The Entangled Quantum Polynomial Hierarchy Collapses

Abstract

We introduce the entangled quantum polynomial hierarchy QEPH as the class of problems that are efficiently verifiable given alternating quantum proofs that may be entangled with each other. We prove QEPH collapses to its second level. In fact, we show that a polynomial number of alternations collapses to just two. As a consequence, QEPH = QRG(1), the class of problems having one-turn quantum refereed games, which is known to be contained in PSPACE. This is in contrast to the unentangled quantum polynomial hierarchy QPH, which contains QMA(2). We also introduce a generalization of the quantum-classical polynomial hierarchy QCPH where the provers send probability distributions over strings (instead of strings) and denote it by DistributionQCPH. Conceptually, this class is intermediate between QCPH and QPH. We prove DistributionQCPH = QCPH, suggesting that only quantum superposition (not classical probability) increases the computational power of these hierarchies. To prove this equality, we generalize a game-theoretic result of Lipton and Young (1994) which says that the provers can send distributions that are uniform over a polynomial-size support. We also prove the analogous result for the polynomial hierarchy, i.e., DistributionPH = PH. These results also rule out certain approaches for showing QPH collapses. Finally, we show that PH and QCPH are contained in QPH, resolving an open question of Gharibian et al. (2022).