Probing for quantum speedup in spin-glass problems with planted solutions

Hen, Itay; Job, Joshua; Albash, Tameem; Rønnow, Troels F.; Troyer, Matthias; Lidar, Daniel A.

doi:10.1103/physreva.92.042325

Cited by 160 publications

(265 citation statements)

References 59 publications

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“…13 shows performance scaling on U 3 1 , U 4 1 , U 5 1 , and U 6 1 instances. These results suggest that several threads of research that probed for computational advantage in U 6 1 problems [2, 9, 10] might be more successfully directed towards U 3 1 problems. Neither SA nor DW2X performance responds monotonically to increas- ing degree.…”

Section: Resultsmentioning

confidence: 93%

“…[12] ran SQA and SA on the same 200-qubit (C 5 ) U 6 1 instances, each containing 120 degree 6 (and therefore potentially floppy) qubits, and investigated the ground state probability p of each solver on a given instance. While they consider τ = 1/p, we consider the number of repetitions R needed to achieve 99% probability of finding a ground state [14]:…”

Section: Resultsmentioning

confidence: 99%

“…These recent works have proposed various important considerations such as error sensitivity, thermal hardness [10], ground state degeneracy, consistency of energy scale across a random ensemble [6,7], potential barrier shape [4,5], and the existence of classical phase transitions [8]. In parallel to this line of research is the consideration of suitable performance metrics for exact and approximate optimization [9,11,12].…”

Section: Introductionmentioning

confidence: 99%

“…Several previous efforts to quantify the performance of D-Wave hardware relative to physically motivated software solvers have focused on the median case performance for a given input class [2,6]. However, Ref.…”

Section: Introductionmentioning

confidence: 99%

“…The recent development of quantum annealing (QA) processors has spurred research into how to construct input instances-Ising spin instances-that might confirm or refute any purported computational advantage conferred by such hardware [1][2][3][4][5][6][7][8][9][10]. These recent works have proposed various important considerations such as error sensitivity, thermal hardness [10], ground state degeneracy, consistency of energy scale across a random ensemble [6,7], potential barrier shape [4,5], and the existence of classical phase transitions [8].…”

Section: Introductionmentioning

confidence: 99%

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Degeneracy, degree, and heavy tails in quantum annealing

et al. 2016

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Both simulated quantum annealing and physical quantum annealing have shown the emergence of "heavy tails" in their performance as optimizers: The total time needed to solve a set of random input instances is dominated by a small number of very hard instances. Classical simulated annealing, in contrast, does not show such heavy tails. Here we explore the origin of these heavy tails, which appear for inputs with high local degeneracy-large isoenergetic clusters of states in Hamming space. This category includes the low-precision Chimera-structured problems studied in recent benchmarking work comparing the D-Wave Two quantum annealing processor with simulated annealing. On similar inputs designed to suppress local degeneracy, performance of a quantum annealing processor on hard instances improves by orders of magnitude at the 512-qubit scale, while classical performance remains relatively unchanged. Simulations indicate that perturbative crossings are the primary factor contributing to these heavy tails, while sensitivity to Hamiltonian misspecification error plays a less significant role in this particular setting.

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Section: Resultsmentioning

confidence: 93%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Degeneracy, degree, and heavy tails in quantum annealing

et al. 2016

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Quantum Computation using Arrays of N Polar Molecules in Pendular States

Cao

Kais

et al. 2016

ChemPhysChem

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We investigate several aspects of realizing quantum computation using entangled polar molecules in pendular states. Quantum algorithms typically start from a product state |00⋯0⟩ and we show that up to a negligible error, the ground states of polar molecule arrays can be considered as the unentangled qubit basis state |00⋯0⟩ . This state can be prepared by simply allowing the system to reach thermal equilibrium at low temperature (<1 mK). We also evaluate entanglement, characterized by concurrence of pendular state qubits in dipole arrays as governed by the external electric field, dipole-dipole coupling and number N of molecules in the array. In the parameter regime that we consider for quantum computing, we find that qubit entanglement is modest, typically no greater than 10 , confirming the negligible entanglement in the ground state. We discuss methods for realizing quantum computation in the gate model, measurement-based model, instantaneous quantum polynomial time circuits and the adiabatic model using polar molecules in pendular states.

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Enhanced Disconnectivity Graphs of the ±1 and ±1, ±2 Spin Glasses

Biswas

2021

Physica Status Solidi (b)

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The energy landscapes of the ±1 and ±1, ±2 small‐spin glasses are studied in the form of enhanced disconnectivity graphs. This new way of displaying disconnectivity graphs incorporates the merging of minima energy states of equal energy which are connected via zero‐energy spin flips. These states form connected structures on the energy landscape, which we distinguish into four basic types. The types are indicated in the disconnectivity graph by different colors and their respective sizes via a bar chart at the corresponding energy levels. This allows for an easy intuitive access to highly degenerate energy landscapes without losing the main features. Further, these connected minima structures are analyzed in terms of their occurrences, sizes, and distributions for the two models of spin glasses. This gives a deep insight into the energy structure of these systems. Further, the use of the classification of minima reduces the description of ±1 spin models by 93%, and that of ±1, ±2 models by 71% without losing the core information about these systems.

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Probing for quantum speedup in spin-glass problems with planted solutions

Cited by 160 publications

References 59 publications

Degeneracy, degree, and heavy tails in quantum annealing

Degeneracy, degree, and heavy tails in quantum annealing

Quantum Computation using Arrays of N Polar Molecules in Pendular States

Enhanced Disconnectivity Graphs of the ±1 and ±1, ±2 Spin Glasses

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