An apparatus controls a motor equipped in a hybrid vehicle. In this apparatus, a basic torque command value of the motor is calculated so as to reduce a deviation between a target rotation speed and an actual rotation speed of the motor. A torque correction value for the motor is calculated based on a variation of the target rotation speed which is obtained per unit time and a value of inertia of a power train rotated integrally with the rotation shaft of the motor. Further, a torque command value finally supplied to the motor is calculated by correcting the basic torque command value with use of the torque correction value.

A power transmission device of a work vehicle has an input shaft, an output shaft, a gear mechanism, and an electric motor. The gear mechanism has a planetary gear mechanism and transmits the rotation of the input shaft to the output shaft. The electric motor is connected to a rotating element of the planetary gear mechanism. The power transmission device is configured to change the rotation speed ratio of the output shaft with respect to the input shaft by changing the rotation speed of the electric motor. A control unit has a target torque determination unit and a target torque correcting unit. The target torque determination unit determines a target torque of the electric motor. The target torque correcting unit corrects the target torque according to a correction torque based on a moment of inertia of the electric motor.

The disclosed vehicle control device (10) controls outputs of a left driving source (2L) and a right driving source (2R) in a vehicle (1) provided with a left driving system including a left axle (4L) and a left wheel (5L) and a right driving system including a right axle (4R) and a right wheel (5R) and includes: a calculator (11) that calculates an equivalent sum value corresponding to a sum of a left requested torque and a right requested torque and an equivalent difference value corresponding to a difference between the left requested torque and the right requested torque; a sum model that models motion states of the left driving system and the right driving system while the vehicle (1) is running straight, the equivalent sum value being applied to the sum model; a difference model that models motion states of the left driving system and the right driving system while the vehicle (1) is cornering, the equivalent difference value being applied to the difference model; and a controller (12) that controls the outputs, using a sum-mode instruction torque and a difference-mode instruction torque obtained by application to the sum model and the difference model, respectively.

The disclosed vehicle control device (10) is for controlling outputs of a left driving source and a right driving source, and includes a calculator (21), a storing unit (22), and a controller (23). The calculator (21) calculates an equivalent sum value corresponding to sum of a left target speed and a right target speed, and calculates an equivalent difference value corresponding to a difference between the left target speed and the right target speed. The storing unit (22) stores a sum model and a difference model. The sum model modes motion states of the left driving system, the right driving system, the left driving source, and the right driving source while the vehicle is running straight and is applied with the equivalent sum value to derive a sum instruction torque. The difference model models motion states of the left driving system, the right driving system, the left driving source, and the right driving source while the vehicle is cornering and is applied with the equivalent difference value to derive a difference instruction torque. The controller (23) controls torques of the left driving source and the right driving source, using the sum instruction torque and the difference instruction torque.