A Converse for Fault-tolerant Quantum Computation

TL;DR

This paper establishes a fundamental lower bound on the redundancy needed for fault-tolerant quantum computation, linking it to quantum communication limits and impacting noise threshold estimates.

Contribution

It introduces a new lower bound on redundancy for fault-tolerant quantum operations, improving understanding of resource requirements and noise thresholds in quantum computing.

Findings

Lower bound on redundancy tighter than previous bounds for certain regimes

Connects fault-tolerance with finite blocklength quantum communication problems

Implications for noise threshold estimates in quantum error correction

Abstract

As techniques for fault-tolerant quantum computation keep improving, it is natural to ask: what is the fundamental lower bound on redundancy? In this paper, we obtain a lower bound on the redundancy required for $\epsilon$-accurate implementation of a large class of operations that includes unitary operators. For the practically relevant case of sub-exponential depth and sub-linear gate size, our bound on redundancy is tighter than the known lower bounds. We obtain this bound by connecting fault-tolerant computation with a set of finite blocklength quantum communication problems whose accuracy requirements satisfy a joint constraint. The lower bound on redundancy obtained here leads to a strictly smaller upper bound on the noise threshold for non-degradable noise. Our bound directly extends to the case where noise at the outputs of a gate are non-i.i.d. but noise across gates are i.i.d.