An optical element is provided. The optical device includes a carrier, a first receiver, and a second receiver. The first receiver is disposed on the carrier and configured to receive a first light. The second receiver is disposed on the carrier and configured to receive a second light. The first light and the second light have different frequency bands.

An optical element is provided. The optical device includes a carrier, a first receiver, and a second receiver. The first receiver is disposed on the carrier and configured to receive a first light. The second receiver is disposed on the carrier and configured to receive a second light. The first light and the second light have different frequency bands.

Methods and apparatus for nonuniformity correction (NUC) for a sensor having an avalanche photodiode (APD) array and an integrated circuit. The sensor can include anode bias control module, a passive mode module, and an active mode module. DC photocurrent from the APD array can be measured and used for controlling an anode reverse bias voltage to each element in the APD to achieve a nonuniformity correction level less than a selected threshold.

Methods and apparatus for nonuniformity correction (NUC) for a sensor having an avalanche photodiode (APD) array and an integrated circuit. The sensor can include anode bias control module, a passive mode module, and an active mode module. DC photocurrent from the APD array can be measured and used for controlling an anode reverse bias voltage to each element in the APD to achieve a nonuniformity correction level less than a selected threshold.

An optoelectronic sensor, including a transmitting unit for transmitting a plurality of optical signals in each case to a plurality of segments of an object, and a receiving unit that includes a first multichannel analog-digital converter device, including: an analog-digital converter unit; a plurality of signal processing channels, the signal processing channels of the plurality of signal processing channels in each case including: a detection antenna for receiving optical signals; and a modulator for generating an individual signal encoding. Signals of the plurality of signal processing channels, with individual signal encoding, are transmittable together to the analog-digital converter unit, are converted, and may be associated once again with the corresponding signal processing channels due to the individual signal encoding via algorithms.

An optoelectronic sensor, including a transmitting unit for transmitting a plurality of optical signals in each case to a plurality of segments of an object, and a receiving unit that includes a first multichannel analog-digital converter device, including: an analog-digital converter unit; a plurality of signal processing channels, the signal processing channels of the plurality of signal processing channels in each case including: a detection antenna for receiving optical signals; and a modulator for generating an individual signal encoding. Signals of the plurality of signal processing channels, with individual signal encoding, are transmittable together to the analog-digital converter unit, are converted, and may be associated once again with the corresponding signal processing channels due to the individual signal encoding via algorithms.

Methods and apparatus for a controlling a stimulus source to direct photons to a pixel in a pixel array contained in a detector system, analyzing a response of the pixel in the pixel array; and generating an alert based on the response of the pixel in the pixel array. Example stimulus sources include a conductive trace, a PN junction, and a current source.

A focal-plane array includes an array of pixels. Each pixel includes an avalanche-type diode on a first layer, a read-out circuit (ROIC) on a second layer, and a power-supply circuit on a middle layer stacked between the first layer and the second layer. Since each pixel includes the avalanche-type diode, the ROIC, and the power-supply circuit on different layers circuitry for each pixel is in a top-down footprint of the pixel. Thus a consistent bias voltage to each pixel, decouples the avalanche-type diodes of the different pixels to eliminate crosstalk between adjacent pixels, and allows for individual control of each pixel.

A focal-plane array includes an array of pixels. Each pixel includes an avalanche-type diode on a first layer, a read-out circuit (ROIC) on a second layer, and a power-supply circuit on a middle layer stacked between the first layer and the second layer. Since each pixel includes the avalanche-type diode, the ROIC, and the power-supply circuit on different layers circuitry for each pixel is in a top-down footprint of the pixel. Thus a consistent bias voltage to each pixel, decouples the avalanche-type diodes of the different pixels to eliminate crosstalk between adjacent pixels, and allows for individual control of each pixel.

A lightweight, inexpensive LADAR sensor incorporating 3-D focal plane arrays is adapted specifically for modular manufacture and rapid field configurability and provisioning. The sensor generates, at high speed, 3-D image maps and object data at short to medium ranges. The techniques and structures described may be used to extend the range of long range systems as well, though the focus is on compact, short to medium range ladar sensors suitable for use in multi-sensor television production systems and 3-D graphics capture and moviemaking. 3-D focal plane arrays are used in a variety of physical configurations to provide useful new capabilities.