Packing sets under finite groups via algebraic incidence structures

Abstract

Let G be a finite group acting on a vector space V = Fpn over a prime field. Given finite sets S ⊂ G and E ⊂ V, we study the restricted orbit union S(E) = g∈ S g(E) and establish quantitative lower bounds for |S(E)| in terms of |S|, |E|, and natural structural conditions. This finite field packing problem has connections to distance geometry, configuration counting, and expanding graphs. For G = SL2(Fp) acting on Fp2, we prove that |S(E)| p2, |S||E|p2, which is sharp. Under geometric non-concentration conditions on E and subgroup-avoidance hypotheses on S, we obtain a power-saving improvement of the form |S(E)| p2, ~|S||E|pk, ~|S|12|E|p1-ε2k12 , where k bounds the radial multiplicity of E. For small sets |E| ≤ p, we establish optimal bounds using weighted incidence theory. Analogous results are proved for the first Heisenberg group H1(Fp) acting on Fp3. Our approach reformulates the problem as an incidence question in a bipartite action graph. The proofs combine Fourier analytic techniques, energy estimates, point-line incidence bounds, and area-energy inequalities for skew dot products. The methods extend classical sum-product type problems and incidence theory to noncommutative group actions.

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