Global ETD Search

21	ADVANCED LOW-COST ELECTRO-MAGNETIC AND MACHINE LEARNING SIDE-CHANNEL ATTACKS Josef A Danial (9520181) 16 December 2020 (has links) Side-channel analysis (SCA) is a prominent tool to break mathematically secure cryptographic engines, especially on resource-constrained devices. SCA attacks utilize physical leakage vectors like the power consumption, electromagnetic (EM) radiation, timing, cache hits/misses, that reduce the complexity of determining a secret key drastically, going from 2<sup>128</sup> for brute force attacks to 2<sup>12</sup> for SCA in the case of AES-128. Additionally, EM SCA attacks can be performed non-invasively without any modifications to the target under attack, unlike power SCA. To develop defenses against EM SCA, designers must evaluate the cryptographic implementations against the most powerful side-channel attacks. In this work, systems and techniques that improve EM side-channel analysis have been explored, making it lower-cost and more accessible to the research community to develop better countermeasures against such attacks. The first chapter of this thesis presents SCNIFFER, a platform to perform efficient end-to-end EM SCA attacks. SCNIFFER introduces leakage localization – an often-overlooked step in EM attacks – into the loop of an attack. Following SCNIFFER, the second chapter presents a practical machine learning (ML) based EM SCA attack on AES-128. This attack addresses issues dealing with low signal-to-noise ratio (SNR) EM measurements, proposing training and pre-processing techniques to perform an efficient profiling attack. In the final chapter, methods for mapping from power to EM measurements, are analyzed, which can enable training a ML model with much lower number of encryption traces. Additionally, SCA evaluation of high-level synthesis (HLS) based cryptographic algorithms is performed, along with the study of futuristic neural encryption techniques. Computer Engineering Computer System Security Hardware Security Side-channel analysis Side-channel attacks Machine Learning
22	Design and Analysis of Assured and Trusted ICs using Machine Learning and Blockchain Technology Hazari, Noor Ahmad January 2021 (has links) No description available. Electrical Engineering Hardware Security PUF Machine Learning ANN Authentication Obfuscation ROPUF FPGA IC Supply Chain Blockchain
23	Logic Encryption for Resource Constrained Designs Luria, David M. January 2020 (has links) No description available. Computer Engineering Hardware Security Logic Encryption Pure-Play Foundry Integrated Circuit Electronics Design Constraints
24	Built-In Return-Oriented Programs in Embedded Systems and Deep Learning for Hardware Trojan Detection Weidler, Nathanael R. 01 December 2019 (has links) Microcontrollers and integrated circuits in general have become ubiquitous in the world today. All aspects of our lives depend on them from driving to work, to calling our friends, to checking our bank account balance. People who would do harm to individuals, corporations and nation states are aware of this and for that reason they seek to find or create and exploit vulnerabilities in integrated circuits. This dissertation contains three papers dealing with these types of vulnerabilities. The first paper talks about a vulnerability that was found on a microcontroller, which is a type of integrated circuit. The final two papers deal with hardware trojans. Hardware trojans are purposely added to the design of an integrated circuit in secret so that the manufacturer doesn’t know about it. They are used to damage the integrated circuit, leak confidential information, or in other ways alter the circuit. Hardware trojans are a major concern for anyone using integrated circuits because an attacker can alter a circuit in almost any way if they are successful in inserting one. A known method to prevent hardware trojan insertion is discussed and a type of circuit for which this method does not work is revealed. The discussion of hardware trojans is concluded with a new way to detect them before the integrated circuit is manufactured. Modern deep learning models are used to detect the portions of the hardware trojan called triggers that activate them. Return-oriented programming hardware trojans hardware security integrated circuit Electrical and Computer Engineering
25	On Reverse Engineering of Encrypted High Level Synthesis Designs Joshi, Manasi 02 November 2018 (has links) No description available. Electrical Engineering Hardware Security High level synthesis SAT Recover flow graph encrypted high level synthesis
26	Split Manufacturing: Attacks and Defenses Chen, Suyuan 07 June 2019 (has links) No description available. Electrical Engineering Split Manufacturing Hardware Security Satisfiability Cycle Constraints Hybrid Attack Proximity Information
27	Bio-Inspired Hardware Security Defenses: A CRISPR-Cas-Based Approach for Detecting Trojans in FPGA Systems Staub, Dillon 24 October 2019 (has links) No description available. Electrical Engineering hardware Trojan CRISPR-Cas bio-inspired hardware security FPGA
28	Hardware Security Threat and Mitigation Techniques for Network-on-Chips Boraten, Travis Henry 17 September 2020 (has links) No description available. Computer Engineering Electrical Engineering Network-on-Chip Hardware Security Hardware Trojans Side-Channels Denial-of-Service
29	Development of an RSA Algorithm using Reduced RISC V instruction Set Chatterjee, Aakriti 28 June 2021 (has links) No description available. Computer Engineering Hardware Security Side Channel Asynchronous ASIC FPGA Cyber Algorithm
30	APEX-ICS: Automated Protocol Exploration And Fuzzing For Closed Source ICS Protocols Parvin Kumar (15354694) 28 April 2023 (has links) <p>A closed-source ICS communication is a fundamental component of supervisory software and PLCs operating critical infrastructure or configuring devices. As this is a vital communication, a compromised protocol can allow attackers to take over the entire critical infrastructure network and maliciously manipulate field device values. Thus, it is crucial to conduct security assessments of these closed-source protocol communications before deploy?ing them in a production environment to ensure the safety of critical infrastructure. However, Fuzzing closed-source communication without understanding the protocol structure or state is ineffective, making testing such closed-source communications a challenging task. </p> <p><br></p> <p>This research study introduces the APEX-ICS framework, which consists of two significant components: Automatic closed-source ICS protocol reverse-engineering and stateful black-box fuzzing. The former aims to reverse-engineer the protocol communication, which is critical to effectively performing the fuzzing technique. The latter component leverages the generated grammar to detect vulnerabilities in communication between supervisory software and PLCs. The framework prototype was implemented using the Codesys v3.0 closed-source protocol communication to conduct reverse engineering and fuzzing and successfully identified 4 previously unknown vulnerabilities, which were found to impact more than 400 manufacturer’s devices. </p> Hardware security Software and application security System and network security Fuzzng reverse engineering concept Codesys ICS

Search results