Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: Methods, devices, and systems for an image sensor device are disclosed. An image sensor device comprises an array of image pixels wherein each pixel is configured for sensing light incident on the pixel. An image sensor device may further comprise a ground contact shared between at least two image pixels of the plurality. The ground contacts may be provided in an even pattern, a random pattern, or a repeating random pattern across the array. The image sensor device may further include an array of shared pixel structures comprising a plurality of pixels, wherein a ground contact may be evenly or randomly placed within each pixel structure across the array of pixel structures.

Abstract: An imager element, device and imaging system image sensor pixel. The image sensor pixel includes a collection region, a floating diffusion region, and a transfer transistor having a recessed gate. The recessed gate is configured to couple the collection region to the floating diffusion region so that collected charge is transferred during activation. The recessed gate has an effective gate length greater than the physical gate length.

Abstract: Methods of forming an improved shallow trench isolation (STI) region are disclosed. Several exemplary techniques are proposed for treating STI sidewalls to improve the silicon (Si) surface at the atomic level. Each of the exemplary methods creates a smooth STI sidewall surface, prior to performing oxidation, by reconstructing silicon atoms at the surface. The suggested STI region can be used in imager pixel cells or memory device applications.

Abstract: Methods of forming an improved shallow trench isolation (STI) region are disclosed. Several exemplary techniques are proposed for treating STI sidewalls to improve the silicon (Si) surface at the atomic level. Each of the exemplary methods creates a smooth STI sidewall surface, prior to performing oxidation, by reconstructing silicon atoms at the surface. The suggested STI region can be used in imager pixel cells or memory device applications.

Abstract: Methods, devices, and systems for image sensors are disclosed that include a multi-mode circuit that can be configured for operating as an imaging pixel and a memory. The multi-mode circuit includes a photo-detector for collecting electrons generated by radiation impinging on the photo-detector. A transfer gate is configured for transferring the collected electrons from the photo-detector to a floating diffusion node when the transfer gate is enabled. A write circuit receives and stores a multi-value voltage on the floating diffusion node and a read circuit is configured for reading a state of the floating diffusion node. The state of the floating diffusion node corresponds to the amount of transferred electrons in an image mode or the multi-value voltage in a memory mode. The semiconductor image sensor may be included in as part of an imaging system that includes a memory for storing a digital representation of an image.

Abstract: An imaging method, apparatus, and system having an image sensor having a p-type substrate to getter metallics and other contaminants, an n-type epitaxial layer arranged on the p-type substrate to reduce dark current, cross-talk, and blooming, and a p-type epitaxial layer arranged on the n-type epitaxial layer.

Abstract: Methods, devices, and systems for an image sensor device are disclosed. An image sensor device comprises an array of image pixels wherein each pixel is configured for sensing light incident on the pixel. An image sensor device may further comprise a ground contact shared between at least two image pixels of the plurality. The ground contacts may be provided in an even pattern, a random pattern, or a repeating random pattern across the array. The image sensor device may further include an array of shared pixel structures comprising a plurality of pixels, wherein a ground contact may be evenly or randomly placed within each pixel structure across the array of pixel structures.

Abstract: Methods, methods of making, devices, and systems for image sensors that include isolation regions are disclosed. A semiconductor imager includes a pixel array and peripheral circuitry arranged on at least one side of the pixel array. Array devices are formed as part of the pixel array and periphery devices are formed in the periphery. Array isolation regions are disposed around at least a portion of at least some of the array devices and periphery isolation regions are disposed around at least a portion of at least some of the periphery devices. Within the semiconductor imager, the periphery isolation regions are configured differently from the array isolation regions. The semiconductor image sensor may be included in as part of an imaging system that includes a processor.

Abstract: An imaging method, apparatus, and system having pixels that store charge from a photosensor in a storage diode are disclosed. Charge accumulated in the photosensor during an integration period is transferred to and stored in the storage diode prior to readout in a global shutter imager.

Abstract: An image sensing circuit and method is disclosed, wherein a photodiode is formed in a substrate through a series of angled implants. The photodiode is formed by a first, second and third implant, wherein at least one of the implants are angled so as to allow the resulting photodiode to extend out beneath an adjoining gate. Under an alternate embodiment, a fourth implant is added, under an increased implant angle, in the region of the second implant. The resulting photodiode structure substantially reduces or eliminates transfer gate subthreshold leakage.

Abstract: A method, apparatus, and system are disclosed providing an imaging device with memory cells containing anti-fuse elements located with or outside a pixel array. The memory cells are read out using control signal lines which are used to readout imaging pixels.

Abstract: A pinned photodiode with an ultra-shallow highly-doped surface layer of a first conductivity type and a method of formation are disclosed. The ultra-shallow highly-doped surface latter has a thickness of about 100 Angstroms to about 500 Angstroms and a dopant concentration of about 5×1017 atoms per cm3 to about 1×1019 atoms per cm3. The ultra-shallow highly-doped surface layer is formed by diffusion of ions from a doped layer into the substrate or by a plasma doping process. The ultra-shallow pinned layer is in contact with a charge collection region of a second conductivity type.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: The barrier region for isolating one or more dark regions of the pixel array of an image sensor from the active array or from the peripheral circuitry includes N-well pixel isolation region. The N-well pixel isolation region includes at least one N-well implant or at least one N-well stripe. The N-well pixel isolation region is adjacent the pixel cells which comprise the dark region. The addition of the N-well in the barrier region improves the isolation properties of the barrier region by reducing or eliminating the neutral P? EPI region in the barrier pixel area below the N-well isolation region.

Abstract: A pinned photodiode with an ultra-shallow highly-doped surface layer of a first conductivity type and a method of formation are disclosed. The ultra-shallow highly-doped surface layer has a thickness of about 100 Angstroms to about 500 Angstroms and a dopant concentration of about 5×1017 atoms per cm3 to about 1×1019 atoms per cm3. The ultra-shallow highly-doped surface layer is formed by diffusion of ions from a doped layer into the substrate or by a plasma doping process. The ultra-shallow pinned layer is in contact with a charge collection region of a second conductivity type.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: A well region of a first conductivity type located in a substrate of the first conductivity type and below about half the channel length of an electrically active portion of a transistor gate is disclosed. The well region is laterally displaced from a charge collection region of a second conductivity type of a pinned photodiode.

Abstract: An imaging system includes a pixel that does not require a row select transistor. Instead, an operating voltage is selectively provided to the pixel's readout circuitry, and the readout circuitry provides output signals based on charge or voltage of a storage node. The operating voltage can be selectively provided to each row of a pixel array by a row driver. Each pixel includes a source follower transistor that provides an output signal on a column output line for readout. An anti-blooming transistor may be linked to each pixel's photosensor to provide an overflow path for electrons during charge integration, prior to transfer of charge to the pixel's storage node by a transfer transistor. Electrons not produced by an image are introduced to the photosensor prior to image acquisition, filling traps in the photosensor to reduce image degradation.

Abstract: Embodiments of the invention provide an image sensor that includes a barrier region for isolating devices. The image sensor comprises a substrate and an array of pixel cells formed on the substrate. Each pixel cell comprises a photo-conversion device. The array comprises a first pixel cell having a first configuration, a second pixel cell having a second configuration, and at least one barrier region formed between the first and second pixel cells for capturing and removing charge. The barrier region comprises a charge accumulation region of a particular conductivity type in a substrate electrically connected to a voltage source terminal. The charge accumulation region accumulates charge and prevents charge transference from a pixel cell or peripheral circuitry on one side of the barrier region to a pixel cell on another side of the barrier region.