Abstract: The present invention provides a semiconductor structure for forming a CMOS image sensor. The semiconductor structure includes at least a photodiode formed in the substrate for collecting photoelectrons, and the photodiode has a pinning layer, a first doped region and a second doped region in order from top to bottom in a height direction of the substrate. The semiconductor structure further includes a third doped region located in the substrate corresponding to a laterally extending region of the second doped region. The first doped region has an ion doping concentration greater than the ion doping concentration of the second doped region, the ion doping concentration of the second doped region is greater than the ion doping concentration of the third doped region, and the third doped region is in contact with the second doped region after diffusion. The present invention also provides a method of manufacturing the above-described semiconductor structure.

Abstract: A system and method for enhancing laser contrast on a remote target utilizing an image processor and a laser power controller is provided. An image processor in an imaging device manipulates a laser power controller in a laser system so that a laser beam emitted from a laser system is ultimately synchronized with the imaging device. Firstly, the original laser signal is shifted one time frame relative to the plurality of time frames to create a shifted laser signal. Secondly, the shifted laser signal is subtracted from the original laser signal. Thirdly, the subtracted laser signal is magnified by a frequency band pass filter. The filtered laser signal is added to the original signal to become the finalized laser signal which has better contrast than the original signal.

Abstract: A method for forming a photomask includes receiving a substrate having a first layer formed thereon, wherein a patterned second layer exposing portions of the first layer is disposed over the substrate, removing the exposed portions of the first layer through the patterned second layer to form a plurality of openings in the first layer, removing the patterned second layer, and performing a wet etching to remove portions of the first layer to widen the plurality of openings with an etchant. The etchant is in contact with a top surface of the first layer and sidewalls of the plurality of openings. Each of the plurality of openings has a first width prior to the performing of the wet etching and a second width after the performing of the wet etching. The second width is greater than the first width.

Abstract: The invention provides a semiconductor device, including: a substrate of a first conductivity type having an active region and a termination region; an epitaxial layer of the first conductivity type over the substrate; a plurality of first trenches and second trenches in the epitaxial layer; an implant blocker layer formed at bottoms of the first and second trenches; a liner of a second conductivity type different from the first conductivity type conformally formed along sidewalls of the first and second trenches; a dielectric material filled in the first and second trenches defining a plurality of first columns and a plurality second column, respectively; a gate dielectric layer over the epitaxial layer; two floating gates formed on the gate dielectric layer; a source region; an inter-layer dielectric layer; and a contact plug formed on the source region.

Abstract: A lateral overflow drain and a channel stop are fabricated using a double mask process. Each lateral overflow drain is formed within a respective channel stop. Due to the use of two mask layers, one edge of each lateral overflow drain is aligned, or substantially aligned, with an edge of a respective channel stop.

Abstract: A global shutter pixel cell includes a serially connected anti-blooming (AB) transistor, storage gate (SG) transistor and transfer (TX) transistor. The serially connected transistors are coupled between a voltage supply and a floating diffusion (FD) region. A terminal of a photodiode (PD) is connected between respective terminals of the AB and the SG transistors; and a terminal of a storage node (SN) diode is connected between respective terminals of the SG and the TX transistors. A portion of the PD region is extended under the SN region, so that the PD region shields the SN region from stray photons. Furthermore, a metallic layer, disposed above the SN region, is extended downwardly toward the SN region, so that the metallic layer shields the SN region from stray photons. Moreover, a top surface of the metallic layer is coated with an anti-reflective layer.

Abstract: An image sensor pixel includes a photosensitive element, a floating diffusion (“FD”) region, and a transfer device. The photosensitive element is disposed in a substrate layer for accumulating an image charge in response to light. The FD region is disposed in the substrate layer to receive the image charge from the photosensitive element. The transfer device is disposed between the photosensitive element and the FD region to selectively transfer the image charge from the photosensitive element to the FD region. The transfer device includes a gate, a buried channel dopant region and a surface channel region. The gate is disposed between the photosensitive element and the FD region. The buried channel dopant region is disposed adjacent to the FD region and underneath the gate. The surface channel region is disposed between the buried channel dopant region and the photosensitive element and disposed underneath the gate.

Abstract: Photodetector arrays, image sensors, and other apparatus are disclosed. In one aspect, an apparatus may include a surface to receive light, a plurality of photosensitive regions disposed within a substrate, and a material coupled between the surface and the plurality of photosensitive regions. The material may receive the light. At least some of the light may free electrons in the material. The apparatus may also include a plurality of discrete electron repulsive elements. The discrete electron repulsive elements may be coupled between the surface and the material. Each of the discrete electron repulsive elements may correspond to a different photosensitive region. Each of the discrete electron repulsive elements may repel electrons in the material toward a corresponding photosensitive region. Other apparatus are also disclosed, as are methods of use, methods of fabrication, and systems incorporating such apparatus.

Abstract: In a solid state imaging device with an electron multiplying function, in a section normal to an electron transfer direction of a multiplication register EM, an insulating layer 2 is thicker at both side portions than in a central region. A pair of overflow drains 1N is formed at a boundary between a central region and both side portions of an N-type semiconductor region 1C. Each overflow drain 1N extends along the electron transfer direction of the multiplication register EM. Overflow gate electrodes G extend from the thin portion to the thick portion of the insulating layer 2. The overflow gate electrodes G are disposed between both ends of each transfer electrode 8 in a longitudinal direction and the insulating layer 2, and they also function as shield electrodes for each electrode 8 (8A and 8B).

Abstract: Embodiments of an image sensor pixel that includes a photosensitive element, a floating diffusion region, and a transfer device. The photosensitive element is disposed in a substrate layer for accumulating an image charge in response to light. The floating diffusion region is dispose in the substrate layer to receive the image charge from the photosensitive element. The transfer device is disposed between the photosensitive element and the floating diffusion region to selectively transfer the image charge from the photosensitive element to the floating diffusion region. The transfer device includes a buried channel device including a buried channel gate disposed over a buried channel dopant region. The transfer device also includes a surface channel device including a surface channel gate disposed over a surface channel region. The surface channel device is in series with the buried channel device. The surface channel gate has the opposite polarity of the buried channel gate.

Abstract: A solid-state imaging device according to the present invention is of a MOS type and includes a plurality of pixels arranged in rows and columns, and includes: a semiconductor substrate; a photodiode which is formed in the semiconductor substrate and converts, into a signal charge, light that is incident from a first main surface of the semiconductor substrate; a transfer transistor which is formed in a second main surface of the semiconductor substrate and transfers the signal charge converted by the photodiode; a light shielding film which is conductive and formed on a boundary between the pixels, above the first main surface of the semiconductor substrate; an overflow drain region electrically connected to the light shielding film and formed in the first main surface of the semiconductor substrate; and an overflow barrier region formed between the overflow drain region and the photodiode.

Abstract: A lateral overflow drain and a channel stop are fabricated using a double mask process. Each lateral overflow drain is formed within a respective channel stop. Due to the use of two mask layers, one edge of each lateral overflow drain is aligned, or substantially aligned, with an edge of a respective channel stop.

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: Photodetector arrays, image sensors, and other apparatus are disclosed. In one aspect, an apparatus may include a surface to receive light, a plurality of photosensitive regions disposed within a substrate, and a material coupled between the surface and the plurality of photosensitive regions. The material may receive the light. At least some of the light may free electrons in the material. The apparatus may also include a plurality of discrete electron repulsive elements. The discrete electron repulsive elements may be coupled between the surface and the material. Each of the discrete electron repulsive elements may correspond to a different photosensitive region. Each of the discrete electron repulsive elements may repel electrons in the material toward a corresponding photosensitive region. Other apparatus are also disclosed, as are methods of use, methods of fabrication, and systems incorporating such apparatus.

Abstract: An n/p semiconductor substrate is formed in such a manner that an n type semiconductor layer is deposited on a p+ semiconductor substrate. An imaging area including a plurality of n type semiconductor regions making photoelectric conversion and a plurality of p type semiconductor region for isolation formed around the n type semiconductor regions, is formed in the n/p semiconductor substrate. The n type semiconductor layer is divided into an upper layer and a lower layer. A second n type semiconductor region is formed to connect to the p+ type semiconductor substrate from a surface of the n/p semiconductor substrate in a peripheral region of the imaging area.

Abstract: A method and structure of providing a doped plug to improve the performance of CCD gaps is discussed. A highly-doped region is implemented in a semiconductor, aligned beneath a gap. The plug provides a highly-conductive region at the semiconductor surface, therefore preventing the development of a region where potential is significantly influenced by surface charges.

Abstract: A pixel of an image sensor includes a gate insulation layer formed over a substrate doped with first-type impurities, a transfer gate formed over the gate insulation layer, a photodiode formed in the substrate at one side of the transfer gate, and a floating diffusion node formed in the substrate at the other side of the transfer gate, wherein the transfer gate has a negative bias during a charge integration cycle.

Abstract: A method for fabricating a back-illuminated semiconductor imaging device and resulting imaging device is disclosed, which includes the steps providing a substrate having a front surface and a back surface; growing an epitaxial layer substantially overlying the front surface of the substrate; forming at least one barrier layer substantially within the epitaxial layer; fabricating at least one imaging structure overlying and extending into the epitaxial layer, the imaging structure at least one charge transfer region, the at least one barrier layer substantially underlying the at least one charge transfer region, wherein light incident on the back surface of the substrate generates charge carriers which are diverted away from the at least one charge transfer region by the at least one barrier layer. At least a portion of the epitaxial layer is grown using an epitaxial lateral overgrowth technique.

Abstract: A solid image capturing element comprising a plurality of vertical shift registers arranged to each correspond to a column of a plurality of light receiving pixels in a matrix arrangement, a horizontal shift register provided on an output side of the plurality of vertical shift registers, and an output section provided on an output side of the horizontal shift register. In this solid image capturing element, a reverse conductive semiconductor region is formed over one major surface of one conductive semiconductor substrate, the plurality of light receiving pixels, the plurality of vertical shift registers, the horizontal shift register, and the output section are formed in the semiconductor region, and a portion of the semiconductor region where the output section is formed has a higher dopant concentration than the portion of the semiconductor region where the horizontal shift register is formed.

Abstract: An MOS type solid-state image pickup device including pixels each of which comprises a photodiode PD, a detection portion N and a transfer transistor QT for transferring the charges accumulated in the photodiode PD to the detection portion N, wherein the gate voltage of the transfer transistor QT when the charges are accumulated in the photodiode PD is set to a negative.

Abstract: A solid-state imaging device with a structure such that an electrode for reading a signal charge is provided on one side of a light-receiving sensor portion constituting a pixel; a predetermined voltage signal V is applied to a light-shielding film formed to cover an image pickup area except the light-receiving sensor portion; a second-conductivity-type semiconductor area is formed in the center on the surface of a first-conductivity-type semiconductor area constituting a photo-electric conversion area of the light-receiving sensor portion; and areas containing a lower impurity concentration than that of the second-conductivity-type semiconductor area is formed on the surface of the first-conductivity-type semiconductor area at the end on the side of the electrode and at the opposite end on the side of a pixel-separation area.

Abstract: A pixel of an image sensor includes a gate insulation layer formed over a substrate doped with first-type impurities, a transfer gate formed over the gate insulation layer, a photodiode formed in the substrate at one side of the transfer gate, and a floating diffusion node formed in the substrate at the other side of the transfer gate, wherein the transfer gate has a negative bias during a charge integration cycle.

Abstract: An image sensor device includes a semiconductor substrate having a first type of conductivity, a first layer overlying the semiconductor substrate and having the first type of conductivity, a second layer overlying the first layer and having a second type of conductivity different than the first type of conductivity, and a plurality of pixels formed in the second layer.

Abstract: A pixel of an image sensor includes only two signal lines per pixel, a pinned photodiode for sensing light, a floating base bipolar transistor, and no reset and address transistors. The floating base bipolar transistor provides the pixel with a gain, which can increase pixel sensitivity and reduce noise. The pixel also incorporates a vertical blooming control structure for an efficient blooming suppression. The output terminals of the pixel are coupled to a common column output line terminated by a special current sensing correlated double sampling circuit, which is used for subtraction of emitter leakage current. Based on this structure, the pixel has high sensitivity, high response uniformity, low noise, reduced size, and efficient layout.

Abstract: A frame shutter type device provides a separated well in which the storage node is located. The storage node is also shielded by a light shield to prevent photoelectric conversion.

Abstract: Apparatus, systems and methods are described to assist in reducing dark current in an active pixel sensor. A potential barrier arrangement is configured to block the flow of charge carriers generated outside a photosensitive region. In various embodiments, a potential well-potential barrier arrangement is formed to direct charge carriers away from the photosensitive region during an integration time.

Abstract: An anti-blooming structure for a back-illuminated imager is disclosed. In one embodiment, the anti-blooming structure is formed in a substrate of a first conductivity type having a back side and a front side, comprising a channel region of a second conductivity type formed in the substrate; a barrier region of the first conductivity type positioned in the substrate substantially overlying the channel region and proximal to the front side of the substrate; and a drain region of the second conductivity type positioned substantially overlying the barrier region, wherein when light impinges on the back side of the substrate the light generates charge carriers that collect in the channel region, the charge carriers passing through the barrier region into the drain region when a potential corresponding to the collected charge carriers in the channel region is about equal to the potential corresponding to the barrier region.

Abstract: For preventing the blooming phenomenon, there is provided an image pickup apparatus comprising a solid-state image pickup device adapted for a first readout method in which plural pixels are added to be read and a second readout method in which plural pixels are not added; and a circuit for applying a predetermined substrate voltage common to the first and second readout methods in an exposure period of the solid-state image pickup device and applying a predetermined substrate voltage corresponding to each readout method of the solid-state image pickup device in a period from the end of exposure of the solid-state image pickup device to the start of transfer to the signal transfer channel.