2019
DOI: 10.1088/2040-8986/ab0e66
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Roadmap on all-optical processing

Abstract: The ability to process optical signals without passing into the electrical domain has always attracted the attention of the research community. Processing photons by photons unfolds new scenarios, in principle allowing for unseen signal processing and computing capabilities. Optical computation can be seen as a large scientific field in which researchers operate, trying to find solutions to their specific needs by different approaches; although the challenges can be substantially different, they are typically … Show more

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Cited by 157 publications
(75 citation statements)
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References 284 publications
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“…However, the use of DSP may be undesirable in midspan regeneration, in which the signal is further transmitted on an optical carrier and it is often simply not possible to use it, e.g., in quantum optics. The use of DSP and ADC also increase power consumption and latency, which is highly-undesirable in many applications such as high-frequency trading, 5G mobile communications [98], and low latency coherent data center interconnection [99], [100]. In these areas, phase locking of the local oscillator to the incoming signal in the optical domain could be beneficial to coherent detection.…”
Section: B Optical Local Oscillator Recoverymentioning
confidence: 99%
“…However, the use of DSP may be undesirable in midspan regeneration, in which the signal is further transmitted on an optical carrier and it is often simply not possible to use it, e.g., in quantum optics. The use of DSP and ADC also increase power consumption and latency, which is highly-undesirable in many applications such as high-frequency trading, 5G mobile communications [98], and low latency coherent data center interconnection [99], [100]. In these areas, phase locking of the local oscillator to the incoming signal in the optical domain could be beneficial to coherent detection.…”
Section: B Optical Local Oscillator Recoverymentioning
confidence: 99%
“…Here, |cat + ⟩ and |cat − ⟩ denote, respectively, the even and odd optical Schrödinger cat states (8) forming the basis of our CV qubit space, corresponding to superpositions of coherent states of amplitude a ≈ 0.9. The single-mode squeezed vacuum and the photon-subtracted squeezed vacuum states generated by the OPO can concurrently reach fidelities above 90% with these states at moderate squeezing levels of about 5 dB.…”
Section: Experimental Setup and Initial Entangled Statesmentioning
confidence: 99%
“…Several experiments have spearheaded the development of the hybrid quantum optics paradigm (6)(7)(8). The first realizations from a decade ago consisted in combining the DV and CV toolboxes to generate non-Gaussian states, such as optical Schrödinger cat states starting from Gaussian squeezed light (9)(10)(11).…”
Section: Introductionmentioning
confidence: 99%
“…Examples are quantum teleportation of a DV using CV protocol [14] or the teleportation of CV qubit to qubit [15], quantum repeater using hybrid protocol [76] or building on-chip integrated circuits [77]. Hybrid optical states have been generated experimentally to entangle the DV and CV [16][17][18][19][78][79][80][81][82][83][84]. Therefore, a natural question arises about whether and up to what extent we can induce the nonlinear effects of RI all-optically.…”
Section: Introductionmentioning
confidence: 99%