Abstract: A backside illuminated (“BSI”) imaging sensor pixel includes a photodiode region and pixel circuitry. The photodiode region is disposed within a semiconductor die for accumulating an image charge in response to light incident upon a backside of the BSI imaging sensor pixel. The pixel circuitry includes transistor pixel circuitry disposed within the semiconductor die between a frontside of the semiconductor die and the photodiode region. At least a portion of the pixel circuitry overlaps the photodiode region.

Abstract: A backside illuminated imaging sensor includes a semiconductor having an imaging pixel that includes a photodiode region, an insulator, and a silicide reflective layer. The photodiode region is formed in the frontside of the semiconductor substrate. The insulation layer is formed on the backside of the semiconductor substrate. The transparent electrode formed on the backside of the insulation layer. The transparent electrode allows light to be transmitted through a back surface of the semiconductor substrate such that when the transparent electrode is biased, carriers are formed in a region in the backside of the semiconductor substrate to reduce leakage current. ARC layers can be used to increase sensitivity of the sensor to selected wavelengths of light.

Abstract: An array of pixels is formed using a substrate, where each pixel has a substrate having a backside and a frontside that includes metalization layers, a photodiode formed in the substrate, frontside P-wells formed using frontside processing that are adjacent to the photosensitive region, and an N-type region formed in the substrate below the photodiode. The N-type region is formed in a region of the substrate below the photodiode and is formed at least in part in a region of the substrate that is deeper than the depth of the frontside P-wells.

Abstract: An array of pixels is formed using a substrate having a frontside and a backside that is for receiving incident light. Each pixel typically includes metallization layers included in the frontside of the substrate, a photosensitive region formed in the backside of the substrate, and a trench formed around the photosensitive region in the backside of the substrate. The trench causes the incident light to be directed away from the trench and towards the photosensitive region.

Abstract: A backside illuminated imaging sensor includes a semiconductor having an imaging pixel that can include a photodiode region, an insulation layer, and a reflective layer. The photodiode is typically formed in the frontside of the semiconductor substrate. A surface shield layer can be formed on the frontside of the photodiode region. A light reflecting layer can be formed using silicided polysilicon on the frontside of the sensor. The photodiode region receives light from the back surface of the semiconductor substrate. When a portion of the received light propagates through the photodiode region to the light reflecting layer, the light reflecting layer reflects the portion of light received from the photodiode region towards the photodiode region. The silicided polysilicon light reflecting layer also forms a gate of a transistor for establishing a conductive channel between the photodiode region and a floating drain.

Abstract: What is disclosed is an apparatus comprising a transfer gate formed on a substrate and a photodiode formed in the substrate next to the transfer gate. The photodiode comprises a shallow N-type collector formed in the substrate, a deep N-type collector formed in the substrate, wherein a lateral side of the deep N-type collector extends at least under the transfer gate, and a connecting N-type collector formed in the substrate between the deep N-type collector and the shallow N-type collector, wherein the connecting implant connects the deep N-type collector and the shallow N-type collector. Also disclosed is a process comprising forming a deep N-type collector in the substrate, forming a shallow N-type collector formed in the substrate, and forming a connecting N-type collector in the substrate between the deep N-type collector and the shallow N-type collector, wherein the connecting implant connects the deep N-type collector and the shallow N-type collector.

Abstract: An apparatus for measuring the power frequency of a light source includes a photo-sensitive transistor, a modulators and a logic unit. The photo-sensitive transistor generates an electrical signal that is responsive to light incident thereon from the light source. The modulator generates a modulated signal based on the electrical signal that toggles at a rate substantially proportional to the power frequency of the light source. The logic unit is coupled to receive the modulated signal and determine its toggling frequency.

Abstract: An image sensor has at least two photodiodes in each unit pixel. A high dynamic range is achieved by selecting different exposure times for the photodiodes. Additionally, blooming is reduced. The readout timing cycle is chosen so that the short exposure time photodiodes act as drains for excess charge overflowing from the long exposure time photodiodes. To improve draining of excess charge, the arrangement of photodiodes may be further selected so that long exposure time photodiodes are neighbored along vertical and horizontal directions by short exposure time photodiodes. A micro-lens array may also be provided in which light is preferentially coupled to the long exposure time photodiodes to improve sensitivity.

Abstract: A method of forming a composite image using a CMOS image sensor. The method comprises capturing a plurality of frames using the image sensor, identifying a reference point in each of the frames, and aligning the frames using the reference point. Finally, the frames are combines, such as be an arithmetic addition, into the composite image.

Abstract: An image sensor that has a pixel array using an isolation structure between pixels that reduce electrical cross-talk is disclosed. The pixel array is formed on a substrate that has a thin (less than 5 microns) epitaxial layer. The isolation structure uses a deep p-well to surround a shallow trench isolation. The deep p-well is formed using an implant energy of typically over 700 keV.

Abstract: A pixel sensor cell used in a CMOS image sensor is disclosed. The cell includes a pinned photodiode formed in a Pwell that is formed in an N-type semiconductor substrate. A transfer transistor is placed between the pinned photodiode and an output node. A reset transistor is coupled between a high voltage rail Vdd and the output node. Finally, an output transistor with its gate coupled to the output node is provided.

Abstract: The present disclosure introduces a simple method for reducing the capacitance of the floating diffusion node of a CMOS image sensor and consequently improving the image sensor's sensitivity. While reducing parasitic capacitances such as the capacitance between the transfer gate and the floating node, the proposed device layouts, in which the channel width of the detection section is different from the channel width of the photoelectric conversion element, demand no more than what is required for the fabrication of the traditional layouts.

Abstract: A CMOS image sensor that has reduced transistor count is disclosed. The individual pixels are formed by a photodiode and a transfer transistor. An output node receives the signal from the photodiode via the transfer transistor. The output node is shared between multiple pixels. Further, a reset transistor is coupled between a selectable low voltage rail Vss or a high voltage reference Vref and the output node. The gate of an output transistor is then coupled to the output node. Both the reset transistor and output transistors are shared between multiple pixels. Further, the pixels have a mirror symmetry about the output transistor or output node.

Abstract: A pixel sensor cell used in a CMOS image sensor is disclosed. The cell includes a pinned photodiode formed in a Pwell that is formed in an N-type semiconductor substrate. A transfer transistor is placed between the pinned photodiode and an output node. A reset transistor is coupled between a high voltage rail Vdd and the output node. Finally, an output transistor with its gate coupled to the output node is provided.

Abstract: An active pixel that incorporates elements of CCD technology into a CMOS image sensor is disclosed. Each pixel includes a reset transistor that resets a sense node. The active pixel includes an amplification transistor that is modulated by the signal on the sense node. A light sensing element, such as a photodiode, is provided and its signal is selectively read out by a transfer gate, selectively stored by a memory gate, and finally read out onto the sense node by a control gate. Underneath the memory gate is a memory well that acts as memory for the pixel and stores the signal output by the light sensing element.

Abstract: A pixel sensor cell used in a CMOS image sensor is disclosed. The cell includes a pinned photodiode formed in a Pwell that is formed in an N-type semiconductor substrate. A transfer transistor is placed between the pinned photodiode and an output node. A reset transistor is coupled between a high voltage rail Vdd and the output node. Finally, an output transistor with its gate coupled to the output node is provided.

Abstract: The present disclosure introduces a simple method for reducing the capacitance of the floating diffusion node of a CMOS image sensor and consequently improving the image sensor's sensitivity. While reducing parasitic capacitances such as the capacitance between the transfer gate and the floating node, the proposed device layouts, in which the channel width of the detection section is different from the channel width of the photoelectric conversion element, demand no more than what is required for the fabrication of the traditional layouts.

Abstract: A active pixel sensor cell is disclosed that comprises a pinned photodiode. A transfer transistor is placed between the pinned photodiode and an output node, the transfer transistor being a depletion mode N-type MOSFET. A reset transistor is coupled between a high voltage rail Vdd and the output node. Finally, an output transistor has its gate coupled to the output node.

Abstract: An active pixel that incorporates elements of CCD technology into a CMOS image sensor is disclosed. Each pixel includes a reset transistor that resets a sense node. The active pixel includes an amplification transistor that is modulated by the signal on the sense node. A light sensing element, such as a photodiode, is provided and its signal is selectively read out by a transfer gate, selectively stored by a memory gate, and finally read out onto the sense node by a control gate. Underneath the memory gate is a memory well that acts as memory for the pixel and stores the signal output by the light sensing element.

Abstract: A method of forming a composite image using a CMOS image sensor. The method comprises capturing a plurality of frames using the image sensor, identifying a reference point in each of the frames, and aligning the frames using the reference point. Finally, the frames are combines, such as be an arithmetic addition, into the composite image.