Abstract: Systems, including apparatus and methods, for driving airflow along a surface of a gimbal. The systems may comprise a gimbal apparatus including a payload and also including a gimbal mount supporting a first gimbal and a second gimbal. The first gimbal may be coupled pivotally to the gimbal mount. The second gimbal may be coupled pivotally to and supported by the first gimbal. The second gimbal may be coupled to and may support the payload. The gimbal apparatus may orient the payload by pivotal movement of the first and second gimbals relative to the gimbal mount about at least two nonparallel axes. The system also may comprise a fan mounted to the first gimbal. The systems also may comprise operating the fan to drive airflow through a gap disposed between the first and second gimbals.

Abstract: Systems and methods provide high and low resolution cameras. For example, in accordance with an embodiment of the present invention, a camera system provides wide and narrow fields of view simultaneously. An operator may select different views to be provided by the camera system (e.g., a wide field of view, a narrow field of view, or the combination of the wide and narrow field of views).

Abstract: An enhanced vision system and method for use with vision systems with an imager sensitive to infrared radiation of less than 2-microns in wavelength, to produce a first image signal. Another imager sensitive to infrared radiation at least 3-microns in wavelength may be used to produce a second image signal. Preferably, the first image signal represents sensed electric light sources, and the second image signal represents sensed background such as terrain, runways, structures, and obstacles. A signal processor combines an image signal representing locally maximum values of the first image signal with the second image signal to create a displayed image.

Abstract: A method of fabricating a semiconductor device includes patterning a layer of photoresist onto a surface of a wafer to define metal feature areas and residual metal areas. A layer of metal is deposited over the patterned layer of photoresist, the metal layer includes metal feature portions in the metal feature areas, residual metal areas in the residual metal areas, and residual metal flaps at the edges of the metal feature portions. The wafer is sprayed with high-pressure solvent at a pressure to dissolve the layer of photoresist and to physically remove the residual metal portions from the residual metal areas, leaving only at least a portion of the residual metal flaps. The wafer is sprayed with a stream of frozen gas particles to remove the residual metal flaps.

Abstract: A portable thermography camera system (100) renders a video image of a survey scene over a narrow spectral bandwidth corresponding with an absorption band of a gas to be detected in the video image. The camera system forms a scene image onto a focal plane array (108) and generates a corrected image signal (162) corresponding with irradiance values at a plurality of locations of the scene image. The camera system further generates a temporally filtered image signal (168) corresponding with a temporal characteristics of the image signal (162) over a selected number of prior image frames. A difference block (166) reduces the temporally filtered image signal (168) by a scaling factor and produces a difference image by subtracting the scaled temporally filtered image signal from the corrected image signal (162). The displayed difference signal improves the visibility of the gas to be detected.

Abstract: An improved emitter tracking system. In aspects of the present teachings, the presence of a desired emitter may be established by a relatively low-power emitter detection module, before images of the emitter and/or its surroundings are captured with a relatively high-power imaging module. Capturing images of the emitter may be synchronized with flashes of the emitter, to increase the signal-to-noise ratio of the captured images.

Abstract: Systems and techniques for imaging spectroscopy using improved data acquisition for infrared and near-infrared imaging. A first filter corresponding to a first wavelength may be positioned in the optical path of an infrared camera, and subframe data may be acquired for different exposures. A second filter corresponding to a second different wavelength may be positioned in the optical path of the infrared camera, and subframe data acquired for different exposures. Image data for the first wavelength and the second wavelength may then be compared to reference spectroscopic data.

Abstract: A compact optical payload for an unmanned aircraft includes two infrared cameras for wide and narrow field viewing, a daylight color camera, a laser pointer and a laser range finder.

Abstract: A video camera 100 for remote operation or surveillance has a lens system 1 supported on a fixed base plate 26 and a pair of image sensors 14, 15, 204 mounted onto a movable plate 13. A pair of balls slides 11, 12 are attached to the fixed base plate 26 and the movable plate 13 to provide linear movement of the movable plate along a linear motion axis 50. An actuator 5 is disposed between the fixed base plate 26 and the movable plate 13 to move the movable plate 13 and each of the image sensors 14, 15, 204 along the linear motion axis 50 to dispose either the first image sensor 14 or the second image sensor 15 in and imagining position where the lens system 1 forms a scene image onto its active surface. In a preferred embodiment, the first image sensor 14 is an Electron Multiplication CCD array suitable for night time imaging and the second sensor 15 is a color CCD array suitable for day light imaging.

Abstract: Scalable, thermally efficient pump diode systems. These systems may include an arrangement of pump diodes and thermally conductive spacers mounted within a single indentation in a substrate or substrate clamps, so as to provide enhanced heat removal from the system. These systems also may include a plurality of such pump diode assemblies mounted, in a symmetric or partially symmetric arrangement, around a lasing medium in a diode pumped laser system, to improve heat removal and/or excitation of the medium.

Abstract: Systems, including apparatus and methods, for obtaining and/or correcting images, particularly from atmospheric and/or other distortions. These corrections may involve, among others, determining corrective information in a first (e.g., visible) wavelength regime, and then applying the corrective information in a second (e.g., longer) wavelength regime, such as infrared (IR) or millimeter-wave (MMW) wavelengths, in real time or with post-processing. For example, these corrections may include scaling a phase diversity correction from one wavelength to another. These systems may be useful in any suitable imaging context, including navigation, targeting, search and rescue, law enforcement, and/or surveillance, among others.

Abstract: An infrared camera, in accordance with one embodiment, includes a housing having disposed therein one or more heating elements; a vent; a sensor for detecting a humidity level and providing a sensor signal indicating the humidity level within the housing; and a logic circuit configured to receive the sensor signal and determine if the humidity level within the housing should be reduced, wherein the logic circuit provides a control signal to switch on at least one of the heating elements if the humidity level should be reduced via the vent.

Abstract: Systems and techniques for improving the dynamic range of infrared detection systems. For example, a mechanical superframing technique may comprise positioning a first filter in the optical path of an infrared camera at a first time, receiving infrared light from an object through the first filter at a detector array, acquiring first subframe image data for the object, positioning a second filter in the optical path of the infrared camera at a later time, receiving infrared light from the object through the second filter, acquiring second subframe image data for the object, and generating first superframe data based on at least some of the first subframe image data and at least some of the second subframe image data.

Abstract: An integrated sensor assembly (10) includes a gas compression unit (104) having a first longitudinal axis (308) and a gas expansion unit (112) having a second longitudinal axis (366) and the gas expansion unit is disposed with its second longitudinal axis orthogonal to the gas compression unit first longitudinal axis (308). A rotary motor (302) includes a rotor (324) supported for rotation with respect to a motor rotation axis (328) and the sensor assembly configuration is folded to orient the motor rotation axis substantially parallel with the second longitudinal axis (366). A motor shaft (320) extending from the rotor includes a first and second mounting features (336, 340) disposed substantially parallel with and radially offset from the motor rotation axis (328). A first drive coupling couples between the first mounting feature (336) and a gas compression piston (304) and drives the piston (304) with a reciprocal linear translation directed along the first longitudinal axis (308).

Abstract: A portable thermography camera system (100) renders a video image of a survey scene over a narrow spectral bandwidth corresponding with an absorption band of a gas to be detected in the video image. The camera system forms a scene image onto a focal plane array (108) and generates a corrected image signal (162) corresponding with irradiance values at a plurality of locations of the scene image. The camera system further generates a temporally filtered image signal (168) corresponding with a temporal characteristics of the image signal (162) over a selected number of prior image frames. A difference block (166) reduces the temporally filtered image signal (168) by a scaling factor and produces a difference image by subtracting the scaled temporally filtered image signal from the corrected image signal (162). The displayed difference signal improves the visibility of the gas to be detected.

Abstract: A gimbal system. The gimbal system may include space-saving features configured to accommodate one or more payload components, thus increasing the payload capacity of the gimbal ball without necessarily increasing the outer dimensions of the gimbal ball. Alternatively, or in addition, the gimbal system may include a motor configured to move at least one gimbal relative to another gimbal about a first axis, with the motor peripherally mounted distal the axis.

Abstract: A refrigeration device includes a gas displacing piston (362) movable within a gas expander cylinder (364). The volume of a gas expansion space (362) is varied as the gas displacing piston (362) is moved over an expansion stroke range. The device includes a compression spring (622) disposed to bias the gas displacing piston (362) toward a compression stroke top end position (85). A cable element (606) extends into the gas expansion cylinder (364) and attaches to the gas displacing piston (362). A motive drive device (302) applies a tensioning force to the cable (606) and the tension force opposes the spring biasing force and moves the gas displacing piston (362) to a compression stroke bottom end position (83).

Abstract: Systems, including devices and methods, for infrared imaging, and more particularly to systems for infrared imaging.