A multifunctional rearview mirror includes a casing having first and second receiving spaces. A mirror is mounted to one side of the casing that is formed with the first receiving space. The second receiving space is located under the first receiving space and has a front surface formed with first through-holes. A distance detection and alarm unit is arranged in the second receiving space and includes an ultrasonic distance detection module, an alarm light module, and a buzzer. The ultrasonic distance detection module is eclectically connected with the alarm light module and the buzzer. The alarm light module is arranged in the first through-holes. The ultrasonic distance detection module emits an ultrasonic wave, which is returned to the ultrasonic distance detection module by an object, so that a distance to the object is calculated and the alarm light module and the buzzer are activated according to the distance.

An aspect of the disclosure sets forth a turn signal system for a steering wheel that is easier to use and improves turn signal usage compliance and, accordingly, safety. The turn signal system includes at least one hand location detection sensor; at least one pressure actuated switch mechanism which is actuatable by the operator; a turn signal control, the turn signal control operatively connected to the at least one hand location detection sensor and the at least one pressure actuated switch mechanism, the turn signal control also operatively connected to left and right turn signals of the vehicle to indicate a turn to the left or right. Wherein actuation of the at least one pressure actuated switch mechanism by a hand of the operator of the vehicle provides a signal to the turn signal control to indicate a turn to the left or right.

A lever operation device includes a lever portion on which a first rotation operation about a first shaft is performed, a magnet attached to a tip portion of the lever portion, a magnetic sensor to detect movement of the magnet due to the first rotation operation performed on the lever portion, and a housing including a first room, in which the tip portion is attached, and a second room which is separated from the first room by a wall and in which the magnetic sensor is disposed.

A driving assistance device includes an unable-to-drive state detection unit configured to detect that a driver is in an unable-to-drive state, the unable-to-drive state detection unit being provided in a vehicle, and a stop control unit configured to execute an automatic stop control causing the vehicle to decelerate and stop based on whether the unable-to-drive state is detected by the unable-to-drive state detection unit, wherein the vehicle is provided with an operator configured to operate the vehicle, includes an operation state detection unit configured to detect an operation state of the operator, and cancels the execution of the automatic stop control in a case where the operation state detection unit detects that the operation state of the operator has changed multiple times during transition to the automatic stop control or during the automatic stop control.

A vehicle lamp includes a turn lamp, a nonvolatile memory, a signal processing device, and a drive circuit. The turn lamp includes a plurality of light emitting elements that independently controllable to be turned on and off. The nonvolatile memory stores a parameter related to control of the plurality of light emitting elements. The signal processing device generates, based on the parameter, a plurality of turn-on commands indicating turn-on states of the plurality of light emitting elements at each time point by executing a software program. The drive circuit drives each of the plurality of light emitting elements based on the plurality of turn-on commands

A lane-change assistance system for a motor vehicle performs a plurality of lane changes from the current lane to a target lane, which are required in order to follow a navigation system outputted route. The plurality of lane changes is performed in response to the lane-change assistance system ascertaining a triggering operation action by the driver, which indicates that the driver wants the lane-change assistance system to perform the plurality of lane changes.

The present disclosure relates to a vehicle and a control method thereof, and more particularly, to an apparatus and a method for implementing a lane change decision aid system (LCDAS). The LCDAS apparatus includes: a sensing device for sensing whether a target vehicle is in adjacent zones of a subject vehicle, whether the target vehicle is in a rear zone of the subject vehicle, or whether the target vehicle is a large vehicle or a compact vehicle; a processor for determining an activation condition for determining whether an LCDAS function is active/inactive and a warning condition for determining whether a warning of the LCDAS function is issued/un-issued, based on a sensing result of the sensing device; a warning device for issuing the warning to a driver based on a determination result of the processor; and a controller for controlling the sensing device, the processor, and the warning device.

Provided herein is a lighting system for a two- or three-wheeled vehicle. The lightning system has at least one light bar each of which has a housing enclosing a support matrix to which a plurality of light emitting diodes are operably attached, a power supply and at least one mount to secure the light bar to the two- or three-wheeled vehicle. The power supply is operably connected to the light bar to operate the light emitting diodes. The power supply may have a driver for operating the light emitting diodes in a sequence.

A direction indicator unit with wipe effect and flashing hazard light function has a right-side flashing light, a left-side flashing light, and a circuit arrangement. The circuit arrangement is configured to detect a first operating signal (B1) indicative of an operation of the right-side flashing light and a second operating signal (B2) indicative of an operation of the left-side flashing light, and to provide a first logical high control signal (SS1) for activating the right-side flashing light when an XOR linkage of the first operating signal (B1) and the second operating signal (B2) results as logical high, and to provide a second logical high control signal (SS2) for activating the left-side flashing light when an XOR linkage of the first operating signal (B1) and the second operating signal (B2) results as logical high.

A method of controlling the vehicle includes determining whether a section to be driven is a turn section; in response to determining that the section to be driven is the turn section, generating a turn path; generating a first risk of collision region based on the generated turn path; predicting a position of an obstacle based on obstacle information detected by an obstacle detector and driving information detected by a driving information detector; generating a second risk of collision region based on the predicted position of the obstacle; based on image information obtained from an imager, determining whether the obstacle exists in the first and second risk of collision regions, respectively; adjusting a risk level based on the presence or absence of the obstacle in the first and second risk of collision regions; and performing a collision avoidance control corresponding to the adjusted risk level.