Fault Diagnosis and Tolerance in Cryptography : Third International Workshop, FDTC 2006, Yokohama, Japan, October 10, 2006, Proceedings / edited by Luca Breveglieri, Israel Koren, David Naccache, Jean-Pierre Seifert.

Format:

Book

Contributor:

Breveglieri, Luca, editor.

Koren, Israel, editor.

Naccache, David, 1967- editor.

Seifert, Jean-Pierre, editor.

SpringerLink (Online service)

Series:

Computer Science (Springer-11645)

LNCS sublibrary. Security and cryptology ; SL 4, 4236.

Security and Cryptology ; 4236

Language:

English

Subjects (All):

Data encryption (Computer science).

Computer networks.

Operating systems (Computers).

Management information systems.

Computer science.

Computers and civilization.

Information storage and retrieval.

Cryptology.

Computer Communication Networks.

Operating Systems.

Management of Computing and Information Systems.

Computers and Society.

Information Storage and Retrieval.

Local Subjects:

Cryptology.

Computer Communication Networks.

Operating Systems.

Management of Computing and Information Systems.

Computers and Society.

Information Storage and Retrieval.

Physical Description:

1 online resource (XIV, 258 pages).

Edition:

First edition 2006.

Contained In:

Springer eBooks

Place of Publication:

Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2006.

System Details:

text file PDF

Summary:

In recent years applied cryptography has developed considerably to satisfy the - creasing security requirements of various information technology disciplines, such as telecommunications, networking, database systems, mobile applications and others. Cryptosystems are inherently computationally complex and in order to satisfy the high throughput requirements of many applications, they are often implemented by means of either VLSI devices (cryptographic accelerators) or highly optimized software routines (cryptographic libraries) and are used via suitable (network) protocols. The sophistication of the underlying cryptographic algorithms, the high complexity of the implementations, and the easy access and low cost of cryptographic devices resulted in increased concerns regarding the reliability and security of crypto-devices. The effectiveness of side channel attacks on cryptographic devices, like timing and power-based attacks, has been known for some time. Several recent investigations have demonstrated the need to develop methodologies and techniques for designing robust cryptographic systems (both hardware and software) to protect them against both accidental faults and maliciously injected faults with the purpose of extracting the secret key. This trend has been particularly motivated by the fact that the equipment needed to carry out a successful side channel attack based on fault injection is easily accessible at a relatively low cost (for example, laser beam technology), and that the skills needed to use it are quite common. The identification of side channel attacks based on fault injections and the development of appropriate counter-measures have therefore become an active field of scientific and industrial research.

Contents:

Attacks on Public Key Systems

Is It Wise to Publish Your Public RSA Keys?

Wagner's Attack on a Secure CRT-RSA Algorithm Reconsidered

Attacking Right-to-Left Modular Exponentiation with Timely Random Faults

Sign Change Fault Attacks on Elliptic Curve Cryptosystems

Cryptanalysis of Two Protocols for RSA with CRT Based on Fault Infection

Protection of Public Key Systems

Blinded Fault Resistant Exponentiation

Incorporating Error Detection in an RSA Architecture

Data and Computational Fault Detection Mechanism for Devices That Perform Modular Exponentiation

Attacks on and Protection of Symmetric Key Systems

Case Study of a Fault Attack on Asynchronous DES Crypto-Processors

A Fault Attack Against the FOX Cipher Family

Fault Based Collision Attacks on AES

An Easily Testable and Reconfigurable Pipeline for Symmetric Block Ciphers

Models for Fault Attacks on Cryptographic Devices

An Adversarial Model for Fault Analysis Against Low-Cost Cryptographic Devices

Cryptographic Key Reliable Lifetimes: Bounding the Risk of Key Exposure in the Presence of Faults

A Comparative Cost/Security Analysis of Fault Attack Countermeasures

Fault-Resistant Arithmetic for Cryptography

Non-linear Residue Codes for Robust Public-Key Arithmetic

Fault Attack Resistant Cryptographic Hardware with Uniform Error Detection

Robust Finite Field Arithmetic for Fault-Tolerant Public-Key Cryptography

Fault Attacks and Other Security Threats

DPA on Faulty Cryptographic Hardware and Countermeasures

Fault Analysis of DPA-Resistant Algorithms

Java Type Confusion and Fault Attacks.

Other Format:

Printed edition:

ISBN:

978-3-540-46251-4

9783540462514

Access Restriction:

Restricted for use by site license.