English

Robust quantum compilation and circuit optimisation via energy minimisation

Quantum Physics 2022-01-26 v5

Abstract

We explore a method for automatically recompiling a quantum circuit A into a target circuit B, with the goal that both circuits have the same action on a specific input i.e. B|in> = A|in>. This is of particular relevance to hybrid, NISQ-era algorithms for dynamical simulation or eigensolving. The user initially specifies B as a blank template: a layout of parameterised unitary gates configured to the identity. The compilation then proceeds using quantum hardware to perform an isomorphic energy-minimisation task, and an optional gate elimination phase to compress the circuit. If B is insufficient for perfect recompilation then the method will result in an approximate solution. We optimise using imaginary time evolution, and a recent extension of quantum natural gradient for noisy settings. We successfully recompile a 7-qubit circuit involving 186 gates of multiple types into an alternative form with a different topology, far fewer two-qubit gates, and a smaller family of gate types. Moreover we verify that the process is robust, finding that per-gate noise of up to 1% can still yield near-perfect recompilation. We test the scaling of our algorithm on up to 20 qubits, recompiling into circuits with up to 400 parameterized gates, and incorporate a custom adaptive timestep technique. We note that a classical simulation of the process can be useful to optimise circuits for today's prototypes, and more generally the method may enable 'blind' compilation i.e. harnessing a device whose response to control parameters is deterministic but unknown.

Keywords

Cite

@article{arxiv.1811.03147,
  title  = {Robust quantum compilation and circuit optimisation via energy minimisation},
  author = {Tyson Jones and Simon C Benjamin},
  journal= {arXiv preprint arXiv:1811.03147},
  year   = {2022}
}

Comments

23 pages, 17 figures; fixed table formats, elaborated on applications and Trotter method in supplementary; added scaling tests and adaptive timestep; updated with noise tests for Quantum publication; updated acknowledgements

R2 v1 2026-06-23T05:08:19.462Z