A controller for a driver assistance system comprises an output for transmitting a braking control signal and control logic. The control logic is capable of identifying a target vehicle, determining an intervention zone and determining an edge zone. The controller will transmit the braking control signal to request activation of the brakes on the host vehicle in response to the edge zone being equal to or less than zero and the target vehicle being within the intervention zone.

An electronic device and a method are described. The electronic device is adapted to be installed on a handlebar of a vehicle, the electronic device comprising: a processor; a communication module; a display comprising a halo-shaped display; a memory for storing therein executable instructions, the instructions upon being processed by the processor, causing the electronic device to: receive, via the communication module, navigational data from a mobile device, the navigational data being associated with a circular visual signal indication, the circular visual signal indication being indicative of at least one of (i) an upcoming directional instruction and (ii) a distance between a current location and an upcoming location associated with the upcoming directional instruction; and, cause to display, on the halo-shaped display, of the circular visual signal indication.

The described positional awareness techniques employing visual-inertial sensory data gathering and analysis hardware with reference to specific example implementations implement improvements in the use of sensors, techniques and hardware design that can enable specific embodiments to provide positional awareness to machines with improved speed and accuracy.

Aspects of the disclosure relate to a dynamic distance estimation output platform that utilizes improved computer vision and perspective transformation techniques to determine vehicle proximities from video footage. A computing platform may receive, from a visible light camera located in a first vehicle, a video output showing a second vehicle that is in front of the first vehicle. The computing platform may determine a longitudinal distance between the first vehicle and the second vehicle by determining an orthogonal distance between a center-of-projection corresponding to the visible light camera, and an intersection of a backside plane of the second vehicle and ground below the second vehicle. The computing platform may send, to an autonomous vehicle control system, a distance estimation output corresponding to the longitudinal distance, which may cause the autonomous vehicle control system to perform vehicle control actions.

A safety guard is configured to extend down from a body portion of a vehicle for engaging animate and inanimate objects in order to prevent the objects from going under the vehicle. A detection system is also provided, including a plurality of sensors configured to sense an impact experienced by the safety guard and a control unit for analyzing the impact. The analysis can result in various actions being taken, including issuance of an impact warning, an evaluation on the cause of the impact, an assessment on any operator negligence associated with the impact and/or a notification regarding a need to replace the safety guard due to the impact.

A vehicle system and method for transmitting camera-based parameters and video data includes a video camera disposed on a vehicle for viewing an exterior region. The video camera includes an image sensor for generating a video data stream from an exterior region of the vehicle, a controller for providing camera-based parameters, and an image signal processor. The image signal processor is configured to receive the video stream from the image sensor, receive camera-based parameters from the controller, transfer the camera-based parameters onto the video stream, and output an analog signal that includes the video stream and the camera-based parameters. An electronic control unit receives the analog signal, retrieves the camera-based parameters from the analog signal. A vehicle display receives and displays the video stream.

A vehicle controller receives images from a camera upon arrival and upon departure. A location of the vehicle may be tracked and images captured by the camera may be tagged with a location. A departure image may be compared to an arrival image captured closest to the same location as the arrival image. A residual image based on a difference between the arrival and departure images is evaluated for anomalies. Attributes of the anomaly such as texture, color, and the like are determined and the anomaly is classified based on the attributes. If the classification indicates an automotive fluid, then an alert is generated. A machine learning algorithm for generating classifications from image data may be trained using arrival and departure images obtained by rendering of a three-dimensional model or by adding simulated fluid leaks to two-dimensional images.

Vehicle event data playback systems described herein may provide users means for reviewing events recorded by a vehicle event recorder. Circumstances relating to vehicle operation may be visually presented in these playback systems. Video playback from multiple recording devices may be synchronized with each other and/or with information related to the operation of the vehicle during the recorded events to affect a presentation of information related to operation of the vehicle. A user may be presented with many data types in graphical and/or intuitive arrangements.

A driving support information display device includes a status display area controller, a menu display area controller, and a status information controller. The status display area controller manages a status display area having a plurality of status display sections arranged vertically in one side area of a display screen. The menu display area controller manages an upper menu display area having a plurality of selection button sections arranged side by side in an upper area of the display screen and a lower menu display area having a plurality of selection button sections arranged side by side in a lower area of the display screen. The status information controller displays status information in the status display section by providing to the status display area controller status information relating to a functional module assigned to the selection button section that has been touch input.

An information processing apparatus capable of assisting safe driving of a vehicle at a place such as an intersection where the view from the vehicle is obstructed or restricted is provided. On the basis of image information representing an image captured by an image capturing apparatus mounted in a vehicle, a detection processing unit detects a traffic mirror in the image and an object in the traffic mirror. And a calculating unit calculates a position of the object in the detected traffic mirror. Driving assist information is generated on the basis of the calculated position of the object in the traffic mirror, and the generated driving assist information is output.