A method and a device for optimizing fuel consumption includes using a charge mode of a plug-in hybrid vehicle.

A control apparatus is used in a vehicle equipped with an internal combustion engine, a rotating electrical machine, and a storage battery. The control apparatus stops the engine when a state of charge (SOC) of the storage battery is higher than a lower limit, and an automatic stop condition is met and also restarts the engine when the SOC of the storage battery is lower than the lower limit, and an automatic restart condition is met. The control apparatus also controls operation of the rotating electrical machine to generate electricity to increase the SOC above a target SOC and also actuates the rotating electrical machine to assist in driving the vehicle when the SOC is higher than a torque assist enable SOC. The target SOC is set higher than the lower limit. The torque assist enable SOC is set higher than the target SOC. This improves the fuel economy.

Method for heating an exhaust aftertreatment system in a hybrid vehicle comprising an internal combustion engine and an electric machine, comprising the steps of measuring an exhaust condition for the function of the exhaust aftertreatment system, determining if the exhaust condition is below a predefined limit, applying a load from the electric machine on the internal combustion engine when the temperature is below the predefined limit, in order to increase the combustion engine torque, charging the battery system of the vehicle with power from the electric machine, and disconnecting the electric machine from the internal combustion engine when the exhaust condition for the function of the exhaust aftertreatment system is above the predefined limit. The advantage of the invention is that the heating of an exhaust aftertreatment system after a cold start of a hybrid vehicle can be improved, such that the exhaust emission of the vehicle can be minimized.

The control device of hybrid vehicle 1 comprises an output control part 41 configured to control outputs of the internal combustion engine 10 and the motor 16, a target SOC setting part 42 configured to set a target state of charge, and an arrival rate calculating part 43 configured to calculate a probability of the hybrid vehicle reaching the charging station. When the hybrid vehicle is being driven outside the charging station, the output control part is configured to control outputs of the internal combustion engine and the motor so that a state of charge of the battery when the hybrid vehicle reaches the charging station becomes the target state of charge. The target SOC setting part is configured to lower the target state of charge when the probability is relatively high compared to when the probability is relatively low.

A vehicle driving control method depending on a baby mode, may include, when the baby mode is activated, receiving information on a state of a vehicle seat, correcting a center state of charge (SOC) value of a battery of the vehicle based on the information on the state of the vehicle seat, determining a state of a transmission of the vehicle, and performing regenerative brake and brake pedal stroke (BPS) scale/filtering correction control or an electric vehicle (EV) mode and accelerator position sensor (APS) scale/filtering correction control based on the state of the transmission of the vehicle and the state of the vehicle seat.

A method and system are provided for adapting a vehicle control strategy of an on-road vehicle following a reoccurring fixed route to a predetermined destination, which fixed route extends through at least one geographical zone associated with at least one environmental restriction. When it is determined that the vehicle is approaching the geographical zone, historical data collected from previous passages of one or several vehicles through the zone is accessed, and the vehicle control strategy inside the geographical zone is adapted based on the historical data and the environmental restriction.

A system includes a power source and a memory to store an event that is predicted to occur, an action to be performed by the power source to increase efficiency of the power source during the stored event, and a mis-prediction counter indicating a count of mis-predictions. The system further includes an ECU designed to predict that the stored event will occur and to control the power source to take the action when the stored event is predicted to occur. The ECU is further designed to update the mis-prediction counter and to adjust at least one of the stored event that is predicted to occur, the stored action to be performed by the power source, or a prediction horizon of the prediction when the mis-prediction counter reaches or exceeds a threshold quantity of mis-predictions to increase efficiency of the power source during a subsequent prediction of the stored event.

A hybrid vehicle includes: an internal combustion engine; a motor generator; an electric storage device electrically connected with the motor generator; and a control device configured to set a control mode of an electric storage level of the electric storage device, to one of a charge depleting mode and a charge sustaining mode. The control device is configured to expand a permissible fluctuation band of the electric storage level during the charge sustaining mode, when the control device is performing a first switching control, compared to when the control device is not performing the first switching control, the first switching control being a control in which the control device automatically performs switching between the charge depleting mode and the charge sustaining mode, at least partly based on a predicted load on a planned traveling route for the hybrid vehicle.

A method for operating an idling control device for a motor vehicle. The idling control device specifies a total setpoint torque including a setpoint torque of an electric motor and a setpoint torque of an internal combustion engine which interacts with the electric motor, and sets the setpoint torques by respective control paths. In a first operating mode the idling control device sets a requested total setpoint torque only via the control path of the internal combustion engine by at least one control intervention, and in a second operating mode the idling control device sets the requested total setpoint torque by at least one control intervention via the control path of the internal combustion engine and by at least one control intervention via the control path of the electric motor. The control interventions via the control path of the internal combustion engine consist of at least one predetermined slow control intervention, and the control interventions in the control path of the electric motor consist of at least one predetermined fast control intervention, which intervenes with a higher rate of change over time than the at least one predetermined slow control intervention.

A method for operating an onboard network of a hybrid motor vehicle. The onboard network is connected to an energy storage unit, especially a battery; an electric motor of a hybrid drive train, which also has an internal combustion engine; and actuators of an electromechanical chassis system that can be operated as generators. At least one reserve capacity of the energy storage unit is kept open for the supplying of electrical energy generated by at least one portion of the actuators to the onboard network. The reserve capacity being held open is dynamically adapted as a function of at least one item of driver style information describing the driving style of the driver of the hybrid motor vehicle and/or at least one item of situation information describing the current and/or future operation of the hybrid motor vehicle.