Abstract: A method for automatically measuring the modulation transfer function of an imager is disclosed. A opaque mask is placed over selected columns and rows of the imager during fabrication. In the course of an automated process, photons are uniformly shone over the image sensor. The amount of the input signal that flows from the unmasked pixel cells to the masked pixel cells can then be measured and the modulation transfer function can be determined.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: A method of operating a pixel array includes activating a global storage signal to store a photosensor charge in a first storage region of each pixel, activating a first reset signal for pixels in a first row to reset a second storage region of first row pixels, sampling the reset second storage region, activating a third reset signal for pixels in a second row to reset a third storage region of second row pixels, sampling the reset third storage region, transferring the photosensor charge from the first storage region of pixels in a first set of columns of the first and second rows of the array respectively to the second and third storage regions, sampling the photosensor charge from the second storage region from first row/first column pixels, and sampling the photosensor charge from the third storage region from second row/first column pixels.

Abstract: The present invention, in the various exemplary embodiments, provides a pixel array architecture having multiple pixel cells with shared pixel cell components. The pixel architecture increases the potential fill factor, and in turn, the quantum efficiency of the pixel array. The common pixel components may be shared by a number of pixels in the array, and may include a shared gate for an providing anti-blooming characteristic of the pixels over conventional pixels. Embodiments include the multi-way sharing of a high dynamic range/anti-blooming gate and methods of operation.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: A pixel cell array architecture having a multiple pixel cells with shared pixel cell components. The individual pixel cell architecture increases the fill factor and the quantum efficiency for the pixel cell. The common pixel cell components may be shared by a number of pixels in the array, and may include several components that are associated with the readout of a signal from the pixel cell. Other examples of the pixel array architecture having improved fill factor for pixels in the array include an angled transfer gate and an efficiently located, shared capacitor.

Abstract: A pixel cell allows both correlated double sampling (CDS) and automatic light control (ALC) operations through a non-destructive, parallel readout. An image sensor may include an array of pixel cells, some or all of which include a photosensor with two readout circuits attached; peripheral circuitry can sample charges generated from the photosensor through one readout circuit, then perform array readout through the other. One readout circuit connected to the photosensor provides a non-destructive readout of the generated charge. The other readout circuit can, for example, be a multiple-transistor circuit that transfers charge from the photosensor to a floating diffusion node for readout. The image sensor's readout circuitry may thus monitor the light reaching the photosensor of the cell to determine when to read out signals from the entire array.

Abstract: A method for automatically measuring the modulation transfer function of an imager is disclosed. A opaque mask is placed over selected columns and rows of the imager during fabrication. In the course of an automated process, photons are uniformly shone over the image sensor. The amount of the input signal that flows from the unmasked pixel cells to the masked pixel cells can then be measured and the modulation transfer function can be determined.

Abstract: A rolling shutter technique for a pixel array is described in which multiple rows of the array are hard reset as the shutter moves down the array. As the rolling shutter progresses down the array, each row is hard reset multiple times before its integration period begins, thereby ensuring that the row is in a true hard reset condition at the beginning of its integration period. Also, multiple rows are hard reset in advance of the beginning of the integration period for a given row, thereby making it less likely that overexposed pixels several rows away will be able to distort the integrating row by blooming.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: A pixel cell in which a capacitance is coupled between a storage node and a row select transistor. The pixel cell utilizes a readout timing sequence between operation of a reset transistor and a row select transistor to boost a reset voltage.

Abstract: A storage gate pixel operates such that the storage gate is not required to have the same capacity as a photodiode of the pixel. This provides greater fill factor for the pixel and a higher signal to noise ratio.

Abstract: An anti-eclipse circuit of an image pixel includes a clamping circuit for pulling up a voltage of a reset signal output by the pixel and an eclipse detection circuit for controllably coupling the clamping circuit output to the output of the pixel. The clamping circuit includes a source follower transistor and a switching transistor. The eclipse detection circuit includes a comparator that is operated to detect an eclipse condition. The eclipse detection circuit outputs a control signal to cause the switching transistor to conduct only when a eclipse condition is detected while the pixel is outputting a reset signal.

Abstract: A pixel cell allows both correlated double sampling (CDS) and automatic light control (ALC) operations through a non-destructive, parallel readout. An image sensor may include an array of pixel cells, some or all of which include a photosensor with two readout circuits attached; peripheral circuitry can sample charges generated from the photosensor through one readout circuit, then perform array readout through the other. One readout circuit connected to the photosensor provides a non-destructive readout of the generated charge. The other readout circuit can, for example, be a multiple-transistor circuit that transfers charge from the photosensor to a floating diffusion node for readout. The image sensor's readout circuitry may thus monitor the light reaching the photosensor of the cell to determine when to read out signals from the entire array.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: A method for automatically measuring the modulation transfer function of an imager is disclosed. A opaque mask is placed over selected columns and rows of the imager during fabrication. In the course of an automated process, photons are uniformly shone over the image sensor. The amount of the input signal that flows from the unmasked pixel cells to the masked pixel cells can then be measured and the modulation transfer function can be determined.