to ICCAD 2024

Published

2024

3. Props for Machine-Learning Security

Author

Juels, Ari and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence

Abstract

We propose protected pipelines or props for short, a new approach for authenticated, privacy-preserving access to deep-web data for machine learning (ML). By permitting secure use of vast sources of deep-web data, props address the systemic bottleneck of limited high-quality training data in ML development. Props also enable privacy-preserving and trustworthy forms of inference, allowing for safe use of sensitive data in ML applications. Props are practically realizable today by leveraging privacy-preserving oracle systems initially developed for blockchain applications.

Published

2024

4. Watermarking Large Language Models and the Generated Content: Opportunities and Challenges

Author

Zhang, Ruisi and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Computation and Language

Abstract

The widely adopted and powerful generative large language models (LLMs) have raised concerns about intellectual property rights violations and the spread of machine-generated misinformation. Watermarking serves as a promising approch to establish ownership, prevent unauthorized use, and trace the origins of LLM-generated content. This paper summarizes and shares the challenges and opportunities we found when watermarking LLMs. We begin by introducing techniques for watermarking LLMs themselves under different threat models and scenarios. Next, we investigate watermarking methods designed for the content generated by LLMs, assessing their effectiveness and resilience against various attacks. We also highlight the importance of watermarking domain-specific models and data, such as those used in code generation, chip design, and medical applications. Furthermore, we explore methods like hardware acceleration to improve the efficiency of the watermarking process. Finally, we discuss the limitations of current approaches and outline future research directions for the responsible use and protection of these generative AI tools., Comment: invited paper to Asilomar Conference on Signals, Systems, and Computers

Published

2024

5. Automated Physical Design Watermarking Leveraging Graph Neural Networks

Author

Zhang, Ruisi, Rajarathnam, Rachel Selina, Pan, David Z., and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Hardware Architecture

Abstract

This paper presents AutoMarks, an automated and transferable watermarking framework that leverages graph neural networks to reduce the watermark search overheads during the placement stage. AutoMarks's novel automated watermark search is accomplished by (i) constructing novel graph and node features with physical, semantic, and design constraint-aware representation; (ii) designing a data-efficient sampling strategy for watermarking fidelity label collection; and (iii) leveraging a graph neural network to learn the connectivity between cells and predict the watermarking fidelity on unseen layouts. Extensive evaluations on ISPD'15 and ISPD'19 benchmarks demonstrate that our proposed automated methodology: (i) is capable of finding quality-preserving watermarks in a short time; and (ii) is transferable across various designs, i.e., AutoMarks trained on one layout is generalizable to other benchmark circuits. AutoMarks is also resilient against potential watermark removal and forging attacks, Comment: accept to MLCAD24, code: https://github.com/ruisizhang123/PD_WM_GNN

Published

2024

6. ICMarks: A Robust Watermarking Framework for Integrated Circuit Physical Design IP Protection

Author

Zhang, Ruisi, Rajarathnam, Rachel Selina, Pan, David Z., and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Hardware Architecture

Abstract

Physical design watermarking on contemporary integrated circuit (IC) layout encodes signatures without considering the dense connections and design constraints, which could lead to performance degradation on the watermarked products. This paper presents ICMarks, a quality-preserving and robust watermarking framework for modern IC physical design. ICMarks embeds unique watermark signatures during the physical design's placement stage, thereby authenticating the IC layout ownership. ICMarks's novelty lies in (i) strategically identifying a region of cells to watermark with minimal impact on the layout performance and (ii) a two-level watermarking framework for augmented robustness toward potential removal and forging attacks. Extensive evaluations on benchmarks of different design objectives and sizes validate that ICMarks incurs no wirelength and timing metrics degradation, while successfully proving ownership. Furthermore, we demonstrate ICMarks is robust against two major watermarking attack categories, namely, watermark removal and forging attacks; even if the adversaries have prior knowledge of the watermarking schemes, the signatures cannot be removed without significantly undermining the layout quality.

Published

2024

7. Token-Specific Watermarking with Enhanced Detectability and Semantic Coherence for Large Language Models

Author

Huo, Mingjia, Somayajula, Sai Ashish, Liang, Youwei, Zhang, Ruisi, Koushanfar, Farinaz, and Xie, Pengtao

Subjects

Computer Science - Machine Learning, Computer Science - Computation and Language, Computer Science - Cryptography and Security

Abstract

Large language models generate high-quality responses with potential misinformation, underscoring the need for regulation by distinguishing AI-generated and human-written texts. Watermarking is pivotal in this context, which involves embedding hidden markers in texts during the LLM inference phase, which is imperceptible to humans. Achieving both the detectability of inserted watermarks and the semantic quality of generated texts is challenging. While current watermarking algorithms have made promising progress in this direction, there remains significant scope for improvement. To address these challenges, we introduce a novel multi-objective optimization (MOO) approach for watermarking that utilizes lightweight networks to generate token-specific watermarking logits and splitting ratios. By leveraging MOO to optimize for both detection and semantic objective functions, our method simultaneously achieves detectability and semantic integrity. Experimental results show that our method outperforms current watermarking techniques in enhancing the detectability of texts generated by LLMs while maintaining their semantic coherence. Our code is available at https://github.com/mignonjia/TS_watermark., Comment: 22 pages, 13 figures, 5 tables

Published

2024

8. EmMark: Robust Watermarks for IP Protection of Embedded Quantized Large Language Models

Author

Zhang, Ruisi and Koushanfar, Farinaz

Subjects

Computer Science - Cryptography and Security, Computer Science - Computation and Language

Abstract

This paper introduces EmMark,a novel watermarking framework for protecting the intellectual property (IP) of embedded large language models deployed on resource-constrained edge devices. To address the IP theft risks posed by malicious end-users, EmMark enables proprietors to authenticate ownership by querying the watermarked model weights and matching the inserted signatures. EmMark's novelty lies in its strategic watermark weight parameters selection, nsuring robustness and maintaining model quality. Extensive proof-of-concept evaluations of models from OPT and LLaMA-2 families demonstrate EmMark's fidelity, achieving 100% success in watermark extraction with model performance preservation. EmMark also showcased its resilience against watermark removal and forging attacks., Comment: Accept to DAC 2024

Published

2024

9. Tailor: Altering Skip Connections for Resource-Efficient Inference.

Author

Weng, Olivia, Marcano, Gabriel, Loncar, Vladimir, Khodamoradi, Alireza, Abarajithan, G, Sheybani, Nojan, Meza, Andres, Koushanfar, Farinaz, Denolf, Kristof, Duarte, Javier Mauricio, and Kastner, Ryan

Published

2024

10. Distributed constrained combinatorial optimization leveraging hypergraph neural networks

Author

Heydaribeni, Nasimeh, Zhan, Xinrui, Zhang, Ruisi, Eliassi-Rad, Tina, and Koushanfar, Farinaz

Published

2024

11. FaceSigns: Semi-fragile Watermarks for Media Authentication.

Author

Neekhara, Paarth, Hussain, Shehzeen, Zhang, Xinqiao, Huang, Ke, McAuley, Julian, and Koushanfar, Farinaz

Abstract

Manipulated media is becoming a prominent threat due to the recent advances in realistic image and video synthesis techniques. There have been several attempts at detecting synthetically tampered media using machine learning classifiers. However, such classifiers do not generalize well to black-box image synthesis techniques and have been shown to be vulnerable to adversarial examples. To address these challenges, we introduce FaceSigns—a deep learning-based semi-fragile watermarking technique that allows media authentication by verifying an invisible secret message embedded in the image pixels. Instead of identifying and detecting manipulated media using visual artifacts, we propose to proactively embed a semi-fragile watermark into a real image or video so that we can prove its authenticity when needed. FaceSigns is designed to be fragile to malicious manipulations or tampering while being robust to benign operations such as image/video compression, scaling, saturation, contrast adjustments, and so forth. This allows images and videos shared over the internet to retain the verifiable watermark as long as a malicious modification technique is not applied. We demonstrate that our framework can embed a 128-bit secret as an imperceptible image watermark that can be recovered with a high bit recovery accuracy at several compression levels, while being non-recoverable when unseen malicious manipulations are applied. For a set of unseen benign and malicious manipulations studied in our work, our framework can reliably detect manipulated content with an AUC score of 0.996, which is significantly higher than prior image watermarking and steganography techniques. [ABSTRACT FROM AUTHOR]

Published

2024

12. You Can Have Your Cake and Eat It Too: Ensuring Practical Robustness and Privacy in Federated Learning

Author

Sheybani, Nojan, primary and Koushanfar, Farinaz, additional

Published

2024

13. Scalable Binary Neural Network Applications in Oblivious Inference

Author

Zhang, Xinqiao, primary, Samragh, Mohammad, additional, Hussain, Siam, additional, Huang, Ke, additional, and Koushanfar, Farinaz, additional

Published

2024

14. Intellectual Property Protection of Deep-Learning Systems via Hardware/Software Co-Design

Author

Chen, Huili, primary, Fu, Cheng, additional, Rouhani, Bita Darvish, additional, Zhao, Jishen, additional, and Koushanfar, Farinaz, additional

Published

2024