Abstract: In a multi-chip module and method, the multi-chip module includes a carrier; a multimode optical waveguide formed on and/or in the carrier; a first and second chip disposed on the carrier and coupled to the multimode optical waveguide; wherein the first chip is configured to transmit light beams into the multimode optical waveguide; the multimode optical waveguide is configured to generate mixed light beams that are an at least partial superposition of the light beams; the second chip is configured to receive the mixed light beams from the multimode optical waveguide; and the second chip is configured to store a representation of the received mixed light beams as a transmission signature and/or as a cryptographic key in a memory associated with the second chip, and/or compare the representation of the received mixed light beams with a target representation stored in the memory associated with the second chip.

Abstract: An optical system and an imaging method are disclosed, wherein the optical system comprises a multifilament conductor and an optical diffuser for imaging an intensity pattern onto the multifilament conductor, the intensity pattern representing phase information of light emitted from one or more three-dimensional objects; wherein the multifilament conductor is configured to transmit the intensity pattern in the form of a plurality of pixels to an evaluation system, and wherein the evaluation system is configured to generate an image based on the intensity pattern transmitted by the multifilament conductor, the image representing the one or more three-dimensional objects.

Abstract: A receiving apparatus and method for determining transmission characteristics of an optical waveguide in which the receiving apparatus includes a waveguide interface for receiving a mixed light beam having a plurality of modes from a multi-mode optical waveguide and for receiving a blended shifted light beam from the multimode optical waveguide, wherein the mixed light beam has an associated phase for each mode of the plurality of modes, and wherein the mixed shifted light beam has an associated shifted phase for each mode of the plurality of modes; and one or more processors for determining mode information for the intermixed light beam and shifted mode information for the intermixed shifted light beam using a trained neural network and for determining, for each mode of the plurality of modes, the respective associated phase using the intermixed shifted light beam.

Abstract: A receiving apparatus and method for determining transmission characteristics of an optical waveguide in which the receiving apparatus includes a waveguide interface for receiving a mixed light beam having a plurality of modes from a multi-mode optical waveguide and for receiving a blended shifted light beam from the multimode optical waveguide, wherein the mixed light beam has an associated phase for each mode of the plurality of modes, and wherein the mixed shifted light beam has an associated shifted phase for each mode of the plurality of modes; and one or more processors for determining mode information for the intermixed light beam and shifted mode information for the intermixed shifted light beam using a trained neural network and for determining, for each mode of the plurality of modes, the respective associated phase using the intermixed shifted light beam.

Abstract: A generally time-varying boundary surface between a plurality of flowing fluids having different refractive indices, e.g. the boundary surface between water and air with an open water surface, produces an optical disturbance. Optical flow measurement procedures that occur through the boundary surface are affected by this disturbance, which can lead to significant measurement deviations or can even completely prevent a measurement from being made. The invention contributes to solving this metrological problem by proposing arrangements and methods for instantaneous, hardware-based correction of optical disturbances caused by a fluctuating boundary surface. For this purpose, a wavefront modulator is introduced into the beam path of the optical measuring method, the modulator actively compensating for the optical disturbance by means of a control system. The invention makes it possible to perform optical flow measurements through a fluctuating boundary surface.

Abstract: A generally time-varying boundary surface between a plurality of flowing fluids having different refractive indices, e.g. the boundary surface between water and air with an open water surface, produces an optical disturbance. Optical flow measurement procedures that occur through the boundary surface are affected by this disturbance, which can lead to significant measurement deviations or can even completely prevent a measurement from being made. The invention contributes to solving this metrological problem by proposing arrangements and methods for instantaneous, hardware-based correction of optical disturbances caused by a fluctuating boundary surface. For this purpose, a wavefront modulator is introduced into the beam path of the optical measuring method, the modulator actively compensating for the optical disturbance by means of a control system. The invention makes it possible to perform optical flow measurements through a fluctuating boundary surface.

Abstract: A method and a fibre-optical system for illuminating and detecting an object by light includes in situ calibration of a fibre bundle and disturbance-corrected illumination or disturbance-corrected detection of an object, in particular for endoscopic and microscopic applications, and makes it possible to directly determine the single phase distortion of the light, caused by the transmission by the fibre bundle, in order to calibrate the fibre bundle, and thus provides a possibility for determining the system function of a fibre bundle that is improved compared with the prior art of measuring the double phase distortion. The system function is used for disturbance correction when illuminating or detecting the object.

Abstract: A method and a fibre-optical system for illuminating and detecting an object by light includes in situ calibration of a fibre bundle and disturbance-corrected illumination or disturbance-corrected detection of an object, in particular for endoscopic and microscopic applications, and makes it possible to directly determine the single phase distortion of the light, caused by the transmission by the fibre bundle, in order to calibrate the fibre bundle, and thus provides a possibility for determining the system function of a fibre bundle that is improved compared with the prior art of measuring the double phase distortion. The system function is used for disturbance correction when illuminating or detecting the object.