[Problem]

An object of the present invention is to provide a high-performance electric power steering apparatus that can smoothly switch a steering control mode with a simple structure and does not make a driver uncomfortable when the driver steers a handle in an automatic steering control.

[Means for Solving the Problem]

The present invention is the electric power steering apparatus that has a function, which switches between a manual steering control which drives a motor by the first motor current command value calculated based on at least a steering torque and an automatic steering control which drives the motor by the second motor current command value calculated at a steering angle control section so that an actual steering angle follows-up a target steering angle, comprising: a target steering angle correcting section that performs a calculation process for the steering torque depending on a steering state and vehicle speed and outputs a target steering angle correction value, and a correction outputting section that corrects the target steering angle by using the target steering angle correction value and inputs a corrected correction target steering angle into the steering angle control section.

Systems, methods, tangible non-transitory computer-readable media, and devices for operating an autonomous vehicle are provided. For example, the disclosed technology can include receiving state data that includes information associated with states of an autonomous vehicle and an environment external to the autonomous vehicle. Responsive to the state data satisfying vehicle stoppage criteria, vehicle stoppage conditions can be determined to have occurred. A severity level of the vehicle stoppage conditions can be selected from a plurality of available severity levels respectively associated with a plurality of different sets of constraints. A motion plan can be generated based on the state data. The motion plan can include information associated with locations for the autonomous vehicle to traverse at time intervals corresponding to the locations. Further, the locations can include a current location of the autonomous vehicle and a destination location at which the autonomous vehicle stops traveling.

A control device for an electric power steering device includes an inverter converting direct current voltage into alternating current voltage, and apply to a synchronous motor; and a controller for converting three-phase current flowing in the synchronous motor into d-axis and q-axis currents, performing proportional integral control for a deviation between q-axis current command and the q-axis current so that the q-axis current follows the q-axis current command, to calculate q-axis voltage command, performing proportional integral control to calculate d-axis voltage command, converting the d-axis and q-axis voltage commands into three-phase voltage command, and controlling the inverter based on the three-phase voltage command. A q-axis proportional gain used in the proportional integral control for the q-axis current is obtained using a time constant of a q-axis current control system, a q-axis or d-axis inductance, and a constant greater than zero and less than one.

An autonomous driving controller includes: a processor to collect driving data when a vehicle is traveling and calculate a steering override reference value, which is a criterion of determining an override mode, based on the collected driving data; and a storage to store the collected driving data and a set of instructions executed by the processor to calculate the steering override reference value. In particular, the processor controls autonomous driving by varying the steering override reference value based on the collected driving data or information regarding a driver of the vehicle.

A steering device is provided to perform a safe transition from an automatic driving mode to a manual driving mode when necessary. When it is determined necessary to transition from the automatic driving mode to the manual driving mode during the automatic driving mode, a transition period before an end time point of the automatic driving mode is set, a driving operation reliability indicative of whether or not it is possible to perform the transition is determined, and the transition when it is determined that it is possible to perform the transition to the manual driving mode during the automatic driving mode. Consequently, the transition can be controlled so that transition is not performed instantly, such as, for example, in a case where a driver is not driving during the automatic driving mode and is not accustomed to manual driving.

An electric steering apparatus may include: a column torque sensor configured to detect column torque; a vehicle speed sensor configured to detect vehicle speed of the vehicle; an autonomous driving control unit configured to determine a second command current in an autonomous driving mode; a driver steering intervention determination unit configured to determine whether a driver intervenes in steering; an MDPS logic unit configured to determine a first command current based on the column torque and the vehicle speed, when the driver's steering intervention occurs in the autonomous driving mode; and an output control unit configured to determine a final weight based on a steering angular velocity and the column torque, when the driver's steering intervention occurs in the autonomous driving mode, and determine a final command current by applying the determined final weight to the first and second command currents.

A vehicle steering assist device includes a first detector to detect steering torque by a driver's steering wheel operation, a first calculator to calculate assist steering torque for the detected steering torque, a second calculator to calculate target steering torque to perform steering control, a controller to switch the first calculator from an active state to an inactive state to limit an output of the assist steering torque when the second calculator is in an active state, an EPS torque setter to set EPS torque to drive an EPS motor based on outputs from the second calculator and the controller, and a second detector to detect a driver's holding state of a steering wheel. Even when the second calculator is in the active state, when the second detector detects that a driver holds the steering wheel, the controller switches the first calculator from the inactive state to the active state.

An electric power steering apparatus includes a function to switch a control system of the motor between a torque control system of a torque system to control a motor output torque and a position and speed control system of a steering angle system to control a steering angle of a steering in accordance with an ON/OFF of a post-diagnosis automatic steering command being a judgment result of an automatic steering execution judging section; and a characteristic calculating section to calculate a fade gain signal F1 that applies a first fade characteristic of the torque system, a fade gain signal F2 that applies a second fade characteristic of the steering angle system, and a fade gain signal F3 that applies a third fade characteristic of the steering angle speed, sensitive to the steering torque.

A steering assistance device includes a steering wheel to which a driver of a vehicle inputs steering torque, a steering shaft connected to the steering wheel, a steering mechanism configured to convert a rotation of the steering shaft into a steering angle for steering target wheels, a steering actuator configured to drive the steering mechanism such that a steering angle corresponding to a command value is generated, a steering torque sensor configured to detect torque acting on the steering shaft, an information providing unit configured to provide road information of a scheduled passage area extending in a traveling direction of the vehicle, and an electronic control unit configured to control the steering actuator, based on an output of the steering torque sensor and the road information.

A steering control device includes a driving support ECU. When white line recognition loss, which is a state in which white lines are not properly recognizable, has occurred during execution of an LCA, the driving support ECU calculates a target trajectory for returning a yaw angle to a state immediately before the start of the LCA. The driving support ECU controls a steering angle based on the calculated target trajectory. As a result, a lateral speed of an own vehicle is reduced, and thus sufficient time can be secured for handing over operation of a steering wheel to a driver from a steering assist state.