Abstract: Embodiments of the invention relate to a camera assembly including a rear-facing camera and a front-facing camera operatively coupled together (e.g., bonded, stacked on a common substrate). In some embodiments of the invention, a system having an array of frontside illuminated (FSI) imaging pixels is bonded to a system having an array of backside illuminated (BSI) imaging pixels, creating a camera assembly with a minimal size (e.g., a reduced thickness compared to prior art solutions). An FSI image sensor wafer may be used as a handle wafer for a BSI image sensor wafer when it is thinned, thereby decreasing the thickness of the overall camera module. According to other embodiments of the invention, two package dies, one a BSI image sensor, the other an FSI image sensor, are stacked on a common substrate such as a printed circuit board, and are operatively coupled together via redistribution layers.

Abstract: A pixel cell includes a photodiode disposed in an epitaxial layer in a first region of semiconductor material. A floating diffusion is disposed in a well region disposed in the epitaxial layer in the first region. A transfer transistor is disposed in the first region and coupled between the photodiode and the floating diffusion to selectively transfer image charge from the photodiode to the floating diffusion. A deep trench isolation (DTI) structure lined with a dielectric layer inside the DTI structure is disposed in the semiconductor material isolates the first region on one side of the DTI structure from a second region of the semiconductor material on an other side of the DTI structure. Doped semiconductor material inside the DTI structure is selectively coupled to a readout pulse voltage in response to the transfer transistor selectively transferring the image charge from the photodiode to the floating diffusion.

Abstract: Embodiments of the invention describe providing a compact solution to provide high dynamic range imaging (HDRI or simply HDR) for an imaging pixel by utilizing a control node for resetting a floating diffusion node to a reference voltage value and for selectively transferring an image charge from a photosensitive element to a readout node. Embodiments of the invention further describe control node to have to a plurality of different capacitance regions to selectively increase the overall capacitance of the floating diffusion node. This variable capacitance of the floating diffusion node increases the dynamic range of the imaging pixel, thereby providing HDR for the host imaging system, as well as increasing the signal-to-noise ratio (SNR) of the imaging system.

Abstract: Techniques and architectures for providing a coating for one or more micro-lenses of a pixel array. In an embodiment, a pixel element includes a micro-lens and a coating portion extending over a surface of the micro-lens, where a profile of the coating portion is super-conformal to, or at least conformal to, a profile of the micro-lens. In another embodiment, the coating portion is formed at least in part by orienting the surface of the micro-lens to face generally downward with the direction of gravity, the orienting to allow a fluid coating material to flow for formation of the coating portion.

Abstract: Embodiments of a pixel including a photosensitive region formed in a surface of a substrate and an overflow drain formed in the surface of the substrate at a distance from the photosensitive area, an electrical bias of the overflow drain being variable and controllable. Embodiments of a pixel including a photosensitive region formed in a surface of a substrate, a source-follower transistor coupled to the photosensitive region, the source-follower transistor including a drain, and a doped bridge coupling the photosensitive region to the drain of the source-follower transistor.

Abstract: An apparatus for a dual-sided image sensor is described. The dual-sided image sensor captures frontside image data incident upon a frontside of the dual-sided image sensor within an array of photosensitive regions integrated into a semiconductor layer of the dual-sided image sensor. Backside image data incident upon a backside of the dual-sided image sensor is also captured within the same array of photosensitive regions.

Abstract: Embodiments of an apparatus including a color filter arrangement formed on a substrate having a pixel array formed therein. The color filter arrangement includes a clear filter having a first clear hard mask layer and a second clear hard mask layer formed thereon, a first color filter having the first clear hard mask layer and the second hard mask layer formed thereon, a second color filter having the first clear hard mask layer formed thereon, and a third color filter having no clear hard mask layer formed thereon. Other embodiments are disclosed and claimed.

Abstract: An integrated circuit system includes a first device wafer having a first semiconductor layer proximate to a first metal layer including a first conductor disposed within a first metal layer oxide. A second device wafer having a second semiconductor layer proximate to a second metal layer including a second conductor is disposed within a second metal layer oxide. A frontside of the first device wafer is bonded to a frontside of the second device wafer at a bonding interface. A conductive path couples the first conductor to the second conductor through the bonding interface. A first metal EMI shield is disposed in one of the first metal oxide layer and second metal layer oxide layer. The first EMI shield is included in a metal layer of said one of the first metal oxide layer and the second metal layer oxide layer nearest to the bonding interface.

Abstract: Embodiments of a process including depositing a sacrificial layer on the surface of a substrate over a photosensitive region, over the top surface of a transfer gate, and over at least the sidewall of the transfer gate closest to the photosensitive region, the sacrificial layer having a selected thickness. A layer of photoresist is deposited over the sacrificial layer, which is patterned and etched to expose the surface of the substrate over the photosensitive region and at least part of the transfer gate top surface, leaving a sacrificial spacer on the sidewall of the transfer gate closest to the photosensitive region. The substrate is plasma doped to form a pinning layer between the photosensitive region and the surface of the substrate. The spacing between the pinning layer and the sidewall of the transfer gate substantially corresponds to a thickness of the sacrificial spacer. Other embodiments are disclosed and claimed.

Abstract: Embodiments of the invention relate to a camera assembly including a rear-facing camera and a front-facing camera operatively coupled together (e.g., bonded, stacked on a common substrate). In some embodiments of the invention, a system having an array of frontside illuminated (FSI) imaging pixels is bonded to a system having an array of backside illuminated (BSI) imaging pixels, creating a camera assembly with a minimal size (e.g., a reduced thickness compared to prior art solutions). An FSI image sensor wafer may be used as a handle wafer for a BSI image sensor wafer when it is thinned, thereby decreasing the thickness of the overall camera module. According to other embodiments of the invention, two package dies, one a BSI image sensor, the other an FSI image sensor, are stacked on a common substrate such as a printed circuit board, and are operatively coupled together via redistribution layers.

Abstract: A pixel cell includes a photodiode, a storage transistor, a transfer transistor and an output transistor disposed in a semiconductor substrate. The transfer transistor selectively transfers image charge accumulated in the photodiode from the photodiode to the storage transistor. The output transistor selectively transfers the image charge from the storage transistor to a readout node. A first isolation fence is disposed over the semiconductor substrate separating a transfer gate of the transfer transistor from a storage gate of the storage transistor. A second isolation fence is disposed over the semiconductor substrate separating the storage gate from an output gate of the output transistor. Thicknesses of the first and second isolation fences are substantially equal to spacing distances between the transfer gate and the storage gate, and between the storage gate and the output gate, respectively.

Abstract: A method of forming microlenses for an image sensor having at least one large-area pixel and at least one small-area pixel is disclosed. The method includes forming a uniform layer of microlens material on a light incident side of the image sensor over the large-area pixel and over the small-area pixel. The method also includes forming the layer of microlens material into a first block disposed over the large-area pixel and into a second block disposed over the small-area pixel. A void is also formed in the second block to reduce a volume of microlens material included in the second block. The first and second blocks are then reflowed to form a respective first microlens and second microlens. The first microlens has substantially the same effective focal length as the second microlens.

Abstract: Embodiments of the present invention are directed to an image sensor having pixel transistors and peripheral transistors disposed in a silicon substrate. For some embodiments, a protective coating is disposed on the peripheral transistors and doped silicon is epitaxially grown on the substrate to form lightly-doped drain (LDD) areas for the pixel transistors. The protective oxide may be used to prevent epitaxial growth of silicon on the peripheral transistors during formation of the LDD areas of the pixel transistors.

Abstract: An imaging device includes a semiconductor substrate having a photosensitive element for accumulating charge in response to incident image light. The semiconductor substrate includes a light-receiving surface positioned to receive the image light. The imaging device also includes a negative charge layer and a charge sinking layer. The negative charge layer is disposed proximate to the light-receiving surface of the semiconductor substrate to induce holes in an accumulation zone in the semiconductor substrate along the light-receiving surface. The charge sinking layer is disposed proximate to the negative charge layer and is configured to conserve or increase an amount of negative charge in the negative charge layer. The negative charge layer is disposed between the semiconductor substrate and the charge sinking layer.

Abstract: An image sensor pixel includes one or more photodiodes disposed in a semiconductor layer. Pixel circuitry is disposed in the semiconductor layer coupled to the one or more photodiodes. A passivation layer is disposed proximate to the semiconductor layer over the pixel circuitry and the one or more photodiodes. A contact etch stop layer is disposed over the passivation layer. One or more metal contacts are coupled to the pixel circuitry through the contact etch stop layer. One or more isolation regions are defined in the contact etch stop layer that isolate contact etch stop layer material through which the one or more metal contacts are coupled are coupled to the pixel circuitry from the one or more photodiodes.

Abstract: A pixel cell includes a photodiode, a storage transistor, a transfer transistor and an output transistor disposed in a semiconductor substrate. The transfer transistor selectively transfers image charge accumulated in the photodiode from the photodiode to the storage transistor. The output transistor selectively transfers the image charge from the storage transistor to a readout node. A first isolation fence is disposed over the semiconductor substrate separating a transfer gate of the transfer transistor from a storage gate of the storage transistor. A second isolation fence is disposed over the semiconductor substrate separating the storage gate from an output gate of the output transistor. Thicknesses of the first and second isolation fences are substantially equal to spacing distances between the transfer gate and the storage gate, and between the storage gate and the output gate, respectively.

Abstract: A high dynamic range image sensor pixel includes a short integration photodiode and a long integration photodiode disposed in semiconductor material. The long integration photodiode has a light exposure area that is substantially larger than a light exposure area of the short integration photodiode. The light exposure area of the short integration photodiode has a first doping concentration from a first doping implantation. The light exposure area of the long integration photodiode includes at least one implanted portion having the first doping concentration from the first doping implantation. The light exposure area of the long integration photodiode further includes at least one non-implanted portion photomasked from the first doping implantation such that a combined doping concentration of the implanted and non-implanted portions of the light exposure area of the long integration photodiode is less than the first doping concentration of the light exposure area of the short integration photodiode.

Abstract: A pixel cell for use in a high dynamic range image sensor includes a photodiode disposed in semiconductor material to accumulate charge in response to light incident upon the photodiode. A transfer transistor is disposed in the semiconductor material and is coupled between a floating diffusion and the photodiode. A first amplifier transistor is disposed in the semiconductor material having a gate terminal coupled to the floating diffusion and a source terminal coupled to generate a first output signal of the pixel cell. A second amplifier transistor is disposed in the semiconductor material having a gate terminal coupled to the floating diffusion and a source terminal coupled to generate a second output signal of the pixel cell.

Abstract: Embodiments of a process including depositing a sacrificial layer on the surface of a substrate over a photosensitive region, over the top surface of a transfer gate, and over at least the sidewall of the transfer gate closest to the photosensitive region, the sacrificial layer having a selected thickness. A layer of photoresist is deposited over the sacrificial layer, which is patterned and etched to expose the surface of the substrate over the photosensitive region and at least part of the transfer gate top surface, leaving a sacrificial spacer on the sidewall of the transfer gate closest to the photosensitive region. The substrate is plasma doped to form a pinning layer between the photosensitive region and the surface of the substrate. The spacing between the pinning layer and the sidewall of the transfer gate substantially corresponds to a thickness of the sacrificial spacer. Other embodiments are disclosed and claimed.

Abstract: An image sensor includes a first pixel unit horizontally adjacent to a second pixel unit. Each pixel unit includes plurality of photodiodes and a shared floating diffusion region. A first pixel transistor region of the first pixel unit has a plurality of pixel transistors. A second pixel transistor region of the second pixel unit is horizontally adjacent to the first pixel transistor region and also has a plurality of pixel transistors. A transistor layout of the second pixel transistor region is a minor image of a transistor layout of the first pixel transistor region.