Provided is a vehicular accelerator pedal device equipped with an accelerator pedal that serves as a footrest during automatic driving, to enable switching to manual driving without causing a feeling of strangeness for a driver upon releasing of the automatic driving. The accelerator pedal device includes an accelerator pedal actuator that moves the accelerator pedal to a desired operation position, and an accelerator pedal operation amount sensor that detects an operation amount of the accelerator pedal. Upon releasing the automatic driving with step-on operation of the accelerator pedal, an accelerator pedal control unit obtains a step-on position of the accelerator pedal from the accelerator pedal operation amount sensor, calculates an operation position of the accelerator pedal corresponding to a throttle opening just before switching to the manual driving, and causes the accelerator pedal to be moved to the operation position by the accelerator pedal actuator.

Provided is a vehicular accelerator pedal device equipped with an accelerator pedal that serves as a footrest during automatic driving, to enable switching to manual driving without causing a feeling of strangeness for a driver upon releasing of the automatic driving. The accelerator pedal device includes an accelerator pedal actuator that moves the accelerator pedal to a desired operation position, and an accelerator pedal operation amount sensor that detects an operation amount of the accelerator pedal. Upon releasing the automatic driving with step-on operation of the accelerator pedal, an accelerator pedal control unit obtains a step-on position of the accelerator pedal from the accelerator pedal operation amount sensor, calculates an operation position of the accelerator pedal corresponding to a throttle opening just before switching to the manual driving, and causes the accelerator pedal to be moved to the operation position by the accelerator pedal actuator.

A control apparatus for a vehicle controls a hybrid vehicle including a drive motor and an engine, both of which are linked to a driving wheel. The control apparatus includes: a regenerative controller; a fuel injection controller; a clutch controller; a condition satisfaction determiner; and a delay controller. The regenerative controller regeneratively drives the drive motor at the time of decelerating the hybrid vehicle. The fuel injection controller stops a fuel injection at the time of decelerating the hybrid vehicle. The clutch controller releases a clutch that switches a power transmission on and off between the engine and the driving wheel at the time of a regenerative driving by the regenerative controller. The condition satisfaction determiner determines whether execution conditions of diagnoses performed in a fuel cut state in which the clutch is engaged and the fuel injection is stopped are all satisfied.

A traffic light detection system for a vehicle is provided. The system may include at least one processing device programmed to receive, from at least one image capture device, a plurality of images representative of an area forward of the vehicle, the area including a traffic light fixture having at least one traffic light. The at least one processing device may also be programmed to analyze at least one of the plurality of images to determine a status of the at least one traffic light, and determine an estimated amount of time until the vehicle will reach an intersection associated with the traffic light fixture. The at least one processing device may further be programmed to cause a system response based on the status of at least one traffic light and the estimated amount of time until the vehicle will reach the intersection.

A vehicle control device includes an electronic control unit configured to: enlarge the detection range, when the electronic control unit determines that a current deceleration support control is control for passing the object; set a new target deceleration of the host vehicle when a new object with a possibility of collision with the host vehicle has been detected in the enlarged detection range; determine whether an interval from an ending time of the current deceleration support control to a starting time of the next deceleration support control is less than a threshold value, when the electronic control unit determines that the next deceleration support control is control for passing the new object; and perform one of the inter-vehicle distance control and acceleration support control from the ending time to the starting time, when the electronic control unit determines that the interval is less than the threshold value.

Described are systems and methods for predicting road collisions between a host vehicle and one or more objects in the surroundings of the vehicle. In aspects, range rate and heading information is acquired regarding a moving object in the surroundings of the vehicle; possible vehicle trajectories of the vehicle are calculated; possible object trajectories are calculated from the range rate of the object, the heading of the object, and a possible turn and acceleration of the object; and a collision calculation is performed.

A vehicle includes a navigation device, and a controller electrically connected to the navigation device, wherein the controller is configured to determine a first speed of the vehicle based on a main line speed limit of a road on which the vehicle is traveling, wherein the main line speed limit is included in navigation information output by the navigation device, determine a second speed for decelerating the vehicle to a predetermined speed when the vehicle is positioned at a target point of a curved lane based on an arc length from a branching point of the road to the curved lane, which is determined based on the predetermined speed and a predetermined allowable maximum deceleration amount in the curved lane in route information included in the navigation information and the navigation information, and determine the first speed or the second speed as a control target speed of the vehicle at the branching point.

An electric vehicle and a cruise control method therefore are capable of improving ride comfort by reducing a pitch caused by a road surface deceleration factor. A method of controlling a smart cruise control function includes determining a target speed of a vehicle that is traveling when a road surface deceleration factor in front of the vehicle is detected, entering the road surface deceleration factor while traveling at a constant speed corresponding to the determined target speed, and performing pitch reduction control upon entering the road surface deceleration factor.

In a detection method of a loading anomaly, relationship between a steering control value of a vehicle and a proper turning radius for the steering control value is constructed as a control map. An actual turning radius of the vehicle is calculated by using a self-location detection function of the vehicle. A difference between the proper turning radius and the actual turning radius is calculated by using the control map. It is determined that a loading anomaly of a cargo loaded on the vehicle has occurred when the difference lies outside a predetermined first reference range.

A materials handling vehicle comprises a processor, a throttle, and a zone sensing subsystem coupled to the processor. The processor, responsive to the zone sensing subsystem detecting that the materials handling vehicle is in a restricted operational zone, controls the materials handling vehicle by applying a maximum vehicle operational limit of the materials handling vehicle to a magnitude that is at or below an operational limit of the restricted operational zone. Further, the processor overrides the maximum vehicle operational limit based on application of a throttle neutral action.