Quantum process tomography of a high-dimensional quantum communication channel

Bouchard, Frédéric; Hufnagel, Felix; Koutný, Dominik; Abbas, Aazad; Sit, Alicia; Heshami, Khabat; Fickler, Robert; Karimi, Ebrahim

doi:10.22331/q-2019-05-06-138

Cited by 20 publications

(17 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…1b. Since simple cross-talk matrices cannot directly reveal information about the unitarity of the mode transformation, we also perform a full high-dimensional quantum process tomography [55] on the simulated 3-dimensional X 1 -gate. Quantum process tomography is based on a set of informationally complete measurements for a given set of input states, leading to a complete characterisation of the corresponding quantum channel.…”

Section: Implementation Using Mplcmentioning

confidence: 99%

See 1 more Smart Citation

High-dimensional quantum gates using full-field spatial modes of photons

Brandt¹,

Hiekkamäki²,

Bouchard³

et al. 2020

Optica

Self Cite

113

View full text Add to dashboard Cite

Unitary transformations are the fundamental building blocks of gates and operations in quantum information processing allowing the complete manipulation of quantum systems in a coherent manner. In the case of photons, optical elements that can perform unitary transformations are readily available only for some degrees of freedom, e.g. wave plates for polarisation. However for highdimensional states encoded in the transverse spatial modes of light, performing arbitrary unitary transformations remains a challenging task for both theoretical proposals and actual implementations. Following the idea of multi-plane light conversion, we show that it is possible to perform a broad variety of unitary operations when the number of phase modulation planes is comparable to the number of modes. More importantly, we experimentally implement several high-dimensional quantum gates for up to 5-dimensional states encoded in the full-field mode structure of photons. In particular, we realise cyclic and quantum Fourier transformations, known as PauliX-gates and HadamardĤ-gates, respectively, with an average visibility of more than 90 %. In addition, we demonstrate near-perfect "unitarity" by means of quantum process tomography unveiling a process purity of 99 %. Lastly, we demonstrate the benefit of the two independent spatial degrees of freedom, i.e. azimuthal and radial, and implement a two-qubit controlled-NOT quantum operation on a single photon. Thus, our demonstrations open up new paths to implement high-dimensional quantum operations, which can be applied to various tasks in quantum communication, computation and sensing schemes.

show abstract

Section: Implementation Using Mplcmentioning

confidence: 99%

“…In addition, we implement also combinedXĤ-gates in dimension three, in particular aX 1Ĥ 2-gate shown in (c) and aX 1Ĥ † 1gate shown in (d). Note that measuring p-modes properly in different mutually unbiased bases has only become possible recently [55]. configuration of the multiport, i.e.…”

Section: Single Photon Controlled-x Gatementioning

confidence: 99%

High-dimensional quantum gates using full-field spatial modes of photons

Brandt¹,

Hiekkamäki²,

Bouchard³

et al. 2020

Optica

Self Cite

113

View full text Add to dashboard Cite

show abstract

“…Earlier attempts at QPT used the linear inversion method [7,8]. Later various statistical methods were developed including maximum likelihood methods [9][10][11][12][13], Bayesian methods [14][15][16], compressed sensing methods [17], tensor network methods [18] and other optimization techniques [19][20][21][22][23][24][25]. Theoretically, quantum process tomography can be related to quantum state tomography through the Jamio lkowski process-state isomorphism [26,27].…”

Section: Introductionmentioning

confidence: 99%

Classical Shadows for Quantum Process Tomography on Near-term Quantum Computers

Levy¹,

Luo²,

Clark³

2021

Preprint

View full text Add to dashboard Cite

“…To make good use of quantum information technology, it is first necessary to characterize quantum devices to evaluate their performance. The standard method for characterizing quantum devices is quantum process tomography (QPT) [1][2][3][4][5][6][7], which allows complete reconstruction of the quantum process of the device, but its resource overhead grows exponentially with the size of the system, making it impractical when the system is large. However, for most applications, the complete information of the quantum device is not needed, but only the fidelity of the evaluated device compared to a perfect device.…”

mentioning

confidence: 99%

Proof-of-principle experimental demonstration of quantum gate verification

Luo,

Zhang,

Zhou

2021

Preprint

View full text Add to dashboard Cite

To employ a quantum device, the performance of the quantum gates in the device needs to be evaluated first. Since the dimensionality of a quantum gate grows exponentially with the number of qubits, evaluating the performance of a quantum gate is a challenging task. Recently, a scheme called quantum gate verification (QGV) has been proposed, which can verifies quantum gates with near-optimal efficiency. In this work, we implement a proof-of-principle optical experiment to demonstrate this QGV scheme. We show that for a singlequbit quantum gate, only ∼ 400 samples are needed to confirm the fidelity of the quantum gate to be at least 97% with a 99% confidence level using the QGV method, while at least ∼ 5000 samples are needed to achieve the same result using the standard quantum process tomography method. The QGV method validated by this work has the potential to be widely used for the evaluation of quantum devices in various quantum information applications.

show abstract

Quantum process tomography of a high-dimensional quantum communication channel

Cited by 20 publications

References 59 publications

High-dimensional quantum gates using full-field spatial modes of photons

High-dimensional quantum gates using full-field spatial modes of photons

Classical Shadows for Quantum Process Tomography on Near-term Quantum Computers

Proof-of-principle experimental demonstration of quantum gate verification

Contact Info

Product

Resources

About