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Wei Hu 0008
Person information
- affiliation: University of California San Diego, Department of Computer Science and Engineering, La Jolla, CA, USA
- affiliation (former): Northwestern Polytechnical University, School of Automation, Xi'an, China
Other persons with the same name
- Wei Hu — disambiguation page
- Wei Hu 0001
— Wuhan University of Science and Technology, College of Computer Science and Technology, China (and 1 more)
- Wei Hu 0002 — Intel Labs China, Beijing, China
- Wei Hu 0003
- Wei Hu 0004
- Wei Hu 0005
- Wei Hu 0006
- Wei Hu 0007
- Wei Hu 0009
- Wei Hu 0010
- Wei Hu 0011
- Wei Hu 0012
- Wei Hu 0013
- Wei Hu 0014 — Princeton University, Computer Science Department, NJ, USA
- Wei Hu 0015
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2020 – today
- 2024
- [j23]Dina G. Mahmoud
X-Attack 2.0: The Risk of Power Wasters and Satisfiability Don't-Care Hardware Trojans to Shared Cloud FPGAs. IEEE Access 12: 8983-9011 (2024) - [j22]Maoyuan Qin, Jiacheng Zhu, Baolei Mao, Wei Hu
Hardware/software security co-verification and vulnerability detection: An information flow perspective. Integr. 94: 102089 (2024) - [j21]Mingping Qi
Provably Secure Asymmetric PAKE Protocol for Protecting IoT Access. IEEE Internet Things J. 11(4): 7071-7078 (2024) - [j20]Mingping Qi
SAE+: One-Round Provably Secure Asymmetric SAE Protocol for Client-Server Model. IEEE Trans. Inf. Forensics Secur. 19: 3906-3913 (2024) - 2023
- [j19]Jinhui Liu, Tianyi Han, Maolin Tan, Bo Tang, Wei Hu
A Publicly Verifiable E-Voting System Based on Biometrics. Cryptogr. 7(4): 62 (2023) - [c37]Huawei Li, Jing Ye, Wei Hu, Jiliang Zhang:
Message from the Chairs. ATS 2023: 1 - [c36]Shibo Tang, Jiacheng Zhu, Yifei Gao, Jing Zhou, Dejun Mu, Wei Hu:
Verifying RISC-V Privilege Transition Integrity Through Symbolic Execution. ATS 2023: 1-6 - [c35]Lingjuan Wu, Yifei Gao, Jiacheng Zhu, Yu Tai, Wei Hu:
Security Verification of RISC-V System Based on ISA Level Information Flow Tracking. ATS 2023: 1-6 - [c34]Lingjuan Wu, Hao Su, Xuelin Zhang
Automated Hardware Trojan Detection at LUT Using Explainable Graph Neural Networks. ICCAD 2023: 1-9 - [c33]Beibei Li
Maximizing Network Reliability in Large Scale Infrastructure Networks: A Heat Conduction Model Perspective. ICMLC 2023: 25-32 - [c32]Liang Hong, Ge Zhu, Jing Zhou, Xuefei Li, Ziyi Chen, Wei Hu:
Hunting for Hardware Trojan in Gate Netlist: A Stacking Ensemble Learning Perspective. ITC-Asia 2023: 1-6 - [i2]Wei Hu, Beibei Li, Lingjuan Wu, Yiwei Li, Xuefei Li, Liang Hong:
Design for Assurance: Employing Functional Verification Tools for Thwarting Hardware Trojan Threat in 3PIPs. CoRR abs/2311.12321 (2023) - 2022
- [j18]Wei Hu
Hardware Information Flow Tracking. ACM Comput. Surv. 54(4): 83:1-83:39 (2022) - [c31]Lingjuan Wu, Xuelin Zhang
Hardware Trojan Detection at LUT: Where Structural Features Meet Behavioral Characteristics. HOST 2022: 121-124 - [c30]Shibo Tang, Xingxin Wang, Yifei Gao, Wei Hu:
Accelerating SoC Security Verification and Vulnerability Detection Through Symbolic Execution. ISOCC 2022: 207-208 - [c29]Xingxin Wang, Shibo Tang, Wei Hu:
Towards Automatic Property Generation for SoC Security Verification. ISOCC 2022: 209-210 - [p1]Wei Hu, Armaiti Ardeshiricham, Lingjuan Wu, Ryan Kastner:
Integrating Information Flow Tracking into High-Level Synthesis Design Flow. Behavioral Synthesis for Hardware Security 2022: 365-387 - 2021
- [j17]Lixiang Shen, Dejun Mu, Guo Cao, Maoyuan Qin, Jiacheng Zhu, Wei Hu
Accelerating hardware security verification and vulnerability detection through state space reduction. Comput. Secur. 103: 102167 (2021) - [j16]Wei Hu
An Overview of Hardware Security and Trust: Threats, Countermeasures, and Design Tools. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 40(6): 1010-1038 (2021) - [c28]Xingxin Wang, Jian Zheng, Lingjuan Wu, Jiacheng Zhu, Wei Hu:
A Correlation Fault Attack on Rotating S-Box Masking AES. AsianHOST 2021: 1-6 - [c27]Wei Hu, Jing Tan, Lingjuan Wu, Yu Tai, Liang Hong:
Developing Formal Models for Measuring Fault Effects Using Functional EDA Tools. ITC-Asia 2021: 1-6 - [c26]Lingjuan Wu, Xuefei Li, Jiacheng Zhu, Jian Zheng, Wei Hu:
Identifying Specious LUTs for Satisfiability Don't Care Trojan Detection. SoCC 2021: 170-175 - 2020
- [j15]Tao Yang
A Standardized ICS Network Data Processing Flow With Generative Model in Anomaly Detection. IEEE Access 8: 4255-4264 (2020) - [j14]Maoyuan Qin, Xinmu Wang, Baolei Mao, Dejun Mu, Wei Hu:
A formal model for proving hardware timing properties and identifying timing channels. Integr. 72: 123-133 (2020) - [j13]Lu Zhang, Dejun Mu, Wei Hu, Yu Tai:
Machine-Learning-Based Side-Channel Leakage Detection in Electronic System-Level Synthesis. IEEE Netw. 34(3): 44-49 (2020) - [j12]Lu Zhang
Memory-Based High-Level Synthesis Optimizations Security Exploration on the Power Side-Channel. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 39(10): 2124-2137 (2020) - [c25]Hang Liu, Chaofan Zhang, Hongming Fei, Wei Hu, Dawei Guo:
Feedback-based Channel Gain Complement and Cluster-based Quantization for Physical Layer Key Generation. AsianHOST 2020: 1-6 - [c24]Wei Hu
A Unified Formal Model for Proving Security and Reliability Properties. ATS 2020: 1-6 - [c23]Jiliang Zhang, Shuang Peng, Yupeng Hu, Fei Peng, Wei Hu, Jinmei Lai, Jing Ye, Xiangqi Wang:
HRAE: Hardware-assisted Randomization against Adversarial Example Attacks. ATS 2020: 1-6 - [c22]Dina G. Mahmoud
X-Attack: Remote Activation of Satisfiability Don't-Care Hardware Trojans on Shared FPGAs. FPL 2020: 185-192 - [i1]Jeremy Blackstone, Wei Hu, Alric Althoff, Armaiti Ardeshiricham, Lu Zhang, Ryan Kastner:
A Unified Model for Gate Level Propagation Analysis. CoRR abs/2012.02791 (2020)
2010 – 2019
- 2019
- [j11]Maoyuan Qin
Theorem proof based gate level information flow tracking for hardware security verification. Comput. Secur. 85: 225-239 (2019) - [c21]Wei Hu
Leveraging Unspecified Functionality in Obfuscated Hardware for Trojan and Fault Attacks. AsianHOST 2019: 1-6 - 2018
- [j10]Yu Tai
Towards Quantified Data Analysis of Information Flow Tracking for Secure System Design. IEEE Access 6: 1822-1831 (2018) - [j9]Baolei Mao
Quantitative Analysis of Timing Channel Security in Cryptographic Hardware Design. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 37(9): 1719-1732 (2018) - [c20]Wei Hu
Security Path Verification Through Joint Information Flow Analysis. APCCAS 2018: 415-418 - [c19]Lu Zhang, Wei Hu
Examining the consequences of high-level synthesis optimizations on power side-channel. DATE 2018: 1167-1170 - [c18]Wei Hu
Property specific information flow analysis for hardware security verification. ICCAD 2018: 89 - [c17]Maoyuan Qin, Wei Hu
Property Based Formal Security Verification for Hardware Trojan Detection. IVSW 2018: 62-67 - 2017
- [c16]Yu Tai, Wei Hu, Dejun Mu, Baolei Mao, Lantian Guo, Maoyuan Qin:
A Simplifying Logic Approach for Gate Level Information Flow Tracking. ChinaCom (2) 2017: 302-311 - [c15]Andrew Becker, Wei Hu
Arbitrary Precision and Complexity Tradeoffs for Gate-Level Information Flow Tracking. DAC 2017: 5:1-5:6 - [c14]Armaiti Ardeshiricham, Wei Hu
Register transfer level information flow tracking for provably secure hardware design. DATE 2017: 1691-1696 - [c13]Armaiti Ardeshiricham, Wei Hu, Ryan Kastner
Clepsydra: Modeling timing flows in hardware designs. ICCAD 2017: 147-154 - [c12]Wei Hu
Why you should care about don't cares: Exploiting internal don't care conditions for hardware Trojans. ICCAD 2017: 707-713 - [c11]Wei Hu, Armaiti Ardeshiricham, Ryan Kastner
Identifying and Measuring Security Critical Path for Uncovering Circuit Vulnerabilities. MTV 2017: 62-67 - 2016
- [j8]Yu Tai, Wei Hu, Huixiang Zhang, Dejun Mu, Xing-Li Huang:
Generating optimized gate level information flow tracking logic for enforcing multilevel security. Autom. Control. Comput. Sci. 50(5): 361-368 (2016) - [j7]Wei Hu
Detecting Hardware Trojans with Gate-Level Information-Flow Tracking. Computer 49(8): 44-52 (2016) - [c10]Ryan Kastner, Wei Hu, Alric Althoff:
Quantifying hardware security using joint information flow analysis. DATE 2016: 1523-1528 - [c9]Wei Hu
Imprecise security: quality and complexity tradeoffs for hardware information flow tracking. ICCAD 2016: 95 - [c8]Wei Hu, Alric Althoff, Armita Ardeshiricham, Ryan Kastner
Towards Property Driven Hardware Security. MTV 2016: 51-56 - 2015
- [c7]Baolei Mao
Quantifying Timing-Based Information Flow in Cryptographic Hardware. ICCAD 2015: 552-559 - 2014
- [j6]Tao Yang, Dejun Mu, Wei Hu, Huixiang Zhang:
Energy-efficient border intrusion detection using wireless sensors network. EURASIP J. Wirel. Commun. Netw. 2014: 46 (2014) - [j5]Dejun Mu, Wei Hu, Baolei Mao
A bottom-up approach to verifiable embedded system information flow security. IET Inf. Secur. 8(1): 12-17 (2014) - [j4]Wei Hu, Dejun Mu, Jason Oberg, Baolei Mao
Gate-Level Information Flow Tracking for Security Lattices. ACM Trans. Design Autom. Electr. Syst. 20(1): 2:1-2:25 (2014) - 2013
- [j3]Wei Hu
Expanding Gate Level Information Flow Tracking for Multilevel Security. IEEE Embed. Syst. Lett. 5(2): 25-28 (2013) - [c6]Bo Ma, Dejun Mu, Wei Fan, Wei Hu:
Improvements the Seccomp Sandbox Based on PBE Theory. AINA Workshops 2013: 323-328 - [c5]Chunlei Chen, Dejun Mu, Huixiang Zhang, Wei Hu:
Towards a Moderate-Granularity Incremental Clustering Algorithm for GPU. CyberC 2013: 194-201 - 2012
- [j2]Wei Hu
On the Complexity of Generating Gate Level Information Flow Tracking Logic. IEEE Trans. Inf. Forensics Secur. 7(3): 1067-1080 (2012) - [c4]Wei Hu, Jason Oberg, Dejun Mu, Ryan Kastner
Simultaneous information flow security and circuit redundancy in Boolean gates. ICCAD 2012: 585-590 - 2011
- [j1]Wei Hu
Theoretical Fundamentals of Gate Level Information Flow Tracking. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 30(8): 1128-1140 (2011) - [c3]Jason Oberg, Wei Hu, Ali Irturk, Mohit Tiwari
Information flow isolation in I2C and USB. DAC 2011: 254-259 - 2010
- [c2]Jason Oberg, Wei Hu
Theoretical analysis of gate level information flow tracking. DAC 2010: 244-247
2000 – 2009
- 2007
- [c1]Meifeng Li, Guanzhong Dai, Hang Liu, Wei Hu:
Design of an Instruction for Fast and Efficient S-Box Implementation. CIS 2007: 623-626
Coauthor Index
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