On the Rational Degree of Boolean Functions and Applications

Abstract

We study a natural complexity measure of Boolean functions known as the rational degree. Denoted rdeg(f), it is the minimal degree of a rational function that is equal to f on the Boolean hypercube. For total functions f, it is conjectured that rdeg(f) is polynomially related to the Fourier degree of f, deg(f). Towards this conjecture, we show that: - Symmetric functions have rational degree at least (deg(f)) and unate functions have rational degree at least deg(f). We observe that both of these lower bounds are asymptotically tight. - Read-once AC and TC formulae have rational degree at least (deg(f)). If these formulae contain parity gates, we show a lower bound of (deg(f)1/2d), where d is the depth. - Almost every Boolean function on n variables has rational degree at least n/2 - O(n). In contrast, we exhibit partial functions that witness unbounded separations between rational and approximate degree, in both directions. As a consequence, we show that for quantum computers, post-selection and bounded-error are incomparable resources in the black-box model. In addition, we show AND and OR composition lemmas for the rational degree and exhibit new polynomial separations between the rational degree and other well-studied complexity measures, such as sensitivity and spectral sensitivity.

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