Infinite families of APN permutations in constrained trivariate classes over F2m
Abstract
We study trivariate permutation polynomials over F2m extending two APN permutation families of Li--Kaleyski (IEEE Trans. Inform. Theory, 2024) by allowing the scalar parameter to vary over F2m*. For \[ Ga(x,y,z)=(xq+1+axqz+yzq,\; xqz+yq+1,\; xyq+ayqz+zq+1), \] where a∈F2m*, q=2i, (i,m)=1, and m is odd, we prove that Ga is a permutation if and only if an associated univariate polynomial has no root in F2m*, and that this condition is also equivalent to Ga being APN. Hence, writing d=q2+q+1, at least \[ 2m+1-(d-1)(d-2)2m/2-dd \] values of a yield APN permutations Ga. In the binary case q=2, we show that a=1 is good whenever 7 m, recovering the Li--Kaleyski family. For the second family \[ Ha(x,y,z)=(xq+1+axyq+yzq,\; xyq+zq+1,\; xqz+yq+1+ayqz), \] we obtain the same root criterion and prove that its defining polynomial is root-equivalent to that of Ga. Thus the same parameters a give APN permutations in both families. We also prove strong inequivalence results. First, Ga (resp.\ Ha) is diagonally equivalent to G1 (resp.\ H1) if and only if aq2+q+1=1; moreover, for m>4, m≠ 6, and 7 m, diagonal non-equivalence implies CCZ non-equivalence by the monomial restriction theorem of Shi et al.\ (DCC, 2025). In particular, when q=2 and 7 m, every good a≠ 1 gives APN permutations CCZ-inequivalent to Li--Kaleyski. Second, for the same range of m, no Ga is CCZ-equivalent to any Hb. Hence these constructions yield two genuinely new, mutually inequivalent families of APN permutations on F23m.
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