Maximal success probabilities of linear-optical quantum gates

Uskov, D. B.; Kaplan, L.; Smith, A. Matthew; Huver, Sean D.; Dowling, Jonathan P.

doi:10.1103/physreva.79.042326

Cited by 50 publications

(62 citation statements)

References 22 publications

(39 reference statements)

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“…In subsequent works, this efficiency was slightly improved [48]. There are also various, more general, treatments of these non-deterministic linear-optics gates deriving bounds on their efficiencies [49][50][51]. Experimental demonstrations were reported as well [52], even entirely in an optical fiber [53].…”

Section: Teleportation-based Approachesmentioning

confidence: 99%

Optical hybrid approaches to quantum information

Loock

2011

Laser & Photonics Reviews

125

119

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This article reviews recent hybrid approaches to optical quantum information processing, in which both discrete and continuous degrees of freedom are exploited. There are well-known limitations to optical single-photon-based qubit and multi-photon-based qumode implementations of quantum communication and quantum computation, when the toolbox is restricted to the most practical set of linear operations and resources such as linear optics and Gaussian operations and states. The recent hybrid approaches aim at pushing the feasibility, the efficiencies, and the fidelities of the linear schemes to the limits, potentially adding weak or measurement-induced nonlinearities to the toolbox

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Section: Teleportation-based Approachesmentioning

confidence: 99%

Optical hybrid approaches to quantum information

Loock

2011

Laser & Photonics Reviews

125

119

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“…metrics, where V d×d denotes the infinite-dimensional unitary V truncated to the d modes of U d×d [35]. Experimentally, the success probability is further degraded by photon loss, an effect absent in an ideal unitary.…”

mentioning

confidence: 99%

“…A simple argument suggests that this undesired "scatter probability" is at least (d − 1)/(2d − 1) for a uniform d-mode mixer based on a single EOM (Appendix A). Yet this limitation can be circumvented by considering two EOMs with a pulse shaper sandwiched between them; the spectral phase imparted by the middle stage ensures that the sidebands populated after the first EOM are returned to the computational space after the second one, thereby making it possible to realize a fully deterministic frequency beamsplitter [12].Quantitatively, the performance of a generic frequency multiport V can be compared to the desiredmetrics, where V d×d denotes the infinite-dimensional unitary V truncated to the d modes of U d×d [35]. Experimentally, the success probability is further degraded by photon loss, an effect absent in an ideal unitary.…”

mentioning

confidence: 99%

Electro-Optic Frequency Beam Splitters and Tritters for High-Fidelity Photonic Quantum Information Processing

et al. 2018

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We report experimental realization of high-fidelity photonic quantum gates for frequency-encoded qubits and qutrits based on electro-optic modulation and Fourier-transform pulse shaping. Our frequency version of the Hadamard gate offers near-unity fidelity (0.99998 ± 0.00003), requires only a single microwave drive tone for near-ideal performance, functions across the entire C-band (1530-1570 nm), and can operate concurrently on multiple qubits spaced as tightly as four frequency modes apart, with no observable degradation in the fidelity. For qutrits we implement a 3 × 3 extension of the Hadamard gate: the balanced tritter. This tritter-the first ever demonstrated for frequency modes-attains fidelity 0.9989 ± 0.0004. These gates represent important building blocks toward scalable, high-fidelity quantum information processing based on frequency encoding.Introduction.-The coherent translation of quantum states from one frequency to another via optical nonlinearites has been the focus of considerable research since the early 1990s [1]; yet only fairly recently have such processes been explored in the more elaborate context of time-frequency quantum information processing (QIP), where optical frequency is not just the carrier of quantum information but the information itself. Important examples include the quantum pulse gate [2,3], which uses nonlinear mixing with shaped classical pulses for selective conversion of the time-frequency modes of single photons [4][5][6], and demonstrations of frequency beamsplitters based on both χ (2) [7,8] and χ (3) [9][10][11] nonlinearities, which interfere two wavelength modes analogously to a spatial beamsplitter. These seminal experiments have shown key primitives in frequency-based QIP, but many challenges remain. For example, optical filters and/or low temperatures are required to remove background noise due to powerful optical pumps, either from the sources themselves or Raman scattering in the nonlinear medium. And achieving the necessary nonlinear mixing for arbitrary combinations of modes will require additional pump fields, as well as properly engineered phase-matching conditions.Recently we proposed a fundamentally distinct platform for frequency-bin manipulations, relying on electrooptic phase modulation and Fourier-transform pulse shaping for universal QIP [12]. Our approach requires no optical pump fields, is readily parallelized, and scales well with the number of modes. In this Letter, we apply this paradigm to experimentally demonstrate the first electro-optic-based frequency beamsplitter. Our frequency beamsplitter attains high fidelity, operates in * lougovskip@ornl.gov parallel on multiple two-mode subsets across the entire optical C-band, and retains excellent performance at the single-photon level. Moreover, by incorporating an additional harmonic in the microwave drive signal, we also realize a balanced frequency tritter, the threemode extension of the beamsplitter. This is the first frequency tritter demonstrated on any platform, and establishes our electro...

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“…However, an arbitrary (N c + N a ) × (N c + N a ) complex matrix U of unit spectral norm ( U = 1, where U is the largest singular value of U ) may be shown via the unitary dilation technique [13,19] to be equivalent to an (N c + N a + N v ) × (N c + N a + N v ) unitary matrix having the same success and fidelity, where N v is the number of vacuum modes in the input and output states. Thus, it is very convenient in practice to relax the unitarity condition and consider general matrices U of norm 1, with the understanding that the number of singular values in U different from unity corresponds to the number of vacuum modes that are required to implement that solution [13]. Furthermore, we may consider arbitrary complex matrices U with the rescaling U → U/ U to ensure unit norm.…”

Section: Loqc Gate Optimizationmentioning

confidence: 99%

“…We note that M c = 2 computational photons in N c = 4 computational modes are required for any two-qubit gate in the dual-rail representation. Additionally, the minimum ancillary resource required to implement CNOT with perfect fidelity consists of two single-photon ancillas; that is, the CNOT gate requires M a = 2 ancilla photons in N a = 2 ancilla modes [13]. Therefore, we have a total of four photons in six modes in the initial state, and the linear-optical transformation U is a 6 × 6 matrix.…”

Section: Two-qubit Gatesmentioning

confidence: 99%

Imperfect linear-optical photonic gates with number-resolving photodetection

et al. 2011

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We use the numerical optimization techniques of Uskov et al. [Phys. Rev. A 81, 012303 (2010)] to investigate the behavior of the success rates for Knill-Laflamme-Milburn-style [Knill et al., Nature (London) 409, 46 (2001)] two-and three-qubit entangling gates. The methods are first demonstrated at perfect fidelity and then extended to imperfect gates. We find that as the perfect fidelity condition is relaxed, the maximum attainable success rates increase in a predictable fashion depending on the size of the system, and we compare that rate of increase for several gates.

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Maximal success probabilities of linear-optical quantum gates

Cited by 50 publications

References 22 publications

Optical hybrid approaches to quantum information

Optical hybrid approaches to quantum information

Electro-Optic Frequency Beam Splitters and Tritters for High-Fidelity Photonic Quantum Information Processing

Imperfect linear-optical photonic gates with number-resolving photodetection

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