Bicycles and automobiles share the roads and it is imperative that a collision between a car and a bicycle be avoided. A warning system that can be placed on the back of a bicycle that extends upward to alert the general traffic in the area. The top portion of the pole will be equipped with a flag or other warning device and will also be illuminated for greater visibility. The warning system can also be extended outward to alert oncoming traffic to a bicycle in the area. When the arm is extended outward it can also rotate backwards if the warning device is struck by an obstacle.

An autonomous urban transport vehicle (AUTV) to transport a user, including a tricycle including brakes and steering and a controller. The controller includes an autonomous mode processor to control the brakes and steering when the AUTV is in an autonomous mode. The controller also includes a manual mode processor to control manual mode functions of the AUTV when the AUTV is in a manual mode. The manual mode functions are exclusive of actuation of the brakes and steering.

The present disclosure provides a method and an apparatus for processing a motor control signal, an electric vehicle, a storage medium and an electronic apparatus. The method may include: a predetermined operation is detected, wherein the predetermined operation includes that a rider leaves an electric vehicle; and a motor control signal which is input via a speed control component of the electric vehicle is shielded. Through the present disclosure, the problem that the rider of the electric vehicle forgets to press a P gear or fails to activate the P gear successfully to cause the false operation of the speed control component and thus cause a harm to the electric vehicle or a user or a surrounding environment in the related art is solved; and therefore, the vehicle is prevented from being uncontrollable, and the safety of the electric vehicle or the user or the surrounding environment is guaranteed.

Disclosed herein is an active cyclist and/or pedestrian safety system for identifying, warning, and reacting to dangerous situations that may be experienced by cyclists and/or pedestrians. The safety system may receive first information indicative of a head position of a cyclist and determine, based on the first information, a field of view of the cyclist. The safety system may receive second information indicative of an environment of the cyclist and determine, based on the field of view and the environment, an expected trajectory of the cyclist in a next road segment. The safety system may also determine, based on the field of view and the environment, a risk probability for the expected trajectory of the cyclist in the next road segment. The safety system may also generate an instruction to transmit a warning to the cyclist if the risk probability exceeds a threshold value.

A bicycle radar system including a camera is disclosed. The system may include a radar unit and a mobile electronic device that are in communication with one another. The radar unit may transmit radar signals, receive return signals (reflections), and process the returned radar signals to determine a location and velocity of one or more targets located in a sensor field behind a user's bicycle. The mobile electronic device may include a communication component configured to wirelessly receive content including cartographic data and one or more high-risk geographic areas and a processor configured to determine a threat level based on the targets, the high-risk geographic area and a determined geographic position.

Respectively a rider of the autonomous scooter may select a manual drive mode to drive without any assistance, or the rider may control the autonomous scooter remotely by a smartphone when riding or not aboard via a smartphone APP whereby the rider may engage a user interface system providing virtual driving control settings linked with an autonomous drive system to control the autonomous scooter, or the rider can manually control the autonomous scooter. Primarily elements of the autonomous scooter may comprise a platform defined by a front end and a rear end, a deck section to place the rider's feet thereon, and having a base supporting a steering column. Accordingly the steering column is rotatably connected by a motorized wheel adapter configured to turn a suspension fork arrangement containing at least one motorized wheel thus steering and balance control of the autonomous scooter, or the steering column is connected to a truck arrangement containing two motorized wheels, whereby the two motorized wheels provide balance and differential propulsion for steering the autonomous scooter. The motorized wheel adapter and the motorized wheels are systematically controlled by an autonomous drive system adapted to control the autonomous scooter during autonomous drive mode setting.

A vehicle, in particular motorcycle, includes a frame, handlebars with two handlebar grips and a communication unit with at least one sensor for the acquisition of data relating to the vehicle, and an interface for transmitting the acquired data. A handlebar protector is arranged, preferably centrally, between the handlebar grips and the communication unit is arranged underneath the handlebar protector or at least partially, preferably entirely, within the handlebar protector.

A multi-rider vehicle retention apparel system includes a jacket and one or more gloves. The jacket includes loop fasteners on the front face of the jacket, on both the left and right sides. The gloves have palms covered with hook fasteners able to releasably attach to the loop fasteners on the jacket. In use, the jacket may be worn by a vehicle operator, and the gloves may be worn by a rider seated behind the operator. Using the gloves, the rider may be able to very securely hold onto the operator while riding on the vehicle, reducing fear of losing grip.

A multi-rider vehicle retention apparel system includes a jacket and one or more gloves. The jacket includes loop fasteners on the front face of the jacket, on both the left and right sides. The gloves have palms covered with hook fasteners able to releasably attach to the loop fasteners on the jacket. In use, the jacket may be worn by a vehicle operator, and the gloves may be worn by a rider seated behind the operator. Using the gloves, the rider may be able to very securely hold onto the operator while riding on the vehicle, reducing fear of losing grip.

A measurement of the rotation speed of an object is made using a time-of-flight sensor configured to detect a passing of one or more of elements of the object through a given position. The time-of-flight sensor is further mounted on a one-person vehicle configured to protect the one-person vehicle against collisions through the making a time-of-flight measurement of a relative speed between the one-person vehicle and an obstacle.