An optical signal processing device capable of performing computation without changing a device configuration even when the number of input and output dimensions changes is provided. An optical signal processing device for converting an input M (M is an integer equal to or greater than 2)-dimensional input signal to an optical signal to perform signal processing includes an input unit configured to convert the input M-dimensional input signal to a one-dimensional input signal, and perform linear processing on the one-dimensional input signal to convert the one-dimensional input signal to an optical signal, a reservoir unit connected to an output of the input unit and configured to perform linear processing and nonlinear processing on the optical signal, and an output unit connected to an output of the reservoir unit and configured to convert the optical signal to an electrical signal to perform linear processing, and output an N-dimensional output.

A light-based apparatus has an input device, accepting two or more numerical inputs and an output command. It has a logic unit that receives the two numerical inputs from the input device, and is adapted to combine various lights, in amplitudes based on the respective values of the numerical inputs, to produce an output light sum representing a sum of the two numerical inputs. The logic unit also has an output sensing circuit to sense the output light sum. The logic unit is responsive to the output command to output a value representing the output light sum. The device uses a computing method that includes comingling light from multiple sources, at the same time, in a light containment area to provide comingled light. The method includes using light amplitude sensing circuitry to sense an amplitude of the comingled light, outputting an arithmetic sum, based on the amplitude of the comingled light, without using a binary computer to compute the arithmetic sum.

A light-based apparatus has an input device, accepting two or more numerical inputs and an output command. It has a logic unit that receives the two numerical inputs from the input device, and is adapted to combine various lights, in amplitudes based on the respective values of the numerical inputs, to produce an output light sum representing a sum of the two numerical inputs. The logic unit also has an output sensing circuit to sense the output light sum. The logic unit is responsive to the output command to output a value representing the output light sum. The device uses a computing method that includes comingling light from multiple sources, at the same time, in a light containment area to provide comingled light. The method includes using light amplitude sensing circuitry to sense an amplitude of the comingled light, outputting an arithmetic sum, based on the amplitude of the comingled light, without using a binary computer to compute the arithmetic sum.

Systems, methods, and apparatus for photonic crystals logic devices are disclosed. In one or more embodiments, a disclosed method for an optical logic device comprises radiating, by at least one source, at least one signal. The method further comprises reflecting at least one signal off of at least one photonic crystal, when at least one photonic crystal senses a physical phenomena of a threshold strength. Also, the method comprises not reflecting at least one signal off of at least one photonic crystal, when at least one photonic crystal does not sense the physical phenomena of the threshold strength. Further, the method comprises detecting or not detecting, by at least one detector, at least one signal.

Systems, methods, and apparatus for photonic crystals logic devices are disclosed. In one or more embodiments, a disclosed method for an optical logic device comprises radiating, by at least one source, at least one signal. The method further comprises reflecting at least one signal off of at least one photonic crystal, when at least one photonic crystal senses a physical phenomena of a threshold strength. Also, the method comprises not reflecting at least one signal off of at least one photonic crystal, when at least one photonic crystal does not sense the physical phenomena of the threshold strength. Further, the method comprises detecting or not detecting, by at least one detector, at least one signal.

A electronic method, includes receiving, by a graphene structure, a SPP mode of a particular frequency. The electronic method includes receiving, by the graphene structure, a driving microwave voltage. The electronic method includes generating, by the graphene structure, an entanglement between optical and voltage fields.

A electronic method, includes receiving, by a graphene structure, a SPP mode of a particular frequency. The electronic method includes receiving, by the graphene structure, a driving microwave voltage. The electronic method includes generating, by the graphene structure, an entanglement between optical and voltage fields.

A electronic method, includes receiving, by a graphene structure, a SPP mode of a particular frequency. The electronic method includes receiving, by the graphene structure, a driving microwave voltage. The electronic method includes generating, by the graphene structure, an entanglement between optical and voltage fields.

An optical DAC includes a 1:N splitter that splits a single light beam into N light beams corresponding to bits of an N-bit electrical digital signal (where N is an integer of 2 or more) and makes the N light beams different in optical intensities such that (N−1) light beams corresponding to bits except a least significant bit of the N-bit electrical digital signal each have an optical intensity which is four times as large as an optical intensity of a light beam corresponding to a next less significant bit, an optical intensity modulator that individually intensity-modulates the N light beams, an N:1 combiner that combines the N output light beams intensity-modulated by the optical intensity modulator and outputs the combined light, and a phase shifter that is adjustable such that the light beams that are combined by the N:1 combiner are made in phase.

An optical DAC includes a 1:N splitter that splits a single light beam into N light beams corresponding to bits of an N-bit electrical digital signal (where N is an integer of 2 or more) and makes the N light beams different in optical intensities such that (N−1) light beams corresponding to bits except a least significant bit of the N-bit electrical digital signal each have an optical intensity which is four times as large as an optical intensity of a light beam corresponding to a next less significant bit, an optical intensity modulator that individually intensity-modulates the N light beams, an N:1 combiner that combines the N output light beams intensity-modulated by the optical intensity modulator and outputs the combined light, and a phase shifter that is adjustable such that the light beams that are combined by the N:1 combiner are made in phase.