A vehicular acceleration input control apparatus is disclosed. The example apparatus includes a power circuit electrically connected to a wiring harness that connects a vehicular control module to accelerator pedal position sensors. The power circuit includes a first power supply line connected to a first harness power wire of the wiring harness and a second power supply line connected to a second harness power wire of the wiring harness. The power circuit also includes a ground line connected to at least one of a first harness ground wire and a second harness ground wire of the wiring harness. The example apparatus also includes a processor electrically connected to and configured to receive power from the power circuit. The processor is configured to adjust acceleration input control signals from acceleration pedal position sensors of an acceleration pedal for transmission to the vehicular control module.

A battery powered ride-on vehicle is provided that has vehicle body, a plurality of wheels, a battery dock, a battery having battery terminals that mate with battery dock terminals, an accelerator switch and an accelerator switch controller, a power line to allow current to flow between the battery dock and the accelerator switch controller, a plurality of electrical components, an electronics controller in electrical communication with the accelerator switch controller and the electrical components, a power line connecting the electronics controller with the accelerator switch controller to allow current to flow between the accelerator switch controller and the electronics controller, a timer that calculates the time between actuations of the accelerator switch, and when the time between actuations of the accelerator switch is greater than a timer threshold the accelerator switch controller prevents a release of current to the electronics controller until the accelerator switch is actuated again.

A method and system for blending between different torque maps of a vehicle so that step changes of torque output are avoided as accelerator pedal position is changed. Different blending rates are provided so as to reduce the blending time if driver demand is in the direction of torque change.

A cruise control apparatus is provided with: a controlling device configured to start a determination period, which is a period for determining whether or not to continue the intermittent operation mode, on condition that a change amount of the accelerator opening degree exceeds a predetermined change amount, during implementation of the intermittent operation mode, and configured to set an accelerator following period, which is a period for allowing the driver's accelerator operation to follow torque of the vehicle, after an end of the determination period, if it is determined that the intermittent operation mode is to be continued according to a change width of the accelerator opening degree obtained in the determination period.

A vehicular acceleration input control apparatus is disclosed. The example apparatus includes a power circuit electrically connected to a wiring harness that connects a vehicular control module to accelerator pedal position sensors. The power circuit includes a first power supply line connected to a first harness power wire of the wiring harness and a second power supply line connected to a second harness power wire of the wiring harness. The power circuit also includes a ground line connected to at least one of a first harness ground wire and a second harness ground wire of the wiring harness. The example apparatus also includes a processor electrically connected to and configured to receive power from the power circuit. The processor is configured to adjust acceleration input control signals from acceleration pedal position sensors of an acceleration pedal for transmission to the vehicular control module.

A vehicular acceleration input control apparatus is disclosed. The example apparatus includes a power circuit electrically connected to a wiring harness that connects a vehicular control module to accelerator pedal position sensors. The power circuit includes a first power supply line connected to a first harness power wire of the wiring harness and a second power supply line connected to a second harness power wire of the wiring harness. The power circuit also includes a ground line connected to at least one of a first harness ground wire and a second harness ground wire of the wiring harness. The example apparatus also includes a processor electrically connected to and configured to receive power from the power circuit. The processor is configured to adjust acceleration input control signals from acceleration pedal position sensors of an acceleration pedal for transmission to the vehicular control module.

An accelerator pedal is located forward of the driver seat. The accelerator pedal is supported by a bracket and is movable by stepping on than accelerator pedal. An accelerator position, sensor is located higher than the bracket and detects a deflection amount of the accelerator pedal. A wire connects the accelerator pedal and the accelerator position sensor to each other. The vehicle can prevent the accelerator position sensor from being splashed with mud and water.

A battery-powered vehicle is provided having dual charging capabilities. The vehicle has a body, a plurality of wheels supporting the body, a motor connected to at least one of the plurality of wheels, a battery port having a battery dock and battery dock terminals, a remote charging dock on an exterior of the vehicle body, the remote charging dock having remote charging terminals, a charger having a charger plug and associated charger terminals, and a removable and rechargeable battery having battery terminals. The battery is configured to be positioned in the battery port for charging in the battery port and to have the battery terminals electrically and mechanically mate with the battery dock terminals. The battery is also configured to be removed from the battery port and to have the battery terminals electrically and mechanically mate with the charger terminals for charging outside the battery port.

A tracked vehicle, controller for the tracked vehicle, and a method performed thereon are provided that enable the pilot to steer the tracked vehicle using an existing joystick of the tracked vehicle.

A vehicle control system includes a communication network, a vehicle integration module, and a pair of control assemblies. Each of the pair of control assemblies is configured to be operated by a respective control lever and communicatively connected to the vehicle integration module. Each of the pair of control assemblies comprises an operator control assembly that includes a neutral switch, a return-to-neutral assembly configured to provide a return force to the respective control lever, a return-to-neutral shaft supporting a portion of the return-to-neutral assembly, a magnet attached to the return-to-neutral shaft, a position sensor assembly, and a linkage connecting the operator control assembly to the return-to-neutral assembly. The position sensor assembly includes a circuit board, a magnetic field sensor configured to sense a rotational orientation of the magnet, and a plurality of terminals for communication with the circuit board.