Abstract: A method and apparatus providing an imager with shared power supply and readout lines. A pixel array has a plurality of pixels arranged in rows and columns. Each column of the array comprises a column line coupled to receive pixel signals from the pixels in the column and selectively operated to provide a supply voltage to at least one pixel in a different column.

Abstract: An image sensor including a substrate, at least one metal layer, and a plurality of pixels arranged in array. Each pixel includes a sense element disposed in the substrate and at least one metal interconnect segment disposed in the at least one metal layer. The array includes a pair of perpendicular axes extending from an optical center, wherein for a line of pixels extending perpendicularly from one of the axes to a peripheral edge of the array a spacing between the sense elements of consecutive pairs of pixels of the line is at least equal to a spacing between the associated at least one metal interconnect segments, and wherein for at least one consecutive pair of pixels of the line the spacing between the sense elements is greater by an incremental amount than the spacing between the corresponding at least one metal interconnect segments.

Abstract: A method and apparatus providing an imager with shared power supply and readout lines. A pixel array has a plurality of pixels arranged in rows and columns. Each column of the array comprises a column line coupled to receive pixel signals from the pixels in the column and selectively operated to provide a supply voltage to at least one pixel in a different column.

Abstract: An image sensor including a substrate, at least one metal layer, and a plurality of pixels arranged in array. Each pixel includes a sense element disposed in the substrate and at least one metal interconnect segment disposed in the at least one metal layer. The array includes a pair of perpendicular axes extending from an optical center, wherein for a line of pixels extending perpendicularly from one of the axes to a peripheral edge of the array a spacing between the sense elements of consecutive pairs of pixels of the line is at least equal to a spacing between the associated at least one metal interconnect segments, and wherein for at least one consecutive pair of pixels of the line the spacing between the sense elements is greater by an incremental amount than the spacing between the corresponding at least one metal interconnect segments.

Abstract: An image sensor including a substrate, at least one metal layer, and a plurality of pixels arranged in array. Each pixel includes a sense element disposed in the substrate and at least one metal interconnect segment disposed in the at least one metal layer. The array includes a pair of perpendicular axes extending from an optical center, wherein for a line of pixels extending perpendicularly from one of the axes to a peripheral edge of the array a spacing between the sense elements of consecutive pairs of pixels of the line is at least equal to a spacing between the associated at least one metal interconnect segments, and wherein for at least one consecutive pair of pixels of the line the spacing between the sense elements is greater by an incremental amount than the spacing between the corresponding at least one metal interconnect segments.

Abstract: A method of sampling image signals generated by pixel circuits of an active pixel sensor (APS) image sensor. The APS image sensor supports a normal mode of operation and a sub-sampling mode of operation. The method includes providing a plurality of column amplifiers. A row of pixels circuits to sample is selected. Image signals from each pixel circuit in the selected row are routed to a different one of the plurality of column amplifiers when the APS image sensor is in the normal mode of operation. Image signals from a plurality of the pixel circuits in the selected row are routed to one of the plurality of column amplifiers when the APS image sensor is in the sub-sampling mode of operation.

Abstract: A ground referenced pixel reset circuit is disclosed. The ground referenced pixel reset circuit supplies a pixel with a reset signal such that when the reset signal is asserted high, the reset signal is at a ground referenced reset voltage independent from a supply voltage. The pixel includes a photosensor, such as a photodiode, that is coupled to a ground having a same potential as the ground of the reference voltage supply. In this manner, noise caused by fluctuations in the supply voltage is reduced.

Abstract: A method of sampling image signals generated by pixel circuits of an active pixel sensor (APS) image sensor. The APS image sensor supports a normal mode of operation and a sub-sampling mode of operation. The method includes providing a plurality of column amplifiers. A row of pixels circuits to sample is selected. Image signals from each pixel circuit in the selected row are routed to a different one of the plurality of column amplifiers when the APS image sensor is in the normal mode of operation. Image signals from a plurality of the pixel circuits in the selected row are routed to one of the plurality of column amplifiers when the APS image sensor is in the sub-sampling mode of operation.

Abstract: A ground referenced pixel reset circuit is disclosed. The ground referenced pixel reset circuit supplies a pixel with a reset signal such that when the reset signal is asserted high, the reset signal is at a ground referenced reset voltage independent from a supply voltage. The pixel includes a photosensor, such as a photodiode, that is coupled to a ground having a same potential as the ground of the reference voltage supply. In this manner, noise caused by fluctuations in the supply voltage is reduced.

Abstract: A pixel column amplifier architecture creates a reduced noise differential image signal from an pixel sensor array. The pixel column amplifier architecture comprises a first double sampling (DS) circuit and a second DS circuit that has the same configuration as the first DS circuit. An image signal containing a combination of noise components created on a substrate is coupled to the first DS circuit. A reference image signal, held in a reset state, represents the noise component of the image signal and is coupled to the second DS circuit. Further, a reference voltage source is coupled to a reference input of both the first DS and the second DS circuits. The first DS circuit provides the first side of the differential image signal, and the second DS circuit provides the second side of the differential image signal.

Abstract: A drive circuit that produces an over-voltage signal and protects circuit components from the over-voltage signal (i.e., such that circuit components operate within process specification limits). A photosensitive pixel cell can be driven by the drive circuit. Use of the drive circuit increases dynamic range of the pixel cell and reduces “ghost images.” Control logic selectively passes an over-voltage signal to individual rows of a 2-D pixel array.

Abstract: A drive circuit that produces an over-voltage signal and protects circuit components from the over-voltage signal (i.e., such that circuit components operate within process specification limits). A photosensitive pixel cell can be driven by the drive circuit. Use of the drive circuit increases dynamic range of the pixel cell and reduces "ghost images." Control logic selectively passes an over-voltage signal to individual rows of a 2-D pixel array.