An example system includes a hub transceiver and a plurality of edge transceivers. The hub transceiver is operable to determine a plurality of optical subcarriers available for assignment by the hub transceiver to the plurality of the edge transceivers for use in communicating over an optical communications network, and assign, to each of the edge transceivers, a respective subset of the optical subcarriers. Each of the subsets of the optical subcarriers includes a respective data optical subcarrier for transmitting data over the optical communications network. At least one of the subsets of the optical subcarriers includes one or more respective idle optical subcarriers. The hub t transceiver is also operable to transmit to each of the edge transceivers, an indication of the respective subset of the optical subcarriers assigned to the edge transceiver.

An apparatus includes a plurality of first optical devices and a second optical device. Each first optical device includes a respective first pair of waveguides comprising a respective first waveguide and a respective second waveguide that are coupled together, a respective second pair of waveguides comprising a respective third waveguide and a respective fourth waveguide that are coupled together, and a first fusion gate that includes a detector. Each first fusion gate is configured to perform a fusion on the respective second waveguide and the respective third waveguide of a respective first optical device. The fusion produces a detection pattern for the respective first optical device. The apparatus further includes a multiplexer to select a respective first optical device of the plurality of first optical devices based at least in part on the detection pattern for the respective first optical device and output photons from the respective first optical device.

The present invention relates to a transmitter for transmitting data and for emitting electromagnetic radiation in the visible spectral range, wherein the transmitter comprises a) a radiation source for generating and emitting first electromagnetic radiation, b) a modulator being adapted to modulate the first electromagnetic radiation depending on the data to be transmitted generating modulated first electromagnetic radiation, and c) a frequency converter for converting at least a part of the modulated first electromagnetic radiation into modulated second electromagnetic radiation, said modulated second electromagnetic radiation being different from the modulated first electromagnetic radiation, wherein the frequency converter comprises a polymeric matrix material comprising at least one organic fluorescent colorant. Furthermore, the invention relates to an illumination device comprising such transmitter. Moreover, the invention relates to a data transmission system comprising such a transmitter as well as a receiver and a data analyzer.

A LIDAR sensor for detecting an object in the surroundings and a method of the LIDAR sensor includes a light source emitting electromagnetic radiation, a micromechanical deflection mirror deflecting the emitted electromagnetic radiation by at least one angle into the surroundings, and a mirror, which includes an aperture situated on a main beam axis of the light source, deflecting onto an optical receiver received electromagnetic radiation that has been reflected from the object.

This underwater optical wireless communication system (100) is provided with a plurality of moving bodies (1) capable of moving underwater. The plurality of moving bodies each includes a plurality of optical wireless communication units (2) each configured to perform bidirectional communication between the plurality of moving bodies using communication light beams (30) having wavelengths different from each other in a plurality of directions which are mutually opposite directions. The plurality of optical wireless communication units is configured to perform bidirectional communication between the plurality of moving bodies using communication light beams, the communication beams having the same wavelength with respect to each of the plurality of directions.

A switched optical phased array based beam steering LiDAR (light detection and ranging) system includes an integrated photonics optical phased array (OPA) that includes an optical switching network for selectively connecting a large number of 1D scanning (in a first direction or field-of-view) antenna arrays to a light source. Each array is configured to emit light in a predefined angle of a second direction or field-of-view and can be switched individually to connect to the light source. At any given time, the phase shifters of only one such array, i.e. the one that is switched to connect the light source, are actively adjusted by the control circuits, so that the active power consumption is greatly reduced. The LiDAR system also includes a photo sensor receiver, other control and signal processing circuits, and other necessary optical and mechanical components.

A method includes detecting an object using a first light scan profile and, in response to detecting the object, using a second light scan profile with increased resolution in a region of interest relative to the first scan profile. The second light scan profile is based, at least in part, on a width of the region of interest, a number of scanlines for the region of interest, and an angular offset to the region of interest.

An apparatus for generating a time-delayed product of two independent signals includes a fixed-wavelength laser. A first optical modulator is optically coupled to the fixed-wavelength laser and configured to modulate a fixed wavelength optical carrier with a first input signal of a set of input signals. The apparatus also includes a tunable laser. A second optical modulator is optically coupled to the tunable laser and configured to modulate a tunable optical carrier with a second input signal of the set of input signals. The apparatus also includes a dispersive element coupled to the second optical modulator, a first optical detector coupled to the dispersive element, a third optical modulator optically coupled to the first optical detector and the first optical modulator, an optical 90-degree hybrid element optically coupled to the third optical modulator, and a plurality of optical detectors optically coupled to the optical 90-degree hybrid element.

Transmitting at least two optical signals to at least two receivers, using a source, an alignment module, and a telescope. The telescope has a field of view in which the at least two receivers are located, and at least a first beam path and a second beam path are aligned in the alignment module in order to respectively steer the first optical signal via the telescope to the first receiver and the second optical signal via the telescope to the second receiver.

A LIDAR apparatus for scanning a scan region with at least one beam is described. The LIDAR apparatus includes at least one beam source for generating the at least one beam; having a mirror for deflecting the at least one generated beam toward the scan region; and having a detector mirror for deflecting at least one beam, reflected at an object, onto a defined region of a detector, the mirror and the detector mirror being disposed on a rotor rotatably around a vertical rotation axis, and the detector mirror focusing the at least one reflected beam onto the detector. A method for operating a LIDAR apparatus is also described.