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Mutual Information Minimization for Side-Channel Attack Resistance via Optimal Noise Injection

ai-safety › robustness

📄 Abstract

Abstract: Side-channel attacks (SCAs) pose a serious threat to system security by extracting secret keys through physical leakages such as power consumption, timing variations, and electromagnetic emissions. Among existing countermeasures, artificial noise injection is recognized as one of the most effective techniques. However, its high power consumption poses a major challenge for resource-constrained systems such as Internet of Things (IoT) devices, motivating the development of more efficient protection schemes. In this paper, we model SCAs as a communication channel and aim to suppress information leakage by minimizing the mutual information between the secret information and side-channel observations, subject to a power constraint on the artificial noise. We propose an optimal artificial noise injection method to minimize the mutual information in systems with Gaussian inputs. Specifically, we formulate two convex optimization problems: 1) minimizing the total mutual information, and 2) minimizing the maximum mutual information across observations. Numerical results show that the proposed methods significantly reduce both total and maximum mutual information compared to conventional techniques, confirming their effectiveness for resource-constrained, security-critical systems.

Key Contributions

Models side-channel attacks (SCAs) as a communication channel and proposes an optimal artificial noise injection method to minimize mutual information between secret information and side-channel observations, subject to a power constraint. This approach is particularly relevant for resource-constrained IoT devices, offering efficient SCA resistance.

Business Value

Enables the development of more secure IoT devices and embedded systems by providing an efficient method to protect against side-channel attacks without excessive power draw.

Paper Metadata

Innovation Type

Optimization Framework and Method

Deployment Feasibility

Feasible, based on established optimization techniques and applicable to various embedded systems where side-channel leakage is a concern.

Limitations Addressed

The high power consumption of traditional artificial noise injection countermeasures, which is prohibitive for resource-constrained devices like IoT.

Performance Gains

Achieves significant reduction in mutual information (information leakage) while adhering to power constraints, leading to more efficient SCA resistance.

Technical Tags

Side-Channel Attacks (SCAs)Mutual Information MinimizationNoise InjectionPower ConstraintConvex OptimizationInformation LeakageIoT DevicesGaussian InputsCountermeasuresSystem Security

Research Topics

Side-Channel AnalysisInformation TheoryCryptographyEmbedded Systems SecurityOptimization Techniques

Methods & Architectures

Modeling SCAs as Communication ChannelsMutual Information MinimizationConvex Optimization ProblemsOptimal Artificial Noise InjectionPower Constraint Optimization

Applications & Tasks

Embedded Systems Internet of Things (IoT) Cybersecurity Hardware Security High Power Consumption of Noise InjectionMinimizing Information Leakage under Power ConstraintsEfficient Side-Channel Attack Resistance Minimizing mutual information between secret data and side-channel observationsDeveloping efficient noise injection methodsAchieving SCA resistance within power budgets

Related Fields

Electrical EngineeringComputer ScienceInformation TheoryMathematics

Keywords

Side-Channel AttackMutual InformationNoise InjectionIoT SecurityPower ConstraintConvex OptimizationInformation LeakageHardware SecurityCountermeasuresCryptography

Academic Context

#Side-Channel Analysis#Information Theory#Cryptography#Embedded Systems Security#Optimization Techniques

Commercial Potential

Potential Products

Secure IoT DevicesHardware Security IP CoresTools for Designing SCA-Resistant Circuits

Target Industries

IoTSemiconductorsElectronicsCybersecurityAutomotive

Use Case Examples

Protecting cryptographic keys in smart cards and IoT sensorsSecuring communication protocols in embedded devicesReducing information leakage from power consumption of microcontrollers

Competitive Edge

Offers a theoretically grounded and optimized approach to noise injection for SCA resistance, specifically addressing the power constraints of embedded systems.

Market Opportunity

Growing market for secure IoT devices and embedded systems.

Revenue Models

Licensing of the optimization methodology or resulting hardware designs.

Resource Requirements

Compute Needs

Moderate to high for solving the convex optimization problems.

Data Requirements

Models of the target system's leakage characteristics and power consumption.

Deployment Constraints

Requires accurate modeling of the system's leakage and power behavior; implementation complexity on hardware.

Scalability

The optimization framework is designed to be general and applicable to various systems.

Regulatory Considerations

Impacts security standards for IoT devices and embedded systems.

Production Readiness

Maturity Level

Theoretical Framework / Methodology

Time to Market

2-4 years for integration into hardware design flows and product development.

Patent Potential

Moderate, for novel optimization algorithms or specific noise injection schemes.

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