Abstract: A back-illuminated image sensor includes a sensor layer of a first conductivity type having a frontside and a backside opposite the frontside. An insulating layer is disposed over the backside. A circuit layer is formed adjacent to the frontside such that the sensor layer is positioned between the circuit layer and the insulating layer. One or more frontside regions of a second conductivity type are formed in at least a portion of the frontside of the sensor layer. A backside region of the second conductivity type is formed in the backside of the sensor layer. A plurality of frontside photodetectors of the first conductivity type is disposed in the sensor layer. A distinct plurality of backside photodetectors of the first conductivity type separate from the plurality of frontside photodetectors is formed in the sensor layer contiguous to portions of the backside region of the second conductivity type.

Abstract: A back-illuminated image sensor includes a sensor layer of a first conductivity type having a frontside and a backside opposite the frontside. One or more frontside regions of the first conductivity type are formed in at least a portion of the frontside of the sensor layer. A backside region of the first conductivity type is formed in the backside of the sensor layer. A plurality of frontside photodetectors of a second conductivity type is disposed in the sensor layer adjacent to the frontside of the sensor layer. A distinct plurality of backside photodetectors of the second conductivity type separate from the plurality of frontside photodetectors are formed in the sensor layer contiguous to the backside region. One or more or more channel regions of the second conductivity type are disposed in respective portions of the sensor layer between the frontside photodetector and the backside photodetector in each photodetector pair.

Abstract: A back-illuminated image sensor includes a sensor layer of a first conductivity type having a frontside and a backside opposite the frontside. One or more frontside regions of a second conductivity type are formed in at least a portion of the frontside of the sensor layer. A backside region of the second conductivity type is formed in the backside of the sensor layer. A plurality of frontside photodetectors of the first conductivity type is disposed in the sensor layer. A distinct plurality of backside photodetectors of the first conductivity type separate from the plurality of frontside photodetectors are formed in the sensor layer contiguous to portions of the region of the second conductivity type. A voltage terminal is disposed on the frontside of the sensor layer. One or more connecting regions of the second conductivity type are disposed in respective portions of the sensor layer between the voltage terminal and the backside region for electrically connecting the voltage terminal to the backside region.

Abstract: A vertically-integrated image sensor includes a sensor wafer connected to a support circuit wafer. Each pixel region on the sensor wafer includes a photodetector, a charge-to-voltage conversion mechanism, a transfer mechanism for transferring charge from the photodetector to the charge-to-voltage conversion mechanism, and a reset mechanism for discharging the charge-to-voltage conversion mechanism. The support circuit wafer includes an amplifier and other support circuitry for each pixel region on the sensor wafer. An inter-wafer connector directly connects each charge-to-voltage mechanism on the sensor wafer to a respective gate to an amplifier on the support circuit wafer.

Abstract: A back-illuminated image sensor includes a sensor layer having a frontside and a backside opposite the frontside. An insulating layer is situated adjacent the backside and a circuit layer is adjacent the frontside. A plurality of photodetectors of a first type conductivity convert light incident on the backside into photo-generated charges. The photodetectors are disposed in the sensor layer adjacent the frontside. A region of a second type conductivity is formed in at least a portion of the sensor layer adjacent the frontside and is connected to a voltage terminal for biasing the second type conductivity region at a predetermined voltage. A well of the second type conductivity is formed in the sensor layer adjacent the backside. Trench isolations in the sensor layer start at the frontside and extend beyond the depletion region of the photodiodes.

Abstract: A method of forming a charge-coupled device including the steps of forming well or substrate of a first conductivity type; a buried channel of a second conductivity type; a plurality of first gate electrodes; partially coating the first gate electrodes with a mask substantially aligned to an edge of the first gate electrodes; implanting ions of the first conductivity type of sufficient energy to penetrate the first gates and into the buried channel; and a plurality of second gate electrodes covering regions each over the buried channel between the first gate electrodes.

Abstract: A CMOS image sensor or other type of image sensor comprises a sensor wafer and an underlying circuit wafer. The sensor wafer comprises a plurality of photosensitive elements arranged in respective positions of a two-dimensional array of positions in which a subset of the array positions do not include photosensitive elements but instead include diffusion regions each of which is shared by two or more of the photosensitive elements. The sensor wafer is interconnected with the circuit wafer utilizing a plurality of inter-wafer interconnects coupled to respective ones of the shared diffusion regions in respective ones of the array positions that do not include photosensitive elements. The image sensor may be implemented in a digital camera or other type of image capture device.

Abstract: An image sensor includes one or more ultraviolet (UV) light filter layers disposed between an insulating layer and a color filter array (CFA) layer. The one or more UV light filter layers reflect or absorb UV light while transmitting visible light.

Abstract: A back-illuminated image sensor includes a sensor layer having a frontside and a backside opposite the frontside. An insulating layer is situated adjacent the backside and a circuit layer is adjacent the frontside. A plurality of photodetectors of a first type conductivity convert light incident on the backside into photo-generated charges. The photodetectors are disposed in the sensor layer adjacent the frontside. A region of a second type conductivity is formed in at least a portion of the sensor layer adjacent the frontside and is connected to a voltage terminal for biasing the second type conductivity region at a predetermined voltage. A well of the second type conductivity is formed in the sensor layer adjacent the backside. Trench isolations in the sensor layer start at the frontside and extend beyond the depletion region of the photodiodes.

Abstract: An image sensor includes a substrate with a plurality of photosensitive elements. A transparent inorganic layer is situated over the substrate, and a plurality of openings is formed in the transparent inorganic layer. A color filter array has a plurality of panchromatic filter elements that are formed by the transparent inorganic layer, and a plurality of color filter elements are situated in the openings. The panchromatic filter elements and the color filter elements each include top surfaces that are essentially planar with the top surface of the transparent inorganic layer.

Abstract: An image sensor and associated image capture device and method include a sensing wafer with a plurality of charge storage elements. One or more floating diffusions are associated with the plurality of charge storage elements, and charge is transferred among the charge storage elements to the one or more floating diffusions. The one or more floating diffusions on the sensing wafer are electrically connected to support circuitry on a circuit wafer.

Abstract: A back-illuminated image sensor includes a sensor layer disposed between an insulating layer and a circuit layer electrically connected to the sensor layer. An imaging area includes a plurality of photodetectors is formed in the sensor layer and a well that spans the imaging area. The well can be disposed between the backside of the sensor layer and the photodetectors, or the well can be a buried well formed adjacent to the backside of the sensor layer with a region including formed between the photodetectors and the buried well. One or more side wells can be formed laterally adjacent to each photodetector. The dopant in the well has a segregation coefficient that causes the dopant to accumulate on the sensor layer side of an interface between the sensor layer and the insulating layer.

Abstract: An image sensor includes an array of pixels comprising a plurality of kernels that repeat periodically and each kernel includes n photosensitive regions for collecting charge in response to light, n is equal to or greater than 2; and a transparent layer spanning the photosensitive regions having n optical paths, at least two of which are different, wherein each optical path directs light of a predetermined spectral band into specific photosensitive regions.

Abstract: An image sensor includes a first sensor layer having a first array of pixels and a second sensor layer having a second array of pixels. Each of the pixels has an optical center. The first sensor layer is stacked over the second sensor layer such that the optical centers of the first array of pixels are offset from the optical centers of the second array to form a predetermined pattern.

Abstract: An image sensor includes (a) a first wafer having (i) a photosensitive area; (ii) a charge-to-voltage conversion region; (b) a second wafer having (i) a first amplifier that receives a signal from the charge-to-voltage conversion region; (c) an electrical interconnect connecting the charge-to-voltage conversion region to an input of the amplifier; (d) an electrically biased shield at least partially enclosing at least a portion of the electrical interconnect.

Abstract: An image sensor includes a first sensor layer having a first array of pixels and a second sensor layer having a second array of pixels. Each pixel of the first and second arrays has a photodetector for collecting charge in response to incident light, a charge-to-voltage conversion mechanism, and a transfer gate for selectively transferring charge from the photodetector to the charge-to-voltage mechanism. The first and second sensor layers each have a thicknesses to collect light with a first and second preselected ranges of wavelengths, respectively. A circuit layer is situated below the first sensor layer and has support circuitry for the pixels of the first and second sensor layers, and interlayer connectors are between the pixels of the first and second layers and the support circuitry.

Abstract: A backside illuminated image sensor comprises a sensor layer implementing a plurality of photosensitive elements of a pixel array, and an oxide layer adjacent a backside surface of the sensor layer. The sensor layer comprises a seed layer and an epitaxial layer formed over the seed layer, with the seed layer having a cross-sectional doping profile in which a designated dopant is substantially confined to a pixel array area of the sensor layer. The doping profile advantageously reduces dark current generated at an interface between the sensor layer and the oxide layer. The image sensor may be implemented in a digital camera or other type of digital imaging device.

Abstract: A vertically-integrated image sensor includes a sensor wafer connected to a support circuit wafer. Each pixel region on the sensor wafer includes a photodetector, a charge-to-voltage conversion mechanism, a transfer mechanism for transferring charge from the photodetector to the charge-to-voltage conversion mechanism, and a reset mechanism for discharging the charge-to-voltage conversion mechanism. The support circuit wafer includes an amplifier and other support circuitry for each pixel region on the sensor wafer. An inter-wafer connector directly connects each charge-to-voltage mechanism on the sensor wafer to a respective gate to an amplifier on the support circuit wafer.

Abstract: A CMOS image sensor or other type of image sensor comprises a sensor wafer and an underlying circuit wafer. The sensor wafer comprises a plurality of photosensitive elements arranged in respective positions of a two-dimensional array of positions in which a subset of the array positions do not include photosensitive elements but instead include diffusion regions each of which is shared by two or more of the photosensitive elements. The sensor wafer is interconnected with the circuit wafer utilizing a plurality of inter-wafer interconnects coupled to respective ones of the shared diffusion regions in respective ones of the array positions that do not include photosensitive elements. The image sensor may be implemented in a digital camera or other type of image capture device.

Abstract: An image sensor includes a plurality of pixels for converting incident photons into electrical charge; an overflow drain to draw off excess charge from at one or more of the pixels; a mechanism for summing charge from two or more of the pixels; a first network of resistive devices generating a first overflow drain voltage where at least one of the resistive devices has, in parallel, a fuse that can be opened in response to an external stimulus to provide the optimum overflow drain voltage for pixel anti-blooming protection and saturation signal level for when a plurality of pixels are summed together; and a second network of resistive devices connected to the first network of resistive devices generating a second overflow drain voltage where the second overflow drain voltage is a fraction of the first overflow drain voltage and the second overflow drain voltage provides the optimum overflow drain voltage for pixel anti-blooming and saturation signal level for when none or substantially none of the plurality o