A headlight control system controls a headlight of a moving object. The moving object includes the headlight including a plurality of light emission units, and an imaging unit configured to capture images of circumstances in front. The headlight control system includes an irradiation pattern controller configured to perform control for changing at least one of presence or absence of light emission and a degree of light emission of each of the light emission units to change an irradiation pattern of the headlight to one of a plurality of irradiation patterns, an imaging controller configured to perform control such that the imaging unit captures the images of the circumstances in front for each of the irradiation patterns to acquire captured images, and a learning unit configured to learn an irradiation pattern suitable for the circumstances in front based on captured images captured for each of the irradiation patterns.

Presented are intelligent electronic footwear and apparel with controller-automated features, methods for making/operating such footwear and apparel, and control systems for executing automated features of such footwear and apparel. A method for operating an intelligent electronic shoe (IES) includes receiving, e.g., via a controller through a wireless communications device from a GPS satellite service, location data of a user. The controller also receives, e.g., from a backend server-class computer or other remote computing node, location data for a target object or site, such as a virtual shoe hidden at a virtual spot. The controller retrieves or predicts path plan data including a derived route for traversing from the user's location to the target's location within a geographic area. The controller then transmits command signals to a navigation alert system mounted to the IES's shoe structure to output visual, audio, and/or tactile cues that guide the user along the derived route.

Presented are intelligent electronic footwear and apparel with controller-automated features, methods for making/operating such footwear and apparel, and control systems for executing automated features of such footwear and apparel. A method for automating a collaborative operation between an intelligent electronic shoe (IES) and an intelligent transportation management (ITM) system includes receiving, via a detection tag attached to the IES shoe structure, a prompt signal from a transmitter-detector module communicatively connected to a traffic system controller of the ITM system. In reaction to the received prompt signal, the detection tag transmits a response signal to the transmitter-detector module. The traffic system controller uses the response signal to determine a location of the IES's user, and the current operating state of a traffic signal proximate the user's location. The traffic system controller transmits a command signal to the traffic signal to switch from the current operating state to a new operating state.

The present disclosure relates to a device and a method for controlling a vehicle. The device may include a camera for obtaining an image of a region around the vehicle and outputting image information, a navigation for outputting a current location of the vehicle as map information, a front radar for sensing an object in front of the vehicle and generating front radar information, a front-lateral radar for sensing an object in front of and lateral to the vehicle and generating front-lateral radar information, a lamp controller that generates a shadow zone code based on at least one of the image information, the map information, the front radar information, or the front-lateral radar information, and a lamp for forming a shadow zone in a light irradiation pattern based on the shadow zone code.

Provided is a vehicle headlight device which can improve overlooking of pedestrians by a drive, even under adverse conditions such as nighttime or rain at night. A vehicle headlight device includes: a photoirradiator which irradiates light on a light distribution region outside of a travel roadway in an irradiation pattern in which a bright region and a dark region are alternately repeated; a detector which detects presence of a pedestrian in the light distribution region; and a controller which controls the photoirradiator based on a detection result of the detector. In this embodiment, the detector generates a detection output in which a pedestrian accuracy which is an extent to which a detection target is likely a pedestrian is a second pedestrian accuracy lower than a first pedestrian accuracy which is a degree activating a pedestrian protection brake, and the controller illuminates the photoirradiator in response to the detection output.

A vehicle headlight device is provided which can improve overlooking of pedestrians by a driver, even under adverse conditions such as nighttime or rain at night. The vehicle headlight device includes a photoirradiator which irradiates light in a light distribution region of the vehicle in an irradiation pattern in which a bright region and dark region are alternately repeated, in which the photoirradiator irradiates an irradiation pattern so as to flow along the travel direction of the vehicle. In this state, the photoirradiator includes a converter which changes a velocity at which flowing the irradiation pattern according to the vehicle speed of the vehicle, and the converter causes the velocity at which scenery viewed from the vehicle flows and the velocity at which flowing the irradiation pattern to match according to vehicle speed.

Presented are intelligent electronic footwear with controller automated features, methods for making/using such footwear, and control systems for executing automated features of intelligent electronic footwear. An intelligent electronic shoe includes an upper that attaches to a user's foot, and a sole structure attached to the upper for supporting thereon the user's foot. A collision threat warning system, a detection tag, a wireless communications device, and a footwear controller are all mounted to the sole structure/upper. The detection tag receives a prompt signal from a transmitter-detector module and responsively transmits thereto a response signal. The footwear controller receives, through the wireless communications device, a pedestrian collision warning signal generated by the remote computing node responsive to the response signal. Responsively, the footwear controller transmits a command signal to the collision threat warning system to generate a visible, audible and/or tactile alert warning the user of an impending collision with a vehicle.

Presented are intelligent electronic footwear with controller automated features, methods for making/using such footwear, and control systems for executing automated features of intelligent electronic footwear. An intelligent electronic shoe (IES) includes an upper that attaches to a user's foot, and a sole structure that is attached to the upper and supports thereon the user's foot. An alert system, which is mounted to the sole structure and/or upper, generates predetermined outputs in response to electronic command signals. The IES system also includes a wireless communications device that wirelessly communicates with a remote computing node, and a footwear controller that communicates with the wireless communications device and alert system. The footwear controller receives location data indicative of the user's and remote computing node's locations, determines whether the user's location is within a predetermined location/proximity to the node's location and, if so, transmits command signals to the alert system to notify the user/vehicle.

A method for controlling an adaptive motor vehicle headlight (AMVH), wherein a first data storage device (DSD) is assigned to the AMVH, which is designed to emit different segmented light distributions having a resolution of at least 2×12 and has light sources arranged in segments for this purpose, each segment including at least one LED light source. The method includes: a) providing the AMVH and the first DSD and storing a number of data sets on the first DSD, b) connecting the AMVH to a motor vehicle, which is designed to output control data for controlling the AMVH, c) transmitting the control data by the motor vehicle to the AMVH, wherein the AMVH has an internal computing unit, which receives the control data and selects and retrieves data sets stored in the first DSD as a function of the control data (“active data sets”),d) controlling the light sources arranged in the segments by the computing unit in accordance with the active data sets, d1) determining the number of active data sets, wherein the control data is used to give each active data set an individual percentage weighting, d2) determining target light intensities to be output of each segment by superimposing the light intensity values that can be derived from the active data sets taking the respective weighting into account, d3) outputting the target light intensities for each segment taking into account a permissible maximum temporal rate of change of the light intensity that can be predetermined.

A lamp control device includes: at least two lamps; a lamp ECU provided in each of the at least two lamps and configured to perform a lamp control on the each of the at least two lamps; and a vehicle ECU configured to communicate a control signal to the lamp ECU. The vehicle ECU is connected to the lamp ECU via a first high-speed communications line. The lamp ECU is configured to independently perform a lamp control by communication through the first high-speed communications line.