A hitch cross path alert system for a vehicle is presented. A first sensor may detect whether a hitch is connected to a hitch receiver connected to the vehicle. A second sensor may identify a pedestrian in proximity to the vehicle. A processor may be configured to predict a path of the pedestrian based on data captured by the second sensor and to cause the vehicle to output an audio or visual warning to the pedestrian.

Among other things, techniques are described for expressive vehicle systems. These techniques may include obtaining, with at least one processor, data associated with an environment, the environment comprising a vehicle and at least one object; determining an expressive maneuver including a deceleration of the vehicle such that the vehicle stops at least a first distance away from the at least one object and the vehicle reaches a peak deceleration when the vehicle is a second distance away from the at least one object; generating data associated with control of the vehicle based on the deceleration associated with the expressive maneuver; and transmitting the data associated with the control of the vehicle to cause the vehicle to decelerate based on the deceleration associated with the expressive maneuver.

A collision avoidance method for a vehicle includes monitoring a lateral distance between the vehicle and a target vehicle while the vehicle is travelling within a first lane and the target vehicle is travelling within an adjacent second lane, activating a warning on the vehicle and automatically adjusting operation of the vehicle to increase the distance between the vehicle and the target vehicle when the lateral distance between the vehicle and the target vehicle is less than the threshold distance while the vehicle is travelling within the first lane. Automatically adjusting operation of the vehicle may include one or both of steering the vehicle laterally away from the target vehicle and adjusting a longitudinal velocity of the vehicle. A related collision avoidance system is also provided.

An external cladding component of or for a vehicle, by which information can be displayed, is disclosed. The cladding component has a base body with a first surface and a second surface, the second surface facing to the exterior of the cladding component, and an aperture running through the base body, and a light source providing a beam of light, wherein the light source is at least partially arranged within the aperture and protrudes the second surface, or the beam of light is running through the aperture, wherein the beam of light at least partially impinges on an illumination section provided by the second surface.

The invention discloses a multi-lighting projection warning device for vehicle turning, which comprises a composite lamp and a control unit. The composite lamp is arranged on one side of a vehicle and combined with a range indicator light, a contour indicator light, and a text or pattern indicator light, so that the composite lamp can project lighting to a visual blind spot when the vehicle turns or reverses to appear a warning area. The range indicator light is used to illuminate an entire range of the warning area, the contour indicator light is used to clearly mark a contour of the warning area, and the text or pattern indicator light is used to project text or pattern on the warning area to enhance warning effect. The control unit is connected to the composite lamp to enable functions of controlling rotation and start-stop lighting of the composite lamp. Thereby, when the vehicle is turning, the invention projects composite lightings on the ground at the turning side to form the warning area, so as to actively warn other passers-by to dodge the warning area and increase the safety of passers-by.

An active notice device according to an embodiment includes a signal receiver configured to receive a signal generated by the active sensor of the surrounding vehicle, a signal analyzer configured to analyze characteristics of the signal received by the signal receiver, an information generator configured to generate information recognizable by the surrounding vehicle according to user setting, a signal generator configured to amplify and generate characteristics of the signal analyzed by the signal analyzer using the information generated by the information generator, and a signal transmitter configured to transmit the signal amplified and generated by the signal generator to an active sensor of the surrounding vehicle corresponding thereto.

A vehicle drive assist apparatus includes a surrounding-condition-information acquiring unit that acquires surrounding condition information, a vehicle-state-information acquiring unit that acquires vehicle state information, a light-distribution control processor that executes light distribution control, a traveling control processor that executes traveling control in accordance with traffic lane designation, a DDI detector that detects a DDI in a front region based on the surrounding condition information and determines whether the vehicle is entering or exiting from the DDI based on the surrounding condition information and the vehicle state information, and a control switch. When the vehicle entering the DDI is detected, the control switch switches the traveling control and the light distribution control from standard traveling control to non-standard traveling control. When the vehicle exiting from the DDI is detected, the control switch switches the traveling control and the light distribution control from the non-standard traveling control to the standard traveling control.

A motorcycle including a motorcycle body having a front part, a tail part and a central part between the front part and the tail part front and rear wheels constrained to the motorcycle body (2,3,4), a traction engine constrained to the motorcycle body (2,3,4) and operatively connected to at least one of the wheels, at least one optical signalling device fixed to the motorcycle body arranged and oriented so as to be visible by a vehicle that is following the motorcycle, an electronic control unit of the optical signalling device operatively connected to the optical signalling device, an obstacle sensor fixed to the motorcycle body (2,3,4) and operatively connected to the electronic control unit, where the electronic control unit is adapted and configured to receive at least one output signal supplied by the obstacle sensor, verifying whether said output signal meets at least one logical activation condition and, in such case, turning on the optical signalling device to signal a risk of collision with the motorcycle to the vehicle which follows the motorcycle, and where the obstacle sensor is arranged and oriented so that the output signal supplied to the electronic control unit carries information correlated to the presence of obstacles placed in front of the motor cycle.

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 head lamp system of a vehicle and an operating method thereof, and includes a vehicle sensor for detecting driving situations of a vehicle, a first Digital Micro mirror Device (DMD) module and a second DMD module that include a plurality of micro-mirrors, and a module controller for controlling the plurality of micro-mirrors included in the first and second DMD modules based on signals provided from the vehicle sensor.