Abstract: 3D sensors, systems, and associated methods are provided. In one aspect, for example, a monolithic 3D sensor for detecting infrared and visible light can include a semiconductor substrate having a device surface, at least one visible light photodiode formed at the device surface and at least one 3D photodiode formed at the device surface in proximity to the at least one visible light photodiode. The device can further include a quantum efficiency enhanced infrared light region functionally coupled to the at least one 3D photodiode and positioned to interact with electromagnetic radiation. In one aspect, the quantum efficiency enhanced infrared light region is a textured region located at the device surface.

Abstract: A monolithic sensor for detecting infrared and visible light according to an example includes a semiconductor substrate and a semiconductor layer coupled to the semiconductor substrate. The semiconductor layer includes a device surface opposite the semiconductor substrate. A visible light photodiode is formed at the device surface. An infrared photodiode is also formed at the device surface and in proximity to the visible light photodiode. A textured region is coupled to the infrared photodiode and positioned to interact with electromagnetic radiation.

Abstract: Photosensitive devices and associated methods are provided. In one aspect, for example, a photosensitive imager device can include a semiconductor substrate having multiple doped regions forming at least one junction, a textured region coupled to the semiconductor substrate and positioned to interact with electromagnetic radiation, and an electrical transfer element coupled to the semiconductor substrate and operable to transfer an electrical signal from the at least one junction. In one aspect, the textured region is operable to facilitate generation of an electrical signal from the detection of infrared electromagnetic radiation. In another aspect, interacting with electromagnetic radiation further includes increasing the semiconductor substrate's effective absorption wavelength as compared to a semiconductor substrate lacking a textured region.

Abstract: Backside illuminated photosensitive devices and associated methods are provided. In one aspect, for example, a backside-illuminated photosensitive imager device can include a semiconductor substrate having multiple doped regions forming a least one junction, a textured region coupled to the semiconductor substrate and positioned to interact with electromagnetic radiation, and a passivation region positioned between the textured region and the at least one junction. The passivation region is positioned to isolate the at least one junction from the textured region, and the semiconductor substrate and the textured region are positioned such that incoming electromagnetic radiation passes through the semiconductor substrate before contacting the textured region. Additionally, the device includes an electrical transfer element coupled to the semiconductor substrate to transfer an electrical signal from the at least one junction.

Abstract: An active pixel sensor (APS) comprises a regular repeating pattern of geometrically similar pixel regions, active pixels of which have photodiodes formed therein. A remainder of the geometrically similar regions has electrical components shared amongst neighboring photodiodes, such as for collecting and amplifying signals from the photodiodes. A 4-way sharing arrangement is shown, with four active pixel regions aligned in a column and the shared electrical components in a pixel region, the pixel region being shaped and sized similarly to the active pixel regions, in an adjacent column.

Abstract: A CMOS imaging system with increased charge storage of pixels yet decreased physical size, kTC noise and active area. A storage node is connected to the transfer gate and provides a storage node for a pixel, allowing for kTC noise reduction prior to readout. The pixel may be operated with the shutter gate on during the integration period to increase the amount of time for charge storage by a pixel.

Abstract: 3D sensors, systems, and associated methods are provided. In one aspect, for example, a monolithic 3D sensor for detecting infrared and visible light can include a semiconductor substrate having a device surface, at least one visible light photodiode formed at the device surface and at least one 3D photodiode formed at the device surface in proximity to the at least one visible light photodiode. The device can further include a quantum efficiency enhanced infrared light region functionally coupled to the at least one 3D photodiode and positioned to interact with electromagnetic radiation. In one aspect, the quantum efficiency enhanced infrared light region is a textured region located at the device surface.

Abstract: Transistor pixel devices, imagers, and associated methods are provided. In one aspect, a transistor pixel device includes a photodiode coupled to a floating diffusion region (FD), a storage node (SN), and a power supply, wherein the FD is coupled between the photodiode and the power supply. The device also includes a first global transfer transistor coupled between the photodiode and the FD for gating between the photodiode and the FD and a second global transfer transistor coupled between the FD and the SN for gating between the FD and the SN. A global reset select transistor is coupled between the FD and the power supply, wherein an open state of the global reset select transistor prevents accumulation of electrical charge at the photodiodes. A source follower transistor is coupled to the FD and to the power supply, where the source follower is operable to receive electrical signal from the FD.

Abstract: Backside illuminated photosensitive devices and associated methods are provided. In one aspect, for example, a backside-illuminated photosensitive imager device can include a semiconductor substrate having multiple doped regions forming a least one junction, a textured region coupled to the semiconductor substrate and positioned to interact with electromagnetic radiation where the textured region includes surface features sized and positioned to facilitate tuning to a preselected wavelength of light, and a dielectric region positioned between the textured region and the at least one junction. The dielectric region is positioned to isolate the at least one junction from the textured region, and the semiconductor substrate and the textured region are positioned such that incoming electromagnetic radiation passes through the semiconductor substrate before contacting the textured region.

Abstract: Photosensitive devices and associated methods are provided. In one aspect, for example, a frontside-illuminated photosensitive imager devices can include a semiconductor substrate having multiple doped regions forming a least one junction and a textured region coupled to the semiconductor substrate and positioned to interact with electromagnetic radiation on an opposite side of the semiconductor substrate from the multiple doped regions. The textured region can include surface features sized and positioned to facilitate tuning to a preselected wavelength of light. The device can also include an electrical transfer element coupled to the semiconductor substrate and operable to transfer an electrical signal from the at least one junction.

Abstract: Raised structures comprising overlying silicon layers formed by controlled selective epitaxial growth, and methods for forming such raised-structure on a semiconductor substrate are provided. The structures are formed by selectively growing an initial epitaxial layer of mono crystalline silicon on the surface of a semi conductive substrate, and forming a thin film of insulative material over the epitaxial layer. A second epitaxial layer is selectively, grown on the exposed surface of the initial epitaxially grown crystal layer, and a thin insulative film is deposited over the second epitaxial layer. Additional epitaxial layers are added as desired to provide a vertical structure of a desired height comprising multiple layers of single silicon crystals, each epitaxial layer have insulated sidewalls, with the uppermost epitaxial layer also with an insulated top surface.

Abstract: An imaging device comprising a plurality of photosensors, a shared diffusion region for receiving charge generated by the photosensors, and a dual conversion gain element that can be selectively coupled to the shared diffusion region to increase a conversion gain of the shared diffusion region. A method of operating such an imaging device is also described, comprising resetting a shared diffusion region, sampling a reset voltage level at the shared diffusion region, transferring charge accumulated in one of a plurality of photosensors to the shared diffusion region, sampling a pixel signal voltage level at the shared diffusion region, and activating a dual conversion gain element to increase a conversion gain of the shared diffusion region.

Abstract: A CMOS imaging system with increased charge storage of pixels yet decreased physical size, kTC noise and active area. A storage node is connected to the transfer gate and provides a storage node for a pixel, allowing for kTC noise reduction prior to readout. The pixel may be operated with the shutter gate on during the integration period to increase the amount of time for charge storage by a pixel.

Abstract: Photosensitive semiconductor devices and associated methods are provided. In one aspect, a semiconductor device can include a semiconductor substrate and a semiconductor layer coupled to the semiconductor substrate, where the semiconductor layer has a device surface opposite the semiconductor substrate. The device also includes at least one textured region coupled between the semiconductor substrate and the semiconductor layer. In another aspect, the device further includes at least one dielectric layer coupled between the semiconductor substrate and the semiconductor layer.

Abstract: A pixel array architecture having multiple pixel cells arranged in a split trunk pixel layout and sharing common pixel cell components. The array architecture increases the fill factor, and in turn, the quantum efficiency of the pixel cells. The common pixel cell components may be shared by a number of pixels in the array, and may include several components that are associated with the storage and readout of a signal from the pixel cells.

Abstract: An optimized color filter array is formed in, above or below one or more damascene layers. The color filter array includes filter regions which are configured to optimize the combined optical properties of the layers of the device to maximize the intensity of the particular wavelength of light incident to a respective underlying photodiode.

Abstract: An active pixel sensor (APS) comprises a regular repeating pattern of geometrically similar pixel regions, active pixels of which have photodiodes formed therein. A remainder of the geometrically similar regions has electrical components shared amongst neighboring photodiodes, such as for collecting and amplifying signals from the photodiodes. A 4-way sharing arrangement is shown, with four active pixel regions aligned in a column and the shared electrical components in a pixel region, the pixel region being shaped and sized similarly to the active pixel regions, in an adjacent column.

Abstract: A CMOS imaging system with increased charge storage of pixels yet decreased physical size, kTC noise and active area. A storage node is connected to the transfer gate and provides a storage node for a pixel, allowing for kTC noise reduction prior to readout. The pixel may be operated with the shutter gate on during the integration period to increase the amount of time for charge storage by a pixel.

Abstract: A monolithic sensor for detecting infrared and visible light according to an example includes a semiconductor substrate and a semiconductor layer coupled to the semiconductor substrate. The semiconductor layer includes a device surface opposite the semiconductor substrate. A visible light photodiode is formed at the device surface. An infrared photodiode is also formed at the device surface and in proximity to the visible light photodiode. A textured region is coupled to the infrared photodiode and positioned to interact with electromagnetic radiation.

Abstract: An imaging device comprising a plurality of photosensors, a shared diffusion region for receiving charge generated by the photosensors, and a dual conversion gain element that can be selectively coupled to the shared diffusion region to increase a conversion gain of the shared diffusion region. A method of operating such an imaging device is also described, comprising resetting a shared diffusion region, sampling a reset voltage level at the shared diffusion region, transferring charge accumulated in one of a plurality of photosensors to the shared diffusion region, sampling a pixel signal voltage level at the shared diffusion region, and activating a dual conversion gain element to increase a conversion gain of the shared diffusion region.