The invention relates to a method and a system for determining the capability of a sensor contained in a satellite to access a target region. The position of the satellite is ascertained, the viewing radius of the sensor in the direction of a target reference point in a target region is then determined, the extension of the target region in the direction of a satellite position point is ascertained, and the sensor is determined to be capable of accessing the target region if the distance between the satellite position point and the target reference point in the target region is less than or equal to the sum of the viewing radius of the sensor and the extension of the target region in the direction of the target reference point.

A tracking method is disclosed. The method determines the position of a location marked on a wall on the basis of image coordinates of a first image point, image coordinates of a second image point, the emission direction associated with the second image point, and the respective distances of the axis of a base station from the wall in the associated emission direction.

The method employs a computer interconnected with a GPS transceiver and a distance measurement means and operatively interconnected with a digital camera, all provided on a moving vehicle, in order to acquire a plurality of geographic location related images. A first geographic position is obtained from the GPS transceiver and a plurality of distance measurements are then received before a second geographic position is taken. A photo request is generated after a pre-determined distance has been traveled and is transmitted to the digital camera. The camera takes a photo based on the request and the photos, photo requests, first and second positions and distance measurements are stored for post-processing. The post-processing determines a path traveled by the vehicle using the positions and distance measurements and assigns an accurate geographic location and orientation to each photo. The method is useful in building a database of geographically related images.

The method employs a computer interconnected with a GPS transceiver and a distance measurement means and operatively interconnected with a digital camera, all provided on a moving vehicle, in order to acquire a plurality of geographic location related images. A first geographic position is obtained from the GPS transceiver and a plurality of distance measurements are then received before a second geographic position is taken. A photo request is generated after a pre-determined distance has been traveled and is transmitted to the digital camera. The camera takes a photo based on the request and the photos, photo requests, first and second positions and distance measurements are stored for post-processing. The post-processing determines a path traveled by the vehicle using the positions and distance measurements and assigns an accurate geographic location and orientation to each photo. The method is useful in building a database of geographically related images.

A system and method for providing a video merged from two independent video sources to a display is disclosed. The system and method includes receiving an enhanced vision video from an enhanced vision system, receiving a synthetic vision video from a synthetic vision system and selecting an enhanced frame in the enhanced vision video. The system and method also includes selecting a synthetic frame from the synthetic vision video corresponding to the selected enhanced frame, analyzing the enhanced frame to detect objects according to a first algorithm, analyzing the synthetic frame to detect default frame segments, merging the enhanced frame and the synthetic frame to provide a merged frame that includes detected objects and detected default frame segments and displaying the merged frame on a display.

A system and method for providing a video merged from two independent video sources to a display is disclosed. The system and method includes receiving an enhanced vision video from an enhanced vision system, receiving a synthetic vision video from a synthetic vision system and selecting an enhanced frame in the enhanced vision video. The system and method also includes selecting a synthetic frame from the synthetic vision video corresponding to the selected enhanced frame, analyzing the enhanced frame to detect objects according to a first algorithm, analyzing the synthetic frame to detect default frame segments, merging the enhanced frame and the synthetic frame to provide a merged frame that includes detected objects and detected default frame segments and displaying the merged frame on a display.

An electronic device and a method for displaying an image transmitted by a robot and remotely controlling a movement of the robot are provided. The electronic device includes a communicator, an inputter, a display, and a controller. The communicator receives, from the robot, an image photographed by the robot and time information. The inputter receives a command to control the robot. The display displays a screen corresponding to the image. The controller calculates a time delay between the electronic device and the robot based on the time information, control the display to display a graphical object to be overlaid on the screen, and control the communicator to transmit the command to the robot. The graphical object represents a field of view of the robot at a current time. The field of view of the robot at the current time may be estimated based on the time delay information.

A system may include an unmanned surveyor and a controller for the surveyor. The controller may include a headset. The surveyor includes a vehicle for moving within an environment and a camera for capturing video or images of the environment. The surveyor identifies points within the environment, and positions of those points (e.g., latitude, longitude, elevation). The surveyor may calculate spatial dimensions of virtual lines and/or shapes superimposed within the real-world environment. The controller may control the surveyor. The surveyor may be responsive to a controller headset that detects movement. The controller may display video or images captured by the surveyor, and may provide to a user an immersive first-person perspective of the environment. The user may utilize the controller to superimpose virtual lines and shapes onto the environment. These superimposed lines and shapes may trace real-world objects, enabling the user to remotely evaluate features of the real-world objects.

[Object] To provide a novel and improved information processing device that can make more efficient an inspection performed by a flying body capable of performing imaging. [Solution] Provided is an information processing device including an imaging position information acquisition unit configured to acquire imaging position information at a time when a structure is imaged which is acquired by an imaging device configured to fly over a periphery of the structure to image the structure on the basis of certain flight information, and a damage data generating unit configured to use a captured image of the structure imaged by the imaging device and the imaging position information and to generate data related to damage of the structure including position information of damage of the structure included in the captured image.

[Object] To provide a novel and improved information processing device that can make more efficient an inspection performed by a flying body capable of performing imaging. [Solution] Provided is an information processing device including an imaging position information acquisition unit configured to acquire imaging position information at a time when a structure is imaged which is acquired by an imaging device configured to fly over a periphery of the structure to image the structure on the basis of certain flight information, and a damage data generating unit configured to use a captured image of the structure imaged by the imaging device and the imaging position information and to generate data related to damage of the structure including position information of damage of the structure included in the captured image.