The rapid growth in the use of computers and networks in government, commercial and
private communications systems has led to an increasing need for these systems to be
secure against unauthorised access and eavesdropping. To this end, modern computer
security systems employ public-key ciphers, of which probably the most well known is the
RSA ciphersystem, to provide both secrecy and authentication facilities.
The basic RSA cryptographic operation is a modular exponentiation where the modulus
and exponent are integers typically greater than 500 bits long. Therefore, to obtain reasonable
encryption rates using the RSA cipher requires that it be implemented in hardware.
This thesis presents the design of a high-performance VLSI device, called the WHiSpER
chip, that can perform the modular exponentiations required by the RSA cryptosystem
for moduli and exponents up to 506 bits long. The design has an expected throughput
in excess of 64kbit/s making it attractive for use both as a general RSA processor within
the security function provider of a security system, and for direct use on moderate-speed
public communication networks such as ISDN.
The thesis investigates the low-level techniques used for implementing high-speed arithmetic
hardware in general, and reviews the methods used by designers of existing modular
multiplication/exponentiation circuits with respect to circuit speed and efficiency.
A new modular multiplication algorithm, MMDDAMMM, based on Montgomery arithmetic,
together with an efficient multiplier architecture, are proposed that remove the
speed bottleneck of previous designs.
Finally, the implementation of the new algorithm and architecture within the WHiSpER
chip is detailed, along with a discussion of the application of the chip to ciphering and key
generation.
Date of Award | 1995 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Peter Sanders (Other Supervisor) |
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A high-speed integrated circuit with applications to RSA Cryptography
Onions, P. D. (Author). 1995
Student thesis: PhD