A vehicle includes a first steered axle and a second steered axle behind the first steered axle. The second steered axle is steerable independently from the first steered axle. The vehicle includes wheels on the second steered axle. An electric steering motor is connected to the at least one of the wheels.

Vehicle suspension systems are described herein. An example wheel steering apparatus includes a steering actuator to couple to a rear axle, a tie rod, and a transfer link to couple the steering actuator and the tie rod. The steering actuator is positioned on a first side of a first longitudinal axis of the rear axle and the tie rod positioned on a second side of the first longitudinal axis of the rear axle opposite the first side.

A omnidirectional vehicle includes a chassis, wheels and wheel steering mechanisms. The wheel steering mechanisms are configured between the chassis and the wheels, and are arranged to drive the wheels to rotate about a steering center shaft of each wheel with 180 or more. The omnidirectional vehicle can achieve longitudinal driving and lateral driving, or other driving manners.

Provided is an electric power steering device including: a front-wheel steering mechanism, which is provided to front wheels of a vehicle, and includes a front-wheel steering motor as a drive source; and a rear-wheel steering mechanism, which is provided to rear wheels of the vehicle, and includes a rear-wheel steering motor as a drive source, wherein the rear-wheel steering motor is configured to be a double-inverter three-phase duplex motor, the double-inverter three-phase duplex motor including two three-phase windings and two inverters each configured to individually drive one of the two three-phase windings. Therefore, the electric power steering device is capable of, even when a failure has occurred in the steering motor of the rear-wheel steering mechanism, maintaining a function of the rear-wheel steering mechanism to secure behavior stability of the vehicle.

Crawl operations for four-wheel steering vehicles are described herein. An example vehicle described herein includes four wheels, a front steering actuator to turn the front wheels, a rear steering actuator to turn the rear wheels, a front drive motor to drive the front wheels, and a rear drive motor to drive the rear wheels. The vehicle also includes an electronic control unit (ECU) to activate the front steering actuator to turn the front wheels in a first direction, activate the rear steering actuator to turn the rear wheels in a second direction opposite the first direction such that the front wheels and the rear wheels are turned in opposite directions, activate the front drive motor to drive the front wheels in a reverse direction, and activate the rear drive motor to drive the rear wheels in a forward direction while the front wheels are driven in the reverse direction.

An actuator (1) for a rear axle steering system of a vehicle includes a thrust rod (2) which is longitudinally displaceable within a housing (3). The thrust rod (2) has a rotation lock (4) having a guide element (5) which is guided in the axial direction in a single-part or multi-part slide rail (6) arranged on the housing (3). An elastomer ring (7) is arranged between the slide rail (6) and the housing (3).

An all-wheel steering system for a motor vehicle is described which has an active front axle steering system and an active rear axle steering system. The front axle steering system includes a gear ratio unit which is coupled to a steering wheel. The gear ratio unit is configured to define a front axle steering angle as a function of a steering wheel angle and a front axle steering ratio. In addition, the gear ratio unit is coupled to the rear axle steering system in such a way that the front axle steering ratio is adjustable as a function of a rear axle steering angle. Further, a motor vehicle having such an all-wheel steering system is discussed. Also presented is a method of operating an all-wheel steering system for a motor vehicle.

A control system of a wheel of a vehicle includes: a wheel speed sensor configured to measure a wheel speed of wheels of the vehicle; a data storage configured to store data relating to a plurality of abnormal patterns based on a slip state or a lock state of each wheel; and a controller configured to extract wheel speed pattern data using wheel speeds measured from the wheel speed sensor, to compare the extracted wheel speed pattern data with the stored data relating to the plurality of abnormal patterns, to determine an abnormal pattern among the plurality of abnormal patterns most similar to the extracted wheel speed pattern data according to the comparison, and to detect an abnormal wheel among the wheels of the vehicle based on the determined abnormal pattern.

A rear wheel steering control system for a rear wheel steering (RWS) system of a vehicle can include: a voltage detecting unit detecting a magnitude of a battery voltage of a battery of the vehicle; a supplemental voltage circuit unit generating a supplemental voltage that supplements the battery voltage; and a control unit comparing the magnitude of the battery voltage with a magnitude of a required voltage required for normally operating a rear wheel steering actuator of the RWS system, calculating a magnitude of the supplemental voltage based on the comparing of the magnitude of the battery voltage with the magnitude of the required voltage, and controlling the supplemental voltage circuit unit so as to generate the supplemental voltage according to the calculated magnitude.

A vehicle kinematic control circuit for a vehicle adjusts the track of one or more rear wheels of the vehicle through a limited angular range, using an electric motor, connected mechanically to at least one rear wheel. The motor has at least two independently operable sets of phase windings, each set comprising at least two phase windings, each set connected to a motor bridge, controlled by a microcontroller. In normal use the microcontroller generates motor control signals that apply appropriate PWM modulated voltage waveforms to the set of phase windings connected to that bridge to drive the rotor of the motor in a first manner thereby to actively steer the rear wheel. A fault detection circuit monitors the operation of the one microcontroller, the motor bridge driver circuit, and the two sets of phase windings, to detect a fault condition, and in the event of a fault condition being detected causes one of the non-faulty motor bridges and an associated non-faulty set of phase windings to be operated to drive the rotor of the motor in a second, different manner.