Disclosed are image data acquisition methods and systems that utilizes selective temporal co-adding of detector integration samples to construct improved high-resolution output imagery for arrays with selectable line rates. Configurable TDI arrays are used to construct output imagery of various resolutions dependent upon array commanding, the acquisition geometry, and temporal sampling. The image acquisition techniques may be applied to any optical sensor system and to optical systems with multiple sensors at various relative rotations which enable simultaneous image acquisitions of two or more sensors. Acquired image data may be up-sampled onto a multitude of image grids of various resolution.

Multi-spectral methods and systems for the day and night remote sensing (detection, identification, and quantification) of greenhouse gas emission sources from space are provided. The sensor system includes a telescope assembly that passively collects light from an observation area and directs that light through spectral, optical filters and to a sensor array having a plurality of rows and columns of pixels. Different groups of sensor array pixel rows are aligned to receive light that has passed through different optical filters. The filters have passbands corresponding to the reflective and emissive bands of gases of interest, as well as associated reflective and emissive reference bands, and broadband spectral bands. A set of image data frames is obtained as the field of view of the sensor system moves over an observation area and an aggregate image showing locations of detected gas emissions is generated using the collected data.

Multi-spectral methods and systems for the day and night remote sensing (detection, identification, and quantification) of greenhouse gas emission sources from space are provided. The sensor system includes a telescope assembly that passively collects light from an observation area and directs that light through spectral, optical filters and to a sensor array having a plurality of rows and columns of pixels. Different groups of sensor array pixel rows are aligned to receive light that has passed through different optical filters. The filters have passbands corresponding to the reflective and emissive bands of gases of interest, as well as associated reflective and emissive reference bands, and broadband spectral bands. A set of image data frames is obtained as the field of view of the sensor system moves over an observation area and an aggregate image showing locations of detected gas emissions is generated using the collected data.

A method for processing a plurality of input images associated with a respective plurality of input times, the input images and input times being provided by an event timing system, comprises: selecting an output frame rate; generating a plurality of output images, corresponding to the output frame rate, from the plurality of input images; and assigning to each output image a final output time provided by the event timing system, the final output time being the input time associated with an input image contributing to the output image.

To eliminate image defects produced by high-energy particles passing through a time delay integration image sensor, upstream detection is effected on the digital values supplied by the pixels of the same rank that have successively observed the same scene point. This detection makes it possible to ignore or to correct values from corrupted pixels in establishing the digital signal representing the luminance of an observed scene point. Detection is based on the calculation of the difference between a first digital value p.sub.i,a(t.sub.1) and a second digital value p.sub.i,b(t.sub.2) supplied by two pixels Px.sub.i,a and Px.sub.i,b that have observed the same scene point, subtracting the second value from the first, and comparing it to a predetermined threshold k. If this difference is above the threshold, the first value is too high, the first value is ignored in the summation .sub.i effected to establish the luminance of the scene point, replacing this value with the second value to which it has been compared. Alternatively it is replaced by a mean value or excluded from the calculation.

Among a plurality of time measurement circuits configured to measure a time until a pixel counter saturates in the imaging sensor having the signal multiplication pixel structure, at least one time measurement circuit functions as a time counter that obtains a time from the pixel counter starting count of pulses until saturation and the other time measurement circuits function as a difference counter that obtains a difference between a time until a certain pixel counter saturates and a time until another pixel counter different from the certain pixel counter saturates. Then, a time from the pixel counter associated with the time measurement circuit that functions as a difference counter starting count of the pulses until saturation is found by calculation processing.

Among a plurality of time measurement circuits configured to measure a time until a pixel counter saturates in the imaging sensor having the signal multiplication pixel structure, at least one time measurement circuit functions as a time counter that obtains a time from the pixel counter starting count of pulses until saturation and the other time measurement circuits function as a difference counter that obtains a difference between a time until a certain pixel counter saturates and a time until another pixel counter different from the certain pixel counter saturates. Then, a time from the pixel counter associated with the time measurement circuit that functions as a difference counter starting count of the pulses until saturation is found by calculation processing.

Examples include an image sensor comprising a pixel array having at least one column of addressable pixel sensors, and a column amplifier coupled to the at least one column of addressable pixel sensors, the column amplifier comprising a transistor bank including a plurality of transistors, and mode select circuitry coupled to the transistor bank and configured to establish one or more connections among the plurality of transistors to configure the column amplifier to operate in one of a differential mode of operation and a single-ended mode of operation.

Examples include an image sensor comprising a pixel array having at least one column of addressable pixel sensors, and a column amplifier coupled to the at least one column of addressable pixel sensors, the column amplifier comprising a transistor bank including a plurality of transistors, and mode select circuitry coupled to the transistor bank and configured to establish one or more connections among the plurality of transistors to configure the column amplifier to operate in one of a differential mode of operation and a single-ended mode of operation.

A method for increasing dynamic range of a time-delay integration (TDI) image includes assigning a value N to a line-number setting and generating each line of the TDI image by (i) selecting N lines from N corresponding images of an image sequence, and (ii) integrating the N lines. The brightness of the TDI image is evaluated, after which the line-number setting is updated to a new value. In another method, the value of a TDI pixel is initialized to the value of a corresponding pixel in a first image of the image sequence. While the TDI pixel value is less than a ceiling, a contribution is added to the TDI pixel value, the contribution being based on the value of an additional corresponding pixel in an additional image of the image sequence. After adding, the resulting TDI pixel value may be scaled based on the number of contributions.