Abstract: A pseudomorphic high electron mobility transistor (pHEMT) comprises: a substrate comprising a Group III-V semiconductor material; buffer layer disposed over the substrate; and a channel layer disposed over the buffer layer. The buffer layer comprises microprecipitates of a Group V semiconductor element. A method of fabricating a pHEMT is also described.

Abstract: A pseudomorphic high electron mobility transistor (PHEMT) comprises a substrate comprising a Group III-V semiconductor material, a buffer layer disposed over the substrate, wherein the buffer layer comprises microprecipitates of a Group V semiconductor element and is doped with an N-type dopant, and a channel layer disposed over the buffer layer.

Abstract: A pseudomorphic high electron mobility transistor (PHEMT) comprises a substrate comprising a Group III-V semiconductor material, a buffer layer disposed over the substrate, wherein the buffer layer comprises microprecipitates of a Group V semiconductor element and is doped with an N-type dopant, and a channel layer disposed over the buffer layer.

Abstract: A pseudomorphic high electron mobility transistor (pHEMT) comprises: a substrate comprising a Group III-V semiconductor material; buffer layer disposed over the substrate; and a channel layer disposed over the buffer layer. The buffer layer comprises microprecipitates of a Group V semiconductor element. A method of fabricating a pHEMT is also described.

Abstract: A pixel including a substrate of a first conductivity type and having a surface, a photodetector of a second conductivity type that is opposite the first conductivity type, a floating diffusion region of the second conductivity type, a transfer region between the photodetector and the floating diffusion, a gate positioned above the transfer region and partially overlapping the photodetector, and a pinning layer of the first conductivity type extending at least across the photodetector from the gate.

Abstract: A semiconductor integrated circuit structure and method for fabricating. The semiconductor integrated circuit structure includes a light sensitive device integral with a semiconductor substrate, a cover dielectric layer disposed over the light sensitive device, and a lens-formation dielectric layer disposed over the cover dielectric layer. Light is transmittable through the cover dielectric layer; and through the lens-formation dielectric layer. The lens-formation dielectric layer forms an embedded convex microlens. The microlens directs light onto the light sensitive device.

Abstract: A method for fabricating a low leakage integrated circuit structure. An antireflective layer is disposed without intervening layers directly onto the top of an interconnect conductor, and a dielectric layer is disposed over the antireflective layer. The interconnect conductor is aluminum; the antireflective layer is titanium nitride, and the antireflective layer has thickness less than or equal to 650 angstroms and greater than or equal to 150 angstroms. A contact window is opened with the contact window extending at least down to the antireflective layer.

Abstract: Imaging systems and methods are provided. One exemplary system incorporates multiple lenses that are individually configured to receive visible light from an object to be imaged, and to direct this light upon a corresponding sensor array. Luminance information is then derived from signals generated in one or more of the sensor arrays. When chrominance information is desired, an optical filter is interposed between a lens and the corresponding sensor array. The mosaic pattern contained in the optical filter is tailored to provide advantageous chrominance information. One or more such filters with different mosaic patterns may be employed. The luminance and chrominance information obtained from the sensor arrays are combined to generate an image of the object.

Abstract: A digital image sensor comprising an array of pixels and a processor is provided. The array of pixels comprises a current pixel in a first color plane that is configured to produce a current sensor value, a first plurality of pixels in the first color plane that is configured to produce a first plurality of sensor values, and a second plurality of pixels in the second color plane that is configured to produce a second plurality of sensor values. The processor is configured to generate a plurality of estimate values using the first plurality of sensor values and a plurality of intensity ratios associated with the second plurality of sensor values, and the processor is configured to determine whether the current pixel is defective using the plurality of estimate values and the current sensor value.

Abstract: Imaging systems and methods are provided. One exemplary system incorporates multiple lenses that are individually configured to receive multi-wavelength light from an object to be imaged. Each lens provides an optimal modulation transfer function (MTF) for an individual wavelength contained in the multi-wavelength light when this individual wavelength of light strikes the lens at a particular incident angle. Associated with each lens is a color filter and a sensor. The color filter receives the multi-wavelength light from the lens, and transmits the individual wavelength of light on to the sensor. The image signals obtained from each of the multiple sensors are combined to generate an image of the object.

Abstract: A method for fabricating a low leakage integrated circuit structure. An antireflective layer is disposed without intervening layers directly onto the top of an interconnect conductor, and a dielectric layer is disposed over the antireflective layer. The interconnect conductor is aluminum; the antireflective layer is titanium nitride, and the antireflective layer has thickness less than or equal to 650 angstroms and greater than or equal to 150 angstroms. A contact window is opened with the contact window extending at least down to the antireflective layer.

Abstract: A semiconductor integrated circuit structure and method for fabricating. The semiconductor integrated circuit structure includes a light sensitive device integral with a semiconductor substrate, a cover dielectric layer disposed over the light sensitive device, and a lens-formation dielectric layer disposed over the cover dielectric layer. Light is transmittable though the cover dielectric layer; and through the lens-formation dielectric layer. The lens-formation dielectric layer forms an embedded convex microlens. The microlens directs light onto the light sensitive device.

Abstract: An integrated polysilicon fuse and diode and methods of making the same are provided. The integrated polysilicon fuse and diode combination may be implemented in a programmable cross point fuse array. The integrated polysilicon fuse and diode may be used in a random access memory (RAM) cell. The polysilicon diode may be isolated from a substrate and other devices, use less area on a substrate, and cost less to manufacture compared to other diodes.

Abstract: An integrated polysilicon fuse and diode and methods of making the same are provided. The integrated polysilicon fuse and diode combination may be implemented in a programmable cross point fuse array. The integrated polysilicon fuse and diode may be used in a random access memory (RAM) cell. The polysilicon diode may be isolated from a substrate and other devices, use less area on a substrate, and cost less to manufacture compared to other diodes.