Abstract: Various embodiments of the methods and systems disclosed herein may be used to provide a surveillance camera that generates native video image frames in the appropriate FOV (orientation) that corresponds to the orientation in which the surveillance camera is installed when the video image frames are captured. The surveillance cameras implemented in accordance with embodiments of the disclosure may facilitate installation that provides a desired FOV in a particular orientation, generate video image frames that natively correspond to the desired FOV, and allow user interaction and video analytics to be performed on the FOV-matched video image frames.

Abstract: Techniques are disclosed for systems and methods to provide remote sensing data and/or imagery (e.g., radar and/or other ranging system data, image data, and/or target detection data). A remote sensing system includes a remote sensing assembly including a scanning sensor array, and a coupled logic device. The logic device is configured to receive remote sensor returns from a plurality of remote sensor beams within an illumination zone of the remote sensing assembly, wherein each remote sensor beam is formed using the scanning sensor array and comprises a substantially static orientation relative to an absolute coordinate frame, and generate remote sensor data based, at least in part, on the remote sensor returns and the substantially static orientations of the plurality of remote sensor beams. Subsequent user input and/or the sensor data may be used to adjust operational modes and/or systems of the remote sensing system.

Abstract: Provided is a system for protecting submerged components of a watercraft from collision with a submerged object or a floor of a body of water. The system includes a depth sensor configured to measure a water depth beneath the watercraft, an actuated mechanism configured to adjust a depth of at least one of the submerged components, and a controller in communication with the depth sensor and the actuated mechanism. The controller is operable to receive the measured water depth and control the actuated mechanism to adjust the depth of the at least one submerged component as a function of the measured water depth to prevent the at least one submerged component from colliding with the submerged object or floor of the body of water.

Abstract: Various techniques are provided for using one or more thermal infrared (IR) imaging modules to enhance the dynamic range of images. In one example, devices and methods provide a first IR imaging module that captures a first image, a second IR imaging module optimized for higher IR irradiance that captures a second image, and a processing system that detects saturated pixels of the first image, determines pixels of the second image corresponding to the saturated pixels of the first image, and generates a combined image based on non-saturated pixels of the first image and the pixels of the second image. The IR imaging modules may be a microbolometer focal plane array (FPA) configured for high-gain, and a microbolometer FPA configured for low-gain. The IR imaging modules may be a photon detector FPA and a microbolometer FPA.

Abstract: A system and method for comparing and searching for digital data, such as images, using histograms includes receiving a source image, receiving a comparison image, generating a first histogram for the source image and generating a second histogram for the comparison image. The source image may be received from a network device, such as a computer or camera, and the comparison image may one of a plurality of stored images in a database. The histograms may correspond to an image characteristic, including a color histogram corresponding to the distribution of the intensity of a corresponding color among image pixels in the source image. Each of first and second histograms is normalized and a similarity score is calculated between the two histograms. The similarity score represents a similarity measure between the two histograms, calculated from a subset of bins, which are independently selected for each image.

Abstract: A device is disclosed including a substrate and a floating blinded infrared detector and/or a shunted blinded infrared detector. The floating blinded infrared detector may include an infrared detector coupled to and thermally isolated from the substrate; and a blocking structure disposed above the infrared detector to block external thermal radiation from being received by the infrared detector; and wherein the blocking structure comprises a plurality of openings. The shunted blinded infrared detector may include an additional infrared detector coupled to the substrate; an additional blocking structure disposed above the infrared detector to block external thermal radiation from being received by the additional infrared detector; and a material that thermally couples the additional infrared detector to the substrate and the additional blocking structure. Methods for using and forming the device are also disclosed.

Abstract: Systems and methods are directed to contacts for an infrared detector. For example, an infrared imaging device includes a substrate having a first metal layer and an infrared detector array coupled to the substrate via a plurality of contacts. Each contact includes for an embodiment a plurality of metal studs each having a first end and a second end and each disposed between the first metal layer and a second metal layer, wherein the first end of each metal stud is disposed on a portion of the first metal layer that is at least partially on the surface of the substrate.

Abstract: Various embodiments of the present disclosure may include an imaging system that allows for the transfer of high dynamic range (HDR) radiometric thermal images over a low bitrate interface. The image system may capture HDR images and output the HDR images over a communications interface to be processed. The HDR images may be converted to low dynamic range (LDR) images by a transfer function in order to be sent over the low bitrate interface. An inverse transfer function may also be sent along with the LDR image. Once the LDR image has been sent over the low bitrate interface, the LDR image may be converted to a reconstructed image using the inverse transfer function.

Abstract: Techniques are disclosed for systems and methods to provide setup, network connection, and/or other operations for network cameras. The operations may be initiated in response to placing a user device having proximity-based communications circuitry in proximity of a camera having proximity-based communications circuitry. The user device and the camera may exchange information responsive to placing the user device in the proximity of the camera. The information may include network information sent from the user device to the camera and/or camera information sent from the camera to the user device. The network information may include information associated with a network. The camera may be connected to the network using the network information. The camera may be added to list of accessible cameras on the user device when the camera is connected to the network. The proximity-based communications circuitry may be Near Field Communications circuitry.

Abstract: System including a rotary seal created by a dual-wiper gasket. In exemplary embodiments, the system may comprise a mounting portion and a gimbal assembly. The gimbal assembly may include a first gimbal pivotably connected to and supported by the mounting portion for rotation of the first gimbal about a first axis, and a second gimbal pivotably connected to and supported by the first gimbal for rotation of the second gimbal about a second axis transverse to the first axis. The system also may comprise a gasket encircling the first axis and creating a rotary seal between the mounting portion and the first gimbal. The gasket may have an inner wiper encircled by an outer wiper, with both wipers disposed in circumferentially sealed engagement with the mounting portion or the first gimbal.

Abstract: Various techniques are provided for calibrating a thermal imaging device using a non-contact temperature sensor. In one example, a method includes capturing a thermal image of a scene. The thermal image comprises a plurality of pixel values. The method also includes detecting, by a non-contact temperature sensor, a temperature value associated with a portion of the scene corresponding to a subset of the pixel values. The method also includes comparing the subset of pixel values with the detected temperature value. The method also includes generating a correction term based on the comparing. The method also includes applying the correction term to at least the subset of pixel values to radiometrically calibrate the subset of pixel values. Related systems and alignment processes are also provided.

Abstract: Various embodiments of the present disclosure may include an imaging system that allows for the transfer of high dynamic range (HDR) radiometric thermal images over a low bitrate interface. The image system may capture HDR images and output the HDR images over a communications interface to be processed. The HDR images may be converted to low dynamic range (LDR) images by a transfer function in order to be sent over the low bitrate interface. An inverse transfer function may also be sent along with the LDR image. Once the LDR image has been sent over the low bitrate interface, the LDR image may be converted to a reconstructed image using the inverse transfer function.

Abstract: Imaging systems and methods are disclosed for generating enhanced visual representations of captured data such as infrared image data. For example, the perceived color distance or contrast between colors representing adjacent output levels (e.g., temperature or infrared intensity levels) are enhanced in visual representations of infrared images. According to embodiments, infrared image data values representing a scene may be mapped according to a color palette implemented using complementary colors as adjacent (e.g., successive) base colors or a sequence of colors, that repeats a predetermine set of hues with varying saturation and/or intensity, thereby increasing the color contrast between pixels representing subtle temperature differences in the scene. The color palette can be enlarged by mapping a larger number of distinct output levels to a larger sequence of colors, for example by increasing the bit-depth of the color palette, such that color transitions look smoother and more natural.

Abstract: An apparatus for the wafer level packaging (WLP) of micro-bolometer vacuum package assemblies (VPAs), in one embodiment, includes a wafer alignment and bonding chamber, a bolometer wafer chuck and a lid wafer chuck disposed within the chamber in vertically facing opposition to each other, means for creating a first ultra-high vacuum (UHV) environment within the chamber, means for heating and cooling the bolometer wafer chuck and the lid wafer chuck independently of each other, means for moving the lid wafer chuck in the vertical direction and relative to the bolometer wafer chuck, means for moving the bolometer wafer chuck translationally in two orthogonal directions in a horizontal plane and rotationally about a vertical axis normal to the horizontal plane, and means for aligning a fiducial on a bolometer wafer held by the bolometer wafer chuck with a fiducial on a lid wafer held by the lid wafer chuck.

Abstract: Techniques are disclosed for measurement devices and methods to obtain physical parameters and thermal images associated with a scene in an integrated manner. In one embodiment, a measurement device includes an infrared (IR) imaging module configured to capture thermal images of a scene; a moisture sensor configured to detect a moisture parameter associated with an external article; a housing configured to be hand-held by a user and at least partially enclosing the IR imaging module; a display fixed relative to the housing and configured to display user-viewable thermal images; and a logic device configured to freeze a user-viewable thermal image on the display, overlay information to indicate a first detection of the moisture parameter onto the frozen user-viewable thermal image on the display, and update the overlaid information to indicate a second detection of the moisture parameter.

Abstract: Techniques are disclosed for systems and methods to provide sailing information to users of a mobile structure. A sailing user interface system includes a logic device in communication with a compass or orientation sensor, a wind sensor, and/or a speed sensor. Sensor signals provided by the various sensors are used to determine a heading and a wind direction for the mobile structure, which can be referenced to Magnet North. The wind direction and heading may be used to orient a sail chart rendered by the logic device. The sail chart graphically indicates the heading of the mobile structure relative to the wind direction and a performance contour for the mobile structure. The sail chart may be displayed to a user to refine manual operation of the mobile structure, and the information rendered in the sail chart may be used to autopilot the mobile structure.

Abstract: Various techniques are provided to facilitate electrostatic discharge mitigation for imaging devices. In one example, an imaging device includes an imager assembly. The imaging device further includes a lens holder. The lens holder includes a receiving interface configured to receive a lens assembly therein. The lens holder further includes an alignment pin including electrically conductive material and coupled to the imager assembly to provide an electrostatic discharge path via the imager assembly, where a first portion of the alignment pin has the electrically conductive material exposed and a second portion of the alignment pin has an insulating layer disposed thereon. Related methods and systems are also provided.