TY - GEN
T1 - Circuit compilation methodologies for quantum approximate optimization algorithm
AU - Alam, Mahabubul
AU - Ash-Saki, Abdullah
AU - Ghosh, Swaroop
N1 - Publisher Copyright:
© 2020 IEEE.
PY - 2020/10
Y1 - 2020/10
N2 - The quantum approximate optimization algorithm (QAOA) is a promising quantum-classical hybrid algorithm to solve hard combinatorial optimization problems. The multi-qubit CPHASE gates used in the quantum circuit for QAOA are commutative i.e., the order of the gates can be altered without changing the output state. This re-ordering leads to the execution of more gates in parallel and a smaller number of additional SWAP gates to compile the QAOA-circuit. Consequently, the circuit-depth and cumulative gate-count become lower which is beneficial for circuit execution time and noise resilience. A less number of gates indicates a lower accumulation of gate-errors, and a reduced circuit-depth means less decoherence time for the qubits. However, finding the best-ordered circuit is a difficult problem and does not scale well with circuit size. This paper presents four generic methodologies to optimize QAOA-circuits by exploiting gate re-ordering. We demonstrate a reduction in gate-count by ≈23.0% and circuit-depth by ≈53.0% on average over a conventional approach without incurring any compilation-time penalty. We also present a variation-aware compilation which enhances the compiled circuit success probability by ≈62.7% for the target hardware over the variation unaware approach. A new metric, Approximation Ratio Gap (ARG), is proposed to validate the quality of the compiled QAOA-circuit instances on actual devices. Hardware implementation of a number of QAOA instances shows ≈25.8% improvement in the proposed metric on average over the conventional approach on ibmq 16 melbourne.
AB - The quantum approximate optimization algorithm (QAOA) is a promising quantum-classical hybrid algorithm to solve hard combinatorial optimization problems. The multi-qubit CPHASE gates used in the quantum circuit for QAOA are commutative i.e., the order of the gates can be altered without changing the output state. This re-ordering leads to the execution of more gates in parallel and a smaller number of additional SWAP gates to compile the QAOA-circuit. Consequently, the circuit-depth and cumulative gate-count become lower which is beneficial for circuit execution time and noise resilience. A less number of gates indicates a lower accumulation of gate-errors, and a reduced circuit-depth means less decoherence time for the qubits. However, finding the best-ordered circuit is a difficult problem and does not scale well with circuit size. This paper presents four generic methodologies to optimize QAOA-circuits by exploiting gate re-ordering. We demonstrate a reduction in gate-count by ≈23.0% and circuit-depth by ≈53.0% on average over a conventional approach without incurring any compilation-time penalty. We also present a variation-aware compilation which enhances the compiled circuit success probability by ≈62.7% for the target hardware over the variation unaware approach. A new metric, Approximation Ratio Gap (ARG), is proposed to validate the quality of the compiled QAOA-circuit instances on actual devices. Hardware implementation of a number of QAOA instances shows ≈25.8% improvement in the proposed metric on average over the conventional approach on ibmq 16 melbourne.
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U2 - 10.1109/MICRO50266.2020.00029
DO - 10.1109/MICRO50266.2020.00029
M3 - Conference contribution
AN - SCOPUS:85097344976
T3 - Proceedings of the Annual International Symposium on Microarchitecture, MICRO
SP - 215
EP - 228
BT - Proceedings - 2020 53rd Annual IEEE/ACM International Symposium on Microarchitecture, MICRO 2020
PB - IEEE Computer Society
T2 - 53rd Annual IEEE/ACM International Symposium on Microarchitecture, MICRO 2020
Y2 - 17 October 2020 through 21 October 2020
ER -