Innovative construction of involutory MDS matrices via self-reciprocal generator polynomials derived from reed-solomon codes

Luong Tran Thi; Cuong Nguyen Ngoc; Xinh Dinh Thi

doi:10.15625/1813-9663/22518

Innovative construction of involutory MDS matrices via self-reciprocal generator polynomials derived from reed-solomon codes

Luong Tran Thi, Cuong Nguyen Ngoc, Xinh Dinh Thi

Author affiliations

Authors

Luong Tran Thi Academy of Cryptography Techniques, No. 141, Chien Thang Road, Thanh Liet Ward, Ha Noi, Viet Nam
Cuong Nguyen Ngoc Academy of Cryptography Techniques, No. 141, Chien Thang Road, Thanh Liet Ward, Ha Noi, Viet Nam
Xinh Dinh Thi Tay Nguyen University, No. 567, Le Duan Street, Ea Kao Ward, Dak Lak Province, Viet Nam

DOI:

https://doi.org/10.15625/1813-9663/22518

Keywords:

MDS matrix, companion matrix, recursive MDS matrix, reed-Solomon codes, self-reciprocal polynomials.

Abstract

Recursive MDS matrices over finite fields optimize diffusion and enable efficient implementation in block ciphers. A key challenge is designing involutory MDS matrices to unify encryption and decryption, reducing costs. Recursive MDS matrices can meet these requirements. In this paper, we present a direct construction method for self-reciprocal recursive MDS matrices of arbitrary sizes, derived from self-reciprocal generator polynomials of Reed-Solomon codes, to generate corresponding involutory MDS matrices. The method for deriving self-reciprocal recursive MDS matrices from Reed-Solomon codes is straightforward. Additionally, we identify self-reciprocal generator polynomials of RS codes over the general finite field , where and is a prime number, including cases where is an odd prime. Involutory MDS matrices derived from self-reciprocal matrices are highly efficient for hardware and software, making them ideal for modern cryptographic applications.

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Published

05-03-2026

How to Cite

[1]L. Tran Thi, Cuong Nguyen Ngoc, and Xinh Dinh Thi, “Innovative construction of involutory MDS matrices via self-reciprocal generator polynomials derived from reed-solomon codes”, J. Comput. Sci. Cybern., Mar. 2026.

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