A driving assistance device enables a driver who manually performs an accelerator operation and a steering operation to easily retain an accelerator operation state in a constant state. A driving assistance device includes a manually operable accelerator operation unit in the vicinity of a steering wheel provided in front of a driver seat in a vehicle cabin. The accelerator operation unit is operable in a state where the steering wheel is gripped and an operation reaction force of the accelerator operation unit exhibits an inflection point POI at which the operation reaction force rapidly becomes large in response to an increase in an operation amount of the accelerator operation unit 21.

A pedal-application-error accident preventing device to be applied to a vehicle includes a steering-wheel-position changing mechanism, a steering-wheel-position adjuster, and an accelerator-pedal-position adjuster. The steering-wheel-position changing mechanism is configured to displace a steering wheel of the vehicle in a vehicle forward-rearward direction. The steering-wheel-position adjuster is configured to displace the steering wheel in accordance with an operation amount of an accelerator pedal of the vehicle such that the steering wheel is positioned further toward a vehicle rearward side as the operation amount of the accelerator pedal operated by a driver who drives the vehicle increases. The accelerator-pedal-position adjuster is configured to displace the accelerator pedal in a direction such that the operation amount of the accelerator pedal returns to zero in a case where the steering wheel is pushed back forward in a state in which the steering wheel is displaced toward the vehicle rearward side.

A vehicle output simulation system is applied to an electric vehicle including a motor and a power supply. The vehicle output simulation system includes a storage module, a control panel, a motor control module, a speaker device, and a host computer. The storage module stores a simulation setting including an acceleration curve characteristic datum and a sound effect. The control panel selects operations, and outputs a control command. The motor control module controls the motor and the power supply according to the acceleration curve characteristic datum. The speaker device outputs the sound effect corresponding to the control command.

A foldable pedal apparatus of a vehicle with a hysteresis module, may include a pedal pad is in a popped-up state of protruding from a pedal housing to be exposed toward a driver, in a manual driving mode in which the driver directly drives the vehicle; the pedal pad is in a hidden state of being inserted into the pedal housing and blocked from being exposed to the driver, in the autonomous driving mode in which the driver does not directly drive the vehicle; and hysteresis may be implemented by a hysteresis module when the pedal pad is operated.

A pedal emulator for a vehicle is provided comprising a base part for mounting the pedal emulator to a structure of the vehicle. A pedal lever is pivotable around a rotary axis of the base part. A force generation unit exerts a counterforce on the pedal lever by means of at least one coupling element for mechanically coupling the force generation unit with the pedal lever. The counterforce works counter to an actuating force exerted on the pedal lever. The force generation unit and the coupling element are designed and arranged in such a way that a progression of the counterforce along a pedal travel of the pedal lever (6) takes the form of a non-linear progression in a pedal travel-counterforce diagram.

A pedal emulator (20, 100) is provided. The pedal emulator includes an emulator piston (28, 102) coupled to a damper (46, D1) that is contained within a housing (22, 104). The damper is surrounded by first (34, S1) and second (38, S2) springs that are carried by a lower spring seat (114), the lower spring seat being upwardly biased by a third spring (S3), for example a wave spring. The first and second springs and the third spring cooperate to provide a counter-force that is tailored to the desired feel of the pedal. First and second sensors measure travel (72, 74) and force in response to downward compression of the emulator piston, and the damper provides hysteresis upon return travel of the emulator piston. A method comprising: providing a brake pedal emulator (100) including an emulator piston (102), the emulator piston (102) being operatively coupled to a brake pedal, wherein the brake pedal emulator (100) is adapted to provide a first force response during a first portion of travel of the emulator piston (102) and a second force response during a second portion of travel of the emulator piston (102); detecting a sequence of actuations of the brake pedal using the brake pedal emulator (100) for conversion into a selected driver input command; and providing vibratory feedback to the brake pedal using a haptic actuator, the vibratory feedback being in response to the selection of a driver input command.

A kickdown switch for an accelerator pedal informs a driver of a misoperation state by using a kickdown switch provided in the accelerator pedal when the driver misoperates the accelerator pedal rather than operating a brake pedal while braking is required. Accordingly, the driver can definitely recognize the misoperation state of the accelerator pedal and rapidly stop misoperation of the accelerator pedal and sudden acceleration of the vehicle, whereby occurrence of accidents can be prevented.

The electric vehicle according to the present disclosure is configured to be able to select a traveling mode between an MT mode in which an electric motor is controlled with torque characteristics like an MT vehicle having a manual transmission and an internal combustion engine, and an EV mode in which the electric motor is controlled with normal torque characteristics. The controller of the electric vehicle controls the electric motor in the MT mode such that responsiveness of the motor torque with respect to a change in the operation amount of the accelerator pedal is lower than in the EV mode.

The present disclosure relates to an organ-type electronic pedal apparatus including a high-load spring module 500 and a hysteresis lever 400 and capable of tuning a pedal effort, a stroke, and a hysteretic force, which are required to vary depending on the types of vehicles, by changing components of the hysteresis lever 400, as necessary.

A pedal device mounted on a vehicle includes a housing, a pedal pad, and a reaction force generation mechanism. The housing is mounted on a vehicle body. The pedal pad is provided to be rotatable with respect to the housing. The reaction force generation mechanism is configured to include a plurality of resilient members each having a predetermined leaf spring. The reaction force generation mechanism is arranged in a space on the side opposite to a surface stepped on by a driver in the pedal pad to generate a reaction force against a pedaling force applied to the pedal pad by the driver.