TY - GEN
T1 - Time-sliced quantum circuit partitioning for modular architectures
AU - Baker, Jonathan M.
AU - Duckering, Casey
AU - Hoover, Alexander
AU - Chong, Frederic T.
N1 - Publisher Copyright:
© 2020 ACM.
PY - 2020/5/11
Y1 - 2020/5/11
N2 - Current quantum computer designs will not scale. To scale beyond small prototypes, quantum architectures will likely adopt a modular approach with clusters of tightly connected quantum bits and sparser connections between clusters. We exploit this clustering and the statically-known control flow of quantum programs to create tractable partitioning heuristics which map quantum circuits to modular physical machines one time slice at a time. Specifically, we create optimized mappings for each time slice, accounting for the cost to move data from the previous time slice and using a tunable lookahead scheme to reduce the cost to move to future time slices. We compare our approach to a traditional statically-mapped, owner-computes model. Our results show strict improvement over the static mapping baseline. We reduce the non-local communication overhead by 89.8% in the best case and by 60.9% on average. Our techniques, unlike many exact solver methods, are computationally tractable.
AB - Current quantum computer designs will not scale. To scale beyond small prototypes, quantum architectures will likely adopt a modular approach with clusters of tightly connected quantum bits and sparser connections between clusters. We exploit this clustering and the statically-known control flow of quantum programs to create tractable partitioning heuristics which map quantum circuits to modular physical machines one time slice at a time. Specifically, we create optimized mappings for each time slice, accounting for the cost to move data from the previous time slice and using a tunable lookahead scheme to reduce the cost to move to future time slices. We compare our approach to a traditional statically-mapped, owner-computes model. Our results show strict improvement over the static mapping baseline. We reduce the non-local communication overhead by 89.8% in the best case and by 60.9% on average. Our techniques, unlike many exact solver methods, are computationally tractable.
UR - https://www.scopus.com/pages/publications/85085951098
UR - https://www.scopus.com/pages/publications/85085951098#tab=citedBy
U2 - 10.1145/3387902.3392617
DO - 10.1145/3387902.3392617
M3 - Conference contribution
AN - SCOPUS:85085951098
T3 - 17th ACM International Conference on Computing Frontiers 2020, CF 2020 - Proceedings
SP - 98
EP - 107
BT - 17th ACM International Conference on Computing Frontiers 2020, CF 2020 - Proceedings
T2 - 17th ACM International Conference on Computing Frontiers, CF 2020
Y2 - 11 May 2020 through 13 May 2020
ER -