Abstract: A color image sensor includes a pixel array including CFA overlaying an array of photo-sensors for acquiring color image data. The CFA includes first color filter elements of a first color overlaying a first group of the photo-sensors and second color filter elements of a second color overlaying a second group of the photo-sensors. The first group of photo-sensors generate first color signals of a first color channel and the second group of photo-sensors generate second color signals of a second color channel. The color image sensor further includes a color signal combiner circuit (“CSCC”) coupled to receive the first and second color signals output from the pixel array. The CSCC includes a combiner coupled to combine the first and second colors signals to generate third color signals of a third color channel. An output port is coupled to the CSCC to output the color image data.

Abstract: Techniques and mechanisms for a pixel array to provide a level of conversion gain. In an embodiment, the pixel array includes conversion gain control circuitry to be selectively configured at different times for different operational modes, each mode for implementing a respective conversion gain. The conversion gain control circuitry selectively provides switched coupling of the pixel cell to—and/or switched decoupling of the pixel cell from—a supply voltage. In another embodiment, the conversion gain control circuitry selectively provides switched coupling of the pixel cell to—and/or switched decoupling of the pixel cell from—sample and hold circuitry.

Abstract: An image sensor pixel includes a photosensitive element, a floating diffusion (“FD”) region, and a transfer device. The photosensitive element is disposed in a substrate layer for accumulating an image charge in response to light. The FD region is disposed in the substrate layer to receive the image charge from the photosensitive element. The transfer device is disposed between the photosensitive element and the FD region to selectively transfer the image charge from the photosensitive element to the FD region. The transfer device includes a gate, a buried channel dopant region and a surface channel region. The gate is disposed between the photosensitive element and the FD region. The buried channel dopant region is disposed adjacent to the FD region and underneath the gate. The surface channel region is disposed between the buried channel dopant region and the photosensitive element and disposed underneath the gate.

Abstract: A backside illuminated imaging sensor includes a semiconductor substrate having a front surface and a back surface. The semiconductor substrate has at least one imaging array formed on the front surface. The imaging sensor also includes a carrier substrate to provide structural support to the semiconductor substrate, where the carrier substrate has a first surface coupled to the front surface of the semiconductor substrate. A re-distribution layer is formed between the front surface of the semiconductor substrate and the second surface of the carrier substrate to route electrical signals between the imaging array and a second surface of the carrier substrate.

Abstract: Techniques and mechanisms for improving full well capacity for pixel structures in an image sensor. In an embodiment, a first pixel structure of the image sensor includes an implant region, where a skew of the implant region corresponds to an implant angle, and a second pixel structure of the image sensor includes a transfer gate. In another embodiment, an offset of the implant region of the first pixel structure from the transfer gate of the second pixel structure corresponds to the implant angle.

Abstract: Embodiments of an apparatus including a color filter arrangement formed on a substrate having a pixel array formed therein. The color filter arrangement includes a clear filter having a first clear hard mask layer and a second clear hard mask layer formed thereon, a first color filter having the first clear hard mask layer and the second hard mask layer formed thereon, a second color filter having the first clear hard mask layer formed thereon, and a third color filter having no clear hard mask layer formed thereon. Other embodiments are disclosed and claimed.

Abstract: A backside illuminated image sensor includes a semiconductor layer and a trench disposed in the semiconductor layer. The semiconductor layer has a frontside surface and a backside surface. The semiconductor layer includes a light sensing element of a pixel array disposed in a sensor array region of the semiconductor layer. The pixel array is positioned to receive external incoming light through the backside surface of the semiconductor layer. The semiconductor layer also includes a light emitting element disposed in a periphery circuit region of the semiconductor layer external to the sensor array region. The trench is disposed in the semiconductor layer between the light sensing element and the light emitting element. The trench is positioned to impede a light path between the light emitting element and the light sensing element when the light path is internal to the semiconductor layer.

Abstract: An image sensor includes a photosensitive region disposed within a semiconductor layer and a stress adjusting layer. The photosensitive region is sensitive to light incident through a first side of the image sensor to collect an image charge. The stress adjusting layer is disposed over the first side of the semiconductor layer to establish a stress characteristic that encourages photo-generated charge carriers to migrate towards the photosensitive region.

Abstract: An integrated circuit system includes a first device wafer bonded to a second device wafer at a bonding interface of dielectrics. Each wafer includes a plurality of dies, where each die includes a device, a metal stack, and a seal ring that is formed at an edge region of the die. Seal rings included in dies of the second device wafer each include a first conductive path provided with metal formed in a first opening that extends from a backside of the second device wafer, through the second device wafer, and through the bonding interface to the seal ring of a corresponding die in the first device wafer.

Abstract: Embodiments of the invention describe providing a compact solution to provide high dynamic range imaging (HDRI or simply HDR) for an imaging pixel by utilizing a control node for resetting a floating diffusion node to a reference voltage value and for selectively transferring an image charge from a photosensitive element to a readout node. Embodiments of the invention further describe control node to have to a plurality of different capacitance regions to selectively increase the overall capacitance of the floating diffusion node. This variable capacitance of the floating diffusion node increases the dynamic range of the imaging pixel, thereby providing HDR for the host imaging system, as well as increasing the signal-to-noise ratio (SNR) of the imaging system.

Abstract: An image sensor pixel includes a photosensitive element, a floating diffusion (“FD”) region, and a transfer device. The photosensitive element is disposed in a substrate layer for accumulating an image charge in response to light. The FD region is dispose in the substrate layer to receive the image charge from the photosensitive element. The transfer device is disposed between the photosensitive element and the FD region to selectively transfer the image charge from the photosensitive element to the FD region. The transfer device includes a gate, a buried channel dopant region and a surface channel region. The gate is disposed between the photosensitive element and the FD region. The buried channel dopant region is disposed adjacent to the FD region and underneath the gate. The surface channel region is disposed between the buried channel dopant region and the photosensitive element and disposed underneath the gate.

Abstract: A monolithic backside-sensor-illumination (BSI) image sensor has a sensor array is tiled with a multiple-pixel cells having a first pixel sensor primarily sensitive to red light, a second pixel sensor primarily sensitive to red and green light, and a third pixel sensor having panchromatic sensitivity, the pixel sensors laterally adjacent each other. The image sensor determines a red, a green, and a blue signal comprising by reading the red-sensitive pixel sensor of each multiple-pixel cell to determine the red signal, reading the sensor primarily sensitive to red and green light to determine a yellow signal and subtracting the red signal to determine a green signal. The image sensor reads the panchromatic-sensitive pixel sensor to determine a white signal and subtracts the yellow signal to provide the blue signal.

Abstract: A color image sensor includes a pixel array including a CFA overlaying an array of photo-sensors for acquiring a color image. The CFA includes first color filter elements of a first color overlaying a first group of the photo-sensors, second color filter elements of a second color overlaying a second group of the photo-sensors, and a plurality of filter stacks overlaying a third group of the photo-sensors. The first group generates first color signals of a first color channel and the second group generates second color signals of a second color channel. Each of the filter stacks includes a first stacked filter of the first color and a second stacked filter of the second color. A sensitivity of the filter stacks equals a product of sensitivities of the first and the second stacked filters and the filter stacks generate a third color channel.

Abstract: An image sensor provides high scalability and reduced image lag. The sensor includes a first imaging pixel that has a first photodiode region formed in a substrate of the image sensor. The sensor also includes a first vertical transfer transistor coupled to the first photodiode region. The first vertical transfer transistor can be used to establish an active channel. The active channel typically extends along the length of the first vertical transfer transistor and couples the first photodiode region to a floating diffusion.

Abstract: Embodiments of a pixel including a substrate having a front surface and a photosensitive region formed in or near the front surface of the substrate. An isolation trench is formed in the front surface of the substrate adjacent to the photosensitive region. The isolation trench includes a trench having a bottom and sidewalls, a passivation layer formed on the bottom and the sidewalls, and a filler to fill the portion of the trench not filled by the passivation layer.

Abstract: Embodiments of the invention describe providing high dynamic range imaging (HDRI or simply HDR) to an imaging pixel by coupling a floating diffusion node of the imaging pixel to a plurality of metal-oxide semiconductor (MOS) capacitance regions. It is understood that a MOS capacitance region only turns “on” (i.e., changes the overall capacitance of the floating diffusion node) when the voltage at the floating diffusion node (or a voltage difference between a gate node and the floating diffusion node) is greater than its threshold voltage; before the MOS capacitance region is “on” it does not contribute to the overall capacitance or conversion gain of the floating diffusion node. Each of the MOS capacitance regions will have different threshold voltages, thereby turning “on” at different illumination conditions. This increases the dynamic range of the imaging pixel, thereby providing HDR for the host imaging system.

Abstract: An integrated circuit system includes a first device wafer having a first semiconductor layer proximate to a first metal layer including a first conductor disposed within a first metal layer oxide. A second device wafer having a second semiconductor layer proximate to a second metal layer including a second conductor is disposed within a second metal layer oxide. A frontside of the first device wafer is bonded to a frontside of the second device wafer at a bonding interface. A conductive path couples the first conductor to the second conductor through the bonding interface. A first metal EMI shield is disposed in one of the first metal oxide layer and second metal layer oxide layer. The first EMI shield is included in a metal layer of said one of the first metal oxide layer and the second metal layer oxide layer nearest to the bonding interface.

Abstract: A method of fabricating a backside-illuminated pixel. The method includes forming frontside components of the pixel on or in a front side of a substrate, the frontside components including a photosensitive region of a first polarity. The method further includes forming a pure dopant region of a second polarity on a back side of the substrate, applying a laser pulse to the backside of the substrate to melt the pure dopant region, and recrystallizing the pure dopant region to form a backside doped layer. Corresponding apparatus embodiments are disclosed and claimed.

Abstract: An image sensor pixel includes a photosensitive element having a first doping type disposed in semiconductor material. A deep extension having the first doping type is disposed beneath and overlapping the photosensitive element in the semiconductor material. A floating diffusion is disposed in the semiconductor material. A transfer gate is disposed over a gate oxide that is disposed over the semiconductor material. The transfer gate is disposed between the photosensitive element and the floating diffusion. The photosensitive element and the deep extension are stacked in the semiconductor material in a “U” shape extending from under the transfer gate.

Abstract: An apparatus includes a semiconductor layer having an array of pixels arranged therein. A passivation layer is disposed proximate to the semiconductor layer over the array of pixels. A segmented etch stop layer including a plurality of etch stop layer segments is disposed proximate to the passivation layer over the array of pixels. Boundaries between each one of the plurality of etch stop layer segments are aligned with boundaries between pixels in the array of pixels.