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 for operating a motor vehicle having an engine and an electric machine, a transmission, a battery, and an exhaust treatment system having a particulate filter. The battery discharges during a charge-depleting mode of the electrical machine and charges when the electrical machine operates as a generator such that the battery charge state moves between lower and upper limits. If a filter regeneration requirement is detected, the filter is regenerated by raising the temperature of the exhaust gas. When the need for filter regeneration is detected, the battery is discharged to below the lower limit, in the charge-depleting mode of the electrical machine, prior to the regeneration. Subsequently, to regenerate the filter, the engine is operated to raise the exhaust gas temperature by increasing the torque provided by the engine, and the electric machine operates as a generator to charge the battery and/or operate an auxiliary electrical load.

A driving control method of a hybrid vehicle is provided. The method includes acquiring link information on each of a current link in which the vehicle currently travels in an electric vehicle (EV) mode and a forward link connected to the current link ahead of the current link. A first average driving load of the current line and a second average driving load of the forward link are calculated based on the acquired link information. When the second average driving load is greater than the first average driving load a minimum required state of charge (SoC) based on the second average driving load and a preset driving mode switch reference are determined.

A system includes an ignition switch, a power source, a power outlet, and an electronic control unit communicatively coupled to the ignition switch. The electronic control unit is configured to: determine that the ignition switch is set to an OFF state, determine whether a state of charge of an electronic device coupled to the power outlet is below a target state of charge, and in response to determining that the ignition switch is set to the OFF state and determining that the state of charge is below the target state of charge, provide power to the electronic device, from the power source and through the power outlet, while the ignition switch is set to the OFF state until the state of charge of the electronic device reaches the target state of charge.

A hybrid vehicle includes an internal combustion engine, a battery, an electric motor, and a controller. The controller is configured to set a traveling schedule to a destination by assigning any control mode out of a charge depleting mode and a charge sustaining mode to each of a plurality of traveling sections on a scheduled traveling route from a current position to the destination. The traveling sections include at least one of a first section, a second section, and a third section. The first section is a traveling section that requires traveling with the internal combustion engine stopped. When the traveling sections include the first section, the controller is configured to execute a suppression process for suppressing consumption of electric power in the battery as compared to a case where the traveling sections do not include the first section.

A vehicle driving apparatus including a first oil pump driven by an internal combustion engine; a second oil pump connected to a torque transmission portion transmitting a driving force of the second motor generator to a drive wheel; a hydraulic circuit configured so that a lubricating oil is supplied from the second oil pump to a lubrication portion in a first mode in which a vehicle travels while stopping the internal combustion engine, and the lubricating oil is supplied from the first and second oil pumps to the lubrication portion in a second mode in which the vehicle travels while driving the internal combustion engine; a slip detector detecting a slip state of the drive wheel, and a control unit switching to the second mode when the slip state is detected during the first mode.

A vehicle controller includes: a prediction unit that acquires position information on a parking place where parking time is predicted to exceed a prescribed threshold value in a travel route of the hybrid vehicle; and a target setting unit that sets a target state of charge of the battery and to change setting of the target state of charge from a first state of charge to a second state of charge that is lower than the first state of charge when the hybrid vehicle satisfies an approach condition to the parking place. A charge and discharge amount of the battery when the state of charge of the battery becomes equal to or less than the second state of charge is controlled to be smaller than the charge and discharge amount of the battery when the state of charge of the battery is larger than the second state of charge.

A control system for a hybrid vehicle that is configured to generate a driving force as required even if it is necessary to charge a battery rapidly. The hybrid vehicle may be propelled in a parallel mode in which power of the engine is partially translated into electric power by a motor and the remaining power of the engine is delivered to drive wheels. In a case that a rapid charging command is transmitted and that a required driving force is greater than a first driving force, the motor is operated to generate electric power in a predetermined amount, and the driving force is restricted to the first driving force.

An electric-axle device for a commercial vehicle that can minimize the frequency of using a main brake when braking, may include a first clutch device disposed between a motor and a differential casing to transmit or block power, a second clutch device disposed between the differential casing and a disc, an electromagnetic brake applying a braking force to the disc, and that can increase a coasting distance and improve energy efficiency and durability of the motor by disengaging the first clutch device and the second clutch device such that kinetic energy, which is transmitted to the motor from an axle shaft, is blocked as if a neutral gear of a transmission is engaged, when the vehicle coasts.

A vehicle control device includes power source, electrical storage device, electric motor connected to driving wheel, able to be driven by supply of electric power from electrical storage device and supplys regenerative electric power generated upon regenerative operation to electrical storage device, a road information acquisition part acquires road information related to scheduled traveling route of the vehicle, a control target segment extraction part extracts control target segment, in which change of remaining capacity of the electrical storage device equal to or greater than predetermined value is predicted, on scheduled traveling route, and a charge/discharge planning part plans charge/discharge of the electrical storage device based on vehicle traveling load in road from the vehicle to the control target segment, and the charge/discharge planning part determines the vehicle traveling load of the segment located before the control target segment according to attribute of the control target segment.