Disclosed are a time delay integration (TDI)-based image sensor and an imaging method thereof. The TDI-based image sensor includes: a multi-stage linear array including a plurality of single-stage linear arrays arranged along a scanning direction of the image sensor. Each single-stage linear array includes a plurality of pixels arranged along the linear array direction. Each single-stage linear array enters a count mode in response to a first control signal, and enters a transfer mode in response to a second control signal. In the count mode, each single-stage linear array counts optical signals incident on the pixels and obtains a count value, and in the transfer mode, each single-stage linear array stops counting, except for the last single-stage linear array, other single-stage linear arrays each output the obtained current count value to the next single-stage linear array, and the last single-stage linear array outputs the obtained current count value.

Real-time autofocus. In an embodiment, a scanning apparatus includes an imaging sensor, a focusing sensor, an objective lens, and processor(s) configured to analyze image data captured by the imaging and focusing sensors, and move the objective lens. Real-time autofocus during scanning of a sample is achieved by determining a true-Z value for the objective lens for a point on a sample and for each of a plurality of regions on the sample. The true-Z values and/or surfaces calculated therefrom are used to determine a predicted-Z value for an unscanned region of the sample. The objective lens is adjusted to the predicted-Z value at the beginning of the unscanned region. After scanning the region, a true-Z value is determined for the region and compared to the predicted-Z value. A rescan of the region is initiated if the comparison exceeds a predetermined threshold.

A TDI scanner including a dynamically programmable focal plane array including a two-dimensional array of detectors arranged in a plurality of columns and a plurality of rows, the array being divided into a plurality of banks separated from one another by gap regions, each bank including a plurality of sub-banks, and each sub-bank including at least one row of detectors, a ROIC coupled to the focal plane array and configured to combine in a TDI process outputs from detectors in each column of detectors in each sub-bank, and a controller configured to program the focal plane array to selectively and dynamically set characteristics of the focal plane array, the characteristics including a size and a location within the two-dimensional array of each of the plurality of sub-banks and the gap regions, the size corresponding to a number of rows of detectors included in the respective sub-bank or gap region.

Systems and methods in accordance with embodiments of the invention implement TDI imaging techniques in conjunction with monolithic CCD image sensors having multiple distinct imaging regions, where TDI imaging techniques can be separately implemented with respect to each distinct imaging region. In many embodiments, the distinct imaging regions are defined by color filters or color filter patterns (e.g. a Bayer filter pattern); and data from the distinct imaging regions can be read out concurrently (or else sequentially and/or nearly concurrently). A camera system can include: a CCD image sensor including a plurality of pixels that define at least two distinct imaging regions, where pixels within each imaging region operate in unison to image a scene differently than at least one other distinct imaging region. In addition, the camera system is operable in a time-delay integration mode whereby time delay-integration imaging techniques are imposed with respect to each distinct imaging region.

A first pixel group disposed in a first direction is read in the first direction. A second pixel group adjacent to the first pixel group is read in a second direction, which is opposite to the first direction.

According to one embodiment, a solid-state image sensor includes a linear array of pixels, a timing generator that outputs a pulse signal, a plurality of clock drivers that generate each generate a different drive signal based on the pulse signal, an analog shift register that transfers the signal charges in one direction along the linear array by applying the drive signals to the respective transfer blocks. The plurality of drive signals generated by the plurality of clock drivers each have a different phase.

According to one aspect, an instrument for scanning a specimen. The instrument includes a scanning stage for supporting the specimen, a detector having a plurality of pixels, the scanning stage and the detector movable relative to each other to move the specimen in a scan direction during a scan, and a pulsed illumination source synchronized with the motion of the specimen on the scanning stage. At least some of the pixels of the detector are operable to collect light emitted from the specimen during the scan due to the pulsed illumination source and generate corresponding image data. The instrument may further include a processor operable to perform MSIA on the image data to generate an image of the specimen.

A first region includes a plurality of first transfer column regions distributed in a first direction. A second region includes a plurality of second transfer column regions distributed in the first direction. The second region is positioned downstream of the first region in a charge transfer direction in the second transfer section. Lengths in a second direction of the plurality of first transfer column regions are equal. Lengths in the second direction of the plurality of second transfer column regions are longer than the length of the first transfer column region, and increase as the second transfer column region is positioned downstream in the charge transfer direction. A third region is disposed to correspond to the first region and extends along the first direction. A fourth region is disposed to correspond to the second region and extends such that an interval between the fourth region and a pixel region in the second direction increases in the charge transfer direction in response to a change in the lengths of the plurality of second transfer column regions.

The application provides a cross-row time delay integral method, apparatus and camera. The method includes obtaining a first stage integral energy in an i-th target region from an i-th row of a first integral piece domain; transferring the first stage integral energy across rows to an i-th row of a second integral piece domain; obtaining the first stage integral energy and an second stage integral energy accumulated in the i-th target region from the i-th row of the second integral piece domain, after an integration period; outputting an image of the i-th target region containing the first stage integral energy and the second stage integral energy. The application performs cross-row integration through the energy obtained by imaging, the shooting of the target can be carried out in a higher-speed environment, the method can be implemented on the existing photoelectric device, and the method has excellent imaging quality and wide applicability.

A charge-coupled device includes an array of insulated electrodes vertically penetrating into a semiconductor substrate. The array includes rows of alternated longitudinal and transverse electrodes. Each end of a longitudinal electrode of a row is opposite and separated from a portion of an adjacent transverse electrode of that row. Electric insulation walls extend parallel to one another and to the longitudinal electrodes. The insulation walls penetrate vertically into the substrate deeper than the longitudinal electrodes. At least two adjacent rows of electrodes are arranged between each two successive insulation walls.