A compressed classical description of quantum states

TL;DR

This paper introduces a method to approximately represent quantum states with significantly less classical memory, enabling efficient computation of observable expectations and improving communication protocols.

Contribution

It presents a novel classical compression scheme for quantum states using stabilizer states, reducing memory requirements and enhancing computational efficiency.

Findings

Classical representation uses O(√2^n) stabilizer states

Compression allows approximate expectation value calculations

Improves communication complexity protocols exponentially

Abstract

We show how to approximately represent a quantum state using the square root of the usual amount of classical memory. The classical representation of an $n$-qubit state $\psi$ consists of its inner products with $O(\sqrt{2^n})$ stabilizer states. A quantum state initially specified by its $2^n$ entries in the computational basis can be compressed to this form in time $O(2^n \mathrm{poly}(n))$, and, subsequently, the compressed description can be used to additively approximate the expectation value of an arbitrary observable. Our compression scheme directly gives a new protocol for the vector in subspace problem with randomized one-way communication complexity that matches (up to polylogarithmic factors) the optimal upper bound, due to Raz. We obtain an exponential improvement over Raz's protocol in terms of computational efficiency.