Feedback‐Assisted Quantum Search by Continuous‐Time Quantum Walks

Candeloro, Alessandro; Benedetti, Claudia; Genoni, Marco G.; Paris, Matteo G. A.

doi:10.1002/qute.202200093

Cited by 6 publications

(3 citation statements)

References 101 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Waveguide arrays 1 are a powerful platform for the optical simulation of condensed matter physics effects ranging from Bloch oscillations 2 to enhanced coherent transport via controllable decoherence 3 , adiabatic passage 4 , 5 , Anderson localization 6 , and many more 7 . Quantum walks in waveguide arrays 8 , 9 have been proposed for simulating particle statistics 10 , 11 , boson sampling 12 , 13 , quantum state transfer 14 , 15 , quantum state generation 16 , 17 , quantum search 18 , 19 , optical transformation 20 and could implement 1 and 2-qubit gates 21 , 22 with the potential of implementing universal unitaries 23 . Waveguide arrays have been used to model topological band structures 24 , 25 and their interplay through non-Hermiticities generated by mode-selective gain and loss 26 .…”

Section: Introductionmentioning

confidence: 99%

Programmable high-dimensional Hamiltonian in a photonic waveguide array

Yang,

Chapman,

Haylock

et al. 2024

Nat Commun

View full text Add to dashboard Cite

Waveguide lattices offer a compact and stable platform for a range of applications, including quantum walks, condensed matter system simulation, and classical and quantum information processing. However, to date, waveguide lattice devices have been static and designed for specific applications. We present a programmable waveguide array in which the Hamiltonian terms can be individually electro-optically tuned to implement various Hamiltonian continuous-time evolutions on a single device. We used a single array with 11 waveguides in lithium niobate, controlled via 22 electrodes, to perform a range of experiments that realized the Su-Schriffer-Heeger model, the Aubrey-Andre model, and Anderson localization, which is equivalent to over 2500 static devices. Our architecture’s micron-scale local electric fields overcome the cross-talk limitations of thermo-optic phase shifters in other platforms such as silicon, silicon-nitride, and silica. Electro-optic control allows for ultra-fast and more precise reconfigurability with lower power consumption, and with quantum input states, our platform can enable the study of multiple condensed matter quantum dynamics with a single device.

show abstract

Section: Introductionmentioning

confidence: 99%

Programmable high-dimensional Hamiltonian in a photonic waveguide array

Yang,

Chapman,

Haylock

et al. 2024

Nat Commun

View full text Add to dashboard Cite

show abstract

“…In the class of parametrized Hamiltonians, an exceptionally diffused and useful example is that of quantum walks (QWs). QWs are a universal and versatile tool that can be harnessed to perform a plethora of tasks ranging from energy transport [42][43][44] to quantum algorithms, [45][46][47][48][49][50][51] quantum computation, [52][53][54] and quantum communication. 55 In particular, continuous-time quantum walks (CTQWs) are the quantum analog of classical random walks [56][57][58][59] that describe the continuous evolution of a quantum particle over a set of discrete positions.…”

Section: Introductionmentioning

confidence: 99%

Multiparameter estimation of continuous-time quantum walk Hamiltonians through machine learning

Gianani

Benedetti

2023

AVS Quantum Science

Self Cite

View full text Add to dashboard Cite

The characterization of the Hamiltonian parameters defining a quantum walk is of paramount importance when performing a variety of tasks, from quantum communication to computation. When dealing with physical implementations of quantum walks, the parameters themselves may not be directly accessible, and, thus, it is necessary to find alternative estimation strategies exploiting other observables. Here, we perform the multiparameter estimation of the Hamiltonian parameters characterizing a continuous-time quantum walk over a line graph with n-neighbor interactions using a deep neural network model fed with experimental probabilities at a given evolution time. We compare our results with the bounds derived from estimation theory and find that the neural network acts as a nearly optimal estimator both when the estimation of two or three parameters is performed.

show abstract

“…In order to achieve such scalability, a perspective is that of extending these results to incorporated machine learning techniques. By relying solely on measured probabilities, our technique provides a simple but yet effective strategy for the routine characterization of networks, and as such constitutes an enabling step towards most developing quantum technologies based on complex networks [46][47][48][49][50][51], as well as a tool for exploring new involved simulation regimes which have non-trivial mapping between the experimental control and the CTQW parameters [52][53][54].…”

mentioning

confidence: 99%