A mobile work machine includes a frame, a set of ground engaging elements movably supported by the frame and driven to drive movement of the mobile work machine, a movable element movably supported by the frame to move relative to the frame, and an actuator coupled to the movable element to controllably drive movement of the movable element. The mobile work machine also includes a control system that generates an actuator control signal, indicative of a commanded movement of the actuator, and provides the actuator control signal to the actuator to control the actuator to perform the commanded movement. Further, the mobile work machine includes a stability system, coupled to the control system, that determines whether the commanded movement will result in an unstable state of the mobile work machine and, if so, generates a restriction signal, restricting the commanded movement to avoid the unstable state.

A system for controlling an engagement operation between first and second movable machines includes a separation sensor, a relative speed sensor and a controller. The separation sensor determines a separation distance between the first and second machines. The relative speed sensor determines a relative difference in speed between the first and second machines. The controller determines the separation distance between the first and second machines, decelerates the first movable machine when the separation distance is within a deceleration zone, determines a relative difference in speed between the first and second machines, and generates an engagement speed command to operate the first movable machine at a first ground speed equal to a second ground speed of the second movable machine plus a relative engagement speed when the separation distance is within a buffer zone.

A vehicle has a frame, at least two wheels, a motor, a straddle seat defining a driver seat portion and a passenger seat portion at least partially rearward of the driver seat portion, left and right passenger footrests connected to the frame, the left and right passenger footrests each being movable between a stowed position and a deployed position, a passenger footrest position sensor for sensing a position of at least one of the left and right passenger footrests, and an electronic stability system electronically connected to the passenger footrest position sensor for receiving a signal from the passenger footrest position sensor indicative of the position of the at least one of the left and right passenger footrests. An output of the electronic stability system is defined at least in part on the signal from the passenger footrest position sensor.

A cruise control interlock system detects a current set of conditions for a vehicle, compares the current conditions with cruise control interlock conditions (e.g., an adjustable threshold state of a windshield wiper system), and executes a process to deactivate the cruise control system. The process to deactivate functionality of the cruise control system may include presenting a notification to the operator to alert the operator to an upcoming automatic deactivation or to encourage the operator to deactivate cruise control. The process also may include a vehicle de-rate process (e.g., reducing vehicle speed) to induce the operator to deactivate cruise control. Deactivation of cruise control may be postponed in some situations, such as when the vehicle is ascending an uphill grade or where doing so may deactivate an active downhill speed control function.

According to an embodiment, an information processing apparatus includes a memory having computer executable components stored therein; and processing circuitry communicatively coupled to the memory, the processing circuitry configured to: acquire vehicle related information serving as information relating to a vehicle switchable between manual driving and automatic driving, the vehicle related information indicating information used for determining whether switching to the automatic driving is possible; determine whether each of one or more conditions to switch from the manual driving to the automatic driving is satisfied, based on the vehicle related information; and output information corresponding to an unsatisfied condition indicating a condition determined to be unsatisfied at the determining.

A system and method of this disclosure control an on/off state of a power take-off by monitoring the power demand of a fluid power circuit that includes the power take-off and a piece of equipment connected to the power take-off. The power demand may be indicated by a pressure or temperature of a fluid power circuit, by a motion of the equipment or its hand-held controller, or by an engine torque of an engine driving the power take-off. When the equipment transitions between an off state and an on state, the controller automatically engages the power take-off. When the equipment is in the on-state for a predetermined amount of time and the power demand is at or below a predetermined threshold during the predetermined amount of timethereby indicating idle time or an inactive state of the equipmentthe controller automatically disengages the power take-off.

A control unit performs a lane departure suppression control when a host vehicle is about to depart from a traveling lane. The control unit determines whether a low impact collision has occurred. The control unit performs a secondary collision damage mitigation control when the low impact collision is determined to have occurred while the lane departure suppression control is being performed.

A vehicle deceleration assistance apparatus executes a deceleration assistance control to assist a deceleration of a vehicle before the vehicle arrives at a deceleration assistance target point to turn left or right. The apparatus executes the deceleration assistance control of a first level as a deceleration assistance level of assisting the deceleration of the vehicle when first and second conditions are satisfied. The first condition is a condition that a target point distance between the vehicle and the deceleration assistance target point is equal to or shorter than a predetermined distance, and blinkers are activated. The second condition is a condition that the blinkers activated for changing traffic lanes continues being activated. The apparatus executes the deceleration assistance control of a second level lower than the first level until a predetermined time elapses since the first condition becomes satisfied while the second condition is satisfied.

A vehicle controller includes a processor configured to determine whether a vehicle under manual driving control is in a situation that allows for starting autonomous driving control of the vehicle, switch, when the vehicle is in a situation that allows for starting autonomous driving control, control of the vehicle from manual driving control to autonomous driving control in the case where operating mode of a device related to ensuring visibility of a driver of the vehicle is set to automatic mode to automatically control the device, and continue manual driving control in the case where the operating mode of the device related to ensuring the driver's visibility is set to manual mode to manually control the device and where the driver's visibility will not be ensured unless the device operates.

A vehicle control device includes a driving controller configured to control one or both of steering and acceleration or deceleration of a vehicle; and a mode determiner configured to determine a driving mode of the vehicle to be one of a plurality of driving modes including a first driving mode and a second driving mod, in which the second driving mode is a driving mode in which a task imposed on a driver of the vehicle is lighter than that of the first driving mode and one or both of the steering and the acceleration or deceleration are controlled by the driving controller, and to change the driving mode to the first driving mode on the basis of an operating state of a wiper mounted in the vehicle when the driving controller controls the vehicle in the second driving mode.