Abstract: A carbon capture system using an efficient method of capturing carbon dioxide is disclosed herein. The carbon capture system described is scalable in shape and size and can be adjusted to achieve different volumes of airflow. This method is efficient due to the maximum surface area to volume ratio achievable in a carbon capture system with the distribution of equally or randomly spaced spray nozzles configured to inject electrically charged carbon capture fluid throughout the interior of the system. The fluid interacts and then combines with air and as a result, large amounts of carbon dioxide are captured within the system. The finer the particulate of carbon capture fluid, the larger the volume ratio which results in an efficient carbon capture system.

Abstract: The present invention provides methods and systems for manipulating radiance data obtained from a radiance sensor that includes a lenslet array and a photodetector array, where the manipulation of the radiance data uses one or more algorithms or mathematical transformations applied by a software program. Manipulating the measured radiance data computationally produces the same optical effects of a desired optical system without having to insert the optical system into the optical path of the electromagnetic radiation. The manipulated radiance data is then used to generate an image.

Abstract: The present invention provides methods and systems for manipulating radiance data obtained from a radiance sensor that includes a lenslet array and a photodetector array, where the manipulation of the radiance data uses one or more algorithms or mathematical transformations applied by a software program. Manipulating the measured radiance data computationally produces the same optical effects of a desired optical system without having to insert the optical system into the optical path of the electromagnetic radiation. The manipulated radiance data is then used to generate an image.

Abstract: A radiance sensor includes a memory and a microprocessor. The memory stores non-transitory computer-readable instructions and adapted to store a plurality of electrical signals output from a photodetector array in response to electromagnetic radiation transmitted through a lenslet array and incident on the photodetector array. The microprocessor is adapted to execute the instructions to (i) determine irradiance of the electromagnetic radiation in a detector plane from the plurality of electrical signals, each electrical signal having generated by a respective one of a plurality of photodetectors of the photodetector array, and (ii) reconstruct, from the determined irradiance, the 4D-radiance in an input plane, the lenslet array being between the input plane and the detector plane.

Abstract: A radiance sensor includes a memory and a microprocessor. The memory stores non-transitory computer-readable instructions and adapted to store a plurality of electrical signals output from a photodetector array in response to electromagnetic radiation transmitted through a lenslet array and incident on the photodetector array. The microprocessor is adapted to execute the instructions to (i) determine irradiance of the electromagnetic radiation in a detector plane from the plurality of electrical signals, each electrical signal having generated by a respective one of a plurality of photodetectors of the photodetector array, and (ii) reconstruct, from the determined irradiance, the 4D-radiance in an input plane, the lenslet array being between the input plane and the detector plane.

Abstract: An apparatus for estimating a wavefront parameter includes a light source, a lenslet array, a detector for detecting light generated by the light source and passed through the lenslet array, a wavefront corrective element disposed between the lenslet array and the light source; and a data analyzer configured to estimate at least one wavefront parameter at a plane located on the light source side of the corrective element. The lenslet array and the sensor array are arranged to form a wavefront sensor, and the wavefront corrective element is configured to correct an aberration of the wavefront.

Abstract: An apparatus for estimating a wavefront parameter includes a light source, a lenslet array, a detector for detecting light generated by the light source and passed through the lenslet array, a wavefront corrective element disposed between the lenslet array and the light source; and a data analyzer configured to estimate at least one wavefront parameter at a plane located on the light source side of the corrective element. The lenslet array and the sensor array are arranged to form a wavefront sensor, and the wavefront corrective element is configured to correct an aberration of the wavefront.