Finite field arithmetic logic is central in the implementation of Reed-Solomon coders and in some cryptographic algorithms. There is a need for good multiplication and inversion algorithms that are easily realized on VLSI chips. Massey and Omura recently developed a new multiplication algorithm for Galois fields based on a normal basis representation. A pipeline structure is developed to realize the Massey-Omura multiplier in the finite field GF(2m). With the simple squaring property of the normal-basis representation used together with this multiplier, a pipeline architecture is also developed for computing inverse elements in GF(2m). The designs developed for the Massey-Omura multiplier and the computation of inverse elements are regular,...
AbstractA new table lookup method for finding the log and antilog of finite field elements has been ...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
Computing the inverse of a number in finite fields GF(p) or GF(2n) is equally important for cryptogr...
Finite field arithmetic logic is central in the implementation of some error-correcting coders and s...
Finite field multiplication is central in the implementation of some error-correcting coders. Massey...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
International audienceHalving methods have been proposed for parallel implementation of ECC primit...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
International audienceHalving methods have been proposed for parallel implementation of ECC primit...
AbstractÐThe Massey-Omura multiplier of GF \u852m uses a normal basis and its bit parallel version ...
Abstract—For efficient hardware implementation of finite field arithmetic units, the use of a normal...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
AbstractA new table lookup method for finding the log and antilog of finite field elements has been ...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
Computing the inverse of a number in finite fields GF(p) or GF(2n) is equally important for cryptogr...
Finite field arithmetic logic is central in the implementation of some error-correcting coders and s...
Finite field multiplication is central in the implementation of some error-correcting coders. Massey...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
International audienceHalving methods have been proposed for parallel implementation of ECC primit...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
The computation of the inverse of a number in finite fields, namely Galois Fields GF(p) or GF(2n), i...
International audienceHalving methods have been proposed for parallel implementation of ECC primit...
AbstractÐThe Massey-Omura multiplier of GF \u852m uses a normal basis and its bit parallel version ...
Abstract—For efficient hardware implementation of finite field arithmetic units, the use of a normal...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
AbstractA new table lookup method for finding the log and antilog of finite field elements has been ...
This study presents a survey of algorithms used in field arithmetic over GF (2m) using normal basis ...
Computing the inverse of a number in finite fields GF(p) or GF(2n) is equally important for cryptogr...
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