A remote control apparatus capable of communicating with a control apparatus of an autonomously running work vehicle via a communication apparatus, the remote control apparatus comprising a communication apparatus, a control apparatus, a display apparatus, and cameras for obtaining images of the front and rear, wherein the display apparatus is provided with at least a remote control region for controlling the autonomously running work vehicle, a peripheral image region for displaying images captured by the cameras, and a work status display region, wherein the peripheral image region is provided with a frontal view and a rear view.

In a system (1) comprising construction machine (2), transport vehicle (3) with loading space (4) and image-recording device (5, 36), wherein the image-recording device (5, 36) is arranged at the construction machine (2) and aligned, as a minimum, also towards the loading space (4) of the transport vehicle (3), it is specified for the following features to be achieved: that a reception and display device (18) is arranged at or in the transport vehicle (3), wherein the data recorded by the image-recording device (5, 36) are transmitted to the reception and display device (18) by means of a transmission device (46) arranged at the construction machine (2).

A method for dynamically registering a graphic upon a cropped image obtained from a camera device includes capturing an original image obtained from the camera device. Intrinsic calibration information for the camera device, extrinsic information for the camera device and vehicle information are monitored. The cropped image is generated based on cropping parameters to exclude undesirable content from the original image. The intrinsic calibration information is adjusted based on a relationship to the cropping parameters. The graphic is dynamically registered upon the cropped image based on the adjusted intrinsic calibration information for the camera device, the monitored extrinsic information for the camera device and the monitored vehicle information.

A monitoring and surveillance system arranged for processing video data associated with a vehicle, wherein said system is arranged to operate in at least two operating modi, a first modus of said two modi being associated with a first latency requirement for said video data and a second modus of said two modi being associated with a second latency requirement, said system comprising a camera unit, arranged to be installed in said vehicle, wherein said camera unit is arranged for capturing video data; a streaming unit, arranged to be installed in said vehicle, and arranged for receiving said video data and for transmitting said video data over a telecommunication network to a video processing server; said video processing server arranged for selecting a modus of said at least two operating modi, and for communicating said selected modus, over said telecommunication network, to said camera unit such that said streaming unit can be tuned to said selected modus. Complementary systems and methods are also presented herein.

In a vehicular visibility support apparatus, a camera positioned on a front portion that is either the left side or the right side of a vehicle provides an image of a view laterally behind the vehicle including a part of a face of the side of the vehicle as a camera image. An input portion accepts input manipulation to generate an input signal. A control portion trims a desired region in the camera image based on the input signal and provides a trimmed image. The control portion trims the camera image based on: a vertical reference line including a part of the face on the side of the vehicle in a trimmed image before the input manipulation is accepted by the input portion, and a horizontal reference line orthogonal to the vertical reference line; and a direction of movement for change to the desired region inputted to the input portion.

This invention relates to an Extended Perception System that extends the perception of an object's surroundings. Three closely related primary sets of embodiments of this invention include: one set of embodiments is mounted on a set of one or more vehicles; a second set of embodiments is worn by a set of one or more persons and/or animals; and a third set of embodiments which can be in a location fixed with respect to terrestrial and/or other features. Improvements to head-mounted displays are disclosed.

An apparatus comprising a processor and a memory. The processor may be configured to (i) receive video frames captured by a capture device and (ii) perform video analysis on the video frames to extract metadata corresponding to objects detected in the video frames. The memory may be configured to (i) store co-ordinates corresponding to a plurality of regions of the video frames and (ii) provide temporary storage for the video frames to enable the processor to perform the video analysis. The video analysis may perform a different amount of processing for detecting the objects on each of the plurality of regions. One of the regions corresponds to a portion of the video frame comprising a hood of a vehicle.

A method for navigating a vehicle automatically from a current location to a destination location without a human operator is disclosed. The method includes identifying a vehicle location using global positioning system (GPS) data regarding the vehicle. Also included is identifying that the vehicle location is near or at a parking location. Then, using mapping data defined for the parking location. The mapping data at least in part is used to find a path at the parking location to avoid a collision of the vehicle with at least one physical structure when the vehicle is automatically moved at the parking location. The method includes instructing the electronics of the vehicle to proceed with controlling the vehicle to automatically move from the current location to the destination location at the parking location. The electronics use as input at least part of the mapping data and sensor data collected from around the vehicle by at least two vehicle sensors. The path is configured to be updatable dynamically based on changes in the destination location or changes along the path. The destination location is a parking spot for the vehicle at the parking location.

The invention is a vehicular surveillance system that captures images of road and vehicles in front of a vehicle as well as position and gaze of a driver. The images are captured and stored so as to enable someone to access image data captured prior to and at the time of an accident.

A system and method for providing rear seat monitoring within a vehicle that include activating a vehicle camera system to capture images of at least one rear seat of the vehicle. The system and method also include determining if at least one rear seat passenger is located within the at least one rear seat of the vehicle and storing a detection indication data when the at least one rear seat passenger is determined to be located within the at least one rear seat of the vehicle. The system and method further include providing at least one type of alert based on analyzing the detection indication data and determining the location of the at least one rear seat passenger included within the detection indication data.