Control system for an electric power steering system

What is claimed is: 1. A control system comprising: an electric motor; a speed reducer that amplifies motor torque generated by the electric motor; a steering torque detector configured to detect a steering torque; a basic motor torque command value computation unit that computes a basic motor torque command value for the electric motor; an external torque specifying unit that specifies external torque that is applied to the speed reducer and that is other than the motor torque; a motor angular velocity computation unit that computes an angular velocity of the electric motor with use of a model formed on an assumption that friction is not generated in the speed reducer or with use of a model obtained by modifying the model formed on the assumption that friction is not generated in the speed reducer, based on an actually-measured motor angular velocity; a friction compensation control unit that estimates friction to be compensated for, with use of the external torque specified by the external torque specifying unit, the angular velocity computed by the motor angular velocity computation unit, and a simulation model of the control system in which the friction to be compensated for including at least friction generated in the speed reducer out of friction generated in the control system is taken into account; a motor torque command value computation unit that computes a motor torque command value that is a target value of the motor torque to be generated from the electric motor, with use of the friction estimated by the friction compensation control unit and the basic motor torque command value computed by the basic motor torque command value computation unit; and a controller that controls the electric motor based on the motor torque command value computed by the motor torque command value computation unit. 2. The control system according to claim 1 , wherein the friction compensation control unit includes: a determination unit that determines a state of contact of the speed reducer with use of the external torque specified by the external torque specifying unit and the detected steering torque; a friction coefficient estimation unit that estimates a friction coefficient of a power column that includes a friction coefficient of the speed reducer based on the angular velocity computed by the motor angular velocity computation unit; and a frictional force estimation unit that computes and estimates the friction to be compensated for, based on a result of determination made by the determination unit, the friction coefficient estimated by the friction coefficient estimation unit, the external torque specified by the external torque specifying unit, and the angular velocity computed by the motor angular velocity computation unit. 3. The control system according to claim 2 , wherein: the determination unit is configured to determine whether the state of contact between two gears that constitute the speed reducer is a single contact state or a double contact state; and the frictional force estimation unit is configured to compute the friction to be compensated for, with use of a computing expression corresponding to the result of determination made by the determination unit out of a friction computing expression for the single contact state and a friction computing expression for the double contact state that are set in advance. 4. The control system according to claim 3 , further comprising: a motor angular velocity detector that detects the angular velocity of the electric motor; and a correction value computation unit that computes a motor torque correction value based on a deviation between the angular velocity computed by the motor angular velocity computation unit and the angular velocity detected by the motor angular velocity detector, wherein the motor torque command value computation unit is configured to compute the motor torque command value with use of the basic motor torque command value computed by the basic motor torque command value computation unit, the motor torque correction value computed by the correction value computation unit, and the estimated friction that is estimated by the friction compensation control unit. 5. The control system according to claim 4 , wherein the determination unit is configured to determine the state of contact of the speed reducer with use of the external torque specified by the external torque specifying unit and a value that is obtained by adding the motor torque correction value computed by the correction value computation unit to the basic motor torque command value computed by the basic motor torque command value computation unit. 6. The control system according to claim 2 , further comprising: a motor angular velocity detector that detects the angular velocity of the electric motor; and a correction value computation unit that computes a motor torque correction value based on a deviation between the angular velocity computed by the motor angular velocity computation unit and the angular velocity detected by the motor angular velocity detector, wherein the motor torque command value computation unit is configured to compute the motor torque command value with use of the basic motor torque command value computed by the basic motor torque command value computation unit, the motor torque correction value computed by the correction value computation unit, and the estimated friction that is estimated by the friction compensation control unit. 7. The control system according to claim 6 , wherein the determination unit is configured to determine the state of contact of the speed reducer with use of the external torque specified by the external torque specifying unit and a value that is obtained by adding the motor torque correction value computed by the correction value computation unit to the basic motor torque command value computed by the basic motor torque command value computation unit. 8. The control system according to claim 2 , wherein the friction coefficient estimation unit is configured to estimate the friction coefficient with use of the angular velocity computed by the motor angular velocity computation unit and a LuGre model wherein the simulation model includes the LuGre model. 9. The control system according to claim 1 , wherein the friction compensation control unit includes: a normal force computation unit that computes a normal force that acts on a tooth surface of the speed reducer, with use of the external torque specified by the external torque specifying unit and the basic motor torque command value computed by the detected steering torque; a friction coefficient estimation unit that estimates a friction coefficient of a power column that includes a friction coefficient of the speed reducer based on the angular velocity computed by the motor angular velocity computation unit; and a frictional force estimation unit that computes and estimates the friction to be compensated for, based on the normal force computed by the normal force computation unit and the friction coefficient estimated by the friction coefficient estimation unit. 10. The control system according to claim 9 , further comprising: a motor angular velocity detector that detects the angular velocity of the electric motor; and a correction value computation unit that computes a motor torque correction value based on a deviation between the angular velocity computed by the motor angular velocity computation unit and the angular velocity detected by the motor angular velocity detector, wherein the motor torque command value computation unit is configured to compute the motor torque command value with use of the basic motor torque command value computed by the basic motor torq