Abstract: Embodiments described herein provide materials, devices, and methods relating to the determination of analytes such as drugs, toxins, explosives, other controlled substances and contraband materials, and the like. In some embodiments, the analyte may be detected in vapor phase. Some embodiments may allow for highly sensitive and essentially instantaneous detection of analytes including drugs.

Abstract: An array of vertical-cavity surface emitting lasers (VCSELs) may be fabricated with very high fill-factors, thereby enabling very high output power densities during pulse, quasi-continuous wave (QCW), and continuous wave (CW) operation. This high fill-factor is achieved using asymmetrical pillars in a rectangular packing scheme as opposed prior art pillar shapes and packing schemes. The use of asymmetrical pillars maintains high efficiency operation of VCSELs by maintaining minimal current injection distance from the metal contacts to the laser active region and by maintaining efficient waste heat extraction from the VCSEL. This packing scheme for very high fill-factor VCSEL arrays is directly applicable for next generation high-power, substrate removed, VCSEL arrays.

Abstract: Provided for an embodiment is a support member for a cryogenic cooler's expander. The support member provides stiffness to the expander to reduce movements at the expander's distal end and may increase the natural frequency of the expander. The support member may increase the natural frequency of the expander at least about two times in the bending and/or twisting sense. The bending natural frequency of the expander and support sub-assembly may be at least about two times greater or lower than the natural frequency of the electrical wires that connect an infrared sensor to a control processing unit to reduce the maximum stress applied to the electrical wires during use. In another embodiment, additional or redundant electrical pathways are provided for connections between the infrared sensor and the CPU. Furthermore, shock absorber and/or shock diverters are provided on rigid pins that connect the electrical wires to the CPU.

Abstract: Various techniques are disclosed for systems and methods using thermal imaging to monitor an infant or other persons that may need observation. For example, an infant monitoring system may include an infrared imaging module, a visible light camera, a processor, a display, a communication module, and a memory. The monitoring system may capture thermal images of a scene including at least a partial view of an infant, using the infrared imaging module enclosed in a portable or mountable housing configured to be positioned for remote monitoring of the infant. Various thermal image processing and analysis operations may be performed on the thermal images to generate monitoring information relating to the infant. The monitoring information may include various alarms that actively provide warnings to caregivers, and user-viewable images of the scene. The monitoring information may be presented at external devices or the display located remotely for convenient viewing by caregivers.

Abstract: Infrared imaging systems and methods disclosed herein, in accordance with one or more embodiments, provide for a wireless thermal imaging system comprising one or more wireless thermal image sensors adapted to capture and provide thermal images of structural objects of a structure for monitoring moisture of the structural objects and a processing component adapted to receive the thermal images of the structural objects from the one or more wireless thermal image sensors, and process the thermal images of the structural objects to generate moisture content information for remote analysis of restoration conditions of the structural objects.

Abstract: The invention provides methods, compositions and kits for segregating a target nucleic acid from a mixed nucleic acid sample. The methods, compositions and kits comprise a non-processive endonuclease (e.g., a restriction enzyme) or an antibody that binds the target nucleic acid (e.g., has methylation specificity). The mixed nucleic acid sample can comprise prokaryotic and eukaryotic nucleic acid and/or nucleic acid from more than one prokaryotic or eukaryotic organisms.

Abstract: A housing for an infrared camera module may be implemented with a substantially non-metal cover configured to substantially or completely enclose various components of an infrared imaging device. A metal layer may be disposed on various interior and/or exterior surfaces of the cover. Such implementations may be used to reduce the effects of various environmental conditions which may otherwise adversely affect the performance of the infrared imaging device. In addition, one or more conductive traces may be built into the housing and/or on interior surfaces of the housing to facilitate the passing of signals from components of the infrared imaging device such as infrared sensors, read out circuitry, a temperature measurement component, and/or other components. One or more fiducial markers may be provided to align various components of the infrared camera module during manufacture.

Abstract: Various systems and methods are disclosed for monitoring and controlling using small infrared imaging modules to enhance occupant safety and energy efficiency of buildings and structures. In one example, thermal images captured by infrared imaging modules may be analyzed to detect presence of persons, identify and classify power-consuming objects, and monitor environmental conditions. Based on the processed thermal images, various power-consuming objects (e.g., an HVAC system, lighting, a water heater, and other appliances) may be controlled to increase energy efficiency. In another example, thermal images captured by infrared imaging modules may be analyzed to detect various hazardous conditions, such as a combustible gas leak, a CO gas leak, a water leak, fire, smoke, and, an electrical hotspot. If such hazardous conditions are detected, an appropriate warning may be generated and/or various objects may be controlled to remedy the conditions.

Abstract: Various techniques are disclosed for systems and methods using small form factor infrared imaging modules to monitor occupants in an interior compartment of a vehicle. For example, a vehicle-mounted system may include one or more infrared imaging modules, a processor, a memory, alarm sirens, and a communication module. The vehicle-mounted system may be mounted on, installed in, or otherwise integrated into a vehicle that has an interior compartment. The infrared imaging modules may be configured to capture thermal images of desired portions of the interior compartments. Various thermal image processing and analytics may be performed on the captured thermal images to determine the presence and various attributes of one or more occupants. Based on the determination of the presence and various attributes, occupant detection information and/or control signals may be generated.

Abstract: A spatially efficient kinematic mirror mount for mounting a mirror or other optical element to a housing. The kinematic mirror mount may include three spaced-apart constraint structures, positioned at or near the outer perimeter or circumference of the mirror. The constraint structures constrain the mirror to lie within a plane, typically the x-y plane defined by the orientation of the housing, substantially without overconstraining the mirror. To accomplish this, each of the three constraint structures may constrain the mirror in the x-y plane by independently providing a tangential constraint to the mirror. The constraint structures may include a tab, coupled to the mirror by a flexure, and a fastening assembly for securing the tab to the housing.

Abstract: Various techniques are provided for forming three-dimensional images. For example, in one embodiment, a system for three-dimensional imaging of an object includes an imaging sensor that provides a focal plane array and a sensor controller. The system also includes a laser illuminator coupled to the sensor controller. The laser illuminator is adapted to emit at least one laser pulse to be reflected from at least one plane of the object and detected by the focal plane array as at least one two-dimensional image frame of light intensities. The sensor controller is adapted to associate a range dimension of the plane with the image frame to facilitate formation of a three-dimensional image of the object. Related methods are also contemplated.

Abstract: A traffic monitoring device may comprise a radar and a camera, said radar having a radar field of view extending around a radar central axis and said camera having a camera field of view extending around a camera central axis in such a manner that said radar field of view is situated within said camera field of view. The radar and the camera may be positioned so that their central axis of their field of view make a predetermined angle with respect to each other, said radar being provided for determining coordinates of moving objects. The device may comprise selecting means for selecting within said image an image section or portion representing at least part of said radar field of view and may also comprise transformation means for transforming said coordinates of said moving object within said image portion into further coordinates relative to an image reference frame for display.

Abstract: A single camera capable of capturing high speed laser return pulses for a target, as well as provide imaging information on the background of the target. This capability is enabled by having a read-out integrated circuit (ROIC) capable of extracting both types of information from a pixel of a focal plane array (FPA). Further, an ROIC topology that allows for the ability to distinguish between high frequency and low frequency signal paths, and provide supporting circuitry to process the two paths separately. One path may integrate the low frequency background scene to provide a high fidelity image of the scene. The second path may process high frequency noise and multiple laser pulse returns within a frame. These two paths may be combined to provide a background image with a superimposed laser return.

Abstract: Systems and methods are disclosed in accordance with some embodiments for integrating an infrared camera system into a vehicle's lighting component. For example in accordance with an embodiment, a lighting component for a vehicle includes a housing; an infrared camera disposed within the housing; a light source disposed within the housing and disposed at least partially around the infrared camera; and a lens coupled to the housing and adapted to allow infrared radiation to pass through and be received by the infrared camera and to allow light provided by the light source to be transmitted through the lens. Furthermore, one or more infrared cameras may be integrated into a vehicle to provide various capabilities, such as for example stereoscopic infrared imaging, multi-spectral stereoscopic imaging (e.g., using infrared and visible wavelengths or various infrared wavelengths for multi-color infrared imaging), and/or provide various fields of view (e.g., foveal imaging).

Abstract: Various techniques are disclosed for providing systems and methods for orienting one or more lenses or other optical elements in a lens sleeve. For example, a system may include a lens sleeve defining an interior lens cavity. A plurality of lens positioning features extend from the lens sleeve adjacent the interior lens cavity. A first lens is secured in the lens cavity at a first position relative to the lens sleeve. A first set of the lens positioning features are located at a second position relative to the lens sleeve, and a second set of the lens positioning features are located at a third position relative to the lens sleeve. A second lens engages either the first set or the second set of the plurality of lens positioning features depending on a desired distance between the first lens and the second lens.

Abstract: A selective diffractive optical element includes a first diffractive region having a first design on a first surface of a substrate, and a second diffractive region having a second design on the first surface of the substrate, the first and second designs being different, wherein, by altering a position of a cross-section of an illumination beam, the selective diffractive optical element outputs a desired proportion of the two diffractive patterns aligned along an optical axis of the illumination beam.

Abstract: In one embodiment, a detector includes an AlxIn(1-x)Sb absorber layer, and an AlyIn(1-y)Sb passivation layer disposed above the AlxIn(1-x)Sb absorber layer, wherein x<y. The detector further includes a junction formed in a region of the AlxIn(1-x)Sb absorber layer, and a metal contact disposed above the junction and through the AlyIn(1-y)Sb passivation layer.

Abstract: In one embodiment, a detector includes an AlzIn(1-x)Sb passivation/etch stop layer, an AlxIn(1-x)Sb absorber layer disposed above the Alzn(1-z)Sb passivation/etch stop layer, and an AlyIn(1-y)Sb passivation layer disposed above the AlxIn(1-x)Sb absorber layer, wherein x<z and x<y. The detector further includes a junction formed in a region of the AlxIn(1?x)Sb absorber layer, and a metal contact disposed above the junction and through the AlyIn(1-y)Sb passivation 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.