Abstract: A system for observing a flow characteristic of a fluid is provided. The system comprises a nadir-facing sensor, an angle flow sensor, and processing circuitry. The nadir-facing sensor and the angle flow sensor are both provided at a distance above the fluid, and the nadir-facing sensor and the angle flow sensor are both Multiple-Input Multiple-Output phase radar sensors. The processing circuitry is configured to receive sensor data from the nadir-facing sensor and the angle flow sensor, the sensor data includes at least one of a fluid speed or a fluid surface level, and the processing circuitry is configured to determine the flow characteristic based upon the sensor data.

Abstract: A first method includes receiving a first reflected radar signal from a target in a first field of view and receiving a second reflected radar signal from a target in a second field of view offset from the first field of view by a predetermined distance; transforming the first and second reflected radar signals to obtain first and second sets of frequency coefficients, from which a frequency-dependent phase difference is obtained; and calculating a time-delay from the slope of the frequency dependence. A second method includes obtaining summed difference values between the first and second radar responses, where each of the summed difference values corresponds to different time shifts between the first and second radar response, and deriving from the summed difference values a time-delay associated with the target's motion from the first field of view to the second field of view. A third method combines the time-delays or associated speeds obtained from independent estimators.

Abstract: Generating panoramic video viewable at a third-party video management system includes receiving image data captured by at least one camera. The received image data may be captured at a plurality of angles (e.g., stop positions) arranged about a single axis (e.g., about which the camera rotates). The received image data may optionally be analyzed. Based on the received image data (and any optional analysis thereof), panoramic video derived from the captured image data (e.g., still images) may then be generated. A single video stream including the generated panoramic video may then be generated. The single generated video stream may then be sent to a third-party video management system (VMS). The video stream may be usable by the video management system for displaying the generated panoramic video. Various other views or other information may also be included in the single video stream sent to the VMS.

Abstract: Systems and methods for managing a multi-region data incident are provided herein. Example methods include receiving, via a risk assessment server, in response to an occurrence of the data incident, data incident data that including information corresponding to the data incident, wherein the data incident has a plurality of facets with each facet having any of unique and overlapping set of privacy data and media type and associated risk factors requiring facet specific incident risk assessment, automatically generating, via the risk assessment server, a risk assessment and decision-support guidance whether the facet is reportable, from a comparison of the facet to privacy rules, the privacy rules define requirements associated with data incident notification obligations, and providing, via the risk assessment server, the risk assessment to a display device that selectively couples with the risk assessment server.

Abstract: Generating panoramic video viewable at a third-party video management system includes receiving image data captured by at least one camera. The received image data may be captured at a plurality of angles (e.g., stop positions) arranged about a single axis (e.g., about which the camera rotates). The received image data may optionally be analyzed. Based on the received image data (and any optional analysis thereof), panoramic video derived from the captured image data (e.g., still images) may then be generated. A single video stream including the generated panoramic video may then be generated. The single generated video stream may then be sent to a third-party video management system (VMS). The video stream may be usable by the video management system for displaying the generated panoramic video. Various other views or other information may also be included in the single video stream sent to the VMS.

Abstract: Systems and methods for managing a multi-region data incident are provided herein. Example methods include receiving, via a risk assessment server, in response to an occurrence of the data incident, data incident data that including information corresponding to the data incident, wherein the data incident has a plurality of facets with each facet having any of unique and overlapping set of privacy data and media type and associated risk factors requiring facet specific incident risk assessment, automatically generating, via the risk assessment server, a risk assessment and decision-support guidance whether the facet is reportable, from a comparison of the facet to privacy rules, the privacy rules define requirements associated with data incident notification obligations, and providing, via the risk assessment server, the risk assessment to a display device that selectively couples with the risk assessment server.

Abstract: A first method includes receiving a first reflected radar signal from a target in a first field of view and receiving a second reflected radar signal from a target in a second field of view offset from the first field of view by a predetermined distance; transforming the first and second reflected radar signals to obtain first and second sets of frequency coefficients, from which a frequency-dependent phase difference is obtained; and calculating a time-delay from the slope of the frequency dependence. A second method includes obtaining summed difference values between the first and second radar responses, where each of the summed difference values corresponds to different time shifts between the first and second radar response, and deriving from the summed difference values a time-delay associated with the target's motion from the first field of view to the second field of view. A third method combines the time-delays or associated speeds obtained from independent estimators.

Abstract: Creating a background model for image processing to identify new foreground objects in successive video frames. A method includes providing a background image in a user interface. The method further includes receiving a first user input in the user interface that comprises an identification of one or more different regions within the background image. The method further includes receiving a second user input in the user interface that comprises a selection of an image change tolerance for each of the identified different regions. The method further includes providing the background image, information identifying the different regions, and the image change tolerances to an image processor. The background image, the information identifying the different regions, and the image change tolerances are used by the image processor to create a background model to thereby compare a successive image with the background model in order to identify foreground objects within the successive image.

Abstract: Systems and methods for managing a multifaceted data incident are provided herein. Example methods include receiving, via a risk assessment server, in response to an occurrence of the data incident, data incident data that including information corresponding to the data incident, wherein the data incident has a plurality of facets with each facet having any of unique and overlapping set of privacy data and media type and associated risk factors requiring facet specific incident risk assessment, automatically generating, via the risk assessment server, a risk assessment and decision-support guidance whether the facet is reportable, from a comparison of the facet to privacy rules, the privacy rules define requirements associated with data incident notification obligations, and providing, via the risk assessment server, the risk assessment to a display device that selectively couples with the risk assessment server.

Abstract: A first method includes receiving a first reflected radar signal from a target in a first field of view and receiving a second reflected radar signal from a target in a second field of view offset from the first field of view by a predetermined distance; transforming the first and second reflected radar signals to obtain first and second sets of frequency coefficients, from which a frequency-dependent phase difference is obtained; and calculating a time-delay from the slope of the frequency dependence. A second method includes obtaining summed difference values between the first and second radar responses, where each of the summed difference values corresponds to different time shifts between the first and second radar response, and deriving from the summed difference values a time-delay associated with the target's motion from the first field of view to the second field of view. A third method combines the time-delays or associated speeds obtained from independent estimators.

Abstract: Thermal imaging camera images are obtained from a thermal imaging camera that rotates through a plurality of stop positions. The camera captures images at a constant frame rate and at least some of the images correspond to stop positions. Thermal imaging camera images that correspond to a stop position are retained, while images that do not correspond to a stop position are discarded. Retained images are sent in a video stream to a video processor. The video stream is separated into individual thermal imaging camera images and stored for corresponding virtual camera devices that correspond to specific stop positions. In addition, the position of the camera and individual pixels of images are both correlated to geographical location data, and depth values for the pixels are determined based on the geographical data.

Abstract: A first method includes receiving a first reflected radar signal from a target in a first field of view and receiving a second reflected radar signal from a target in a second field of view offset from the first field of view by a predetermined distance; transforming the first and second reflected radar signals to obtain first and second sets of frequency coefficients, from which a frequency-dependent phase difference is obtained; and calculating a time-delay from the slope of the frequency dependence. A second method includes obtaining summed difference values between the first and second radar responses, where each of the summed difference values corresponds to different time shifts between the first and second radar response, and deriving from the summed difference values a time-delay associated with the target's motion from the first field of view to the second field of view. A third method combines the time-delays or associated speeds obtained from independent estimators.

Abstract: Controlling a stepper motor. A stepper motor is driven towards an index position. An attempt is made to stop the stepper motor on the index position in a fashion that would ordinarily cause the stepper motor to ring at the index position. Characteristics of one or more subsequent pulses that would counteract the ringing are determined. The one or more determined subsequent pulses are issued to the stepper motor.

Abstract: Thermal imaging camera images are obtained from a thermal imaging camera that rotates through a plurality of stop positions. The camera captures images at a constant frame rate and at least some of the images correspond to stop positions. Thermal imaging camera images that correspond to a stop position are retained, while images that do not correspond to a stop position are discarded. Retained images are sent in a video stream to a video processor. The video stream is separated into individual thermal imaging camera images and stored for corresponding virtual camera devices that correspond to specific stop positions. In addition, the position of the camera and individual pixels of images are both correlated to geographical location data, and depth values for the pixels are determined based on the geographical data.

Abstract: Detecting an extreme temperature event. A method includes collecting raw data from a high resolution sensor. The method further includes identifying in the raw collected data one or more changing data point values. The method further includes identifying, in the raw collected data that the one or more changing data point values have reached a determined threshold that indicates with a high level of probability that an extreme temperature event has occurred. Alternatively, the method may include identifying in the raw collected data a sudden extreme increase in one or more data point values that cross a threshold which indicates with a high level of probability that an extreme temperature event has occurred. As a result, the method includes issuing an alert indicating that an extreme temperature event has occurred.

Abstract: A seamless lens cover, and methods of forming such a seamless lens cover. The cap structure that covers a camera of a rotating panoramic camera system includes a seamless lens cover through which images are obtained by the camera. The cap structure may be injection molded at an initial lens cover thickness, and then a portion of the as molded initial lens cover thickness may be removed (e.g., by machining away) to achieve the final desired thickness. By such a method, the lens cover may be injection molded at thicknesses suitable for injection molding (e.g., about 0.06 to about 0.1 inch), after which most of the thickness may be machined away, to provide a seamless lens cover having a thickness of less than about 0.015 inch, exhibiting at least 60% transmittance to the thermal spectrum, no lensing characteristics, and no curvature effect.

Abstract: An indexing mechanism may include a drive table, an indexing table, a control ring between the tables, and a cam follower. The cam includes lobes on an inner surface. A drive arm of the cam follower is coupled to the drive table and an end of an indexing arm of the cam follower rides over the lobes during use. A spring may be coupled between the drive table and the indexing table. As the drive table rotates continuously, the components serve to move the indexing table in a non-continuous movement, by which it stops for a period and then moves to the next stop, etc. A camera may take a still image at each stop position, and the images may be stitched together (e.g., through use of an onboard computer) to produce a panoramic image. A power supply may also be provided, so that the entire system may be self-contained.

Abstract: An indexing mechanism may include a drive table, an indexing table, a control ring between the tables, and a cam follower. The cam includes lobes on an inner surface. A drive arm of the cam follower is coupled to the drive table and an end of an indexing arm of the cam follower rides over the lobes during use. A spring may be coupled between the drive table and the indexing table. As the drive table rotates continuously, the components serve to move the indexing table in a non-continuous movement, by which it stops for a period and then moves to the next stop, etc. A camera may take a still image at each stop position, and the images may be stitched together (e.g., through use of an onboard computer) to produce a panoramic image. A power supply may also be provided, so that the entire system may be self-contained.