An apparatus for controlling an MDPS system may include: a column torque sensor configured to sense column torque applied to a steering column of a vehicle; a vehicle velocity sensor configured to sense vehicle velocity of the vehicle; an MDPS basic logic unit configured to decide a first assist command current for driving an MDPS motor in a manual driving mode of a driver; an autonomous driving control unit configured to decide a second assist command current for driving the MDPS motor in an autonomous driving mode of the vehicle; and a mode switching control unit configured to decide a weight into which the driver's steering intention is reflected, and apply the decided weight to the first and second assist command currents to decide a final assist command current for driving the MDPS motor when the vehicle is switched from the autonomous driving mode to the manual driving mode.

A vehicle system for operating a vehicle is provided. The vehicle system includes a first output device configured to output a first output, and a second output device configured to output a second output. The vehicle system operates the vehicle based on the first output from the first output device while obtaining vehicle environment information, determines whether an autonomous take-over event occurs based on the vehicle environment information, operates the vehicle in an autonomous driving mode in response to determining that the autonomous takeover event occurred, determines whether the vehicle system receives a take-over signal from the second output device, and operates the vehicle based on the second output from the second output device in response to determining that the vehicle system received the take-over signal from the second output device.

A host vehicle includes a driver re-engagement assessment system and an X-by-wire device adapted for both manual control and automated control by an automated guidance system. The driver re-engagement assessment system includes a controller, a user interface, and test execution module and a test evaluation module. The user interface is configured to interface with an occupant and output an occupant directive signal for manual control to the controller. The test execution module initiates an occupant re-engagement test upon receipt of the occupant directive signal by the controller. The test evaluation module is configured to receive an occupant performance signal indicative of occupant performance during the re-engagement test, and evaluate the occupant performance signal to determine a test pass result and a test fail result. The manual control of the host vehicle is assumed by the occupant upon the determination of the test pass result.

A steer torque manager (STM) for an advanced driver assistance system (ADAS) of a road vehicle and a method therefor. A driver in the loop functionality determines when to hand over control to a driver. A wheel angle controller uses an ADAS wheel angle request to produce an overlay torque request to be added to a torque request from an electrical power assisted steering. The STM is arranged to receive an assistance torque related signal. When driver assistance is provided by the ADAS, the STM is arranged to feed forward and subtract from the overlay torque request a feed forward signal scaled to be a scaled version of the assistance torque related signal, using a scale factor in the range from 0 to 1 that assumes a lower value if a measure of driver activity indicates high driver activity and a higher value if the measure indicates low driver activity.

A steer torque manager for an advanced driver assistance system of a road vehicle and a method therefor. The steer torque manager includes a driver in the loop functionality for determining when to hand over control to a driver, and a wheel angle controller for providing, from an advanced driver assistance system wheel angle request, an overlay torque request to be added to a torque request from an electrical power assisted steering. The steer torque manager is configured to receive an assistance torque related signal and arranged to scale, in a scaling functionality the bandwidth of the wheel angle controller based on a measure of driver activity, such that the bandwidth is reduced if the measure of driver activity indicates high driver activity and increased if the measure of driver activity indicates low driver activity.

A driving assistance apparatus includes: a driving assistance unit configured to control a braking unit which decelerates a moving body, and assist driving of the moving body by automatic driving; and a switching unit configured to perform instructing a driver of the moving body to operate the braking unit which is under control by the driving assistance unit, and switching from the automatic driving to manual driving by transferring an authority of driving to the driver when receiving an operation of the braking unit by the driver.

An electric power steering apparatus includes a steering angle control section that calculates a steering angle control current command value and the current command value using at least the steering angle control current command value. This control section has a position control section to calculate a basic steering angular velocity command value, a steering intervention compensating section to obtain a compensatory steering angular velocity command value, and a steering angular velocity control section to calculate a steering angle control current command value with the basic steering angular velocity command value, the compensatory steering angular velocity command value and an actual steering angular velocity. The steering intervention compensating section includes a compensating map section having a steering intervention compensating map that determines a characteristic of the compensatory steering angular velocity command value to a steering torque, and obtains the compensatory steering angular velocity command value by the steering torque.

An apparatus for controlling a steering angle, a system including the same, and a method thereof are provided may include a steering angle gain variation determination device that determines an increase or a decrease of a steering angle gain variation rate depending on a steering angle error value, a steering angle gain determination device that determines a steering angle gain based on the steering angle gain variation rate, a steering angle gain regulation device that determines a final gain by reflecting a driver intention in a steering angle gain, and a steering torque determination device that determines steering torque by use of the final gain.

[Problem] An object of the present invention is to provide an electric power steering apparatus that achieves manual steering even if steering intervention is performed by a driver during automatic steering, ensures more safety when the driver steers urgently, and enables both assist control and steering angle control. [Means for solving the problem] An electric power steering apparatus comprises a steering angle control section that calculates a steering angle control current command value for steering angle control based on at least a steering angle command value and an actual steering angle, and a switch judging and gradual-change gain generating section that judges a steering state based on manual input judgment and performs switching of the steering state; the switch judging and gradual-change gain generating section comprises a manual input judging section that performs the manual input judgment by using a threshold to a steering torque; and the electric power steering apparatus calculates a current command value by using at least the steering angle control current command value.

A method for detecting a steering engagement by a driver in a vehicle without a steering wheel sensor system, in which at least one steering sensor associated with a steering system of the vehicle, which sensor is associated either with the steering wheel or with a steering linkage of the vehicle, is used to capture a first application of force into the steering system of the vehicle, in which at least one chassis sensor associated with at least one chassis component of the vehicle is used to capture a second application of force onto the at least one chassis component.