A steer-by-wire steering system for a vehicle is disclosed, having a steering wheel, at least one sensor for capturing a steering angle of the steering wheel, a processing logic unit for determining a wheel setting angle requirement on the basis of the captured steering angle, and an actuator unit for setting a wheel setting angle at wheels of the vehicle according to the wheel setting angle requirement determined by the processing logic unit. The sensor is electrically connected directly to the vehicle electrical system and is supplied with electrical energy via the latter.

A method for determining a rack-and-pinion position in a steering system having an electric servomotor and a rack includes determining kinematic changes in a transmission path between the servomotor and the rack. The method further includes generating an event signal when a kinematic or dynamic rotor size of the servomotor exceeds an assigned threshold value.

An ECU includes plural sensor units and plural control units. The sensor units include magnetic field detection elements for detecting a rotation of a motor, and output mechanical angles related to the rotation angle in one rotation and count values related to the number of rotations of the motor, respectively. One rotation of the motor is divided into indefinite regions, in which detection deviation of the count values may occur, and definite regions, in which no detection deviation occurs. The definite region of the count value is set to deviate from the definite region of the other count value. Absolute angle calculation units calculate the absolute angles using the count values of the definite regions.

A steering control device for controlling a rotation angle of a motor that drives a steering mechanism according to a rotation angle of a steering wheel, includes a torque controller to control torque of the motor with the rotation angle of the steering wheel as a command value, and a phase advance processor to perform feedback control on the torque of the motor with at least one of the rotation angle and angular velocity of the motor as a command value, and advance a phase of a signal waveform to be fed back for a partial frequency range that includes a resonance frequency of the motor and the steering mechanism in an entire frequency range.

A steering system includes: a steering member; a steering operation mechanism; a reaction force motor; a steering motor; a steering torque sensor; a command value setting circuit; a reaction force command value calculation circuit configured to calculate a reaction force command value; a steering operation command value calculation circuit configured to calculate a steering operation command value based on a steering operation steering angle command value and a manual steering angle command value; a reaction force control circuit configured to cause a rotation angle of the reaction force motor to follow the reaction force command value; and a steered angle control circuit configured to cause a rotation angle of the steering motor to follow the steering operation command value.

A redundant circuit device including a first system circuit and a second system circuit having identical function, the redundant circuit device comprises: a substrate that is partitioned into a first region in which a part of the first system circuit is provided and a second region in which a part of the second system circuit is provided, each of the first region and the second region having a printed wiring; a first mount component that is included in the first system circuit, has three or more pins, and is surface-mounted on one surface of the substrate; and a second mount component that is included in the second system circuit, has an identical number of pins as that of the first mount component and having an identical function as that of the first mount component, and is surface-mounted on the one surface.

A steering control method includes driving a steering wheel to rotate a preset angle by using a steering wheel motor in response to a steering instruction. A rotation angle of the steering wheel is controlled by rotation of the steering wheel motor.

Methods and apparatus are disclosed herein to center a steering wheel. An example vehicle includes a steering assistance system, an axle including a wheel, memory, and a processor to execute instructions to identify a first position of the wheel, detect a request to move the wheel to a second position, adjust the wheel from the first position to the second position via the steering assistance system, disengage the steering assistance system, the disengagement of the steering assistance system to cause the wheel to move to a third position, the third position offset from the second position by an angular offset in a first direction, adjust the wheel to a fourth position, the fourth position offset from the second position by the angular offset in a second direction different than the first direction, and disengage the steering assistance system, the disengagement of the steering assistance system to cause the wheel to move to the second position..

Systems and methods for track vehicle control are provided. In one embodiment, a method comprises: receiving a steering control signal; inputting a first rotation signal from a first encoder representing a rotational frequency and phase of a first electric motor coupled to a first continuous track mechanism; inputting a second rotation signal from a second encoder representing a rotational frequency and phase of a second electric motor coupled to a second continuous track mechanism; and outputting motor control signals to a first and second motor controllers in response to the steering control signal and differences between the rotational frequency and phase for the first electric motor and the rotational frequency and phase for the second electric motor, wherein the first motor controller is coupled to the first electric motor and the second motor controller is coupled to the second electric motor.

A rotation angle detection device including: an angular position calculation unit configured to calculate angular position information representing an angular position of the motor rotation shaft based on a first sensor signal of the first sensor; an rotation number detection unit configured to detect a rotation number of the motor rotation shaft based on a second sensor signal of a second sensor and outputs rotation number information representing the rotation number; a rotation angle calculation unit configured to calculate rotation angle information indicating a rotation angle of the motor rotation shaft based on the angular position information and the rotation number information; and a power supply unit configured to stop supplying power to the first sensor, the angular position calculation unit and the rotation angle calculation unit and to supply power to the second sensor and the rotation number detection unit when the power switch is off.