Dual inverter system and method of controlling the same

What is claimed is: 1. A dual inverter system to drive a motor in an electronic apparatus, the dual inverter system comprising: a first inverter connected to one side of a winding of the motor to modulate a pulse width and to adjust power supplied to the motor; a second inverter connected to the other side of the winding of the motor to modulate a pulse width and to adjust power supplied to the motor; a first current detector connected to the first inverter to detect a current flowing in the first inverter; a second current detector connected to the second inverter to detect a current flowing in the second inverter; and a controller to control the motor by controlling a pulse-width modulation (PWM) signal applied to the first inverter or the second inverter based on the current flowing in at least one of the first inverter and the second inverter. 2. The dual inverter system of claim 1 , wherein the first inverter includes a plurality of first high side switching devices and a plurality of first low side switching devices connected to emitters of the plurality of first high side switching devices, respectively, and the second inverter includes a plurality of second high side switching devices and a plurality of second low side switching devices connected to emitters of the plurality of second high side switching devices, respectively. 3. The dual inverter system of claim 2 , wherein the first current detector includes a plurality of resistors connected between the plurality of first low side switching devices and a ground, respectively, and the second current detector includes a plurality of resistors connected between the plurality of second low side switching devices and the ground, respectively. 4. The dual inverter system of claim 3 , wherein if a reference value of a phase voltage applied to the motor is a positive value, the PWM generator switching-controls the first high and low side switching devices of the first inverter and ON-controls the second low side switching devices of the second inverter, and if a reference value of the phase voltage applied to the motor is a negative value, the PWM generator switching-controls the second high and low side switching devices of the second inverter and ON-controls the second low side switching devices of the first inverter. 5. The dual inverter system of claim 4 , wherein the controller includes a current selector to select a current flowing in at least one resistor connected to the ON-controlled low side switching devices, and a current controlling unit to compare the selected current with a target current and to generate a phase voltage reference. 6. The dual inverter system of claim 2 , wherein pairs of the high side switching devices and the low side switching devices of the first inverter and pairs of the high side switching devices and the low side switching devices of the second inverter correspond to the number of phases of the motor. 7. A dual inverter system to drive a motor in an electronic apparatus, the dual inverter system comprising: a first inverter and a second inverter connected between voltage lines and each connected to opposite contacts of the motor, such that the first and second inverters are connected to opposite sides of a winding of the motor, respectively; a first current detector and a second current detector disposed to detect a current flowing between one of the voltages lines and the first and second inverters, respectively; and a controller to control a PWM operation on the first inverter when performing an ON operation on switching devices of the second inverter connected to the one voltage line, and to control a PWM operation on the second inverter when performing an ON operation on switching devices of the first inverter connected to the one voltage line, according to the detected current and a target current. 8. The dual inverter system of claim 7 , wherein: the first inverter and the second inverter each comprise high side switching devices and low side switching devices; and the switching devices of the first inverter and the switching devices of the second inverter are the low side switching devices of the first inverter and the low side switching devices of the second inverter, respectively. 9. The dual inverter system of claim 7 , wherein: the motor comprises three windings each having the opposite contacts; the first inverter and second converter each comprise pairs of switching devices connected between the voltage lines; one of the opposite contacts is connected to a contact between each pair of switching devices of the first inverter; and the other one of the opposite contacts is connected to a contact between each pair of switching devices of the second inverter. 10. The dual inverter system of claim 7 , wherein the first current detector and the second current detector each comprise a resistor connected between the one voltage line and the respective switching devices. 11. The dual inverter system of claim 10 , wherein the first current detector and the second detector each detects the current at a contact between the resistor and the respective switching devices such that the detected current is lower than another current at another contact between the voltage lines. 12. The dual inverter system of claim 7 , further comprising; a PWM generator to generate a PWM signal to the first inverter or the second inverter to perform the PWM operation. 13. The dual inverter system of claim 12 , wherein the PWM generator generates a constant signal to the first inverter or the second inverter during a phase corresponding to the ON operation such that the switching devices of the first inverter or the second inverter are on. 14. The dual inverter system of claim 7 , wherein the first current detector and the second current detector detect the current from the first inverter and the second inverter during the PWM operation and the ON operation. 15. The dual inverter system of claim 14 , wherein the controller adjusts a PWM signal corresponding to the PWM operation and a duration of the ON operation on the first inverter and the second inverter according to the detected current from the first inverter and the second inverter.