Modifications of Quantum Computation and Adaptive Queries to PP

Abstract

In 2004, Aaronson introduced the complexity class PostBQP (BQP with postselection) and showed that it is equal to PP. Following their line of work, we introduce two new complexity classes. The first, CorrBQP, is a modification of BQP which has the power to perform correlated measurements, i.e. measurements that output the same value across a partition of registers. The second, MajBQP, augments BQP with the ability to collapse a register to its most likely measurement outcome. Specifically, we consider two variants, MajBQP and AdMajBQP, where the latter may perform intermediate measurements. We exactly characterize the computational power of the models, CorrBQP = AdMajBQP = BPPPP and MajBQP = PPP. In fact, we show that other metaphysical modifications of BQP, such as CBQP (i.e. BQP with the ability to clone arbitrary quantum states), are also equal to BPPPP. We show that CorrBQP and MajBQP are self-low with respect to classically-accessible queries. In contrast, if they were self-low under quantumly-accessible queries, the counting hierarchy would collapse. Furthermore, we introduce a variant of rational degree that lower-bounds the query complexity of BPPPP. Lastly, we extend the adversary lower-bounding technique to AdPDQP, BQP with the ability to sample the current state of an algorithm with collapsing it and adapt the computation based on the samples.