A vehicular rear backup system includes a rear backup digital camera disposed at a vehicle and a display device having a video display screen disposed in an interior cabin of the vehicle and viewable by the driver of the vehicle. Rear backup video images that are derived from image data captured by the rear backup digital camera are displayed on the video display screen no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode to commence a first backup event. Until the first backup event is completed, the video display screen displays rear backup video images. During a backup event of the vehicle, image data captured by the rear backup digital camera is provided to and is processed by an image processor of the system to detect presence of an object rearward of the vehicle.

An unmanned aerial vehicle (UAV) logs first UAV information at a first frequency. The UAV triggers a camera associated with the UAV to capture an image. In response to triggering the camera to capture the image, the UAV logs second UAV information at a second frequency that is higher than the first frequency. A device that is separate from the UAV identifies a location of the UAV corresponding to the image based on a capture timestamp of the image received from the camera, the first UAV information, and the second UAV information. The device generates a geo-rectified imagery based on the image and the location of the UAV.

A method of collecting visual data using a mobile image capture device is provided. The method comprises the steps of: capturing image data with the mobile image capture device and associating time and location data with each image; and storing the image data and associated time and location data. The method further comprises monitoring the position and orientation of the image capture device. The method further comprises: defining an area surrounding or next to the location of the mobile image capture device; and identifying a characteristic of the defined area based on one or more of: the density of the image data in the area; the age of the image data in the area; and/or data demand values associated with locations within the defined area. The timing of capture of image data is based on the characteristic of the defined area.

According to the present invention there is provided a method of taking a measurement using a sensor mounted on an aerial vehicle, the aerial vehicle having one or more propellers and one or more motors which are selectively operable to drive the one or more propellers to rotate to cause the vehicle to fly, and a sensor mounted on the aerial vehicle, the method comprising the steps of, operating the one or more motors to drive the one or more propellers to cause the vehicle to fly; at a first time instant, slowing down or turning off said one or more motors; while the one or more motors are slowed down or turned off, taking a measurement using said sensor; at a second time instant, which is after the measurement has been taken using the sensor, operating the one or more motors again to drive the one or more propellers to cause the vehicle to fly. There is further provided a corresponding aerial vehicle.

A method for receiving a plurality of captures of a vehicle from a plurality of locations. Calculating a plurality of signatures of the vehicle, each respectfully associated with a corresponding capture from the plurality of captures. Associating the plurality of signatures resulting in a single signature and utilizing the single signature for identifying the vehicle.

A DVM system is configured to include an incident trigger, which is actuated either manually or automatically in response to an “incident. In response to the actuation of the trigger, an incident identifier is defined. During the period of actuation, a plurality of recordings is automatically made, based on an incident recording protocol. These recordings are all associated with the incident identifier. The automation allows an operator to, at the time of the incident, focus on factors other than ensuring important video evidence is being recorded (such as following a subject through a building by looking at various cameras). The association streamlines subsequent review of an incident, as recordings relevant to the incident are commonly identifiable based on the incident identifier.

Technologies assessing driver behavior include a vehicle telematics device configured to analyze sensor data from one or more vehicle sensors to detect whether a vehicle event has occurred and to communicate with a vehicle camera system to obtain video data associated with the detected vehicle event. The vehicle telematics device may transmit the obtained sensor data and/or video data to a remote server system. The vehicle telematics device may also receive a notification from the vehicle camera system that indicates the vehicle camera system has detected a vehicle event. In response to the notification, the vehicle telematics device may obtain sensor data form the one or more vehicle sensors and/or video data from the vehicle camera system and transmit the sensor and/or video data to the remove server system.

A firearm front sight post that is comprised of a camera assembly which captures an image or video, or a series of images or videos of what is in front of the firearm at the instant that the firearm is first fired, and at the instant that each and every subsequent shot is fired. The camera assembly is actuated by a actuation mechanism in communication with the trigger assembly of the firearm, and is activated when the trigger wall is met in the act of pulling the trigger of a firearm. The system is also comprised of a wireless transmitter that automatically sends the image/video from the camera assembly to a mobile application on a smartphone or other smart device, wherein the images/videos are encrypted, time-stamped and dated.

A system (300) and a related method (100) for controlling an optical output of at least one electronic label in a retail environment is provided. The system comprises a camera (310) comprising a transmitter for transmitting a control signal (380, 381) and an electronic label (320) comprising a receiver (325) for receiving the control signal and wherein the electronic label is adapted to change its optical output in response to the control signal, the electronic label is arranged within the field of view of the camera. The camera is adapted to receive an identifier of the electronic label and transmit a control signal comprising the identifier and wherein the electronic label is adapted to receive the control signal comprising the identifier and change its optical output based on that the identifier comprised in the control signal matches an identifier of the electronic label.

The application provides a monitoring method, electronic device and storage medium. The method includes determining a target area to be monitored from an acquired image of a monitored scene; determining a target capture posture and a target capture focal length according to the target area; and controlling a Pan Tilt Zoom (PTZ) camera to capture according to the target capture posture and the target capture focal length. The application can monitor any object within the monitored scene using the PTZ camera with a good capture effect.