Among other things, we describe techniques for electric power steering torque compensation. Techniques are provided for a method implemented by a computer, e.g., a computer onboard an autonomous vehicle. A planning circuit onboard the vehicle and connected to an EPS of the vehicle determines a compensatory torque signal to modify an actual steering angle of a steering wheel of the vehicle to match an expected steering angle of the steering wheel. The planning circuit transmits the compensatory torque signal to a control circuit that controls the steering angle of the steering wheel. The EPS modifies the actual steering angle based on the compensatory torque signal resulting in a modified steering angle. The control circuit operates the vehicle based on the modified steering angle.

A trailer assembly includes first and second axles supporting first and second wheels which are coupled to first and second actuators of a steering system. The steering system includes a control circuit connected to the actuators and the control circuit includes a driving device configurable in a low speed maneuvering mode with: a synchronized sub-mode in which the actuators can be actuated in a synchronized manner to steer the wheels in a synchronized manner, and a desynchronized sub-mode in which the first and second actuators can be actuated individually and independently to steer only the first wheels or only the second wheels. A control device is connected to the driving device to: select one of the sub-modes in the low speed maneuvering mode, and select an actuation either of the first actuator or of the second actuator, in the desynchronized sub-mode.

A control apparatus of a vehicle including a steering operator is provided. The control apparatus includes an environment detection unit configured to detect a surrounding environment of the vehicle, a travel control unit configured to execute automatic steering control based on the surrounding environment, and an operation detection unit configured to detect a first operation and a second operation by a driver. The travel control unit can take a first state in which automatic steering control is not performed, a second state in which automatic steering control is performed on condition of the second operation, and a third state in which automatic steering control is performed without condition of the second operation. The travel control unit transitions from the third state to the first state on condition of the first operation.

The disclosure describes systems and methods including a mobile device for remotely controlling the movement of a vehicle and trailer. The mobile device provides an intuitive interface for controlling the movement of the vehicle and trailer by changing the orientation of a vehicle graphic (e.g., of the vehicle and trailer) according to a position of the mobile device around a periphery of the vehicle and trailer. This allows the user to walk around the vehicle and trailer to determine a best position from which to control the vehicle and trailer depending on a given situation without losing the intuitiveness of the user interface.

A vehicle (10) comprising: a vehicle body (12) defining a longitudinal axis “L”; a suspension system (40) mounted to the vehicle body (12) and connected to a drive wheel (32A, 32B) defining a drive wheel axis “A”, the suspension system (40) being configured to allow displacement of the drive wheel axis “A” relative to the vehicle body (12) with a component of the displacement occurring in a direction parallel to the longitudinal axis “L” of the vehicle body (12); a sensor (110) for providing an output indicative of a level of displacement provided by the suspension system (40); and a torque control device (120) for automatically varying torque supplied to the drive wheel (32A, 32B) in dependence upon the output of the sensor (110).

A trailer assembly includes first and second axles supporting first and second wheels which are coupled to first and second actuators of a steering system. The steering system includes a control circuit connected to the actuators and the control circuit includes a driving device configurable in a low speed maneuvering mode with: a synchronized sub-mode in which the actuators can be actuated in a synchronized manner to steer the wheels in a synchronized manner, and a desynchronized sub-mode in which the first and second actuators can be actuated individually and independently to steer only the first wheels or only the second wheels. A control device is connected to the driving device to: select one of the sub-modes in the low speed maneuvering mode, and select an actuation either of the first actuator or of the second actuator, in the desynchronized sub-mode.

Examples implementations relate to determining path confidence for a vehicle. An example method includes receiving a request for a vehicle to navigate a target location. The method further includes determining a navigation path for the vehicle to traverse a first segment of the target location based on a plurality of prior navigation paths previously determined for traversal of segments similar to the first segment of the target location. The method also includes determining a confidence level associated with the navigation path. Based on the determined confidence level, the method additionally includes selecting a navigation mode for the vehicle from a plurality of navigation modes corresponding to a plurality of levels of remote assistance. The method further includes causing the vehicle to traverse the first segment of the target location using a level of remote assistance corresponding to the selected navigation mode for the vehicle.

A control apparatus of a vehicle including a steering operator is provided. The control apparatus includes an environment detection unit configured to detect a surrounding environment of the vehicle, a travel control unit configured to execute automatic steering control based on the surrounding environment, and an operation detection unit configured to detect a first operation and a second operation by a driver. The travel control unit can take a first state in which automatic steering control is not performed, a second state in which automatic steering control is performed on condition of the second operation, and a third state in which automatic steering control is performed without condition of the second operation. The travel control unit transitions from the third state to the first state on condition of the first operation.

An autonomous traveling device to tow a cart including a caster, which swivels around an axis perpendicular to a rotation axis of a wheel, includes a drive wheel, and circuitry configured to detect a position of the autonomous traveling device, drive the drive wheel to move the autonomous traveling device, drive the drive wheel to move the autonomous traveling device backward, and drive the drive wheel to turn the autonomous traveling device. In response to a detection that the autonomous traveling device towing the cart is at a turning position, the circuitry drives the drive wheel so that the autonomous traveling device turn by a predetermined angle while moving forward or backward. Based on a determination that the autonomous traveling device towing the cart is at a moving-back position, the circuitry drives the drive wheel to move the autonomous traveling device backward to a target position.

Among other things, we describe techniques for electric power steering torque compensation. Techniques are provided for a method implemented by a computer, e.g., a computer onboard an autonomous vehicle. A planning circuit onboard the vehicle and connected to an EPS of the vehicle determines a compensatory torque signal to modify an actual steering angle of a steering wheel of the vehicle to match an expected steering angle of the steering wheel. The planning circuit transmits the compensatory torque signal to a control circuit that controls the steering angle of the steering wheel. The EPS modifies the actual steering angle based on the compensatory torque signal resulting in a modified steering angle. The control circuit operates the vehicle based on the modified steering angle.