Abstract: An imaging system may include multiple imaging arrays. One or more of the arrays may be a low-power array that detects trigger events in observed scenes and, in response to the detection of a trigger event, activates one or more primary imaging arrays. One or more of the arrays may be a polarization sensing array, a hyperspectral array, a stacked photodiode array, a wavefront sensing array, a monochrome array, a single color array, a dual color array, or a full color array. In at least one embodiment, image data from a stacked photodiode imaging array may be enhanced using image data from a separate monochrome imaging array. In at least another embodiment, image data from a wavefront sensing array may provide focus detection for a full color array.

Abstract: Several embodiments for semiconductor devices and methods for forming semiconductor devices are disclosed herein. One embodiment is directed to a method for manufacturing a microelectronic imager having a die including an image sensor, an integrated circuit electrically coupled to the image sensor, and electrical connectors electrically coupled to the integrated circuit. The method can comprise covering the electrical connectors with a radiation blocking layer and forming apertures aligned with the electrical connectors through a layer of photo-resist on the radiation blocking layer. The radiation blocking layer is not photoreactive such that it cannot be patterned using radiation. The method further includes etching openings in the radiation blocking layer through the apertures of the photo-resist layer.

Abstract: An imaging system may include an image sensor package with through-oxide via connections between the image sensor die and the digital signal processing die in the image sensor package. The image sensor die and the digital signal processing die may be attached to each other. The through-oxide via may connect a bond pad on the image sensor die with metal routing paths in the image sensor and digital signal processing dies. The through-oxide via may simultaneously couple the image sensor die to the digital signal processing die. The through-oxide via may be formed through a shallow trench isolation structure in the image sensor die. The through-oxide via may be formed through selective etching of the image sensor and digital signal processing dies.

Abstract: An imaging system may be used to image a fluid sample containing particles. The imaging system may include a fluid channel that receives the fluid sample and a reactive agent that selectively attaches to target particles in the fluid sample. An activation mechanism may be operated to trigger a chemical reaction between the fluid sample and the reactive agent. The imaging system may include an image sensor integrated circuit and image sensor pixels to capture a detectable effect of the chemical reaction. The image sensor integrated circuit may be synchronized to the activation mechanism such that it captures an image of the fluid sample after the chemical reaction is triggered by the activation mechanism.

Abstract: Several embodiments for semiconductor devices and methods for forming semiconductor devices are disclosed herein. One embodiment is directed to a method for manufacturing a microelectronic imager having a die including an image sensor, an integrated circuit electrically coupled to the image sensor, and electrical connectors electrically coupled to the integrated circuit. The method can comprise covering the electrical connectors with a radiation blocking layer and forming apertures aligned with the electrical connectors through a layer of photo-resist on the radiation blocking layer. The radiation blocking layer is not photoreactive such that it cannot be patterned using radiation. The method further includes etching openings in the radiation blocking layer through the apertures of the photo-resist layer.

Abstract: An image sensor unit may have a backside-illuminated imager and an image co-processor stacked together. The image co-processor may be mounted in a cavity in a permanent carrier. The permanent carrier may include fluid channels that allow cooling fluid to flow past the image co-process and past the imager, thereby removing excess heat generated by the image sensor unit during operation.

Abstract: An array of color filter elements may be formed over an array of photodiodes in an integrated circuit for an imaging device using a carrier substrate. The carrier substrate may have a planar surface with a release layer. A layer of color filter material may be applied to the release layer. The carrier substrate may then be flipped and the layer of color filter material may be bonded to the integrated circuit. Heat may be applied to activate the release layer and the carrier substrate may be removed at the interface between the release layer and the color filter material. The layer of color filter material may be patterned either before bonding the layer of color filter material or after the carrier substrate is removed. A layer of microlenses may be formed over the array of color filter elements using a carrier substrate.

Abstract: An imaging system may include an image sensor package with an image sensor wafer mounted on a carrier wafer, which may be a silicon substrate. A capacitor may be formed in the carrier wafer. Trenches may be etched in a serpentine pattern in the silicon substrate. Conductive plates of the capacitor may be formed at least partially in the trenches. An insulator material may be formed between the capacitor and the silicon substrate. A dielectric layer may be formed between the conductive plates of the capacitor. The image sensor package may be mounted on a printed circuit board via a ball grid array. Conductive vias may electrically couple the capacitor and the image sensor wafer to the printed circuit board.

Abstract: An image sensor die may include a pixel array formed in an image sensor substrate and covered by a transparent cover layer. The transparent cover layer may be attached to the image sensor substrate using adhesive. Electrical interconnect structures such as conductive vias may be formed in the transparent cover layer and may be used in conveying electrical signals between the image sensor and a printed circuit board. The conductive vias may have one end coupled to a bond pad on the upper surface of the transparent cover layer and an opposing end coupled to a bond pad on the upper surface of the image sensor substrate. The conductive vias may pass through openings that extend through the transparent cover layer and the adhesive. Conductive structures such as wire bonds, stud bumps, or solder balls may be coupled to the bond pads on the surface of the transparent cover layer.

Abstract: An imaging system such as an array camera may include an array of image sensors. The image sensors may each include an array of image pixels formed in a common image sensor substrate. A protective glass cover layer may be provided over the array of image sensors. The cover layer may be attached to the image sensor substrate using an adhesive. The adhesive may be formed on the image sensor substrate in a grid-like pattern in between adjacent image sensors in the array. A light blocking material may be formed on the adhesive grid to minimize optical crosstalk between neighboring image sensors. The light blocking material may fill or partially fill a trench in the adhesive, may coat the outer surfaces of the adhesive, and/or may coat the inner surfaces of the adhesive. If desired, light barriers may also be formed in openings in the glass cover layer.

Abstract: An imaging system may include a first image sensor die stacked on top of a second image sensor die. A pixel array may include first pixels having photodiodes in the first image sensor die and second pixels having photodiodes in the second image sensor die. The first pixels may be optimized to detect a first type of electromagnetic radiation (e.g., visible light), whereas the second pixels may be optimized to detect a second type of electromagnetic radiation (e.g., infrared light). Light guide channels may be formed in the first image sensor die to help guide incident light to the photodiodes in the second image sensor substrate. The first and second image sensor dies may be bonded at a wafer level. A first image sensor wafer may be a backside illumination image sensor wafer and a second image sensor wafer may be a front or backside illumination image sensor wafer.

Abstract: A fluid sample analyzing system may be formed from an image sensor integrated circuit substrate. A glass wafer may be used to cover a wafer of image sensors. The glass wafer and the image sensor wafer may be attached using oxide bonding. Fluid channels may be formed in a layer that is interposed between the image sensor wafer and the glass wafer. The layer may be deposited on the image sensor wafer and the glass wafer prior to oxide bonding. A spacer may be used to deliver the fluid channel layer to the image sensor wafer before the glass wafer is bonded to the image sensor wafer. The spacer may be formed from a silicon wafer. The silicon wafer may be bonded to the image sensor wafer and thinned, leaving a thin spacer wafer layer on the image sensor wafer in which fluid channels may be formed.

Abstract: Methods for forming backside illuminated (BSI) image sensors having metal redistribution layers (RDL) and solder bumps for high performance connection to external circuitry are provided. In one embodiment, a BSI image sensor with RDL and solder bumps may be formed using a temporary carrier during manufacture that is removed prior to completion of the BSI image sensor. In another embodiment, a BSI image sensor with RDL and solder bumps may be formed using a permanent carrier during manufacture that partially remains in the completed BSI image sensor. A BSI image sensor may be formed before formation of a redistribution layer on the front side of the BSI image sensor. A redistribution layer may, alternatively, be formed on the front side of an image wafer before formation of BSI components such as microlenses and color filters on the back side of the image wafer.

Abstract: Methods for forming backside illuminated (BSI) image sensors having metal redistribution layers (RDL) and solder bumps for high performance connection to external circuitry are provided. In one embodiment, a BSI image sensor with RDL and solder bumps may be formed using a temporary carrier during manufacture that is removed prior to completion of the BSI image sensor. In another embodiment, a BSI image sensor with RDL and solder bumps may be formed using a permanent carrier during manufacture that partially remains in the completed BSI image sensor. A BSI image sensor may be formed before formation of a redistribution layer on the front side of the BSI image sensor. A redistribution layer may, alternatively, be formed on the front side of an image wafer before formation of BSI components such as microlenses and color filters on the back side of the image wafer.

Abstract: An imaging system may include an image sensor package with an image sensor wafer mounted on a carrier wafer, which may be a silicon substrate. A capacitor may be formed in the carrier wafer. Trenches may be etched in a serpentine pattern in the silicon substrate. Conductive plates of the capacitor may be formed at least partially in the trenches. An insulator material may be formed between the capacitor and the silicon substrate. A dielectric layer may be formed between the conductive plates of the capacitor. The image sensor package may be mounted on a printed circuit board via a ball grid array. Conductive vias may electrically couple the capacitor and the image sensor wafer to the printed circuit board.

Abstract: Method and apparatus providing a wafer level fabrication of imager modules in which a permanent carrier protects imager devices on an imager wafer and is used to support a lens wafer.

Abstract: An image sensor unit may have a backside-illuminated imager and an image co-processor stacked together. The image co-processor may be mounted in a cavity in a permanent carrier. The permanent carrier may include fluid channels that allow cooling fluid to flow past the image co-process and past the imager, thereby removing excess heat generated by the image sensor unit during operation.

Abstract: Some embodiments include methods of forming semiconductor constructions in which a semiconductor material sidewall is along an opening, a protective organic material is over at least one semiconductor material surface, and the semiconductor material sidewall and protective organic material are both exposed to an etch utilizing at least one fluorine-containing composition. The etch is selective for the semiconductor material relative to the organic material, and reduces sharpness of at least one projection along the semiconductor material sidewall. In some embodiments, the opening is a through wafer opening, and subsequent processing forms one or more materials within such through wafer opening to form a through wafer interconnect. In some embodiments, the opening extends to a sensor array, and the protective organic material is comprised by a microlens system over the sensor array. Subsequent processing may form a macrolens structure across the opening.

Abstract: Microfeature workpieces having conductive vias formed by chemically reactive processes, and associated systems and methods are disclosed. A method in accordance with one embodiment includes disposing a conductive lining on walls of a via in a microfeature workpiece, so that a space is located between opposing portions of the lining facing toward each other from opposing portions of the wall. The method can further include chemically reacting the lining with a reactive material to form a chemical compound from a constituent of the reactive material and a constituent of the lining. The method can still further include at least partially filling the space with the compound. In particular embodiments, the conductive lining includes copper, the reactive material includes sulfur hexafluoride, and the chemical compound that at least partially fills the space in the via includes copper sulfide.

Abstract: An image sensor may be provided with an array of imaging pixels. A color filter array may be formed over photosensitive elements in the pixel array. The color filter array may include a Bayer color filter array. Separating material may be interposed between color filter elements of adjacent imaging pixels. The separating material may be relatively low index of refraction material configured to reduce or eliminate optical crosstalk between adjacent imaging pixels. The separating material may be air so that neighboring color filter elements are separated by an air gap. The air gaps may be formed during the color filter array fabrication process by depositing a sacrificial layer on the substrate, forming openings in the sacrificial layer, forming color filter elements in the openings, and removing remaining portions of the sacrificial layer that are formed between the color filter elements.