A throttle pedal assembly may include: a base; a pedal movably mounted on the base; and an adjustment member extending at least between a first reference location of the throttle pedal assembly and an adjustment surface at an end of the adjustment member. The adjustment member may be adjustable to adjust an adjustment distance from the first reference location of the throttle pedal assembly to the adjustment surface. The throttle pedal assembly may be operable to indicate a throttle level according to relative positions of a second reference location of the throttle pedal assembly and a third reference location of the throttle pedal assembly. Adjusting the adjustment distance may cause an idle position of the pedal to move relative to base and maintains relative positions of the second and third reference locations when the pedal is in the idle position.

An automotive vehicle includes a body having a passenger compartment and a pedal assembly disposed within the passenger compartment. The pedal assembly includes a brake pedal emulator housing and at least one pedal interface coupled to the housing. The vehicle also includes an actuator operably coupled to the brake pedal emulator housing. The actuator is configured to selectively move the housing and the pedal interface between a first position and a second position with respect to the passenger compartment. The vehicle further includes at least one controller in communication with the actuator. The controller is configured to, in response to satisfaction of a first operating condition, control the actuator to move the housing and the pedal interface to the first position, and, in response to satisfaction of a second operating condition, control the actuator to move the housing and the pedal interface to the second position.

A mechanism for adjusting the angular position of a vehicle pedal includes a motor for generating and transmitting rotary motion to a rotating member, a first pedal assembly having a first support frame with a first slotted hole, rotatably supported on a first fulcrum and supporting a first pedal, a first motion conversion mechanism, having a first rotating member rotatable about a first rotation axis and a first translating member, receiving and converting rotational motion into translational motion, and a first pin, for joint translation with the first translating member and sliding inside the first slotted hole. Sliding of the first pin draws the first support frame in rotation about the first fulcrum between a first and a second angular position. The mechanism includes a second pedal assembly. The first rotating member is connected to the motor to receive rotary motion. A second rotating member of a second motion conversion mechanism is connected in rotation to the first rotating member through a flexible transmission.

A pedal device includes a base disposed on an inner wall surface of a vehicle body, a pedal pad movable relative to the base, and a pad fixation portion configured to fix the pedal pad to be immovable relative to the base.

A pedal assembly, including an upper housing and a lower housing with an upper surface positioned below the upper housing. A receiving cavity is positioned in the lower housing, with at least a portion positioned below the upper surface in the pedal assembly vertical direction. A pedal arm having a pivot end and an opposite pedal pad, pivotally coupled to the upper housing at the pivot end. The pedal arm is movable between a stowed position and a use position, wherein in the stowed position, the pedal pad is positioned in the receiving cavity and below the upper surface in the pedal assembly vertical direction such that access to the pedal pad is prohibited. In the use position, the pedal pad is positioned above the receiving cavity and the upper surface in the pedal assembly vertical direction such that access to the pedal pad is permitted.

A motor vehicle comprising a plurality of wheels; at least one controllable driving system to control at least the speed and the orientation of said wheels; a control unit operatively connected to the driving system in order to adjust the operation of the driving system; and an interface configured to receive at least one driving command given by a driver; the motor vehicle further comprises a support structure defining a horseman-like driving position for the driver, who is in a prone position; the interface comprises a first control, which can be operated by a first hand of the driver, and a second control, which can be operated by a first foot of said driver; the first control is arranged in front of said second control (33; 34), with reference to a normal moving direction of the motor vehicle.

A method for operating a self-driving motor vehicle includes changing from a self-driving mode into a manual-driving mode, monitoring a footwell of the motor vehicle with a gesture recognition device, and checking whether at least one specified gesture is present.

A vehicle in one embodiment includes a driver module which can include a driver seat and a driver control assembly both of which are movably coupled to a chassis of the vehicle to allow the driver module to move between a center position and at least one of a left position and a right position along a first row in the interior of the vehicle. In one embodiment, the driver control assembly includes a steering wheel, a brake pedal, and an accelerator pedal. In one embodiment, a driver can drive the vehicle in any one of these positions. In one embodiment, the vehicle further includes a first rear seat and a second rear seat coupled to the chassis in a second row in the interior of the vehicle. In one embodiment, passengers in the rear seats can extend their legs into the first row when the driver seat is in the center position. In one embodiment, the driver seat and the driver control assembly are movable laterally along a set of rails coupled to the chassis of the vehicle. Other embodiments are also described.

A work vehicle including a floor, a forward pedal arm, a reverse pedal arm, a forward rotation shaft, and a reverse rotation shaft. The floor has a first insertion hole and a second insertion hole. The forward pedal arm is placed in the first insertion hole and provided with a forward pedal. The reverse pedal arm is placed in the second insertion hole and provided with a reverse pedal. The forward rotation shaft serves as a rotation shaft of the forward pedal arm, and is oriented so that an outer end thereof is directed toward the rear of a vehicle body of the work vehicle. The reverse rotation shaft serves as a rotation shaft of the reverse pedal arm, and is oriented so that an outer end thereof is directed toward the rear of the vehicle body.

Please substitute the new Abstract submitted herewith for the original Abstract: The invention relates to operating a vehicle having an electro-hydraulic brake system. The vehicle can be operated in a manual and an autonomous driving mode. The brake system is divided into a first and a second hydraulic brake circuit. The two brake circuits can be hydraulically decoupled from one another by a circuit separating valve. The two brake circuits are each assigned to hydraulically enable at least one respective wheel brake of the vehicle. A brake pedal is brought into an at least partially actuated position during an autonomous driving mode.