Computing Invariant Spaces via Global Cluster Analysis and Representation Theory

Abstract

The Singer algebraic transfer is a fundamental homomorphism in algebraic topology, providing a bridge between the homology of classifying spaces and the cohomology of the Steenrod algebra A, which forms the E2-term of the Adams spectral sequence. The domain of its dual is isomorphic to the space of GLk(F2)-invariants in the quotient of the polynomial algebra, (QPk)GLk(F2), where Pk is regarded as a module over A. A direct computation of this invariant space and its dual (i.e., the domain of the Singer transfer) remains a challenging problem. In this paper, we construct a new algorithm to compute (QPk)GLk(F2), which differs from the method presented in our recent work [15]. We refer to this new approach as the Global Cluster Analysis algorithm. It builds a weight interaction graph to identify clusters of interacting weight spaces that form closed k-submodules (where k ⊂ GLk(F2)). By performing invariance analysis on these larger clusters, our algorithm enables a complete and accurate computation of the global k-invariants, which are then used to determine the final GLk( F2)-invariants. We also introduce an algorithm to directly compute the domain of the Singer transfer for ranks k ≤ 3 in certain generic degrees, based entirely on Boardman's modular representation theory framework [2].