Apparatus, system, and method for controlling motor

What is claimed is: 1. A motor control apparatus comprising: an inverter that is configured to, based on a switching operation, convert an input current received from an external power source into a driving current for operating a motor, the inverter being configured to output the driving current to the motor; and a controller configured to: detect a motor current in the motor, control the switching operation of the inverter based on the motor current to thereby control an operation of the motor, and based on starting the operation of the motor, drive the motor to an alignment position by controlling the switching operation to apply a first waveform current and a second waveform current to a stator of the motor, each of the first waveform current and the second waveform current having a magnitude configured to vary with time, wherein each of the first waveform current and the second waveform current is half-wave rectified and has a positive value, wherein the motor is configured to define a d-axis based on magnetic flux of the motor, wherein the first waveform current and the second waveform current are currents corresponding to the d-axis, and wherein direct current (DC) offsets of the first waveform current and the second waveform current are equal to each other. 2. The motor control apparatus of claim 1 , wherein each of the first waveform current and the second waveform current comprises a sine waveform. 3. The motor control apparatus of claim 2 , wherein each of the first waveform current and the second waveform current is defined by rectifying the sine waveform into a half-waveform. 4. The motor control apparatus of claim 3 , wherein each of the first waveform current and the second waveform current comprises a pulse-type waveform having a plurality of cycles. 5. The motor control apparatus of claim 4 , wherein the pulse-type waveform has a preset interval between adjacent pluses. 6. The motor control apparatus of claim 1 , wherein each of the first waveform current and the second waveform current defines a sawtooth waveform. 7. The motor control apparatus of claim 1 , wherein the DC offsets of the first waveform current and the second waveform current are zero. 8. The motor control apparatus of claim 7 , wherein the first waveform current and the second waveform current are defined according to a preset condition. 9. The motor control apparatus of claim 8 , wherein the preset condition comprises at least one of a reference frequency at which the motor is configured to not rotate or a reference magnitude of current that saturates an air gap of the stator. 10. The motor control apparatus of claim 1 , wherein the controller is configured to apply the first waveform current to the stator during a preset first application time, and then apply the second waveform current to the stator during a preset second application time. 11. The motor control apparatus of claim 10 , wherein the magnitude of the second waveform current is greater than the magnitude of the first waveform current. 12. The motor control apparatus of claim 1 , wherein the controller is configured to detect a stator resistance of the stator based on a motor voltage of the motor according to the first waveform current and the second waveform current. 13. A motor control system comprising: a motor comprising a stator and a rotor; and a control apparatus comprising an inverter that is configured to, by a switching operation, convert an input current received from an external power source into a driving current for operating the motor, the inverter being configured to output the driving current to the motor, wherein the control apparatus configured to: control an operation of the motor by the switching operation of the inverter, based on starting the operation of the motor, drive the rotor to an alignment position by applying a first waveform current and a second waveform current to the stator, each of the first waveform current and the second waveform current having a magnitude configured to vary with time, wherein each of the first waveform current and the second waveform current is half-wave rectified and has a positive value, wherein the motor is configured to define a d-axis based on magnetic flux of the motor, wherein the first waveform current and the second waveform current are currents corresponding to the d-axis, and wherein direct current (DC) offsets of the first waveform current and the second waveform current are equal to each other. 14. The motor control system of claim 13 , wherein the control apparatus is configured to apply the first waveform current to the stator for a preset first application time, and then apply the second waveform current to the stator for a preset second application time. 15. The motor control system of claim 13 , wherein the control apparatus is configured to apply the first waveform current and the second waveform current to the stator with a frequency at which the motor is configured to not rotate. 16. The motor control system of claim 13 , wherein the control apparatus is configured to apply the first waveform current and the second waveform current to the stator with a magnitude that saturates an air gap of the stator. 17. The motor control system of claim 13 , wherein the magnitude of the second waveform current to the stator is greater than the magnitude of the first waveform current. 18. The motor control system of claim 13 , wherein the control apparatus is configured to detect a stator resistance of the stator based on applying the first waveform current and the second waveform current to the stator. 19. A motor control method for controlling a motor, the method comprising: detecting a motor current in the motor; controlling a switching operation of an inverter based on the motor current to thereby control an operation of the motor; based on starting the operation of the motor, driving the motor to an alignment position by controlling the switching operation; applying a first waveform current to a stator of the motor, the first waveform current being a half-wave rectified current having a first magnitude that is a positive value and configured to vary with time; applying a second waveform current to the stator of the motor, the second waveform current being a half-wave rectified current having a second magnitude that is a positive value and configured to vary with time; and detecting a stator resistance of the stator based on applying each of the first waveform current and the second waveform current to the stator, wherein the motor is configured to define a d-axis based on magnetic flux of the motor, wherein the first waveform current and the second waveform current are currents corresponding to the d-axis, and wherein direct current (DC) offsets of the first waveform current and the second waveform current are equal to each other. 20. The method of claim 19 , wherein applying the first waveform current comprises applying the first waveform current to the stator for a preset first application time, and wherein applying the second waveform current comprises applying the second waveform current to the stator for a preset second application time.