Abstract: A method of image sensor package fabrication includes providing an image sensor, including a pixel array disposed in a semiconductor material, and a transparent shield adhered to the semiconductor material. The pixel array is disposed between the semiconductor material and the transparent shield. The method further includes removing portions of the transparent shield to form recessed regions in the transparent shield, where lateral bounds of the transparent shield extend beyond lateral bounds of the pixel array, and wherein the recessed regions are disposed in portions of the transparent shield that extend beyond the lateral bounds of the pixel array. The recessed regions are filled with a light blocking layer.

Abstract: A method of image sensor package fabrication includes providing an image sensor, including a pixel array disposed in a semiconductor material, and a first transparent shield adhered to the semiconductor material. The pixel array is disposed between the semiconductor material and the first transparent shield. A light blocking layer is deposited and disposed between lateral edges of the pixel array and lateral edges of the first transparent shield, and a second transparent shield is placed on the image sensor package, where the light blocking layer is disposed between the first transparent shield and the second transparent shield.

Abstract: Disclosed aspects relate to image processing. An image includes one or more original objects and an original background. The image has a first resolution. A first object having a second resolution is obtained. The second resolution is not higher than the first resolution. The first object is corresponds to at least one of the one or more original objects. A first background with a third resolution is obtained. The third resolution is lower than the second resolution. The first background corresponds to a portion of the image which includes at least the original background. The first object and the first background are sent to a user to display a processed image.

Abstract: Approaches presented herein enable displaying a barrage message. Specifically, one or more objects and location information for each object in a frame of a video are identified. A barrage message to be displayed in the frame of the video is obtained. The barrage message is displayed without covering any object in the frame.

Abstract: A PDAF imaging system includes an image sensor and an image data processing unit. The image sensor has an asymmetric-microlens PDAF detector that includes: (a) a plurality of pixels forming a sub-array having at least two rows and two columns, and (b) a microlens located above each of the plurality of pixels and being rotationally asymmetric about an axis perpendicular to the sub-array. The axis intersects a local extremum of a top surface of the microlens. The image data processing unit is capable of receiving electrical signals from each of the plurality of pixels and generating a PDAF signal from the received electrical signals. A method for forming a gull-wing microlens includes forming, on a substrate, a plate having a hole therein. The method also includes reflowing the plate.

Abstract: A liquid crystal display includes a display area and a border area at least partially surrounding the display area, where the display area displays images for viewing and the border area displays display-protection images, which are used to control ion migration in the liquid crystal layer. In a more particular embodiment, the border area displays a series of checkerboard pattern(s), where the checkerboard patterns can alternate between initial and inverted values. The display-protection images protect the liquid crystal display from migrating ions accumulating in particular regions of the pixel array and causing permanent defects in the display area. A liquid crystal display that includes a liquid crystal alignment layer having a plurality of liquid crystal alignment directions is also disclosed. The customized liquid crystal alignment director(s) over the border area promote ion migration away from the display area.

Abstract: A liquid crystal display includes a display area and a border area at least partially surrounding the display area, where the display area displays images for viewing and the border area displays display-protection images, which are used to control ion migration in the liquid crystal layer. In a more particular embodiment, the border area displays a series of checkerboard pattern(s), where the checkerboard patterns can alternate between initial and inverted values. The display-protection images protect the liquid crystal display from migrating ions accumulating in particular regions of the pixel array and causing permanent defects in the display area. A liquid crystal display that includes a liquid crystal alignment layer having a plurality of liquid crystal alignment directions is also disclosed. The customized liquid crystal alignment director(s) over the border area promote ion migration away from the display area.

Abstract: An image sensor package includes an image sensor with a pixel array disposed in a semiconductor material. A first transparent shield is adhered to the semiconductor material, and the pixel array is disposed between the semiconductor material and the first transparent shield. The image sensor package further includes a second transparent shield, where the first transparent shield is disposed between the pixel array and the second transparent shield. A light blocking layer is disposed between the first transparent shield and the second transparent shield, and the light blocking layer is disposed to prevent light from reflecting off edges of the first transparent shield into the pixel array.

Abstract: An image sensor includes first and second pluralities of photodiodes interspersed among each other in a semiconductor substrate. Incident light is to be directed through a surface of the semiconductor substrate into the first and second pluralities of photodiodes. The first plurality of photodiodes has greater sensitivity to the incident light than the second plurality of photodiodes. A metal film layer is disposed over the surface of the semiconductor substrate over the second plurality of photodiodes and not over the first plurality of photodiodes. A metal grid is disposed over the surface of the semiconductor substrate, and includes a first plurality of openings through which the incident light is directed into the first plurality of photodiodes. The metal grid further includes a second plurality of openings through which the incident light is directed through the metal film layer into the second plurality of photodiodes.

Abstract: An alignment layer for a liquid crystal on silicon (LCOS) display includes a nano-particle layer. In a particular embodiment the nano-particle layer includes a lower nano-layer and an upper nano-layer, each formed onto oxide layers of the LCOS display. In a more particular embodiment, the lower nano-layer and the upper nano-layer are offset printed onto the oxide layers.

Abstract: A PDAF imaging system includes an image sensor and an image data processing unit. The image sensor has an asymmetric-microlens PDAF detector that includes: (a) a plurality of pixels forming a sub-array having at least two rows and two columns, and (b) a microlens located above each of the plurality of pixels and being rotationally asymmetric about an axis perpendicular to the sub-array. The axis intersects a local extremum of a top surface of the microlens. The image data processing unit is capable of receiving electrical signals from each of the plurality of pixels and generating a PDAF signal from the received electrical signals. A method for forming a gull-wing microlens includes forming, on a substrate, a plate having a hole therein. The method also includes reflowing the plate.

Abstract: A stacked-filter image-sensor spectrometer includes an image sensor, a first color filter array, and a second color filter array. The image sensor has a pixel array including a plurality of pixels. The first color filter array has a plurality of first color filters, wherein each first color filter is located above at least one pixel. The second color filter array is located between the first color filter array and the image sensor and has a plurality of second color filters. Each second color filter is located above at least one pixel. Each of the plurality of pixels has thereabove a compound color filter formed of one of the second color filters and one of the first color filters, the second filter having a second passband that partially overlaps a first passband of the first color filter in a first overlapping wavelength range.

Abstract: A novel method of forming an alignment layer of a liquid crystal display device includes the steps of providing a substrate (e.g., a processed silicon wafer, etc.) having an alignment layer material deposited thereon and applying a series of pulses from a pulse laser to anneal portions of the alignment layer material and alter its surface morphology. The method can include the step of depositing the alignment layer material (e.g., a spin-on dielectric including SiO2) over the substrate using a spin-on process prior to laser annealing. Applying the series of laser pulses creates a repetitive pattern of features that facilitate alignment of liquid crystals according to a laser scan trace. Liquid crystal display devices with laser-annealed alignment layer(s) are also disclosed. The alignment layers of the invention are quickly and inexpensively applied and are very robust under prolonged, high-intensity light stress.

Abstract: Disclosed aspects relate to image processing. An image includes one or more original objects and an original background. The image has a first resolution. A first object having a second resolution is obtained. The second resolution is not higher than the first resolution. The first object is corresponds to at least one of the one or more original objects. A first background with a third resolution is obtained. The third resolution is lower than the second resolution. The first background corresponds to a portion of the image which includes at least the original background. The first object and the first background are sent to a user to display a processed image.

Abstract: Methods and systems for improving content accessibility include retrieving an accessibility tag for a piece of content. The piece of content is modified with the accessibility tag to enable one or more accessibility features for the piece of content. The piece of content is then rendered with the accessibility features.

Abstract: An image sensor package includes an image sensor with a pixel array disposed in a semiconductor material. A first transparent shield is adhered to the semiconductor material, and the pixel array is disposed between the semiconductor material and the first transparent shield. The image sensor package further includes a second transparent shield, where the first transparent shield is disposed between the pixel array and the second transparent shield. A light blocking layer is disposed between the first transparent shield and the second transparent shield, and the light blocking layer is disposed to prevent light from reflecting off edges of the first transparent shield into the pixel array.

Abstract: A color filter array includes a plurality of tiled minimal repeating units, each minimal repeating unit comprising an M×N set of individual filters. Each minimal repeating unit includes a plurality of imaging filters including individual filters having at least first, second, and third photoresponses, and at least one reference filter having a reference photoresponse, wherein the reference filter is positioned among the imaging filters and wherein the reference photoresponse transmits substantially the same percentage of wavelengths that remain unfiltered by filters of a different photoresponse than the incident wavelength. Other embodiments are disclosed and claimed.

Abstract: A novel head mounted display includes a display/image sensor. In a particular embodiment the display/image sensor is formed on a single silicon die, which includes display pixels and light sensor pixels. The display pixels and light sensor pixels are each arranged in rows and columns, and the arrays of light sensor pixels and display pixels are interlaced. The center of each light sensor pixel is located between adjacent rows and adjacent columns of display pixels.

Abstract: A method of fabricating an image system includes forming a first wafer that includes a first semiconductor substrate and a first interconnect layer. A pixel array is formed in an imaging region of the first semiconductor substrate and a first insulation-filled trench is formed in a peripheral circuit region of the first semiconductor substrate. Additionally, a second wafer is formed that includes a second semiconductor substrate and a second interconnect layer. A second insulation-filled trench is formed in a second semiconductor substrate, and the first wafer is bonded to the second wafer. A third interconnect layer of a third wafer is bonded to the second wafer. At least one deep via cavity is formed through the first and second interconnect layers and through the first and second insulation-filled trenches. The at least one deep via cavity is filled with a conductive material to form a deep via.

Abstract: An image sensor includes first and second pluralities of photodiodes interspersed among each other in a semiconductor substrate. Incident light is to be directed through a surface of the semiconductor substrate into the first and second pluralities of photodiodes. The first plurality of photodiodes has greater sensitivity to the incident light than the second plurality of photodiodes. A metal film layer is disposed over the surface of the semiconductor substrate over the second plurality of photodiodes and not over the first plurality of photodiodes. A metal grid is disposed over the surface of the semiconductor substrate, and includes a first plurality of openings through which the incident light is directed into the first plurality of photodiodes. The metal grid further includes a second plurality of openings through which the incident light is directed through the metal film layer into the second plurality of photodiodes.