Abstract: An image sensor may include a pixel array having pixels arranged in rows and columns, column readout circuitry, and control circuitry. Column readout circuitry may include corresponding readout circuits each coupled to a corresponding column path for a respective column of pixels. The readout circuits may each include signal processing circuits such as correlated double sampling circuitry and analog-to-digital converter circuitry. To reduce peak-to-average power ratio, during the signal processing operations for each pixel row, the control circuitry may control the signal processing circuits to perform time-domain multiplexing across the pixel columns to activate the signal processing circuits at varied times within the row time. If desired, the pattern of time-domain multiplexing may be varied across the signal processing operations for different pixel rows and/or for different image frames.

Abstract: An imaging device may have an array of image sensor pixels arranged in rows and columns and column readout circuitry coupled to the array. The rows of pixels may receive drive signals from row driver circuitry, and the drive signals may be sent from timing circuitry based on the locations of rows within the array. In particular, rows closer to the readout circuitry may require less settling time and therefore be driven faster than the rows further from the readout circuitry. All of the rows may be driven in a single direction, or the array of pixels may have a cut, in which case rows above the cut may be driven up and rows below the cut may be driven down. A frame buffer may be used to store the signals generated by the rows of pixels and may account for the asynchronous read out of image data.

Abstract: Various embodiments of the present technology provide a method and apparatus for an image sensor. In various embodiments, the apparatus provides a driver circuit connected to a plurality of electrically distinct pixel groups to provide the pixel groups with a control signal. A delay measurement circuit is connected to the driver circuit and at least one of the pixel groups to measure a time delay of the control signal. A row control circuit is connected to the delay measurement circuit to receive the measured time delay and, in turn, deliver, via the driver circuit, the control signal to all pixel groups in a single row substantially simultaneously.

Abstract: An image sensor may be implemented using a stitched image sensor die. The stitched image sensor die may be formed from a step and repeat exposure process using a set of tiles in a reticle set. Multiple instantiations of a same circuitry block on a given tile may be patterned and formed on the image sensor die. The image sensor die may include circuitry configured to enable testing of one or more instantiations of the same circuitry block. The image sensor die may include memory circuitry for storing indications of a functional instantiation of the multiple instances and may use the functional instantiation for normal operation.

Abstract: Various embodiments of the present technology provide a method and apparatus for an image sensor. In various embodiments, the apparatus provides a driver circuit connected to a plurality of electrically distinct pixel groups to provide the pixel groups with a control signal. A delay measurement circuit is connected to the driver circuit and at least one of the pixel groups to measure a time delay of the control signal. A row control circuit is connected to the delay measurement circuit to receive the measured time delay and, in turn, deliver, via the driver circuit, the control signal to all pixel groups in a single row substantially simultaneously.

Abstract: An image sensor may include a pixel array, row control circuitry, and column readout circuitry. The row control circuitry may operate the pixel array in a global shutter mode of operation. In particular, timing control circuitry may provide global timing clock signals associated with a global photodiode reset event and a global photodiode charge transfer event to row driver circuitry providing control signals to each row in the array. Each driver circuitry may include a time delay circuit that delays the global timing clock signal by different amounts across the rows. Therefore, these global events may be offset on a per-row or per-row group basis, thereby mitigating power surges associated with global events. Further, by offsetting the global photodiode reset and charge transfer events using the same delay for a given row, the same global integration time may be preserved across different rows.

Abstract: An image sensor may include a pixel array having pixels arranged in rows and columns, column readout circuitry, and control circuitry. Column readout circuitry may include corresponding readout circuits each coupled to a corresponding column path for a respective column of pixels. The readout circuits may each include signal processing circuits such as correlated double sampling circuitry and analog-to-digital converter circuitry. To reduce peak-to-average power ratio, during the signal processing operations for each pixel row, the control circuitry may control the signal processing circuits to perform time-domain multiplexing across the pixel columns to activate the signal processing circuits at varied times within the row time. If desired, the pattern of time-domain multiplexing may be varied across the signal processing operations for different pixel rows and/or for different image frames.

Abstract: Various embodiments of the present technology provide a method and apparatus for an image sensor. In various embodiments, the apparatus provides a driver circuit connected to a plurality of electrically distinct pixel groups to provide the pixel groups with a control signal. A delay measurement circuit is connected to the driver circuit and at least one of the pixel groups to measure a time delay of the control signal. A row control circuit is connected to the delay measurement circuit to receive the measured time delay and, in turn, deliver, via the driver circuit, the control signal to all pixel groups in a single row substantially simultaneously.

Abstract: An image sensor may be implemented using a stitched image sensor die. The stitched image sensor die may be formed from a step and repeat exposure process using a set of tiles in a reticle set. Multiple instantiations of a same circuitry block on a given tile may be patterned and formed on the image sensor die. The image sensor die may include circuitry configured to enable testing of one or more instantiations of the same circuitry block. The image sensor die may include memory circuitry for storing indications of a functional instantiation of the multiple instances and may use the functional instantiation for normal operation.

Abstract: An image sensor may be implemented using a stitched image sensor die. The stitched image sensor die may be formed from a step and repeat exposure process using a set of tiles in a reticle set. Multiple instantiations of a same circuitry block on a given tile may be patterned and formed on the image sensor die. The image sensor die may include circuitry configured to enable testing of one or more instantiations of the same circuitry block. The image sensor die may include memory circuitry for storing indications of a functional instantiation of the multiple instances and may use the functional instantiation for normal operation.

Abstract: An electronic system such as an imaging system may include processing circuitry and memory circuitry. A portion of the electronic device may be formed from a stamp-and-repeat structure. As an example, an integrated circuit die in the electronic device may be formed from multiple identical circuitry block unit cells. Block access circuitry may be used to selectively access one or more (e.g. a subset) of the identical circuitry blocks. The block access circuitry may include data input circuitry, data output circuitry, and data loop-back circuitry. The block access circuitry may be formed from a serial chain of data storage circuits that selectively provides enable signals to the one or more circuitry blocks being accessed. The serial chain of data storage circuits may receive and store different sets of enable bits.

Abstract: An imaging device may have an array of image sensor pixels arranged in rows and columns and column readout circuitry coupled to the array. The rows of pixels may receive drive signals from row driver circuitry, and the drive signals may be sent from timing circuitry based on the locations of rows within the array. In particular, rows closer to the readout circuitry may require less settling time and therefore be driven faster than the rows further from the readout circuitry. All of the rows may be driven in a single direction, or the array of pixels may have a cut, in which case rows above the cut may be driven up and rows below the cut may be driven down. A frame buffer may be used to store the signals generated by the rows of pixels and may account for the asynchronous read out of image data.

Abstract: An image sensor may be implemented using a stitched image sensor die. The stitched image sensor die may be formed from a step and repeat exposure process using a set of physical tiles in a reticle set. The physical tiles may include a center tile forming pixel circuitry on the image sensor die and peripheral tiles forming non-pixel circuitry on the image sensor die. Each of the physical tiles may be sized based on an integer multiple of a virtual unit tile. As such, the physical tiles may have dimensions that are not required to be an integer multiple of the smallest physical tile. The step and repeat exposure process may use the unit lengths of the virtual unit tile to properly position the die relative to the processing tools.

Abstract: A system is disclosed for setting an electrical circuit parameter at a predetermined value. The system comprises a first electrical component having a first electrical parameter associated therewith. Sensing means generate a control signal indicative of the value of the first electrical parameter. A second electrical component has a second electrical parameter associated therewith, the value of which has a predetermined relation to the value of the first electrical parameter. Adjustment means receive the control signal generated by the sensing means; and, in response to the control signal being indicative that the electrical circuit parameter is not at the predetermined value, selectively connects or disconnects at least one further electrical component to or from the second electrical component thereby to provide said predetermined value.