Abstract: An image sensor includes an optical sensor region, a stack of dielectric and metal layers, and an embedded layer. The optical sensor is disposed within a semiconductor substrate. The stack of dielectric and metal layers are disposed on the front side of the semiconductor substrate above the optical sensor region. The embedded focusing layer is disposed on the backside of the semiconductor substrate in a Backside Illuminated (BSI) image sensor, supported by a support grid, or a support grid composed of the semiconductor substrate.

Abstract: An example image sensor includes first, second, and third micro-lenses. The first micro-lens is in a first color pixel and has a first curvature and a first height. The second micro-lens is in a second color pixel and has a second curvature and a second height. The third micro-lens is in a third color pixel and has a third curvature and a third height. The first curvature is the same as both the second curvature and the third curvature and the first height is greater than the second height and the second height is greater than the third height, such that light absorption depths for the first, second, and third color pixels are the same.

Abstract: A method of operation of a backside illuminated (BSI) pixel array includes acquiring an image signal with a first photosensitive region of a first pixel within the BSI pixel array. The image signal is generated in response to light incident upon a backside of the first pixel. The image signal acquired by the first photosensitive region is transferred to pixel circuitry of the first pixel disposed on a frontside of the first pixel opposite the backside. The pixel circuitry at least partially overlaps the first photosensitive region of the first pixel and extends over die real estate above a second photosensitive region of a second pixel adjacent to the first pixel such that the second pixel donates die real estate unused by the second pixel to the first pixel to accommodate larger pixel circuitry than would fit within the first pixel.

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: A backside illuminated (“BSI”) complementary metal-oxide semiconductor (“CMOS”) image sensor includes a photosensitive region disposed within a semiconductor layer and a stress adjusting layer. The photosensitive region is sensitive to light incident on a backside of the BSI CMOS image sensor to collect an image charge. The stress adjusting layer is disposed on a backside of the semiconductor layer to establish a stress characteristic that encourages photo-generated charge carriers to migrate towards the photosensitive region.

Abstract: A backside illuminated imaging sensor includes a vertical stacked sensor that reduces cross talk by using different silicon layers to form photodiodes at separate levels within a stack (or separate stacks) to detect different colors. Blue light-, green light-, and red light-detection silicon layers are formed, with the blue light detection layer positioned closest to the backside of the sensor and the red light detection layer positioned farthest from the backside of the sensor. An anti-reflective coating (ARC) layer can be inserted in between the red and green light detection layers to reduce the optical cross talk captured by the red light detection layer. Amorphous polysilicon can be used to form the red light detection layer to boost the efficiency of detecting red light.

Abstract: A color image sensor is disclosed. The color image sensor includes a pixel array including a color filter array (“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 and second color filter elements of a second color overlaying a second group of the photo-sensors. The first color filter elements contribute to a first color channel of the color image and the second color filter elements contribute to a second color channel of the color image. The color image sensor further includes a color combiner unit coupled to combine the first color channel with the second color channel to generate a third color channel of the color image based on the first and second color channels. An output port is coupled to the pixel array to output the color image having three color channels including the first, second, and third color channels.

Abstract: An apparatus and technique for fabricating an image sensor including the dark sidewall films disposed between adjacent color filters. The image sensor further includes an array of photosensitive elements disposed in a substrate layer, a color filter array (“CFA”) including CFA elements having at least two different colors disposed on a light incident side of the substrate layer, and an array of microlenses disposed over the CFA. Each microlens is aligned to direct light incident on the light incident side of the image sensor through a corresponding CFA element to a corresponding photosensitive element. The dark sidewall films are disposed on sides of the CFA elements and separate adjacent ones of the CFA elements having different colors.

Abstract: A backside illuminated (“BSI”) imaging sensor pixel includes a photodiode region and pixel circuitry. The photodiode region is disposed within a semiconductor die for accumulating an image charge in response to light incident upon a backside of the BSI imaging sensor pixel. The pixel circuitry includes transistor pixel circuitry disposed within the semiconductor die between a frontside of the semiconductor die and the photodiode region. At least a portion of the pixel circuitry overlaps the photodiode region.

Abstract: Embodiments of an apparatus comprising a pixel array comprising a plurality of macropixels. Each macropixel includes a pair of first pixels each including a color filter for a first color, the first color being one to which pixels are most sensitive, a second pixel including a color filter for a second color, the second color being one to which the pixels are least sensitive and a third pixel including a color filter for a third color, the third color being one to which pixels have a sensitivity between the least sensitive and the most sensitive, wherein the first pixels each occupy a greater proportion of the light-collection area of the macropixel than either the second pixel or the third pixel. Corresponding process and system embodiments are disclosed and claimed.

Abstract: An image sensor having a plurality of micro-lenses disposed on a semiconductor substrate. A first micro-lens has a different focal length, height, shape, curvature, thickness, etc., than a second micro-lens. The image sensor may be back side illuminated or front side illuminated.

Abstract: Embodiments of a method for separating dies from a wafer having first and second sides. The process embodiment includes masking the first side of the wafer, the mask including openings therein to expose parts of the first side substantially aligned with scribe lines of the wafer. The process embodiment also includes etching from the exposed parts of the first side of the wafer until an intermediate position between the first and second sides and sawing the remainder of the wafer, starting from the intermediate position until reaching the second surface.

Abstract: A backside illuminated imaging sensor includes a vertical stacked sensor that reduces cross talk by using different silicon layers to form photodiodes at separate levels within a stack (or separate stacks) to detect different colors. Blue light-, green light-, and red light-detection silicon layers are formed, with the blue light detection layer positioned closest to the backside of the sensor and the red light detection layer positioned farthest from the backside of the sensor. An anti-reflective coating (ARC) layer can be inserted in between the red and green light detection layers to reduce the optical cross talk captured by the red light detection layer. Amorphous polysilicon can be used to form the red light detection layer to boost the efficiency of detecting red light.

Abstract: A technique for fabricating an image sensor including a pixel circuitry region and a peripheral circuitry region includes fabricating front side components on a front side of the image sensor. A dopant layer is implanted on a backside of the image sensor. A anti-reflection layer is formed on the backside and covers a first portion of the dopant layer under the pixel circuitry region while exposing a second portion of the dopant layer under the peripheral circuitry region. The first portion of the dopant layer is laser annealed from the backside of the image sensor through the anti-reflection layer. The anti-reflection layer increases a temperature of the first portion of the dopant layer during the laser annealing.

Abstract: Embodiments of a process for forming a photodetector region in a CMOS pixel by dopant implantation, the process comprising masking a photodetector area of a surface of a substrate for formation of the photodetector region, positioning the substrate at a plurality of twist angles, and at each of the plurality of twist angles, directing dopants at the photodetector area at a selected tilt angle. Embodiments of a CMOS pixel comprising a photodetector region formed in a substrate, the photodetector region comprising overlapping first and second dopant implants, wherein the overlap region has a different dopant concentration than the non-overlapping parts of the first and second implants, a floating diffusion formed in the substrate, and a transfer gate formed on the substrate between the photodetector and the transfer gate. Other embodiments are disclosed and claimed.

Abstract: An apparatus of one aspect includes a photodetector array, and a peripheral region at a periphery of the photodetector array. A thinner interconnect line corresponding to the photodetector array is disposed within one or more insulating layers. A thicker interconnect line corresponding to the peripheral region is disposed within the one or more insulating layers. Other apparatus, methods, and systems are also disclosed.

Abstract: An imaging system capable of black level calibration includes an imaging pixel array, at least one black reference pixel, and peripheral circuitry. The imaging pixel array includes a plurality of active pixels each coupled to capture image data. The black reference pixel is coupled to generate a black reference signal for calibrating the image data. Light transmitting layers are disposed on a first side of a pixel array die including the imaging system and cover at least the imaging pixel array and the black reference pixel. A light shielding layer is disposed on the first side of the pixel array die and covers a portion of the light transmitting layers and the black reference pixel without covering the imaging pixel array.

Abstract: A backside illuminated imaging sensor includes a semiconductor layer, a metal interconnect layer and a silicide light reflecting layer. The semiconductor layer has a front surface and a back surface. An imaging pixel that includes a photodiode region is formed within the semiconductor layer. The metal interconnect layer is electrically coupled to the photodiode region and the silicide light reflecting layer is coupled between the metal interconnect layer and the front surface of the semiconductor layer. In operation, the photodiode region receives light from the back surface of the semiconductor layer, where a portion of the received light propagates through the photodiode region to the silicide light reflecting layer. The silicide light reflecting layer is configured to reflect the portion of light received from the photodiode region.

Abstract: An example method of forming a pinned photodiode includes applying a photoresist mask to a semiconductor layer at a location where a transfer gate will subsequently be formed. First dopant ions are then implanted at a first angle to form a first dopant region under an edge of the photoresist mask. Next, a photoresist mask is etched such that a thickness of the photoresist mask is reduced to form a trimmed photoresist mask. Second dopant ions are then implanted at a second angle to form a second dopant region, wherein the second dopant ions are shadowed by the trimmed photoresist mask to exclude the second dopant ions from a region partially above the first dopant region and adjacent to an edge of the trimmed photoresist mask.

Abstract: An image sensor pixel includes a substrate doped to have a first conductivity type. A first epitaxial layer is disposed over the substrate and doped to also have the first conductivity type. A transfer transistor gate is formed on the first epitaxial layer. An epitaxially grown photo-sensor region is disposed in the first epitaxial layer and has a second conductivity type. The epitaxially grown photo-sensor region includes an extension region that extends under a portion of the transfer transistor gate.