A work machine includes a frame; an engine supported by the frame; a plurality of ground engaging devices supporting the frame and driven by the engine; an operator cabin supported by the frame; a plurality of sensors and input devices configured to provide a plurality of signals; and a control module. The control module is configured to receive the plurality of signals from the plurality of sensors and input devices, determine if any of the plurality of signals is a positive signal, where a positive signal indicates that an operator is present in the machine, indicate an ‘operator present’ status if at least one of the plurality of signals remains positive for a debounce time, and indicate a ‘no operator present’ status if none of the plurality of signals remains positive for a threshold time.

A vehicle includes a motor; a transmission; a battery; a mode input device for receiving a driving mode; a control information input device for receiving regenerative braking control information or gearshift level control information; and a controller configured to control at least one of braking torque of the motor and gearshift level of the transmission to control an amount of regenerative braking during regenerative braking by recognizing a signal received from the control information input device as a signal corresponding to the regenerative braking control information when the driving mode input to the mode input device is a first mode, and control the transmission to control the gearshift level of the transmission by recognizing a signal received from the control information input device as a signal corresponding to the gearshift level control information when the driving mode input to the mode input device is a second mode.

An autonomous driving control apparatus for a vehicle includes: a processor that determines whether a current driving condition of the vehicle is a limit situation during an autonomous driving control, performs a demand for control authority transition to a user during the autonomous driving control when the current driving condition is the limit situation, and starts a minimum risk maneuver to transmit a signal for disabling reactivation of the autonomous driving control when control authority is not transferred to the user; and a storage to store a set of instructions and driving condition data to be used by the processor. In particular, the processor demands for engagement of an electronic parking brake device when the vehicle is stopped after the minimum risk maneuver ends.

A vehicle comprises an autonomous driving system and a vehicle platform that controls the vehicle in response to a command received from the autonomous driving system. In the present vehicle, when the autonomous driving system issues a first command to request the vehicle platform to provide deceleration to stop the vehicle and a first signal indicates 0 km/h or a prescribed velocity or less, the autonomous driving system issues a second command to request the vehicle platform to maintain stationary. And after brake hold control is finished, a second signal indicates standstill. Until the second signal indicates standstill, the first command continues to request the vehicle platform to provide deceleration.

A system for controlling at least partially autonomous operation of a motor-vehicle, including: a sensor-device with which environment-data characterizing the environment of the motor vehicle is generated; an electronic-main-control-unit, which receives the environment-data from the sensor-device, and, depending on the data, inputs adjusting-commands into at least one device/actuator, which device/actuator is used in the at least partially autonomous operation of the motor-vehicle; a first electronic-backup-control-unit, which, for a fault/failure of the electronic-main-control-unit, receives the data from the sensor-device, and, depending on the data, inputs adjusting-commands into the at least one device/actuator, which device/actuator is used in the at least partially autonomous operation of the motor-vehicle; and a second electronic-backup-control-unit, which, for a fault/failure of the electronic-main-control-unit and the first electronic-backup-control-unit, receives the data from the sensor-device, and, depending on the data, inputs adjusting-commands into the at least one device/actuator, which device/actuator is used in the operation of the motor-vehicle.

A park brake system for adjusting a tension in a brake cable that is coupled to a park brake. The park brake system can include a driver that is communicatively coupled to a microcontroller, and an actuator that is rotatably displaceable by operation of the driver. An equalizer assembly can be linearly displaced along the rotating actuator to adjust a tension in the brake cable. The microcontroller can monitor a current being drawn by the driver as the driver is operated, and generate instructions to cease operation of the driver upon the current reaching a predetermined current threshold that corresponds a maximum force that is to be applied by the park brake. The microcontroller can also, when the park brake is being released from a set position, count pulses outputted by an encoder in connection with determining whether the park brake has reached a running clearance position.

The present invention provides a travel support system of a vehicle, including a detection unit configured to detect information of a periphery of the vehicle, a control unit configured to perform travel support control based on the information detected by the detection unit, and a stationary state control unit configured to cause the vehicle to be stationary at one of completion and suspension of the travel support control by the control unit, wherein the stationary state control unit performs steering control to maintain a steering angle at one of the completion and suspension of the travel support control while the vehicle is stationary.

A parking support system of a vehicle, comprises: a detection unit configured to detect information of a periphery of the vehicle; a control unit configured to control, based on the information detected by the detection unit, a parking space entry operation of the vehicle to a parking space and a parking space exit operation of the vehicle from the parking space; and a stationary state control unit configured to maintain a stationary state of the vehicle after one of the parking space entry operation and the parking space exit operation has been completed. The stationary state control unit maintains the stationary state by first maintenance control when the parking space entry operation has been completed and maintains the stationary state by second maintenance control, which is different from the first maintenance control when the parking space exit operation has been completed.

A brake control device is a control device for a vehicle used in a vehicle on which the shift-by-wire system and the brake-by-wire system are mounted. A function of automatically operating the brake device without an operation of the driver of the vehicle is referred to as a BBW automatic operation function, and a request by the driver for disabling the BBW automatic operation function is referred to as a disabling request. A brake control device includes a disabling determination part configured to determine a presence or absence of the disabling request, the vehicle stop determination part configured to determine whether the vehicle is stopped, a slope determination part configured to determine whether the vehicle is located on a slope, and a BBW automatic operation part. The BBW automatic operation part operates the brake device when the vehicle is stopped on the slope even if the disabling request is made.

An automatic parking system includes a smart key recognizing sensor recognizing a smart key positioned in a first area, a sensor system sensing presence or absence of a parking section line, and positions of surrounding vehicles when the smart key is recognized, a controller configured to analyze data sensed by the sensor system to calculate parking areas around a subject vehicle, calculate a range allowing generation of a moving path based on the parking areas, determine at least two parking types available at a current position of the subject vehicle in the range allowing generation of a moving path, provide a moving path range for a parking type that is selected among the moving path ranges, and receive a signal transmitted by the smart key to automatically park the subject vehicle in the optimal parking area.