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13 results on '"Wu, Zhuanhao"'

1. Secure and Lightweight Strong PUF Challenge Obfuscation with Keyed Non-linear FSR

Author

Stangherlin, Kleber, Wu, Zhuanhao, Patel, Hiren, and Sachdev, Manoj

Subjects
Computer Science - Cryptography and Security, Electrical Engineering and Systems Science - Systems and Control
Abstract

We propose a secure and lightweight key based challenge obfuscation for strong PUFs. Our architecture is designed to be resilient against learning attacks. Our obfuscation mechanism uses non-linear feedback shift registers (NLFSRs). Responses are directly provided to the user, without error correction or extra post-processing steps. We also discuss the cost of protecting our architecture against power analysis attacks with clock randomization, and Boolean masking. Security against learning attacks is assessed using avalanche criterion, and deep-neural network attacks. We designed a testchip in 65 nm CMOS. When compared to the baseline arbiter PUF implementation, the cost increase of our proposed architecture is 1.27x, and 2.2x when using clock randomization, and Boolean masking, respectively.

Published
2022

2. Design Exploration and Security Assessment of PUF-on-PUF Implementations

Author

Stangherlin, Kleber, Wu, Zhuanhao, Patel, Hiren, and Sachdev, Manoj

Subjects
Computer Science - Cryptography and Security, Electrical Engineering and Systems Science - Systems and Control
Abstract

We design, implement, and assess the security of several variations of the PUF-on-PUF (POP) architecture. We perform extensive experiments with deep neural networks (DNNs), showing results that endorse its resilience to learning attacks when using APUFs with 6, or more, stages in the first layer. Compositions using APUFs with 2, and 4 stages are shown vulnerable to DNN attacks. We reflect on such results, extending previous techniques of influential bits to assess stage bias in APUF instances. Our data shows that compositions not always preserve security properties of PUFs, the size of PUFs used plays a crucial role. We implemented a testchip in 65 nm CMOS to obtain accurate measurements of uniformity, uniqueness, and response stability for our POP implementations. Measurement results show that minimum bit error rate is obtained when using APUFs with 8 stages in the first layer, while fewer APUF stages lead to a large spread of bit error rate across different chips.

Published
2022

3. Enhancing Strong PUF Security with Non-monotonic Response Quantization

Author

Stangherlin, Kleber, Wu, Zhuanhao, Patel, Hiren, and Sachdev, Manoj

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Cryptography and Security
Abstract

Strong physical unclonable functions (PUFs) provide a low-cost authentication primitive for resource constrained devices. However, most strong PUF architectures can be modeled through learning algorithms with a limited number of CRPs. In this paper, we introduce the concept of non-monotonic response quantization for strong PUFs. Responses depend not only on which path is faster, but also on the distance between the arriving signals. Our experiments show that the resulting PUF has increased security against learning attacks. To demonstrate, we designed and implemented a non-monotonically quantized ring-oscillator based PUF in 65 nm technology. Measurement results show nearly ideal uniformity and uniqueness, with bit error rate of 13.4% over the temperature range from 0 C to 50 C.

Published
2022

4. Predictable Sharing of Last-level Cache Partitions for Multi-core Safety-critical Systems

Author

Wu, Zhuanhao and Patel, Hiren

Subjects
Computer Science - Hardware Architecture
Abstract

Last-level cache (LLC) partitioning is a technique to provide temporal isolation and low worst-case latency (WCL) bounds when cores access the shared LLC in multicore safety-critical systems. A typical approach to cache partitioning involves allocating a separate partition to a distinct core. A central criticism of this approach is its poor utilization of cache storage. Today's trend of integrating a larger number of cores exacerbates this issue such that we are forced to consider shared LLC partitions for effective deployments. This work presents an approach to share LLC partitions among multiple cores while being able to provide low WCL bounds.

Published
2022

5. High Performance and Predictable Shared Last-level Cache for Safety-Critical Systems.

Author

Wu, Zhuanhao, Kaushik, Anirudh, and Patel, Hiren

Subjects
MEMORY, ARBITRATION & award, CACHE memory, SHARING, BUSES
Abstract

We propose ZeroCost-LLC (ZCLLC), a novel shared inclusive last-level cache (LLC) design for timing predictable multi-core platforms that offers lower worst-case latency (WCL) when compared with a traditional shared inclusive LLC design. ZCLLC achieves low WCL by eliminating certain memory operations in the form of cache line invalidations across the cache hierarchy that are a consequence of a core's memory request that misses in the cache hierarchy and when there is no vacant entry in the LLC to accommodate the fetched data for this request. In addition to low WCL, ZCLLC offers performance benefits in the form of additional caching capacity and unlike state-of-the-art approaches, ZCLLC does not impose any constraints on its usage across multiple cores. In this work, we describe the impact of LLC cache line invalidations on the WCL and systematically build solutions to eliminate these invalidations resulting in ZCLLC. We also present ZCLLC-OPT, an optimized variant of ZCLLC that offers lower WCL and improved average-case performance over ZCLLC. We apply optimizations to the shared bus arbitration mechanism and extend the micro-architecture of ZCLLC to allow for overlapping memory requests to the main memory. Our analysis reveals that the analytical WCL of a memory request under ZCLLC-OPT is 87.0%, 93.8%, and 97.1% lower than that under state-of-the-art LLC partition sharing techniques for 2, 4, and 8 cores, respectively. ZCLLC-OPT shows average-case performance speedups of 1.89×, 3.36×, and 6.24× compared with the state-of-the-art LLC partition sharing techniques for 2, 4, and 8 cores, respectively. When compared with the original ZCLLC that does not have any optimizations, ZCLLC-OPT shows lower analytical WCLs that are 76.5%, 82.6%, and 86.2% lower compared with ZCLLC-NORMAL for 2, 4, and 8 cores, respectively. [ABSTRACT FROM AUTHOR]

Published
2024
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