Abstract: A Light Detection And Ranging (LIDAR) measurement circuit includes a control circuit configured to receive respective detection signals output from one or more single-photon detectors in response to a plurality of photons incident thereon. The control circuit includes a photon counter circuit including a digital counter circuit and an analog counter circuit, the digital counter circuit being responsive to an output of the analog counter circuit or the analog counter circuit being responsive to an output of the digital counter circuit to count detection of respective photons of the plurality of photons based on the respective detection signals, and a time integration circuit configured to output a time integration signal representative of respective times of arrival indicated by the respective detection signals.

Abstract: A Light Detection and Ranging (LIDAR) system includes an emitter array comprising a plurality of emitter units operable to emit optical signals, a detector array comprising a plurality of detector pixels operable to detect light for respective strobe windows between pulses of the optical signals, and one or more control circuits. The control circuit(s) are configured to selectively operate different subsets of the emitter units and/or different subsets of the detector pixels such that a field of illumination of the emitter units and/or a field of view of the detector pixels is varied based on the respective strobe windows. Related devices and methods of operation are also discussed.

Abstract: A Light Detection And Ranging (LIDAR) apparatus includes a pulsed light source to emit optical signals, a detector array comprising single-photon detectors to output respective detection signals indicating times of arrival of a plurality of photons incident thereon, and processing circuitry to receive the respective detection signals.

Abstract: A photodetector device includes a semiconductor material layer and at least one photodiode in the semiconductor material layer. The at least one photodiode is configured to be biased beyond a breakdown voltage thereof to generate respective electrical signals responsive to detection of incident photons. The respective electrical signals are independent of an optical power of the incident photons. A textured region is coupled to the semiconductor material layer and includes optical structures positioned to interact with the incident photons in the detection thereof by the at least one photodiode. Two or more photodiodes may define a pixel of the photodetector device, and the optical structures may be configured to direct the incident photons to any of the two or more photodiodes of the pixel.

Abstract: A Time of Flight (TOF) system includes an incrementing circuit and a plurality of pixels. Each pixel includes a plurality of detectors configured to output respective detection signals responsive to detection of a plurality of photons incident thereon and a shared memory configured to store a respective count of the photons incident on each of the plurality of detectors. The incrementing circuit is configured to update the respective count for each of the plurality of detectors in the shared memory based on the respective detection signals.

Abstract: An active illumination apparatus includes an emission source configured to illuminate a field of view. The emission source includes one or more emitter elements, and is configured to output optical signals having respective wavelengths that vary based on respective portions of the field of view to be illuminated thereby. The respective wavelengths of the optical signals may vary over respective field angles of the field of view according to variations in optical characteristics of a detection module, such as a passband of a detector-side spectral filter element, for the respective field angles. Related imaging apparatus and methods are also discussed.

Abstract: A flash LIDAR apparatus includes emitter units configured to emit optical signals over a field of view, and detector pixels configured to output detection signals responsive to light representing the optical signals incident thereon. The detection signals correspond to respective phase offsets relative to a frequency of the optical signals. A circuit is configured to determine component measurements corresponding to the respective phase offsets from the detection signals, and calculate a distance of a target from which the light was reflected based on the detection signals. The distance is corrected for motion of the target based on subsets of the component measurements.

Abstract: A photodetector device includes a semiconductor material layer and at least one photodiode in the semiconductor material layer. The at least one photodiode is configured to be biased beyond a breakdown voltage thereof to generate respective electrical signals responsive to detection of incident photons. The respective electrical signals are independent of an optical power of the incident photons. A textured region is coupled to the semiconductor material layer and includes optical structures positioned to interact with the incident photons in the detection thereof by the at least one photodiode. Two or more photodiodes may define a pixel of the photodetector device, and the optical structures may be configured to direct the incident photons to any of the two or more photodiodes of the pixel.

Abstract: A Light Detection and Ranging (LIDAR) system includes a light source configured to emit a plurality of light beams having respective divergence angles over respective fields of illumination, and a detector array comprising plurality of detector pixels having respective fields of detection and configured to output respective detection signals responsive to light incident thereon. The respective fields of detection of the detector pixels are greater than or equal to the respective divergence angles of the light beams. Related devices and methods are also discussed.

Abstract: A Time of Flight (ToF) system, includes one or more optical elements configured to emit optical signals at two or more measurement frequencies and at least one disambiguation frequency, a detector array comprising a plurality of detectors that are configured to output respective detection signals responsive to light provided thereto, and a circuit configured to control the detector array to obtain a first subset of the detection signals at a first plurality of phase offsets corresponding to the two or more measurement frequencies and to obtain a second subset of the detection signals at a second plurality of phase offsets corresponding to the at least one disambiguation frequency, wherein the second plurality comprises fewer phase offsets than the first plurality.

Abstract: A Time of Flight (ToF) system includes an emitter array comprising one or more emitters configured to emit optical signals, a detector array comprising a plurality of detectors that are configured to output respective detection signals responsive to the optical signals that are reflected from a target, and a control circuit. The control circuit is configured to: control the emitter array to emit a first optical signal; and provide a plurality of activation signals to a subset of the plurality of detectors responsive to the first optical signal to activate respective ones of the detectors of the subset for a first duration to generate detection signals associated with the first optical signal. Respective ones of the plurality of activation signals are offset from one another by respective time offsets.

Abstract: Biosensor including a device base having a sensor array of light sensors and a guide array of light guides. The light guides have input regions that are configured to receive excitation light and light emissions generated by biological or chemical substances. The light guides extend into the device base toward corresponding light sensors and have a filter material. The device base includes device circuitry electrically coupled to the light sensors and configured to transmit data signals. A passivation layer extends over the device base and forms an array of reaction recesses above the light guides. The biosensor also includes peripheral crosstalk shields that at least partially surround corresponding light guides of the guide array to reduce optical crosstalk between adjacent light sensors.

Abstract: Biosensor including a device base having a sensor array of light sensors and a guide array of light guides. The light guides have input regions that are configured to receive excitation light and light emissions generated by biological or chemical substances. The light guides extend into the device base toward corresponding light sensors and have a filter material. The device base includes device circuitry electrically coupled to the light sensors and configured to transmit data signals. A passivation layer extends over the device base and forms an array of reaction recesses above the light guides. The biosensor also includes peripheral crosstalk shields that at least partially surround corresponding light guides of the guide array to reduce optical crosstalk between adjacent light sensors.

Abstract: A method of operating a time of flight system includes detecting first optical signals comprising a first frequency having a first unambiguous range, the first optical signals reflected from a target, processing the first optical signals to determine a first estimated distance to the target, and generating an output frame comprising a true distance to the target based on the first estimated distance and a second estimated distance to the target, wherein the second estimated distance was used to generate a previous output frame.

Abstract: A system detects an analyte suspected of being present in a sample. The reader reads an optical tag on a substrate, which is configured to immobilize the tag on a substrate surface. The optical tag is bound to a probe and includes a plurality of pores that create an effective index of refraction. The plurality of pores and a thickness of the tag are selected for a reflectance property. The substrate is configured to contact a sample suspected of comprising an analyte. The probe is capable of binding specifically to the analyte. The reader is configured to expose the tag to light to generate a sample spectral signature that is a function of the effective index of refraction, the thickness of the optical tag, and whether the analyte is coupled to the probe. The sample spectral signature is compared to a reference to detect the analyte in the sample.

Abstract: Biosensor including a device base having a sensor array of light sensors and a guide array of light guides. The light guides have input regions that are configured to receive excitation light and light emissions generated by biological or chemical substances. The light guides extend into the device base toward corresponding light sensors and have a filter material. The device base includes device circuitry electrically coupled to the light sensors and configured to transmit data signals. A passivation layer extends over the device base and forms an array of reaction recesses above the light guides. The biosensor also includes peripheral crosstalk shields that at least partially surround corresponding light guides of the guide array to reduce optical crosstalk between adjacent light sensors.

Abstract: A LIDAR apparatus includes an emitter array having a plurality of emitter pixels configured to emit optical signals, a detector array having a plurality of detector pixels configured to output detection signals responsive to light incident thereon, and a circuit that is coupled to the detector array. The circuit is configured to perform operations including receiving the detection signals output from the detector array, where each of the detection signals includes component measurements defining a respective phase vector, generating a combined vector based on the component measurements of a plurality of the detection signals, and identifying a distance range of a target from which the optical signals were reflected based on an angle of the combined vector. Related devices and methods of operation are also discussed.

Abstract: A Time of Flight (ToF) system, includes one or more optical elements configured to emit optical signals at two or more measurement frequencies and at least one disambiguation frequency, a detector array comprising a plurality of detectors that are configured to output respective detection signals responsive to light provided thereto, and a circuit configured to control the detector array to obtain a first subset of the detection signals at a first plurality of phase offsets corresponding to the two or more measurement frequencies and to obtain a second subset of the detection signals at a second plurality of phase offsets corresponding to the at least one disambiguation frequency, wherein the second plurality comprises fewer phase offsets than the first plurality.

Abstract: A Light Detection and Ranging (LIDAR) detector circuit includes a memory device comprising a non-transitory storage medium that is configured to store data indicative of detection events in respective memory bins, and at least one control circuit. The at least one control circuit is configured to receive detection signals from one or more photodetector elements, identify a presence or an absence of detection events indicated by the detection signals during a portion of time between pulses of an emitter signal output from a LIDAR emitter element, and execute one of a first memory operation or a second memory operation to update the data in the respective memory bins responsive to identification of the presence or the absence of the detection events, respectively. Related circuits and methods of operation are also discussed.

Abstract: A flash LIDAR apparatus includes emitter units configured to emit optical signals over a field of view, and detector pixels configured to output detection signals responsive to light representing the optical signals incident thereon. The detection signals correspond to respective phase offsets relative to a frequency of the optical signals. A circuit is configured to determine component measurements corresponding to the respective phase offsets from the detection signals, and calculate a distance of a target from which the light was reflected based on the detection signals. The distance is corrected for motion of the target based on subsets of the component measurements.