Abstract
Perfect nonlinear functions are of importance in cryptography. By using Galois ring, relative trace and investigating the character values of corresponding relative difference sets, we present a construction of perfect nonlinear functions from \({\mathbb{Z}_4^{2m}}\) to \({\mathbb{Z}_4^{m'}}\) , where m′ is a divisor of 2m, and a construction of perfect nonlinear functions from \({\mathbb{Z}_{p^2}^{n}}\) to \({\mathbb{Z}_{p^2}^m}\) where 2m is possibly larger than the largest divisor of n. Meanwhile we prove that there exists a perfect nonlinear function from \({\mathbb{Z}_{2p}^2}\) to \({\mathbb{Z}_{2p}}\) if and only if p = 2, and there doesn’t exist a perfect nonlinear function from \({\mathbb{Z}_{2^kl}^{2n}}\) to \({\mathbb{Z}_{2^kl}^m}\) if m > n and l(l is odd) is self-conjugate modulo 2k(k ≥ 1).
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Zhang, X., Guo, H. On perfect nonlinear functions (Π). AAECC 19, 293–309 (2008). https://doi.org/10.1007/s00200-008-0065-1
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DOI: https://doi.org/10.1007/s00200-008-0065-1