Power of Pausing: Advancing Understanding of Thermalization in Experimental Quantum Annealers

Marshall, Jeffrey; Venturelli, Davide; Hen, Itay; Rieffel, Eleanor

doi:10.1103/physrevapplied.11.044083

Cited by 99 publications

(125 citation statements)

References 38 publications

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“…with conventional quantum annealing, where the success probability exhibits a peak as a function of the pausing time, when the pause is inserted about 20 % later than s ∆ , and then rapidly returns to its baseline value [15,22]. In contrast, for s inv < s ∆ , the effect of the pause is negligible; the solid (with pause) and dotted (no pause) lines in Fig.…”

Section: Open System Dynamics With a Pausementioning

confidence: 91%

“…If the inversion point is chosen well, the output is an improved trial solution, i. e., a quantum state having larger overlap with the correct one. Reverse annealing can also be combined with the pausing features of the D-Wave machines, allowing to stop the annealing for an extended time period to favor relaxation towards the ground state [15].…”

Section: Introductionmentioning

confidence: 99%

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Reverse quantum annealing of the p -spin model with relaxation

et al. 2020

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In reverse quantum annealing, the initial state is an eigenstate of the final problem Hamiltonian and the transverse field is cycled rather than strictly decreased as in standard (forward) quantum annealing. We present a numerical study of the reverse quantum annealing protocol applied to the p-spin model (p = 3), including pausing, in an open system setting accounting for dephasing in the energy eigenbasis, which results in thermal relaxation. We consider both independent and collective dephasing and demonstrate that in both cases the open system dynamics substantially enhances the performance of reverse annealing. Namely, including dephasing overcomes the failure of purely closed system reverse annealing to converge to the ground state of the p-spin model. We demonstrate that pausing further improves the success probability. The collective dephasing model leads to somewhat better performance than independent dephasing. The protocol we consider corresponds closely to the one implemented in the current generation of commercial quantum annealers, and our results help to explain why recent experiments demonstrated enhanced success probabilities under reverse annealing and pausing.

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Section: Open System Dynamics With a Pausementioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Reverse quantum annealing of the p -spin model with relaxation

et al. 2020

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“…As discussed in Section 3.3, the |J F | that enforces a chain of qubits to return a series of values which are all in agreement (either all +1 or −1), and the annealing time T a are both key performance parameters that determine the net time to find a solution, and hence overall QA performance. We also introduce 1, 10, and 100 µs pause time T p in the middle of annealing (T a = 1 µs) with various pause positions s p , to see the effect of pausing [43] on our problems. Setting |J F | too large would wash out the problem information due to ICE, however |J F | on average should increase with the number of logical chains in fullyconnected problems in the absence of ICE [69].…”

Section: Methodsmentioning

confidence: 99%

“…• Second, the user may accelerate or delay A(t)/B(t) evolution, thus determining annealing time (1-300 µs), the duration of the machine's computation. • Finally, the user may introduce stops (anneal pause) in the annealing process, which have been shown to improve performance in certain settings [43].…”

Section: Primer: Quantum Annealingmentioning

confidence: 99%

Leveraging quantum annealing for large MIMO processing in centralized radio access networks

Kim

Venturelli

Jamieson

2019

Proceedings of the ACM Special Interest Group on Data Communication

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User demand for increasing amounts of wireless capacity continues to outpace supply, and so to meet this demand, significant progress has been made in new MIMO wireless physical layer techniques. Higher-performance systems now remain impractical largely only because their algorithms are extremely computationally demanding. For optimal performance, an amount of computation that increases at an exponential rate both with the number of users and with the data rate of each user is often required. The base station's computational capacity is thus becoming one of the key limiting factors on wireless capacity. QuAMax is the first large MIMO centralized radio access network design to address this issue by leveraging quantum annealing on the problem. We have implemented QuAMax on the 2,031 qubit D-Wave 2000Q quantum annealer, the state-of-the-art in the field. Our experimental results evaluate that implementation on real and synthetic MIMO channel traces, showing that 10 µs of compute time on the 2000Q can enable 48 user, 48 AP antenna BPSK communication at 20 dB SNR with a bit error rate of 10 −6 and a 1,500 byte frame error rate of 10 −4 .

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“…However, in the continuous-time setting, the application of quantum walks to optimization problems has not been studied in detail. There is increasing interest in quenches (Amin et al 2018) or pauses (Marshall et al 2019, Passarelli et al 2019 in quantum annealing, which effectively run an open-system version of a quantum walk during part of the computation. Thermal relaxation effects dominate in the regime currently accessible by flux qubit quantum annealers, which is the focus of these works.…”

Section: Introductionmentioning

confidence: 99%

Finding spin glass ground states using quantum walks

et al. 2019

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Quantum computation using continuous-time evolution under a natural hardware Hamiltonian is a promising near-and mid-term direction toward powerful quantum computing hardware. We investigate the performance of continuous-time quantum walks as a tool for finding spin glass ground states, a problem that serves as a useful model for realistic optimization problems. By performing detailed numerics, we uncover significant ways in which solving spin glass problems differs from applying quantum walks to the search problem. Importantly, unlike for the search problem, parameters such as the hopping rate of the quantum walk do not need to be set precisely for the spin glass ground state problem. Heuristic values of the hopping rate determined from the energy scales in the problem Hamiltonian are sufficient for obtaining a better quantum advantage than for search. We uncover two general mechanisms that provide the quantum advantage: matching the driver Hamiltonian to the encoding in the problem Hamiltonian, and an energy redistribution principle that ensures a quantum walk will find a lower energy state in a short timescale. This makes it practical to use quantum walks for solving hard problems, and opens the door for a range of applications on suitable quantum hardware.

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Power of Pausing: Advancing Understanding of Thermalization in Experimental Quantum Annealers

Cited by 99 publications

References 38 publications

Reverse quantum annealing of the p -spin model with relaxation

Reverse quantum annealing of the p -spin model with relaxation

Leveraging quantum annealing for large MIMO processing in centralized radio access networks

Finding spin glass ground states using quantum walks

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