A device for detecting a driver demand, the device outputting a purely electronic actuating signal, includes an actuating surface, for a foot of a user, the actuating surface being displaceable in an actuation direction in order to generate the actuating signal. At least two compression bodies arranged one behind the other in the actuation direction are provided, each of which has one elastic element and one rigid element, which are arranged one behind the other in the actuation direction in such a way that one rigid element acts on one elastic element when the actuating surface is acted upon by an actuation force. In addition, a sensor system is provided, the signal of which permits an inference to be made regarding the displacement of the actuating surface and is usable for generating the actuating signal.

A pedal assembly for a vehicle that includes a pedal, a sensor configured to sense a force exerted on the pedal, and an electronic processor connected to the sensor. The electronic processor is configured to determine a first output value, and receive a signal indicative of the force exerted on the pedal from the sensor. The electronic processor is further configured to determine a second output value based on the force exerted on the pedal, the first output value, and a model that defines a mechanical hysteresis effect and generate an output signal for controlling the vehicle, the output signal corresponding to the second output value.

A standing pedal is provided for a vehicle, comprising a support, a pedal arm, a rocker, a return spring for forcing the pedal arm into a direction of an idle position of the pedal arm, and a power transmission element. The return spring is linked to the support and the rocker in a power transmitting manner. The power transmission element is linked to the pedal arm and the rocker in a power transmitting manner. In order to provide a standing pedal for a vehicle, which is robust and shows an enhanced durability, the pivot axis of the pedal arm and the power transmission element are located on a common first side of the rocker with respect to a basic part of the rocker.

An accelerator pedal device of the present invention includes: an accelerator pedal; a hysteresis generation mechanism that generates a hysteresis in pedal effort during a depression operation and a return operation of the accelerator pedal; a reaction force addition mechanism that adds a reaction force in a direction to push back the accelerator pedal; and a control unit that controls the drive of the reaction force addition mechanism in a manner that, with a predetermined target opening degree at which the accelerator pedal is depressed as a boundary, a ratio of change in the pedal effort in an opening degree range above the target opening degree becomes relatively larger than a ratio of change in pedal effort in an opening degree range below the target opening degree.

A pedal device for a vehicle includes a first link that is pivotally supported at one end and receives a pedaling force of a driver, a return spring that biases the first link toward a standard position, a second link supported so as to be pivotable in a direction opposite to that of the first link, and a third link transmitting force and displacement between the first and second links. The return spring has a first and second ends connected to the first and second links, respectively, A moment in which a tensile force of the return spring pivots the first link toward the standard position is greater than a moment in which the tensile force of the return spring pivots the first link away from the standard position via the first end.

A pedal apparatus for a vehicle is provided. The pedal apparatus includes a pedal arm coupled to a pedal housing such that the pedal arm is rotated with respect to a first axis by an actuating force applied to a pedal pad disposed on a distal end of the pedal arm, a pressing member for applying a force to a proximal end of the pedal arm in response to the pedal arm being rotated, a pedal reaction force generating unit disposed between the pedal arm and the pressing member to generate a pedal reaction force corresponding to the actuating force, a first friction member disposed at the pressing member to contact the proximal end of the pedal arm, and a second friction member disposed at the proximal end of the pedal arm to contact an inner surface of the pedal housing.

An accelerator pedal apparatus in which an acceleration operation for a vehicle is to be performed by a pedal configured to be operated by a foot includes a vibration application unit and a vibration application control processor. The vibration application unit is configured to apply vibration to the pedal. The vibration application control processor is configured to cause the vibration application unit to apply the vibration to the pedal with a vibration application waveform including one or both of a frequency component that is higher than or equal to 10 hertz and lower than or equal to 50 hertz and a frequency component that is higher than or equal to 100 hertz and lower than or equal to 300 hertz.

System, methods, and other embodiments described herein relate to communicating a recommended speed through feedback on a combined pedal for acceleration or braking. In one embodiment, a control system includes a pedal coupled to a first device having a throttle sensor for a vehicle and a first actuator that generates throttle feedback by applying force to the pedal. The control system also includes the pedal being coupled to a second device having a brake activation sensor for the vehicle and a second actuator that generates braking feedback, the first actuator triggers a rotation of the pedal that initiates a braking command through the brake activation sensor according to a recommended speed computed using vehicle data.

An accelerator device includes a case provided on a floor, a pad arranged outside the case to be stepped on by a driver, a pedal arranged in the case to be rotatable in an accelerator opening direction by a stepping force of the pad, an arm connecting the pad to the pedal, and a biasing member configured to bias the pedal in an accelerator closing direction. One end of the arm is press-fitted into a connecting portion of the pad in a press-fitting direction. At least one of the arm or the pad is provided with a play removing part that is configured to eliminate a play between the one end of the arm and the connecting portion in the press-fitting direction by contacting the one end of the arm and the connecting portion.

A reactive pedal algorithm is used to modify an accelerator pedal output (APO)-to-torque conversion to produce more deceleration for the same accelerator pedal position. Modifying the APO-to-torque conversion provides the driver of a vehicle the sensation that the vehicle is resisting approaching closer to a lead vehicle. The APO-to-torque conversion is modified based on a scene determination to classify vehicles as in-lane, neighbor-lane, or on-coming. Lane change assist methods and systems are used to modify the APO-to-torque conversion range based on a lead vehicle, a neighbor vehicle, or both.