Related papers: Unitary-transformed projective squeezing: applications for circuit-knitting and state-preparation of non-Gaussian states

Unitary-transformed projective squeezing: applications for circuit-knitting and state-preparation of non-Gaussian states

URL: http://arxiv.org/abs/2411.19505v2
Date: Mon, 16 Dec 2024 07:11:03 GMT
Title: Unitary-transformed projective squeezing: applications for circuit-knitting and state-preparation of non-Gaussian states
Authors: Keitaro Anai, Yasunari Suzuki, Yuuki Tokunaga, Yuichiro Matsuzaki, Shuntaro Takeda, Suguru Endo,
Abstract summary: Continuous-variable (CV) quantum computing is a promising candidate for quantum computation. This work extends the projective squeezing method to establish a formalism for projecting quantum states onto the states that are unitary-transformed from the squeezed vacuum.
Score: 0.15833270109954137
License:
Abstract: Continuous-variable (CV) quantum computing is a promising candidate for quantum computation because it can, even with one mode, utilize infinite-dimensional Hilbert spaces and can efficiently handle continuous values. Although photonic platforms have been considered as a leading platform for CV computation, hybrid systems that use both qubits and bosonic modes, e.g., superconducting hardware, have shown significant advances because they can prepare non-Gaussian states by utilizing the nonlinear interaction between the qubits and the bosonic modes. However, the size of hybrid hardware is currently restricted. Moreover, the fidelity of the non-Gaussian state is also restricted. This work extends the projective squeezing method to establish a formalism for projecting quantum states onto the states that are unitary-transformed from the squeezed vacuum at the expense of the sampling cost. Based on this formalism, we propose methods for simulating larger quantum devices and projecting states onto the cubic phase state, a typical non-Gaussian state, with a higher squeezing level and higher nonlinearity. To make implementation practical, we can, by leveraging the interactions in hybrid systems of qubits and bosonic modes, apply the smeared projector by using either the linear-combination-of-unitaries or virtual quantum error detection algorithms. We numerically verify the performance of our methods and show that projection can suppress the effect of photon-loss errors.

Related papers

Scalable Optical Quantum State Synthesizer with Dual-Mode Cavity Memory [0.9051845653704739]
We demonstrate a scalable method for generating optical non-Gaussian states using a cavity-based quantum memory operating in continuous time. We successfully generated Wigner-negative states, a key requirement for quantum error correction. This work also marks the first full demonstration of continuous-time cavity-based quantum memory.
arXiv Detail & Related papers (2025-02-13T07:41:44Z)
Experimental realization of deterministic and selective photon addition in a bosonic mode assisted by an ancillary qubit [50.591267188664666]
Bosonic quantum error correcting codes are primarily designed to protect against single-photon loss. Error correction requires a recovery operation that maps the error states -- which have opposite parity -- back onto the code states. Here, we realize a collection of photon-number-selective, simultaneous photon addition operations on a bosonic mode.
arXiv Detail & Related papers (2022-12-22T23:32:21Z)
Quantum emulation of the transient dynamics in the multistate Landau-Zener model [50.591267188664666]
We study the transient dynamics in the multistate Landau-Zener model as a function of the Landau-Zener velocity. Our experiments pave the way for more complex simulations with qubits coupled to an engineered bosonic mode spectrum.
arXiv Detail & Related papers (2022-11-26T15:04:11Z)
Multi-squeezed state generation and universal bosonic control via a driven quantum Rabi model [68.8204255655161]
Universal control over a bosonic degree of freedom is key in the quest for quantum-based technologies. Here we consider a single ancillary two-level system, interacting with the bosonic mode of interest via a driven quantum Rabi model. We show that it is sufficient to induce the deterministic realization of a large class of Gaussian and non-Gaussian gates, which in turn provide universal bosonic control.
arXiv Detail & Related papers (2022-09-16T14:18:53Z)
SPDCinv: Inverse Quantum-Optical Design of High-Dimensional Qudits [8.257400045757374]
Spontaneous parametric down-conversion in quantum optics is an invaluable resource for the realization of high-dimensional qudits with spatial modes of light. One of the main open challenges is how to directly generate a desirable qudit state in the SPDC process. Here, we introduce a physically-constrained and differentiable model, validated against experimental results for shaped pump beams and structured crystals.
arXiv Detail & Related papers (2021-12-11T09:05:23Z)
Bosonic field digitization for quantum computers [62.997667081978825]
We address the representation of lattice bosonic fields in a discretized field amplitude basis. We develop methods to predict error scaling and present efficient qubit implementation strategies.
arXiv Detail & Related papers (2021-08-24T15:30:04Z)
Simulating gauge theories with variational quantum eigensolvers in superconducting microwave cavities [2.0781167019314806]
A variational quantum eigensolver (VQE) delegates costly state preparations and measurements to quantum hardware. We propose a bosonic VQE using superconducting microwave cavities, overcoming the typical restriction of a small Hilbert space when the VQE is qubit based.
arXiv Detail & Related papers (2021-08-18T17:12:24Z)
All-optical Quantum State Engineering for Rotation-symmetric Bosonic States [0.0]
We propose and analyze a method to generate a variety of non-Gaussian states using coherent photon subtraction. Our method can be readily implemented with current quantum photonic technologies.
arXiv Detail & Related papers (2021-05-23T22:43:23Z)
Fast simulation of bosonic qubits via Gaussian functions in phase space [0.0]
We present a novel formalism for simulating classes of states that can be represented as linear combinations of Gaussian functions in phase space. We demonstrate how useful classes of bosonic qubits -- Gottesman-Kitaev-Preskill (GKP), cat, and Fock states -- can be simulated using this formalism.
arXiv Detail & Related papers (2021-03-09T16:16:24Z)
Efficient simulatability of continuous-variable circuits with large Wigner negativity [62.997667081978825]
Wigner negativity is known to be a necessary resource for computational advantage in several quantum-computing architectures. We identify vast families of circuits that display large, possibly unbounded, Wigner negativity, and yet are classically efficiently simulatable. We derive our results by establishing a link between the simulatability of high-dimensional discrete-variable quantum circuits and bosonic codes.
arXiv Detail & Related papers (2020-05-25T11:03:42Z)
Simulating nonnative cubic interactions on noisy quantum machines [65.38483184536494]
We show that quantum processors can be programmed to efficiently simulate dynamics that are not native to the hardware. On noisy devices without error correction, we show that simulation results are significantly improved when the quantum program is compiled using modular gates.
arXiv Detail & Related papers (2020-04-15T05:16:24Z)

This list is automatically generated from the titles and abstracts of the papers in this site.