A Quadratic Speedup in the Optimization of Noisy Quantum Optical Circuits

De Prins, Robbe; Yao, Yuan; Apte, Anuj; Miatto, Filippo M.

doi:10.22331/q-2023-08-29-1097

Quantum

2023

DOI: 10.22331/q-2023-08-29-1097

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A Quadratic Speedup in the Optimization of Noisy Quantum Optical Circuits

Robbe De Prins,

Yuan Yao,

Anuj Apte

et al.

Abstract: Linear optical quantum circuits with photon number resolving (PNR) detectors are used for both Gaussian Boson Sampling (GBS) and for the preparation of non-Gaussian states such as Gottesman-Kitaev-Preskill (GKP), cat and NOON states. They are crucial in many schemes of quantum computing and quantum metrology. Classically optimizing circuits with PNR detectors is challenging due to their exponentially large Hilbert space, and quadratically more challenging in the presence of decoherence as state vectors are rep… Show more

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2024

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Cited by 3 publications

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Ground State Nature and Nonlinear Squeezing of Gottesman-Kitaev-Preskill States

Marek

2024

Phys. Rev. Lett.

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Ground State Nature and Nonlinear Squeezing of Gottesman-Kitaev-Preskill States

Marek

2024

Phys. Rev. Lett.

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Beyond Bits: A Review of Quantum Embedding Techniques for Efficient Information Processing

Khan,

Aman,

Sikdar

2024

IEEE Access

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The existing body of research on quantum embedding techniques is not only confined in scope but also lacks a comprehensive understanding of the intricacies of the quantum embedding process. To address this critical issue, this article explores quantum encoding schemes, uncovering valuable insights into their encoding algorithms from theoretical foundations to a mathematical perspective, as well as practical applications. Initially, the article briefly overviews classical computing and the limitations associated with classical bits in representing and processing complex information. Next, the article scrutinizes a variety of quantum embedding patterns, including basis encoding, amplitude encoding, Qsample encoding, angle encoding, quantum associative memory encoding, quantum random access memory, superdense encoding, Hamiltonian encoding, and others. In addition, each technique is accompanied by mathematical formulas and examples illustrating how each strategy can be applied. Finally, the article provides a comparative analysis of different quantum embedding/encoding methods, outlining their strengths and limitations. Overall, this insightful article highlights the potential of quantum encoding techniques for efficient information processing beyond classical bits, thereby facilitating scientists and design engineers in selecting the most appropriate encoding technique to develop smart algorithms for revolutionizing the field of quantum computing.INDEX TERMS Encoding patterns, qubits, quantum computing, quantum information processing, quantum circuits.

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Riemannian optimization of photonic quantum circuits in phase and Fock space

Yao,

Miatto,

Quesada

2024

SciPost Phys.

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We propose a framework to design and optimize generic photonic quantum circuits composed of Gaussian objects (pure and mixed Gaussian states, Gaussian unitaries, Gaussian channels, Gaussian measurements) as well as non-Gaussian effects such as photon-number-resolving measurements. In this framework, we parametrize a phase space representation of Gaussian objects using elements of the symplectic group (or the unitary or orthogonal group in special cases), and then we transform it into the Fock representation using a single linear recurrence relation that computes the Fock amplitudes of any Gaussian object recursively. We also compute the gradient of the Fock amplitudes with respect to phase space parameters by differentiating through the recurrence relation. We can then use Riemannian optimization on the symplectic group to optimize MM-mode Gaussian objects, avoiding the need to commit to particular realizations in terms of fundamental gates. This allows us to “mod out” all the different gate-level implementations of the same circuit, which now can be chosen after the optimization has completed. This can be especially useful when looking to answer general questions, such as bounding the value of a property over a class of states or transformations, or when one would like to worry about hardware constraints separately from the circuit optimization step. Finally, we make our framework extendable to non-Gaussian objects that can be written as linear combinations of Gaussian ones, by explicitly computing the change in global phase when states undergo Gaussian transformations. We implemented all of these methods in the freely available open-source library MrMustard, which we use in three examples to optimize the 216-mode interferometer in Borealis, and 2- and 3-modes circuits (with Fock measurements) to produce cat states and cubic phase states.

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A Quadratic Speedup in the Optimization of Noisy Quantum Optical Circuits

Cited by 3 publications

References 29 publications

Ground State Nature and Nonlinear Squeezing of Gottesman-Kitaev-Preskill States

Ground State Nature and Nonlinear Squeezing of Gottesman-Kitaev-Preskill States

Beyond Bits: A Review of Quantum Embedding Techniques for Efficient Information Processing

Riemannian optimization of photonic quantum circuits in phase and Fock space

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