There is provided with a straddle type vehicle. A direction indicator is formed to project outward in a vehicle width direction and shows a traveling direction of the vehicle. A sensing device detects an obstacle around the vehicle using an ultrasonic wave. The sensing device is arranged in a distal end portion of the direction indicator.

A signaling device is intended to be worn by a driver or rider of a land vehicle or intended to be mounted on such a vehicle, the vehicle preferably being a two-wheeled vehicle. The signaling device includes an accelerometer, an assembly of electrochemical batteries, a first light source, a wireless communicator intended to emit a warning signal, and a control unit. The control unit is intended to activate: the light source when the accelerometer measures a deceleration greater than or equal to a first predetermined deceleration threshold; and the communicator when the accelerometer measures a deceleration greater than or equal to a second predetermined deceleration threshold.

To provide a semiconductor device which suppresses a message image projected by a mobile from varying from a desired position. A semiconductor device has a first area decision part which decides a first area onto which a message image is projected, based on movement information of a mobile. The semiconductor device has a delay period calculation part which calculates a delay period being a period from a first time for projecting the message image onto the first area to a second time when the message image is projectable. Also, the semiconductor device has a second area decision part which adjusts the first area, based on the delay period to decide a second area. Further, the semiconductor device has an image signal conversion part which converts a message image signal according to the second area.

To provide a semiconductor device which suppresses a message image projected by a mobile from varying from a desired position. A semiconductor device has a first area decision part which decides a first area onto which a message image is projected, based on movement information of a mobile. The semiconductor device has a delay period calculation part which calculates a delay period being a period from a first time for projecting the message image onto the first area to a second time when the message image is projectable. Also, the semiconductor device has a second area decision part which adjusts the first area, based on the delay period to decide a second area. Further, the semiconductor device has an image signal conversion part which converts a message image signal according to the second area.

A method for guiding a cyclist on a bicycle equipped with a bicycle handlebar. The method includes: on each side of a central zone in which the bicycle handlebar is attached to the bicycle handlebar stem, separately illuminating a proximal light-emitting zone located next to the central attachment zone or a distal light-emitting zone depending on the route to be followed.

A vehicle lamp tool providing a controller which calculates the luminance distribution of light distribution pattern, an optical device which generates light distribution pattern in an illuminatable area D and a first driving circuit which drives the optical device. The controller transmits a first light distribution correction signal for correcting the inclination of a current light distribution pattern to the first driving circuit if the inclination angle of a vehicle with respect to vertical direction indicated by a detection signal received from a vehicle height sensor is equal to or less than a threshold value. The first driving circuit transmits a first correction driving signal based on the first light distribution correction signal to the optical device. The optical device drives an LD and a light deflector to correct the current light distribution pattern.

Disclosed is a lighting and communication system for providing communication between a vehicle and a helmet worn by a rider over a communication network. The lighting and communication system includes a vehicle system and a helmet system. The vehicle system attached to a handle of the vehicle, the vehicle system includes a joystick attached to the frame of the vehicle for allowing the rider to provide directional signals, a first communication unit configured in the joystick for communicating directional signals with the helmet over the communication network, and a first battery configured to power the joystick and the first communication unit. The helmet system attached to the helmet for communicating with the vehicle system. The helmet system includes a second communication unit attached to the helmet to receive the directional commands from the joystick via the first communication unit, a microprocessor attached to the helmet to process the directional commands received by the second communication unit from the first communication unit, wherein the second communication unit communicates the processed signals over the communication network, plurality of LED lights configured on the helmet to indicate movement of the vehicle based upon the movement of the joystick initiated by the rider, and a second battery configured in the helmet to power the plurality of LED lights, the second communication unit and the microprocessor. The microprocessor controls the operation of the LED lights, wherein the LED lights illuminate based on the directional signals from the joystick to reflect movement of the vehicle.

Disclosed is a lighting and communication system for providing communication between a vehicle and a helmet worn by a rider over a communication network. The lighting and communication system includes a vehicle system and a helmet system. The vehicle system attached to a handle of the vehicle, the vehicle system includes a joystick attached to the frame of the vehicle for allowing the rider to provide directional signals, a first communication unit configured in the joystick for communicating directional signals with the helmet over the communication network, and a first battery configured to power the joystick and the first communication unit. The helmet system attached to the helmet for communicating with the vehicle system. The helmet system includes a second communication unit attached to the helmet to receive the directional commands from the joystick via the first communication unit, a microprocessor attached to the helmet to process the directional commands received by the second communication unit from the first communication unit, wherein the second communication unit communicates the processed signals over the communication network, plurality of LED lights configured on the helmet to indicate movement of the vehicle based upon the movement of the joystick initiated by the rider, and a second battery configured in the helmet to power the plurality of LED lights, the second communication unit and the microprocessor. The microprocessor controls the operation of the LED lights, wherein the LED lights illuminate based on the directional signals from the joystick to reflect movement of the vehicle.

Various systems and methods associated with protecting a rider of an electric bicycle from hazards while riding their bicycle are described. In some embodiments, the systems and methods enhance the safety of the rider in response to current detected conditions surrounding the rider, such as conditions associated with the route or path traveled by the rider, other vehicles within the route or path traveled by the rider, potential hazards within the route or path traveled by the rider, environmental conditions through which the rider is traveling, and so on.

Various systems and methods associated with protecting a rider of an electric bicycle from hazards while riding their bicycle are described. In some embodiments, the systems and methods enhance the safety of the rider in response to current detected conditions surrounding the rider, such as conditions associated with the route or path traveled by the rider, other vehicles within the route or path traveled by the rider, potential hazards within the route or path traveled by the rider, environmental conditions through which the rider is traveling, and so on.