A rear alarm sensor assembly includes: a sensing part that generates waves and a sensing signal, based on contents obtained by detecting an approaching object by the generated waves; a controller that generates a transmission signal including the sensing signal and an identifier for identification and transmits the generated transmission signal to a body control module, the controller including a plurality of identification terminals for changing the identifier according to a connection relation and a ground terminal that is grounded; and a determination device that is electrically connected to the ground terminal and moves so as not to be connected to the plurality of identification terminals or so as to be connected to one of the plurality of identification terminals. In particular, the determination device electrically connects the connected identification terminal and the ground terminal to change the connection relation of the plurality of identification terminals.

An assisted driving system can provide forward clearance guidance for a vehicle by using data about an object attached to the vehicle and data about a space in an expected path of travel of the vehicle. The data about the object can be input into the vehicle's data processing systems through a mobile application on a driver's smartphone, and the mobile application can be configured to exchange information with the vehicle's data processing systems through a wired (e.g. USB) or wireless (e.g., Bluetooth) interface.

A sensor and indicator light mounting structure comprising: a single sensor configured to observe an obstacle by emitting an emission wave to an area around a vehicle body of a cargo handling vehicle and receiving a reflection of the emission wave; a single indicator light configured to notify a person around the vehicle body of a presence of the cargo handling vehicle; and a mounting member configured to mount the sensor and the indicator light on the vehicle body, wherein the mounting member is configured to be disposed on an upper surface of the vehicle body, the sensor and the indicator light vertically overlap each other to be mounted on the mounting member, and the indicator light is arranged below the sensor.

A retrofit trailer board system for vehicles is disclosed, including a trailer board carrying a plurality of signalling lights on a surface thereof, and a relaying control unit which is connected between the trailer board and a plurality of optical sensors. Each optical sensor is arranged for removable connection to the exterior surface of respective vehicle lights, each sensor being configured to issue a signal responsive to operation of a vehicle light.

A vehicle lighting system includes: a lighting device that emits a first light and a second light to a periphery of an own vehicle, the second light having a higher directivity than the first light; a camera to acquire image information; a detector to emit an electromagnetic wave and acquire a reflection wave; and an electronic control unit configured to detect a physical body using the image information, detect the physical body using information of the reflection wave, control the lighting device such that the first light is emitted to the physical body detected by the reflection wave, determine whether the physical body detected using the image information in a state where the first light is being emitted is an target object, and control the lighting device such that the lighting device emits the second light toward a predetermined range around the target object.

A system is described for providing forward maneuvering information of a vehicle to avoid obstacles that may damage the vehicle. The system includes a microprocessor configured to execute instructions stored on a non-transitory computer readable medium. The microprocessor is coupled to a sensor, a monitoring sensor, and a head-up display (HUD). The sensor receives information of surroundings of the vehicle. The monitoring sensor determines an angle of a steering wheel. The microprocessor receives the information and the angle, determines a guided path for the vehicle based on the information and the angle, and transmits the guided path to the HUD.

Vehicle parking assist is described. In an example, computing system(s) associated with a first vehicle can receive, from sensor(s) associated with the first vehicle, sensor data associated with a second vehicle. Additionally, the computing system(s) can receive an indication that a second vehicle is proximate the first vehicle and can determine, based at least partly on the sensor data, that the second vehicle is moving toward a location proximate the first vehicle (e.g., to park). Based at least partly on the sensor data, the computing system(s) associated with the first vehicle can determine a position, an orientation, and/or a velocity of the second vehicle and based at least partly on determining the position, the orientation, and/or the velocity, can determine instruction(s) for guiding the second vehicle, for example to park. The instruction(s) can be output via light emitter(s), sound emitter(s), and/or a remote user interface associated with the second vehicle.

Disclosed is a method and system that receives sensor information from each of a plurality of sensors. Each sensor in the plurality is associated with a vehicle. The sensor information includes location coordinates of each vehicle in the plurality. The sensor information associated with each vehicle in the plurality then is translated to parking statistics information. In one embodiment, the translation is based on an aggregate of sensor information corresponding to the plurality of vehicles. The system then communicates parking statistics information to the vehicle.

Disclosed is a method and system that receives sensor information from each of a plurality of sensors. Each sensor in the plurality is associated with a vehicle. The sensor information includes location coordinates of each vehicle in the plurality. The sensor information associated with each vehicle in the plurality then is translated to parking statistics information. In one embodiment, the translation is based on an aggregate of sensor information corresponding to the plurality of vehicles. The system then communicates parking statistics information to the vehicle.

Disclosed is a parking assist device (100) including a parking assist control unit (5) that performs parking assist for a host vehicle (1) by using a first sensor (4) for parking assist disposed in the host vehicle (1), and a guide display control unit (25) that causes a display device (20) to display a guide display based on a first effective detection range (A.sub.L, A.sub.R) of the first sensor (4) in a state in which the guide display is superimposed on a front view with respect to the host vehicle (1).