Vehicle control apparatus

What is claimed is: 1. A vehicle control apparatus, which is applied to a vehicle to control driving of an electric motor of the vehicle, the vehicle including an engine; a transmission; a clutch configured to connect and disconnect a crankshaft of the engine and an input shaft of the transmission; a torsion damper configured to allow relative rotation of the crankshaft and the input shaft by torsional deformation in a connection state of the clutch; a wheel connected to a drive shaft of the transmission; and the electric motor connected to one of the input shaft, the transmission, and the drive shaft, which constitute a power train that transmits power of the engine to the wheel, the vehicle control apparatus comprising circuitry including a processor connected to a memory and configured to: calculate an engine pulsation frequency that indicates a frequency of torque pulsation generated in the engine in proportion to a rotational speed of the engine and to calculate a damper resonance frequency, at which the torsion damper resonates with the engine pulsation frequency in a torsional direction; switch a damping control content that suppresses vibration generated in the power train using the engine pulsation frequency and the damper resonance frequency; calculate a gain, used for a torque command for driving the electric motor, using the engine pulsation frequency and the damper resonance frequency according to the damping control content; calculate the torque command by multiplying the calculated gain by at least one of a torsion torque reduction component having a reverse phase with respect to a torsion torque generated by the torsion damper and a motor torque reduction component having a reverse phase with respect to a motor torque generated according to rotation of the electric motor; determine a damping control torque command, which generates, in the electric motor, a damping control torque for suppressing the vibration generated in the power train, based on the torque command; and control the driving of the electric motor based on the damping control torque command so as to generate the damping control torque in the electric motor, wherein the circuitry calculates a first gain, which increases as the engine pulsation frequency varies so as to coincide with the damper resonance frequency, and a second gain, which decreases as the engine pulsation frequency increases, and the circuitry calculates a first torque command that drives the electric motor by summing up a value calculated by multiplying the first gain by the torsion torque reduction component having the reverse phase with respect to the torsion torque generated by the torsion damper, and a value calculated by multiplying the second gain by an inertia torque reduction component having a reverse phase with respect to a motor inertia torque generated according to rotation of the electric motor. 2. The vehicle control apparatus according to claim 1 , wherein the circuitry determines a case where the engine pulsation frequency is less than a first frequency obtained by subtracting a first predetermined value from the damper resonance frequency, a case where the engine pulsation frequency is equal to or greater than the first frequency and is also equal to or less than a second frequency obtained by adding a second predetermined value to the damper resonance frequency, and a case where the engine pulsation frequency is greater than the second frequency. 3. The vehicle control apparatus according to claim 2 , wherein the circuitry is further configured to: calculate a first gain, which becomes a minimum value when the engine pulsation frequency coincides with the first frequency in the case where the engine pulsation frequency is less than the first frequency; calculate a second gain, which decreases as the engine pulsation frequency increases from the first frequency toward the second frequency, and a third gain, which increases as the engine pulsation frequency increases from the first frequency toward the second frequency, in the case where the engine pulsation frequency is equal to or greater than the first frequency and is also equal to or less than the second frequency; and calculate a fourth gain, which becomes a maximum value when the engine pulsation frequency coincides with the second frequency in the case where the engine pulsation frequency is greater than the second frequency; calculate the torque command by multiplying the motor torque reduction component by the first gain in the case where the engine pulsation frequency is less than the first frequency; calculate the torque command by summing up a value obtained by multiplying the motor torque reduction component by the second gain, and a value obtained by multiplying the torsion torque reduction component by the third gain, in the case where the engine pulsation frequency is equal to or greater than the first frequency and is also equal to or less than the second frequency; and calculate the torque command by multiplying the torsion torque reduction component by the fourth gain in the case where the engine pulsation frequency is greater than the second frequency. 4. The vehicle control apparatus according to claim 1 , wherein the circuitry is further configured to determine whether or not to generate the damping control torque in the electric motor according to a clutch stroke amount directed in a connection direction of the clutch, and determine that the damping control torque command is zero when it is determined that generation of the damping control torque is unnecessary. 5. The vehicle control apparatus according to claim 1 , wherein the circuitry determines the damping control torque command by performing an upper/lower limit processing on the torque command. 6. The vehicle control apparatus according to claim 1 , wherein the circuitry is further configured to set a band pass filter having the engine pulsation frequency as a pass band and perform a band pass filter processing on the torque command to calculate a post-filter torque command, and calculate the damping control torque command based on the post-filter torque command. 7. The vehicle control apparatus according to claim 1 , wherein the circuitry is further configured to set the second gain to be greater than the first gain when the engine pulsation frequency is lower than the damper resonance frequency, or set the first gain to be greater than the second gain when the engine pulsation frequency is higher than the damper resonance frequency. 8. The vehicle control apparatus according to claim 1 , wherein the circuitry is further configured to calculate the torsion torque of the torsion damper using a stiffness preset in the torsion damper in the torsional direction, a crank angle of the crankshaft, and a rotation angle of the electric motor, and calculate the motor inertia torque of the electric motor using a moment of inertia preset in the electric motor and a rotational angular acceleration calculated from the rotation angle of the electric motor. 9. The vehicle control apparatus according to claim 1 , wherein the circuitry is further configured to calculate the engine pulsation frequency using the rotational speed of the engine calculated from the crank angle of the crankshaft, and calculate the damper resonance frequency according to a gear position of the transmission. 10. A vehicle control method to control an electric motor of a vehicle, the vehicle including an engine; a transmission; a clutch configured to connect and disconnect a crankshaft of the engine and an input shaft of the transmission; a torsion damper configured to allow relative rotation of the crankshaft and t