Linear gaps between degrees for the polynomial calculus modulo distinct primes
STOC '99 Proceedings of the thirty-first annual ACM symposium on Theory of computing
Bounded-Depth Frege Systems with Counting Axioms Polynomially Simulate Nullstellensatz Refutations
ICALP '02 Proceedings of the 29th International Colloquium on Automata, Languages and Programming
Annals of Mathematics and Artificial Intelligence
Groebner bases computation in Boolean rings for symbolic model checking
MS '07 The 18th IASTED International Conference on Modelling and Simulation
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The weak form of the Hilbert's Nullstellensatz says that a system of algebraic equations over a field, Q/sub i/(x~)=0, does not have a solution in the algebraic closure iff 1 is in the ideal generated by the polynomials Q/sub i/(x~). We shall prove a lower bound on the degrees of polynomials P/sub i/(x~) such that /spl Sigma//sub i/ P/sub i/(x~)Q/sub i/(x~)=1. This result has the following application. The modular counting principle states that no finite set whose cardinality is not divisible by q can be partitioned into q-element classes. For each fixed cardinality N, this principle can be expressed as a propositional formula Count/sub q//sup N/. Ajtai (1988) proved recently that, whenever p, q are two different primes, the propositional formulas Count/sub q//sup qn+1/ do not have polynomial size, constant-depth Frege proofs from instances of Count/sub p//sup m/, m/spl ne/0 (mod p). We give a new proof of this theorem based on the lower bound for the Hilbert's Nullstellensatz. Furthermore our technique enables us to extend the independence results for counting principles to composite numbers p and q. This results in an exact characterization of when Count/sub q/ can be proven efficiently from Count/sub p/, for all p and q.