Diagonal parity and loop toggling for symmetric matrices over F2

Abstract

Let M be a symmetric matrix over F2, and let (M) be its diagonal vector. It is known that \[ (M)∈ (M). \] Thus the affine system Mx=(M) is always solvable. We strengthen this existence statement to a parity rigidity theorem: every solution satisfies \[ (M)T x (M) 2 . \] For graph matrices this gives a common extension of Sutner's odd-domination theorem and Batal's parity theorem from closed-neighborhood matrices A(G)+I to arbitrary partially looped graph matrices A(G)+D. We also study how rank and nullity change when loops are toggled. Algebraically, simultaneous loop toggling on the support of a vector u is the diagonal rank-one update M M+uuT. We prove an exact three-case rank and nullity formula for this update. Finally, for rooted trees with arbitrary binary diagonal labels, we give a finite-state boundary recursion using affine subspaces of F22. This recursion counts all generalized odd-domination patterns and implies eventual quasigeometric nullity formulas for complete rooted trees with eventually periodic depth labels.