Deciding One to One property of Boolean maps: Condition and algorithm in terms of implicants

Abstract

This paper addresses the computational problem of deciding invertibility (or one to one-ness) of a Boolean map F in n-Boolean variables. This problem is a special case of deciding invertibilty of a map F:Fqn→Fqn over the finite field Fq for q=2. Algebraic condition for invertibility of F is well known to be equivalent to invertibility of the Koopman operator of F as shown in RamSule. In this paper a condition for invertibility is derived in the special case of Boolean maps F:B0n→ B0n where B0 is the two element Boolean algebra in terms of implicants of Boolean equations defined by the map. This condition is then extended to the case of general maps in n variables and m≥ n equations. Hence this condition answers the special case of invertibility of maps F defined over the binary field F2 alternatively, in terms of implicants instead of the Koopman operator. The problem of deciding invertibility of a map F (or that of finding its Garden of Eden (GOE)) over finite fields is distinct from the satisfiability problem (SAT) or the problem of deciding consistency of polynomial equations over finite fields. Hence the well known algorithms for deciding SAT or of solvability using Grobner basis for checking membership in an ideal generated by polynomials is not known to answer the question of invertibility of a map. Similarly it appears that algorithms for satisfiability or polynomial solvability are not useful for computation of GOE of F even for maps over the binary field F2.