Quantum search with hybrid adiabatic–quantum-walk algorithms and realistic noise

Morley, James G.; Chancellor, Nicholas; Bose, Sougato; Kendon, Viv

doi:10.1103/physreva.99.022339

Cited by 44 publications

(46 citation statements)

References 61 publications

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“…Note that none of these constraints requires prior knowledge of the gap

, other than an upper bound. Hence, the algorithm is robust to a multiplicative error of the Hamiltonian due to calibration errors, similar to previous approaches [ 25 ]. A different choice of parameters may improve the algorithm’s robustness to the variations in the total evolution time, as demonstrated in [ 26 ].…”

Section: Resultsmentioning

confidence: 77%

“…The limit

yields maximal

, and corresponds to evolving by the time-independent Hamiltonian

, which we denote

. This is exactly the “analog” algorithm for the search problem by Farhi and Gutmann [ 24 ], and, more generally, a search by a quantum walk [ 25 , 27 , 28 , 29 , 30 , 31 , 32 , 33 ]. The Hamiltonian

is the core of algorithms for the search problem: in the adiabatic algorithm [ 12 ], the Hamiltonian spends most of the time close to

, where the gap is minimal [ 25 ], while the original gate-model algorithm by Grover [ 5 ] can be seen as a simulation (or an approximation by Trotter formula [ 34 ]) of

[ 24 ].…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Robust Diabatic Grover Search by Landau–Zener–Stückelberg Oscillations

Atia

Oren

Katz

2019

Entropy

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Quantum computation by the adiabatic theorem requires a slowly varying Hamiltonian with respect to the spectral gap. We show that the Landau-Zener-Stückelberg oscillation phenomenon, that naturally occurs in quantum two level systems under non-adiabatic periodic drive, can be exploited to find the ground state of an N dimensional Grover Hamiltonian. The total runtime of this method is O( √ 2 n ) which is equal to the computational time of the Grover algorithm in the quantum circuit model. An additional periodic drive can suppress a large subset of Hamiltonian control errors using coherent destruction of tunneling, providing superior performance compared to standard algorithms.Adiabatic Quantum Computation (AQC) [1, 2] is a computational model, motivated by the physical phenomenon described by the adiabatic theorem, which states that if a system is prepared in the ground state of an initial Hamiltonian, and the Hamiltonian slowly varies in time, then it is guaranteed that the evolution will be adiabatic -meaning that the system will remain close to its instantaneous ground state throughout [3,4]. By encoding a solution for a computational problem in the ground state of the finally applied Hamiltonian, one can exploit this phenomenon to produce the aforementioned ground state, and thus produce a solution to the problem. The maximal rate of change allowed for such evolution usually scales with the inverse square of the energy gap between the ground state and the first excited state [1].The Grover problem [5], also known as The Unstructured Search Problem is one of the few problems solvable by a native adiabatic algorithm, which achieves the same performance as the best possible algorithm in the circuit model [6] (for other native algorithms see [7] and the partially adiabatic [8]). The input to the problem is an n qubit Hamiltonian, which can only be used as a black box, i.e., can be switched on or off [9]where I N is the N × N identity matrix with N = 2 n , and the problem is to find the unknown string y. The problem is comparable to finding the ground state of a known multiple-qubit Hamiltonian; the ground state might be computationally hard to find and therefore can be considered "computationally unknown" [10]. An adiabatic algorithm for the search problem was suggested by [1]. The system is initialized to a symmetric superposition of states denoted |u = |+ · · · + , and then evolves by the time-dependent Hamiltonian H G (s(t)) =(1 − s(t)) · (I N − |u u|)where the control function s(t) : [t i , t f ] → [0, 1] is initialized to 0 and increases monotonically with time to 1. The minimal gap for n qubit systems is ∆ = √ 2 −n . Evolving with a linear s(t) requires O(2 n ) time, while a specially tailored control function, whose rate matches the instantaneous spectral gap, generates the ground state of H p in the optimal time, O( √ 2 n ) [11,12]. In this work, we introduce a diabatic algorithm for the Grover problem, denoted algorithm A, whose performance matches both the optimized adiabatic and the circuit model algor...

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“…Note that none of these constraints requires prior knowledge of the gap

Section: Resultsmentioning

confidence: 77%

“…The limit

yields maximal

, and corresponds to evolving by the time-independent Hamiltonian

, which we denote

is the core of algorithms for the search problem: in the adiabatic algorithm [ 12 ], the Hamiltonian spends most of the time close to

, where the gap is minimal [ 25 ], while the original gate-model algorithm by Grover [ 5 ] can be seen as a simulation (or an approximation by Trotter formula [ 34 ]) of

[ 24 ].…”

Section: Resultsmentioning

confidence: 99%

Robust Diabatic Grover Search by Landau–Zener–Stückelberg Oscillations

Atia

Oren

Katz

2019

Entropy

View full text Add to dashboard Cite

show abstract

“…As for the quantum walk, the qubits start in the initial state in equation (8), the ground state ofĤ h , and are measured after a time t f ∝ √ N to obtain a quadratic quantum speed up. Both quantum walk and adiabatic quantum search algorithms are analytically solvable [14,43] in the large N limit, because they reduce to a two state single avoided crossing model [14,39]. There are many subtleties involved in setting the parameters A(t), B(t), γ, to achieve a quantum speed up, for detailed discussion and results, see [39].…”

Section: Hybrid Qw-aqc Algorithmsmentioning

confidence: 99%

“…For quantum walk, the system oscillates between the equal superposition initial state, and the marked state, while for adiabatic, the system transitions steadily from the initial state to the marked state. A smooth interpolation between adiabatic and quantum walk can be done, and optimal contributions from both mechanisms employed to improve performance on imperfect hardware [39].…”

Section: Hybrid Qw-aqc Algorithmsmentioning

confidence: 99%

“…They are effective when used with many short runs and repeats, which suits early, noisy quantum hardware. The benefits of combining both quantum walk and adiabatic techniques can be demonstrated in a range of settings, especially in the presence of hardware imperfections [39]. However, it is important to use quantum algorithms where they will be most effective, to obtain a practical quantum advantage.…”

Section: Hybrid Qw-aqc Algorithmsmentioning

confidence: 99%

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How to Compute Using Quantum Walks

Kendon

2020

Electron. Proc. Theor. Comput. Sci.

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Quantum walks are widely and successfully used to model diverse physical processes. This leads to computation of the models, to explore their properties. Quantum walks have also been shown to be universal for quantum computing. This is a more subtle result than is often appreciated, since it applies to computations run on qubit-based quantum computers in the single walker case, and physical quantum walks in the multi-walker case (quantum cellular automata). Nonetheless, quantum walks are powerful tools for quantum computing when correctly applied. In this paper, I explain the relationship between quantum walks as models and quantum walks as computational tools, and give some examples of their application in both contexts.

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Noisy Effect on Nonlinear Quantum Search Algorithm

Njafa

Engo

2021

Fortschritte der Physik

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In this paper, we investigate the effects of three single-qubit quantum noise channels on the quantum nonlinear search algorithm proposed by Abrams and Lloyd. We focus on the gates of the nonlinear part of the algorithm and consider the case where the quantum noise channel only affects the qubit on which the gate is proceeding. Assuming that quantum noise effects occur after using the gates of the nonlinear part of the algorithm, we find that the quantum nonlinear search algorithm appears to be very resilient to the quantum noise when the desired state does not exist in the first register and is subject to the phase damping channel or the depolarising channel.

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Quantum search with hybrid adiabatic–quantum-walk algorithms and realistic noise

Cited by 44 publications

References 61 publications

Robust Diabatic Grover Search by Landau–Zener–Stückelberg Oscillations

Robust Diabatic Grover Search by Landau–Zener–Stückelberg Oscillations

How to Compute Using Quantum Walks

Noisy Effect on Nonlinear Quantum Search Algorithm

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