Complete solution over pn of the equation Xpk+1+X+a=0
Abstract
The problem of solving explicitly the equation Pa(X):=Xq+1+X+a=0 over the finite field Q, where Q=pn, q=pk and p is a prime, arises in many different contexts including finite geometry, the inverse Galois problem ACZ2000, the construction of difference sets with Singer parameters DD2004, determining cross-correlation between m-sequences DOBBERTIN2006 and to construct error correcting codes Bracken2009, cryptographic APN functions BTT2014,Budaghyan-Carlet2006, designs Tang2019, as well as to speed up the index calculus method for computing discrete logarithms on finite fields GGGZ2013,GGGZ2013+ and on algebraic curves M2014. Subsequently, in Bluher2004,HK2008,HK2010,BTT2014,Bluher2016,KM2019,CMPZ2019,MS2019,KCM19, the Q-zeros of Pa(X) have been studied. In Bluher2004, it was shown that the possible values of the number of the zeros that Pa(X) has in Q is 0, 1, 2 or p(n, k)+1. Some criteria for the number of the Q-zeros of Pa(x) were found in HK2008,HK2010,BTT2014,KM2019,MS2019. However, while the ultimate goal is to explicit all the Q-zeros, even in the case p=2, it was solved only under the condition (n, k)=1 KM2019. In this article, we discuss this equation without any restriction on p and (n,k). In KCM19, for the cases of one or two Q-zeros, explicit expressions for these rational zeros in terms of a were provided, but for the case of p(n, k)+1 Q- zeros it was remained open to explicitly compute the zeros. This paper solves the remained problem, thus now the equation Xpk+1+X+a=0 over pn is completely solved for any prime p, any integers n and k.
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