Probabilistically checkable proofs for the Existential Theory of the Reals

Abstract

We prove a PCP theorem for the existential theory of the reals, showing that MAX-ETR-INV is ∃R-hard to approximate to within some constant factor. The existential theory of the reals (ETR) is a decision problem asking if there exists a set of real-valued variables satisfying some constraints involving polynomials and inequalities, and ∃R is the complexity class of problems polynomial-time reducible to ETR. Many important geometric problems are known to be ∃R-complete. ∃R-hardness results frequently work by a reduction from the ∃R-complete problem ETR-INV, which asks if there is a an assignment of real variables each in the interval [12, 2] satisfying some constraints of form x=1, xy=1 and x+y=z. MAX-ETR-INV is a related optimization problem that asks, given a set of constraints of form x=1, xy=1, and x+y=z, for a feasible (that is, satisfiable with variables in [12, 2]) subset of those constraints of the largest possible size. We show that there is some constant ε>0 such that it is ∃R-hard to approximate MAX-ETR-INV better than a 1-ε factor. This means that even a non-deterministic polynomial-time algorithm can't approximate MAX-ETR-INV better than this factor unless ∃R=NP. We also give a polynomial-time 8-factor approximation algorithm and a non-deterministic-polynomial-time 2-factor approximation algorithm for MAX-ETR-INV.