A method is described for influencing the engine control of a single-track motor vehicle, in which the current driving situation is ascertained, a predefined driving situation is selected from a specified class of predefined driving situations as a function of the current driving situation, and the engine control is influenced as a function of the selected predefined driving situation in a manner that is independent of the driver.

A method for influencing the energy consumption during the operation of a motor, particularly a motor in a vehicle, to reduce the total amount of energy consumed. A setpoint value that is based on a parameter that correlates with the energy consumed by the motor is defined. The parameter can be distance consumption, for example, mpg or liter/100 km, or some other parameter that correlates with the energy consumed. The actual value of the parameter is calculated during operation of the motor and compared with the setpoint value. Energy consumption is reduced if the actual value exceeds the setpoint. The method allows some flexibility in defining how frequently or when a reduction in the energy consumption is effected, in order to accommodate particular operating or driving conditions or driving behavior. One example of the variation is a consumption credit that possibly allows an overrun of the setpoint value.

An electric supercharging system has an electric supercharger disposed on an intake air passage of an engine and a control unit in which a microcomputer is built. Then, control unit changes an actuation timing of the electric supercharger on the basis of change amounts of a rotational speed and an accelerator opening of the engine. At this time, the control unit changes the actuation timing of the electric supercharger by correcting the actuation timing of the electric supercharger according to the rotational speed of the engine with a coefficient according to the change amount of the accelerator opening.

A throttle control system and methods are disclosed that provide a driver of a vehicle with greater control over engine functions and vehicle performance. The throttle control system processes input signals from a throttle pedal of the vehicle and sends modified throttle position signals to a throttle body of the vehicle so as to increase throttle responsiveness of the vehicle. The throttle control system includes a control module, a wiring harness, and a signal adjuster. The wiring harness electrically couples the control module with the throttle pedal and the throttle body. The control module sends signals directly to the throttle body of the engine, bypassing an electronic control unit of the vehicle. The signal adjuster includes a rheostat that enables manual adjustment of the throttle responsiveness of the vehicle. A control dial coupled with the rheostat facilitates hand operation of the rheostat.

Methods and systems are provided for providing torque reserve via an electrically assisted turbocharger. A portion of requested torque reserve is provided by intentionally reducing turbine speed of an electric turbocharger by operating the associated electric motor as a generator. The resulting reduction in air mass allows for the torque reserve to be provided with reduced reliance on spark and throttle based torque reserve.

In accordance with an aspect of the present disclosure, cruise control of an automotive vehicle in a fuel economy cruise control mode controls vehicle speed to be within a fuel economy speed band about a cruise control set speed so that instantaneous fuel economy is at least equal to average fuel economy.

Provided is an engine control device capable of, when performing control of an in-cylinder oxygen concentration according to engine operation state, controlling an engine to accurately realize vehicle behavior intended by a driver, while suppressing generation of knock noises due to abnormal combustion. The engine control device comprises: a basic target torque-determining part (61) configured to determine a basic target torque based on a driving state of a vehicle including manipulation of an accelerator pedal; a torque reduction amount-determining part (63) configured to determine a torque reduction amount based on a driving state of the vehicle other than the manipulation of the accelerator pedal; a final target torque-determining part (65) configured to determine a final target torque based on the basic target torque and the torque reduction amount; and an engine control part (69) configured, based on a fuel injection parameter preliminarily set correspondingly to an operation state of an engine, to control a fuel injector to enable the engine to output the final target torque, and, when the final target torque changes correspondingly to a change in the torque reduction amount, to correct the fuel injection parameter.

Methods, apparatus, systems, and computer-readable media are provided for employing a mode expansion module to increase a number of operating modes in which a vehicle can operate. The mode expansion module can operate as a computing device, which can be connected to an existing vehicle for sending and receiving both sensor signals and engine control signals. The mode expansion module can be controlled by a user using an existing vehicle control switch that is connected to the vehicle, and can leverage connections to an existing display panel in the vehicle in order to indicate to the user the operating mode that has been selected. Furthermore, when a particular mode of the mode expansion module is selected, the mode expansion module can modify control commands being transmitted from an existing engine control module, and/or modify sensor signals being provided to the existing engine control module.

The invention relates to a verification module (118) for verifying accuracy of a controller (116). The controller (116) is arranged to generate a demand based on a first input and a second input. The verification module (118) comprises; a calculation module (120) arranged to calculate an expected demand; a correction module (122) arranged to calculate an error between the demand and the expected demand and modify the expected demand to reduce the error; and a limiter (136) arranged to limit the demand in response to the error being greater than a threshold.

A control circuit and method for a fuel-saving multi-state switch is provided. The control circuit comprises a vehicle body ECU, a fuel-saving control unit, and a PWM voltage regulating unit. The fuel-saving control unit is connected to the vehicle body ECU through a CAN bus to collect CAN signals. The fuel-saving control unit determines a switch gear required by a current vehicle according to the CAN signals and outputs a PWM pulse signal having a corresponding duty cycle. The PWM voltage regulating unit is connected to the fuel-saving control unit to receive the PWM pulse signal. The PWM voltage regulating unit outputs a voltage value corresponding to the switch gear according to the PWM pulse signal. The vehicle body ECU is connected to the PWM voltage regulating unit to receive the voltage value, so as to control a speed and torque of an engine according to the voltage value.