Abstract: A system comprises a first control module that meets specified operational criteria for controlling a component of a vehicle and a second control module that meets specified operational criteria for actuating the component. The first control module is arranged to send a first signal to open a relay that, when closed, electrically couples a power output of the second control module to ground via a fuse, send a second signal to cause the second control module to power a motor for actuating the component, receive a third signal indicating a completion of actuation of the component, and responsive to receiving the third signal, send a fourth signal to close the relay.

Abstract: Methods and apparatus for determining positions of a stowable pedal assembly are disclosed. An example apparatus to determine a position of a stowable pedal assembly of a vehicle includes motor control circuitry to provide a control signal to a motor operatively coupled to the stowable pedal assembly, the motor to cause movement of the stowable pedal assembly toward a desired position, response detection circuitry to detect a current response of the motor to the control signal, and position determination circuitry to determine the position of the stowable pedal assembly based on the current response.

Abstract: A system comprises a first control module that meets specified operational criteria for controlling a component of a vehicle and a second control module that meets specified operational criteria for actuating the component. The first control module is arranged to send a first signal to open a relay that, when closed, electrically couples a power output of the second control module to ground via a fuse, send a second signal to cause the second control module to power a motor for actuating the component, receive a third signal indicating a completion of actuation of the component, and responsive to receiving the third signal, send a fourth signal to close the relay.

Abstract: A computer includes a processor and a memory, the memory storing instructions executable by the processor to detect an actual steering column torque and an actual steering wheel angle, predict a steering wheel torque with a state-estimation algorithm that outputs a plurality of vehicle states including the predicted steering wheel torque, adjust the plurality of vehicle states based on an algorithm noise that is based on a steering wheel angular speed to generate estimated vehicle states, output the estimated vehicle states including an estimated user-applied steering wheel torque, and transition from an autonomous mode to a manual mode when the estimated steering wheel torque exceeds a threshold. The state-estimation algorithm accepts input including the actual steering column torque and the actual steering wheel angle and outputs the plurality of vehicle states.

Abstract: A vehicle includes a power source configured to provide drive torque, a front axle, a rear axle, and a transfer case configured to distribute drive torque from the power source between the front axle and the rear axle. The vehicle additionally includes a clutch arranged between the front axle and the transfer case. The clutch has a disengaged state and an engaged state drivingly coupling the transfer case and the front axle. The vehicle also includes a regenerative braking system configured to, in response to a braking request, provide regenerative braking torque to the rear axle. The vehicle further includes a controller. The controller is configured to, in response to a braking request and the clutch being in the disengaged state, control the clutch to shift into the engaged state to couple the regenerative braking system to the front axle and provide regenerative braking torque to the front axle.

Abstract: A computer includes a processor and a memory, the memory storing instructions executable by the processor to detect an actual steering column torque and an actual steering wheel angle, predict a steering wheel torque with a state-estimation algorithm that outputs a plurality of vehicle states including the predicted steering wheel torque, adjust the plurality of vehicle states based on an algorithm noise that is based on a steering wheel angular speed to generate estimated vehicle states, output the estimated vehicle states including an estimated user-applied steering wheel torque, and transition from an autonomous mode to a manual mode when the estimated steering wheel torque exceeds a threshold. The state-estimation algorithm accepts input including the actual steering column torque and the actual steering wheel angle and outputs the plurality of vehicle states.

Abstract: A computer includes a processor and a memory, the memory storing instructions executable by the processor to receive a request to activate a vehicle, receive diagnostic data for one or more vehicle components from an activation component, arbitrate the request and the diagnostic data to identify an activation mode of the vehicle that is one of an unpowered mode, a power-up mode, or a fully-started mode, and instruct the activation component to activate one or more vehicle components associated with the identified activation mode.

Abstract: A system includes a computer. The computer includes a processor and a memory storing instructions executable by the processor to receive locally stored identifiers from each of a plurality of control modules of a vehicle; transmit a current list of the received locally stored identifiers to a remote server; receive a master list of compatible identifiers from the remote server, wherein each compatible identifier corresponds to a respective one of the control modules, and the master list includes file-verification data; prevent the vehicle from operating autonomously upon determining that one of the locally stored identifiers is different from the respective compatible identifier or upon determining that the file-verification data is incorrect; and permit the vehicle to operate autonomously upon determining that each locally stored identifier is the same as the respective compatible identifier and that the file-verification data is correct.

Abstract: A ball joint assembly includes a ball including an outer surface and a recess in the outer surface, a cup including an inner surface and a protrusion on the inner surface, and a sensor programmed to detect friction between the cup and the ball from the protrusion engaging the recess.

Abstract: A remote vehicle control is activated. A throttle position on the control is maintained for a specified time. A transmission of a vehicle is engaged based on the throttle position.

Abstract: A computer includes a processor and a memory storing instructions executable by the processor to, upon determining that a local set of identifiers is inconsistent with a remotely served set of identifiers, prevent a vehicle from entering an autonomous mode or instruct the vehicle to perform a minimal risk condition.

Abstract: A system includes means for identifying a risk condition based on a diagnostic trouble code (DTC) and an operating condition in a vehicle, means for determining an instruction for the vehicle based on the identified risk condition, and means for navigating the vehicle based on the instruction.

Abstract: A remote vehicle control is activated. A throttle position on the control is maintained for a specified time. A transmission of a vehicle is engaged based on the throttle position.

Abstract: A computer includes a processor and a memory storing instructions executable by the processor to, upon determining that a local set of identifiers is inconsistent with a remotely served set of identifiers, prevent a vehicle from entering an autonomous mode or instruct the vehicle to perform a minimal risk condition.

Abstract: A first computer including a processor is programmed to receive an indication of a failure mode in a vehicle and wirelessly transmit the indication of the failure mode to a remote server. The computer is further programmed to receive a revised route to a destination based at least in part on the failure mode and operate the vehicle along the revised route.

Abstract: A vehicle parking brake system includes a power bridge. The power bridge is electrically connected to a primary power source and to a secondary power source. The power bridge has a first condition in which the primary power source is active in which the primary source is electrically connected to a parking brake actuator. The power bridge has a second condition in which the primary power source is not active in which the secondary power source is electrically connected to the parking brake.

Abstract: Vehicles can be equipped to operate in both autonomous and occupant piloted mode. Vehicles can be equipped with hardware and software to determine a driving-acceptable region defined by lateral and longitudinal coordinates relative to a first vehicle, wherein the lateral and longitudinal coordinates are based on the locations and sizes of one or more second vehicles and the location and size of a roadway. Upon determining a vehicle fault, a computing device in the vehicle can pilot the vehicle to a stop within the driving-acceptable region.

Abstract: A ball joint assembly includes a ball including an outer surface and a recess in the outer surface, a cup including an inner surface and a protrusion on the inner surface, and a sensor programmed to detect friction between the cup and the ball from the protrusion engaging the recess.

Abstract: A system includes means for identifying a risk condition based on a diagnostic trouble code (DTC) and an operating condition in a vehicle, means for determining an instruction for the vehicle based on the identified risk condition, and means for navigating the vehicle based on the instruction.

Abstract: A system includes an autonomous sub-system that includes first and second braking modules. Each of the modules includes a processor and a memory, the memory storing instructions executable by the processor for detecting a fault. The system further includes a brake sub-system programmed to actuate a brake mechanism in response to a signal from the second braking module. The autonomous sub-system is further programmed to select one of the braking modules to provide a signal to the brake mechanism depending on whether a fault is detected.