Triplets and Symmetries of Arithmetic mod pk
Abstract
The finite ring Zk = Z(+,.) mod pk of residue arithmetic with odd prime power modulus is analysed. The cyclic group of units Gk in Zk(.) has order (p-1)pk-1, implying product structure Gk = Ak Bk. Here core Ak of order p-1 is an extension for k >1 of Fermat's Small Theorem (FST*), where np == n (mod pk) for each core residue, while extension subgroup Bk has order pk-1. It is shown that each subgroup S >1 of core Ak has zero sum, and that p+1 generates subgroup Bk of all n == 1 (mod p) in Gk. The p-th power residues np mod pk in Gk form an order |Gk|/p subgroup Fk, with |Fk|/|Ak| = pk-2, so Fk properly contains core Ak for k >2. By quadratic analysis (mod p3) rather than linear analysis (mod p2, re Hensel's lemma [5]), the additive structure of subgroups Gk and Fk is derived. ... Successor function S(n)=n+1 combines with the two arithmetic symmetries -n (complement) and 1/n (inverse) to yield the "triplet structure" of Gk : three inverse pairs ni, 1/(ni) with (ni)+1 = - 1/ni+1 (mod pk), with indices mod 3, and product n0.n1.n2 = 1 mod pk. In case n0 = n1 = n2 = n this reduces to the cubic root solution n+1 = -(1/n) = -(n2) (mod pk, p=1 mod 6). The property "EDS" of exponent p distributing over a sum of core residues: (x+y)p == x+y == xp + yp (mod pk), is employed to derive the known FLT inequality for integers. In other words, to any FLT(mod pk) equivalence for k digits correspond p-th power integers of pk digits, and the (p-1)k "carries" make the difference, representing the sum of mixed-terms in the binomial expansion.
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