Abstract: A microbolometer is disclosed, including a bottom multilayered dielectric, having a first silicon oxynitride layer and a second silicon oxynitride layer disposed above the first silicon oxynitride layer, the first and second silicon oxynitride layers having different refractive indices. The microbolometer further includes a detector layer disposed above the bottom multilayered dielectric, the detector layer comprised of a temperature sensitive resistive material, and a top dielectric disposed above the detector layer.

Abstract: Techniques are disclosed to provide a reference signal via a switched capacitor filter for image detector arrays in accordance with one or more embodiments. For an example embodiment, a method of providing a sampled and filtered reference signal to an image detector array includes receiving a reference signal; sampling the reference signal with a first capacitor to store a sampled reference signal based on the reference signal; coupling a second capacitor to the first capacitor to share charge stored on the first and second capacitors to generate the sampled and filtered reference signal to store on the second capacitor; and decoupling the second capacitor from the first capacitor, wherein the sampled and filtered reference signal is stored on the second capacitor to provide for one or more image detectors within the image detector array.

Abstract: A microbolometer is disclosed, including a bottom dielectric of a bridge structure; a detector layer disposed above the bottom dielectric, the detector layer comprised of a metal-doped vanadium pentaoxide material; and a top dielectric disposed above the detector layer.

Abstract: A microbolometer is disclosed, including a bottom dielectric of a bridge structure; a detector layer disposed above the bottom dielectric, the detector layer comprised of a metal-doped vanadium pentaoxide material; and a top dielectric disposed above the detector layer.

Abstract: A microbolometer is disclosed, including a bottom multilayered dielectric, having a first silicon oxynitride layer and a second silicon oxynitride layer disposed above the first silicon oxynitride layer, the first and second silicon oxynitride layers having different refractive indices. The microbolometer further includes a detector layer disposed above the bottom multilayered dielectric, the detector layer comprised of a temperature sensitive resistive material, and a top dielectric disposed above the detector layer.

Abstract: Systems and methods for microbolometer focal plane arrays provide for the selection of microbolometers within the microbolometer focal plane arrays. In accordance with an embodiment, a microbolometer focal plane array includes a plurality of microbolometers forming a microbolometer array, wherein contacts within the microbolometer array are shared by the microbolometers; a first plurality of switches adapted to provide a voltage to respective ones of the plurality of microbolometers; a second plurality of switches adapted to receive an output signal from respective ones of the plurality of microbolometers; and a third plurality of switches adapted to selectively short respective ones of the plurality of microbolometers in the microbolometer array.

Abstract: An infrared imaging system having a focal plane array including an array of detector elements and a readout circuit and including nonuniformity correction circuitry on the focal plane array. The individual detector elements correspond to pixels of an infrared scene to be imaged. Offsets in detection signals from each pixel arising from nonuniformities in the individual detector elements in the array are corrected by storing offset correction values for each detector element and using the stored offset values to control correction circuitry as the respective detector element signals are read out. The detector array and readout circuit are preferably formed as a monolithic or hybrid structure and the offset correction is provided on the focal plane array prior to signal amplification and analog to digital conversion.

Abstract: There is disclosed herein a holographic optical element (HOE) which is particularly useful for head up display (HUD) systems and similar systems wherein the holographic element is used in a transmission mode as well as in a reflection mode. The element introduces little or no flare when bright light sources are viewed in transmission. The reduction in flare is accomplished by constructing the holographic element so that the fringe density (or spatial frequency) is low or zero at the surfaces of the hologram which forms the holographic element, or stated differently, the fringes in the hologram are formed parallel or substantially parallel to the surfaces of the hologram so that no fringes or very few fringes intersect the surfaces of the hologram. This is accomplished through control of the construction geometry to appropriately orientate the fringes, and a suitable fringe density is approximately two or fewer line pairs per millimeter for a typical application.

Abstract: An infrared imaging system having a focal plane array including an array of detector elements and a readout circuit and including nonuniformity correction circuitry on the focal plane array. The individual detector elements correspond to pixels of an infrared scene to be imaged. Offsets in detection signals from each pixel arising from nonuniformities in the individual detector elements in the array are corrected by storing offset correction values for each detector element and using the stored offset values to control correction circuitry as the respective detector element signals are read out. The detector array and readout circuit are preferably formed as a monolithic or hybrid structure and the offset correction is provided on the focal plane array prior to signal amplification and analog to digital conversion.