A steering device includes a steering shaft, a motor, a stopper mechanism, and a controller. The controller is configured to execute a first process and a second process when a determined condition is established. The first process includes causing the steering wheel to operate to a first operation end through control of the motor and thereafter operate in reverse to a second operation end. The second process includes computing a neutral position of the steering wheel based on a rotational angle of the motor at a time when reverse operation of the steering wheel is started and at a time when the reverse operation of the steering wheel is ended.

Flexibility in design of steering characteristics is enhanced in a leaning vehicle including two front steerable wheels. A vehicle includes a body frame, a left front wheel, a right front wheel, a rear wheel, a leaning mechanism, a steering mechanism, and a leaning-responsiveness-adjusting mechanism. The leaning mechanism includes arms rotatably supported by the body frame. The arms rotate with respect to the body frame so that the body frame leans. The steering mechanism mechanically transfers rotation of the handle to the left front wheel and the right front wheel. Accordingly, the body frame leans in the direction opposite to the rotation direction of the handle. The leaning-responsiveness-adjusting mechanism controls a motor by using an instruction value based on a time derivative value of a physical quantity generated by a motion of a rider affecting leaning of the body frame to thereby adjust responsiveness of leaning of the body frame.

A steering device includes: a turning actuator drive command signal output section to output the turning actuator drive command signal, a turning actuator drive command signal including a drive command signal, and a test drive command signal, the drive command signal being outputted to the turning actuator when the vehicle is in a first state, the test drive command signal being outputted to the turning actuator when the vehicle is in a second state, the turning actuator operation signal input section to receive a signal relating to the operation of the turning actuator, and the abnormality diagnosis section to judge whether or not the steering device is in an abnormal state, based on the signal relating to the operation of the turning actuator with respect to the test drive command signal.

A device for locating a noise occurring in a steering system includes: a sound receiving unit detecting noise occurring in a steering system; a processing unit inputting data on the noise in the steering system into a neural network model that performs learning in advance and locating a position or a component at which the noise occurs in the steering system, the noise being detected by the sound receiving unit; and a storage unit in which the neural network model that performs the learning in advance is stored.

A method and a device generate haptic feedback for a vehicle driver, the haptic feedback being generated by applying an additional torque, which alternates about an average total steering torque, to a steering grip of a vehicle by way of an actuator. When the present haptic feedback is recognized and/or simultaneously when haptic feedback occurs, the actuator is actuated such that the magnitude of the average total steering torque is increased by a compensation torque.

A steering control apparatus and method of an electric power steering (EPS) system for a vehicle includes a learning module configured to learn a learning end angle based on an end angle of an end of a rack bar based on a steering angle, an angular speed limit module configured to detect a target limit angular speed based on the learning end angle and the steering angle, detect an actual motor angular speed based on a steering angular speed, generate a limit current based on an error between the target limit angular speed and the actual motor angular speed, and limit the steering angular speed within the target limit angular speed, and a motor current generation module configured to generate a motor current for motor control based on the limit current and a command current received from a steering control module.

A drive device includes a motor having two sets of winding wires, a controller coaxially disposed with the motor for controlling the motor, and a connector for connecting the controller to an external connector. The controller has a first system control unit for controlling power supplied to one set of winding wires and a second system control unit for controlling power supplied to the other set of winding wires. The connector has a first positive electrode terminal and a first negative electrode terminal for power supplied to the first system control unit, and a second positive electrode terminal and a second negative electrode terminal for power supplied to the second system control unit. A portion of a planar face of the first positive electrode terminal is positioned to overlap a portion of a planar face of the first negative electrode terminal, and a portion of a planar face of the second positive electrode terminal is positioned to overlap a portion of a planar face of the second negative electrode terminal.

A LiDAR system is provided. The LiDAR system includes a first data transmission apparatus, a second data transmission apparatus, a rotator, and a central shaft. The first data transmission apparatus and the second data transmission apparatus are located in the LiDAR system. The rotator is connected with the central shaft through a bearing, the rotator is connected to a bearing rotor, and the central shaft is connected to a bearing stator. The first data transmission apparatus includes a first optical module and a second optical module. The second data transmission apparatus includes a third optical module, a coupling optical system, and a fourth optical module.

A method for determining a sensor offset of a sensor in a device, in particular in a steering system for a motor vehicle. The device has a first component, a second component which is movable with respect to the first component, a resetting element, an actuator and a sensor for determining the relative motion between the first component and the second component. The method comprises the following steps: firstly, a predetermined relative motion between the first component and the second component is generated by the actuator. The resulting relative motion is measured by means of the sensor, and the sensor data obtained from the measurement are stored. A constant sensor offset of the sensor is then determined on the basis of the stored sensor data. Furthermore, a device is described whose sensor offset can be determined by means of the method.

A motor vehicle control device may have a switch-on and switch-off function for at least one electrical load to be controlled by the motor vehicle control device. The motor vehicle control device may include an electronic switching element for arrangement in a supply voltage path of the electrical load and a control unit for controlling the electronic switching element. The control unit is designed to provide a control signal for switching the electronic switching element based on at least one input signal. The control unit may include a resistor connected to the supply voltage path and a current control means connected in series therewith for generating a predefinable voltage difference at the resistor as the control signal for the electronic switching element.