Quantum Computation with Correlated Measurements: Implications for the Complexity Landscape

In 2004, Aaronson introduced the complexity class $\mathsf{PostBQP}$ ($\mathsf{BQP}$ with postselection) and showed that it is equal to $\mathsf{PP}$. In this paper, we define a new complexity class, $\mathsf{CorrBQP}$, a modification of $\mathsf{BQP}$ which has the power to perform correlated measurements, i.e. measurements that output the same value across a partition of registers. We show that $\mathsf{CorrBQP}$ is exactly equal to $\mathsf{BPP}^{\mathsf{PP}}$, placing it "just above" $\mathsf{PP}$. In fact, we show that other metaphysical modifications of $\mathsf{BQP}$, such as $\mathsf{CBQP}$ (i.e. $\mathsf{BQP}$ with the ability to clone arbitrary quantum states), are also equal to $\mathsf{BPP}^{\mathsf{PP}}$. Furthermore, we show that $\mathsf{CorrBQP}$ is self-low with respect to classical queries. In contrast, if it were self-low under quantum queries, the counting hierarchy ($\mathsf{CH}$) would collapse to $\mathsf{BPP}^{\mathsf{PP}}$. Finally, we introduce a variant of rational degree that lower-bounds the query complexity of $\mathsf{BPP}^{\mathsf{PP}}$.