QSWalk: A Mathematica package for quantum stochastic walks on arbitrary graphs

Falloon, Peter E.; Rodriguez, J. P. J.; Wang, Jingbo

doi:10.1016/j.cpc.2017.03.014

Cited by 23 publications

(43 citation statements)

References 38 publications

(60 reference statements)

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“…To simulate environmental interactions decoherence was introduced to the system in the form of scattering, dissipation and dephasing through the use of the Lindblad operators, L k , in QSWs. This was done using the 'QSWalk' package by Falloon et al [29], which computes quantum stochastic walks on graphs using the Mathematica system. Figure 13 shows the probability distribution once again for C 4 with the same complex edge weights given in the example before with decoherence introduced to the system.…”

Section: Addition Of Decoherence and Applicationmentioning

confidence: 99%

Zero transfer in continuous-time quantum walks

Sett

Pan

Falloon

et al. 2019

Quantum Inf Process

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In this paper we show how using complex valued edge weights in a graph can completely suppress the flow of probability amplitude in a continuous time quantum walk to specific vertices of the graph when the edge weights, graph topology and initial state of the quantum walk satisfy certain conditions. The conditions presented in this paper are derived from the so-called chiral quantum walk, a variant of the continuous time quantum walk which incorporates directional bias with respect to site transfer probabilities between vertices of a graph by using complex edge weights. We examine the necessity to break the time reversal symmetry in order to achieve zero transfer in continuous time quantum walks. We also consider the effect of decoherence on zero transfer and suggest that this phenomena may be used to detect decoherence in the system.

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Section: Addition Of Decoherence and Applicationmentioning

confidence: 99%

Zero transfer in continuous-time quantum walks

Sett

Pan

Falloon

et al. 2019

Quantum Inf Process

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“…The model is used to study quantum-to-classical transition and to probe the influence of quantum evolution on the efficiency of information processing [3]. Quantum stochastic walks have been widely analysed in context of propagation [3,4,5,6,7], application in computer science [8,9,10] and physics [11,12,13]. In particular, new model of fast-propagating quantum walk on arbitrary directed graph was developed [4,6].…”

Section: Introductionmentioning

confidence: 99%

“…Comparison with the existing software. Many software packages for simulating quantum computing [15], including some focused on various models of discrete quantum walks [16,17] and continuous-time quantum walks [9,18] are available. Most of them are focused on the discrete-time evolution, restricted to the unitary operations and undirected graphs.…”

Section: Introductionmentioning

confidence: 99%

“…Most of them are focused on the discrete-time evolution, restricted to the unitary operations and undirected graphs. The first exception is QSWalk.m package [9] for Wolfram Mathematica, which provides implementation of a quantum stochastic walk model. Package QSWalk.m utilizes MatrixExp function and sparse representation of superoperators for simulating the evolution of quantum stochastic walks.…”

Section: Introductionmentioning

confidence: 99%

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QSWalk.jl: Julia package for quantum stochastic walks analysis

Glos

Miszczak

Ostaszewski

2019

Computer Physics Communications

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The paper describes QSWalk.jl package for Julia programming language, developed for the purpose of simulating the evolution of open quantum systems. The package enables the study of quantum procedures developed using stochastic quantum walks on arbitrary directed graphs. We provide a detailed description of the implemented functions, along with a number of usage examples. The package is compared with the existing software offering a similar functionality.Keywords: directed graph, moral graph, quantum walk, open quantum system. PROGRAM SUMMARYProgram Title: QSWalk.jl Licensing provisions: MIT Distribution format: Source code available at https://github.com/QuantumWalks/QSWalk. jl Programming language: Julia Nature of problem: The package implements functions for simulating quantum stochastic walks, including local regime, global regime, and nonmoralizing global regime [1]. It can be used for arbitrary quantum continuous evolution based on GKSL master equation on arbitrary graphs. Solution method: We utilize Expokit routines for fast sparse matrix exponentials on vectors. For dense matrices exponentiation is computed separately, which is faster for small matrices. Restrictions: Currently package requires Julia v0.6.

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“…One promising application of quantum walks is to provide an efficient quantum algorithm for vertex centrality ranking in network analysis [6,[33][34][35][36][37]. Using continuous-time quantum walks (CTQWs), the aforementioned algorithm has been implemented on an undirected graph [10].…”

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confidence: 99%

Experimental Parity-Time Symmetric Quantum Walks for Centrality Ranking on Directed Graphs

Izaac

et al. 2020

Phys. Rev. Lett.

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Using quantum walks (QWs) to rank the centrality of nodes in networks, represented by graphs, is advantageous compared to certain widely used classical algorithms. However, it is challenging to implement a directed graph via QW, since it corresponds to a non-Hermitian Hamiltonian and thus cannot be accomplished by conventional QW. Here we report the realizations of centrality rankings of a three-, a four-, and a nine-vertex directed graph with parity-time (PT) symmetric quantum walks by using highdimensional photonic quantum states, multiple concatenated interferometers, and dimension dependent loss to achieve these. We demonstrate the advantage of the QW approach experimentally by breaking the vertex rank degeneracy in a four-vertex graph. Furthermore, we extend our experiment from single-photon to two-photon Fock states as inputs and realize the centrality ranking of a nine-vertex graph. Our work shows that a PT symmetric multiphoton quantum walk paves the way for realizing advanced algorithms.

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QSWalk: A Mathematica package for quantum stochastic walks on arbitrary graphs

Cited by 23 publications

References 38 publications

Zero transfer in continuous-time quantum walks

Zero transfer in continuous-time quantum walks

QSWalk.jl: Julia package for quantum stochastic walks analysis

Experimental Parity-Time Symmetric Quantum Walks for Centrality Ranking on Directed Graphs

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