Patent Publication Number: US-11646668-B2

Title: Power converter

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority to China Patent Application No. 202011163688.7, filed on Oct. 27, 2020. The entire contents of the above-mentioned patent application are incorporated herein by reference for all purposes. 
     FIELD OF THE INVENTION 
     The present disclosure relates to a power converter, and more particularly to a power converter capable of reducing the number of signal lines and the wiring area on the system board thereof. 
     BACKGROUND OF THE INVENTION 
     A power converter is used for converting between different forms or voltages of electricity. Conventionally, there are two types of power converters. 
     The first-type conventional power converter usually includes a buck circuit. The buck circuit performs associated operations according to the PWM control signal from the controller. For example, a 12V input voltage is converted into a 1.8V output voltage, and the output voltage is provided to electronic components. However, when the first-type conventional power converter is applied to a circumstance requiring a higher input voltage (e.g., 48V or 54V), for example a data center, the duty cycle of the control signal for controlling the first-type power converter needs to be very small in order to convert the input voltage (e.g., 48V or 54V) into the 1.8V output voltage. In other words, the conversion efficiency of the first-type power converter is not satisfied. 
     For reducing the volume, the weight and the generated heat and increasing the power density of the power converter, the second-type conventional power converter is usually applied to the circumstance requiring the higher input voltage (e.g., 48V or 54V). The second-type conventional power converter is a single-stage converter with a transformer. By adjusting the turn ratio of the primary winding to the secondary winding of the transformer, the conversion efficiency is increased. 
     However, the second-type conventional power converter still has some drawbacks. For example, the primary side of the power converter includes a bridge circuit with many power switches, and the secondary side of the power converter also includes a synchronous rectifier circuit with many power switches. In other words, the second-type conventional power converter includes more power switches than the first-type conventional power converter. Consequently, the controller needs to provide more PWM control signals to the plurality of power switches of the second-type conventional power converter. In this way, the number of the signal lines on the system board of the power converter is large, and the wiring area on the system board is also large. Moreover, the controller needs to use more resource to process more PWM control signals. 
     Moreover, in case that the second-type conventional power converter is a multi-phase power converter with a plurality of single-phase circuits, the controller needs to have many signal terminals to output the PWM control signals for controlling the multi-phase power converter. Consequently, the above problems become more serious, and the size of the controller is too large. As known, the dead time between associated PWM control signals from the controller should be precisely set to avoid the synchronous conduction of the upper switches and the lower switches of the bridge circuit in the primary side of the power converter or avoid the short-circuited condition of the primary/secondary sides of the power converter. Consequently, the controller needs to output more PWM control signals, and the method of designing the controller is more complicated. 
     Therefore, there is a need of providing an improved power converter in order to overcome the drawbacks of the conventional technologies. 
     SUMMARY OF THE INVENTION 
     The present disclosure provides a power converter. Due to the special design of the circuitry structure of the power converter, the number of the control signals to be outputted from the controller is reduced. In this way, the number of signal lines on the system board of the power converter is reduced, and the wiring area on the system board is reduced. 
     The present disclosure provides a power converter. Due to the special design of the circuitry structure of the power converter, it is not necessary to increase the size of the controller and the method of designing the controller is simplified. 
     In accordance with an aspect of present disclosure, a power converter including N power conversion units is provided, wherein N is an integer greater than or equal to 1. Each power conversion unit includes a main switching circuit, a transformer, a synchronous rectifier circuit, an input signal terminal and a signal processor. The main switching circuit includes a bridge circuit. A primary winding of the transformer is electrically connected with the main switching circuit. The synchronous rectifier circuit is electrically connected with a secondary winding of the transformer. The synchronous rectifier circuit includes at least two synchronous rectifier switches. The input signal terminal receives a first PWM control signal. The signal processor generates a first PWM driving signal and a second PWM driving signal to drive the bridge circuit according to the first PWM control signal, and a phase difference between the first PWM driving signal and the second PWM driving signal is (180±θ) degree. The signal processor generates a third PWM driving signal and a fourth PWM driving signal to drive the at least two synchronous rectifier switches according to the first PWM control signal, and a phase difference between the third PWM driving signal and the fourth PWM driving signal is (180±θ) degree. When N is greater than 1, the N power conversion units are connected with each other in parallel, and a difference between every two adjacent ones of the N first PWM control signals is (360/N±θ) degree, wherein θ is greater than or equal to 0 degree and less than 30 degree. 
     The above contents of the present disclosure will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which: 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG.  1    is a schematic circuit diagram illustrating the circuitry structure of a power converter according to a first embodiment of the present disclosure; 
         FIG.  2    is schematic timing waveform diagram illustrating associated control signals and driving signals for the power converter as shown in  FIG.  1   ; 
         FIG.  3    is a schematic circuit diagram illustrating the detailed circuitry structure of the delay logic circuit of the power converter as shown in  FIG.  1   ; 
         FIG.  4    is a schematic circuit diagram illustrating the circuitry structure of a power converter according to a second embodiment of the present disclosure; 
         FIG.  5    is schematic timing waveform diagram illustrating associated control signals of the power converter as shown in  FIG.  4   ; and 
         FIG.  6    is a schematic circuit diagram illustrating an integrated circuitry structure of plural power converters according to an embodiment of the present disclosure. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present disclosure will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this disclosure are presented herein for purpose of illustration and description only. It is not intended to be exhaustive or to be limited to the precise form disclosed. 
     Please refer to  FIGS.  1  and  2   .  FIG.  1    is a schematic circuit diagram illustrating the circuitry structure of a power converter according to a first embodiment of the present disclosure.  FIG.  2    is schematic timing waveform diagram illustrating associated control signals and driving signals for the power converter as shown in  FIG.  1   . The power converter  1  can be applied to a power supply unit (not shown) and disposed on a system board (not shown) of the power supply unit. The power converter  1  receives an input voltage Vin and converts the input voltage Vin into an output voltage Vout. The output voltage Vout is provided to the electronic components of the power supply unit for powering the electronic components of the power supply unit. For example, the input voltage Vin is a 54V or 48V DC voltage, and the output voltage Vout is a 1.8V DC voltage, but not limited thereto. 
     The power converter  1  includes N power conversion units  2 , wherein N is an integer greater than or equal to 1. In the embodiment of  FIG.  1   , N is equal to 1. That is, the power converter  1  includes one power conversion unit  2 , and the power converter  1  is a single-phase power converter. As shown in  FIG.  1   , the power conversion unit  2  includes a main switching circuit  3 , a transformer  4 , a synchronous rectifier circuit  5 , a signal processor  6  and an input signal terminal  7 . 
     The main switching circuit  3  receives the input voltage Vin. The main switching circuit  3  includes a bridge circuit. The bridge circuit is a half-bridge circuit or a full-bridge circuit. In the embodiment of  FIG.  1   , the bridge circuit is a half-bridge circuit including two main switches M 1  and M 2  connected in series. The two main switches M 1  and M 2  are connected with each other and collaboratively formed as a bridge arm. By alternately turning on and turning off the two main switch elements M 1  and M 2 , the input voltage Vin is converted into a first transition AC voltage by the main switching circuit  3 . 
     The transformer  4  includes a primary winding N 1  and a secondary winding N 2 . The primary winding N 1  is electrically connected with the main switching circuit  3  to receive the first transition AC voltage. Due to the electromagnetic coupling effect between the primary winding N 1  and the secondary winding N 2 , the secondary winding N 2  generates a second transition AC voltage. Preferably but not exclusively, the secondary winding N 2  has a center-tap structure. 
     The synchronous rectifier circuit  5  is electrically connected with the secondary winding N 2  of the transformer  4 . The synchronous rectifier circuit  5  includes at least two synchronous rectifier switches Q 1  and Q 2 . By alternately turning on and turning off the two synchronous rectifier switches Q 1  and Q 2 , the second transition AC voltage is converted into the output voltage Vout by the synchronous rectifier circuit  5 . 
     The input signal terminal  7  is electrically connected with a controller  9  of the power supply unit. The input signal terminal  7  receives a first pulse width modulation (PWM) control signal PWM 1  from the controller  9 . 
     The signal processor  6  generates a first PWM driving signal PWM_ 1  and a second PWM driving signal PWM_ 2  according to the first PWM control signal PWM 1 . The phase difference between the first PWM driving signal PWM_ 1  and the second PWM driving signal PWM_ 2  is (180±θ) degree. Consequently, the main switch M 1  is driven by the first PWM driving signal PWM_ 1 , and the main switch M 2  is driven by the second PWM driving signal PWM_ 2 . Similarly, the signal processor  6  generates a third PWM driving signal PWM_ 3  and a fourth PWM driving signal PWM_ 4  according to the first PWM control signal PWM 1 . The phase difference between the third PWM driving signal PWM_ 3  and the fourth PWM driving signal PWM_ 4  is (180±θ) degree. Consequently, the synchronous rectifier switch Q 2  is driven by the third PWM driving signal PWM_ 3 , and the synchronous rectifier switch Q 1  is driven by the fourth PWM driving signal PWM_ 4 . Preferably but not exclusively, the angle θ is greater than or equal to 0 degree and less than 30 degrees. However, the angle θ is not limited to the above embodiment and may be varied according to the practical requirements. 
     As previously described, in case that the second-type conventional power converter is a single-phase circuit, the controller needs to output at least two PWM control signals to control the switches in the main switching circuit and the switches in the synchronous rectifier circuit. In comparison with the second-type conventional power converter, the power converter  1  of the present disclosure is equipped with the signal processor  6 . Consequently, the following benefits can be achieved. In case that the power converter  1  of the present disclosure includes a power conversion unit  2  being a single-phase circuit, the controller  9  needs to output the single first PWM control signal PWM 1  only. After the first PWM control signal PWM 1  is processed into the PWM driving signals PWM_ 1 , PWM_ 2 , PWM_ 3  and PWM_ 4  by the signal processor  6  of the power conversion unit  2 , the PWM driving signals PWM_ 1 , PWM_ 2 , PWM_ 3  and PWM_ 4  are provided to the two main switches M 1  and M 2  and the two synchronous rectifier switches Q 2  and Q 1 , respectively. In this way, the number of the signal lines on the system board of the power converter  1  is reduced, and the wiring area on the system board is reduced. Moreover, the resources of the controller  9  for outputting PWM control signals are also reduced. 
     In some embodiments, the main switching circuit  3  and the synchronous rectifier circuit  5  are electrically connected with a ground terminal G. The signal processor  6  further includes a phase splitter  60 . The phase splitter  60  is used to perform a phase-splitting operation on the first PWM control signal PWM 1 , and thus a second PWM control signal PWM 2  and a third PWM control signal PMW 3  are generated. There is a predetermined phase difference between the second PWM control signal PWM 2  and the third PWM control signal PMW 3 . The frequency of the first PWM control signal PWM 1  is twice the frequency of the second PWM control signal PWM 2 . In addition, the frequency of the first PWM control signal PWM 1  is twice the frequency of the third PWM control signal PWM 3 . For example, the predetermined phase difference between the second PWM control signal PWM 2  and the third PWM control signal PWM 3  is (180±θ) degree. 
     Moreover, the signal processor  6  includes a logic delay circuit  61 . The logic delay circuit  61  delays the second PWM control signal PWM 2  for two different time intervals, respectively. Consequently, a fourth PWM control signal PWM 4  and a fifth PWM control signal PWM 5  are generated, wherein there is a dead time between the fourth PWM control signal PWM 4  and the fifth PWM control signal PWM 5 . The logic delay circuit  61  also delays the third PWM control signal PWM 3  for two different time intervals, respectively. Consequently, a sixth PWM control signal PWM 6  and a seventh PWM control signal PWM 7  are generated, wherein there is a dead time between the sixth PWM control signal PWM 6  and the seventh PWM control signal PWM 7 . 
       FIG.  3    is a schematic circuit diagram illustrating the detailed circuitry structure of the logic delay circuit of the power converter as shown in  FIG.  1   . As shown in  FIG.  3   , the logic delay circuit  61  includes a first delay circuit  610  and a second delay circuit  620 . 
     The first delay circuit  610  includes a first resistor R 1 , a second resistor R 2 , a third resistor R 3 , a first diode D 1 , a second diode D 2 , a first capacitor C 1  and a second capacitor C 2 . The first terminal of the first resistor R 1  is connected with a voltage source. The first terminal of the second resistor R 2 , the first terminal of the third resistor R 3 , the cathode of the first diode D 1 , the anode of the second diode D 2  and the second terminal of the first resistor R 1  are electrically connected with the phase splitter  60  to receive the second PWM control signal PWM 2  from the phase splitter  60 . The first terminal of the first capacitor C 1  is electrically connected with the second terminal of the second resistor R 2  and the anode of first diode D 1 . The second terminal of the first capacitor C 1  is electrically connected with the ground terminal G. The first terminal of the second capacitor C 2  is electrically connected with the second terminal of the third resistor R 3  and the cathode of the second diode D 2 . The second terminal of the second capacitor C 2  is electrically connected with the ground terminal G. 
     The second delay circuit  620  includes a fourth resistor R 4 , a fifth resistor R 5 , a sixth resistor R 6 , a third diode D 3 , a fourth diode D 4 , a third capacitor C 3  and a fourth capacitor C 4 . The first terminal of the fourth resistor R 4  is electrically connected with the voltage source. The first terminal of the fifth resistor R 5 , the first terminal of the sixth resistor R 6 , the cathode of the third diode D 3 , the anode of the fourth diode D 4  and the second terminal of the fourth resistor R 4  are electrically connected with the phase splitter  60  to receive the third PWM control signal PWM 3  from the phase splitter  60 . The first terminal of the third capacitor C 3  is electrically connected with the second terminal of the fifth resistor R 5  and the anode of the third diode D 3 . The second terminal of the third capacitor C 3  is electrically connected with the ground terminal G. The first terminal of the fourth capacitor C 4  is electrically connected with the second terminal of the sixth resistor R 6  and the cathode of the fourth diode D 4 . The second terminal of the fourth capacitor C 4  is electrically connected with the ground terminal G. 
     As mentioned above, the first delay circuit  610  delays the second PWM control signal PWM 2  for different time intervals to generate the fourth PWM control signal PWM 4  and the fifth PWM control signal PWM 5 . There is a dead time between the PWM signals PWM 4  and PWM 5 . The second delay circuit  620  delays the third PWM control signal PWM 3  for different time intervals to generate the sixth PWM control signal PWM 6  and the seventh PWM control signal PWM 7 . There is a dead time between the PWM signals PWM 6  and PWM 7 . The circuitry structures of the first delay circuit  610  and the second delay circuit  620  are not restricted to the embodiment of  FIG.  3   . That is, the circuitry structures of the first delay circuit  610  and the second delay circuit  620  may be varied and selected as long as the first delay circuit  610  is capable of delaying the second PWM control signal PWM 2  for different time intervals to generate the fourth PWM control signal PWM 4  and the fifth PWM control signal PWM 5  with a dead time therebetween and the second delay circuit  620  is capable of delaying the third PWM control signal PWM 3  for different time intervals to generate the sixth PWM control signal PWM 6  and the seventh PWM control signal PWM 7  with a dead time therebetween. 
     Please refer to  FIGS.  1 ,  2  and  3    again. In some embodiments, the signal processor  6  further includes two first drivers  62  and  63 . The two first drivers  62  and  63  are electrically connected with the logic delay circuit  61 . The first driver  62  receives the fourth PWM control signal PWM 4  from the first delay circuit  610  of the logic delay circuit  61 . The first driver  63  receives the sixth PWM control signal PWM 6  from the second delay circuit  620  of the logic delay circuit  61 . The first driver  62  can amplify the power of the fourth PWM control signal PWM 4  and enhance its driving capability. Consequently, the first PWM driving signal PWM_ 1  is generated. The first driver  63  can amplify the power of the sixth PWM control signal PWM 6  and enhance its driving capability. Consequently, the second PWM driving signal PWM_ 2  is generated. 
     The signal processor  6  further includes two second drivers  64  and  65 . The two second drivers  64  and  65  are electrically connected with the logic delay circuit  61 . The second driver  64  receives the fifth PWM control signal PWM 5  from the first delay circuit  610  of the logic delay circuit  61 . The second driver  65  receives the seventh PWM control signal PWM 7  from the second delay circuit  620  of the logic delay circuit  61 . The second driver  64  can amplify the power of the fifth PWM control signal PWM 5  and enhance its driving capability. In addition, the second driver  64  performs an inverting operation on the fifth PWM control signal PWM 5 , so that the third PWM driving signal PWM_ 3  is generated. The second driver  65  can amplify the power of the seventh PWM control signal PWM 7  and enhance its driving capability. In addition, the second driver  65  performs an inverting operation on the seventh PWM control signal PWM 7 , so that the fourth PWM driving signal PWM_ 4  is generated. 
     As shown in  FIG.  2   , there is a time delay between the first PWM driving signal PWM_ 1  (or the third PWM driving signal PWM_ 3 ) and the second PWM control signal PWM 2 , and there is a time delay between the second PWM driving signal PWM_ 2  (or the fourth PWM driving signal PWM_ 4 ) and the third PWM control signal PWM 3 . Since the time delay is very short with respect to the whole cycle, the time delay is not shown in  FIG.  2   . 
     In an embodiment, as shown in  FIG.  2   , the first PWM driving signal PWM_ 1  and the third PWM driving signal PWM_ 3  are complementary, and the second PWM driving signal PWM_ 2  and the fourth PWM driving signal PWM_ 4  are complementary. In addition, when the first PWM driving signal PWM 1  is not transmitted into the input signal terminal  7 , voltages provided by the first PWM driving signal PWM_ 1 , the second PWM driving signal PWM_ 2 , the third PWM driving signal PWM_ 3  and the fourth PWM driving signal PWM_ 4  are off-state voltages. 
     In an embodiment, the synchronous rectifier circuit  5  is a current doubler circuit or a center-tap circuit. The operating principles of driving and controlling the current doubler circuit and the center-tap circuit according to the driving control method of the third PWM driving signal PWM_ 3  and the fourth PWM driving signal PWM_ 4  are identical. 
     Please refer to  FIG.  1    again. In some embodiments, the power conversion unit  2  further includes a current detection element (e.g., a current detection resistor Rc as shown in  FIG.  1   ). In some other embodiments, the current detection element is a current sensor. The current detection resistor Rc is connected with the bridge arm of the bridge circuit of the main switching circuit  3 . By detecting the current flowing through the bridge arm of the bridge circuit of the main switching circuit  3 , the current detection resistor Rc generates a current detection signal SC corresponding to the current amplitude of the power conversion unit  2 . The current detection signal SC can be further subjected to a signal processing operation (e.g., a filtering operation) by an independent processing circuit (not shown) or a processing circuit (not shown) of the controller  9 . According to the processed current detection signal SC, the controller  9  performs a corresponding control operation on each power conversion circuit  2 . For example, the control operation includes a current sharing control operation or an overcurrent protection control operation. Moreover, the controller  9  can sample the output voltage Vout from the power converter  1 . The duty cycle or the width of the first PWM control signal PWM 1  are adjusted according to the output voltage Vout and the current detection signal SC collaboratively. 
     In some embodiments, the power converter includes N power conversion units, wherein N is equal to or greater than 2. Consequently, the power converter is a multi-phase circuit. 
     Please refer to  FIGS.  4  and  5   .  FIG.  4    is a schematic circuit diagram illustrating the circuitry structure of a power converter according to a second embodiment of the present disclosure.  FIG.  5    is schematic timing waveform diagram illustrating associated control signals of the power converter as shown in  FIG.  4   . As shown in  FIG.  4   , the power converter  1   a  includes two power conversion units  2   a  and  2   b . The concepts of this embodiment can be applied to the power converter with three or more than three power converters. The circuitry structures and the operations of the power conversion units  2   a  and  2   b  in the second embodiment as shown in  FIG.  4    are similar to those of the power conversion unit  2  in the first embodiment as shown in  FIG.  1   . Component parts and elements corresponding to those of the first embodiment are designated by identical numeral references, and detailed descriptions thereof are omitted. 
     As shown in  FIG.  4   , the power conversion units  2   a  and  2   b  are connected with each other in parallel, and there is a phase difference between associated signals of the power conversion units  2   a  and  2   b . In  FIG.  5   , the first PWM control signal, the second PWM control signal, the third PWM control signal, the first PWM driving signal, the second PWM driving signal, the third PWM driving signal and the fourth PWM driving signal related to the power conversion unit  2   a  are respectively indicated as PWM 1   a , PWM 2   a , PWM 3   a , PWM_ 1   a , PWM_ 2   a , PWM_ 3   a  and PWM_ 4   a . The first PWM control signal, the second PWM control signal, the third PWM control signal, the first PWM driving signal, the second PWM driving signal, the third PWM driving signal and the fourth PWM driving signal related to the power conversion unit  2   b  are respectively indicated as PWM 1   b , PWM 2   b , PWM 3   b , PWM_ 1   b , PWM_ 2   b , PWM_ 3   b  and PWM_ 4   b.    
     The input terminals of the power conversion units  2   a  and  2   b  are electrically connected with each other in parallel to receive the input voltage Vin. The output terminals of the power conversion units  2   a  and  2   b  are electrically connected with each other in parallel to output the output voltage Vout. In case that the power converter  1   a  is an N-phase circuit comprising N parallel-connected power conversion units, the controller  9  correspondingly generates N first PWM control signals PWM 1 . The number of the first PWM control signals PWM 1  is the same as the number of the power conversion units  2 . Moreover, the phase difference between every two adjacent ones of the N first PWM control signals PWM 1  is equal to (360/N±θ) degree. For example, in the embodiment of  FIG.  4   , N is equal to 2. Consequently, the controller  9  generates two first PWM control signals PWM 1 , i.e., PWM 1   a  and PWM 1   b . The phase difference between the two first PWM control signals PWM 1   a  and PWM 1   b  are equal to (360/2±θ) degree. 
     As shown in  FIG.  5   , there is a time delay between the first PWM driving signal PWM_ 1   a  (or the third PWM driving signal PWM_ 3   a ) and the second PWM control signal PWM 2   a . Similarly, there is a time delay between the second PWM driving signal PWM_ 2   a  (or the fourth PWM driving signal PWM_ 4   a ) and the third PWM control signal PWM 3   a . Similarly, there is a time delay between the first PWM driving signal PWM_ 1   b  (or the third PWM driving signal PWM_ 3   b ) and the second PWM control signal PWM 2   b . Similarly, there is a time delay between the second PWM driving signal PWM_ 2   b  (or the fourth PWM driving signal PWM_ 4   b ) and the third PWM control signal PWM 3   b . Since the time delay is very short with respect to the whole cycle, the time delay is not shown in  FIG.  5   . 
     In case that the second-type conventional power converter is a multi-phase circuit (e.g., a six-phase circuit), the controller needs to output 4 PWM control signals to control the switches of each phase circuit. That is, the controller needs to generate a total of 24 PWM control signals to control the switches of the power converter. Consequently, the size of the controller is too large, the wiring pattern of the system board is complicated, and the circuitry structure of the controller is complicated. Whereas, in case that the power converter of the present disclosure is a six-phase circuit, the controller needs to generate a total of 6 PWM control signals only. Consequently, the occupied resource of the controller is largely reduced, the wiring pattern of the system board is simplified, and the size of the controller is reduced. 
       FIG.  6    is a schematic circuit diagram illustrating an integrated circuitry structure of plural power converters according to an embodiment of the present disclosure. The present disclosure further provides an integrated circuitry structure of X power converters, wherein X is an integer greater than or equal to 2. For example, X is 2, and each power converter has the circuitry structure of the power converter  1  as shown in  FIG.  1   . That is, as shown in  FIG.  6   , the integrated circuitry structure includes two single-phase power converters  1   a  and  1   b . In case that the integrated circuitry structure includes X power converters  1 , the input terminals of the X power converters  1  are electrically connected with each other in parallel, and the output terminals of the X power converters  1  are electrically connected with each other in parallel. The phase difference between the associated signals of every two adjacent power converters  1  is (180/X±θ) degree. Moreover, the phase difference between every two adjacent ones of the N first PWM control signals PWM 1  is equal to (360/X±θ) degree. 
     From the above descriptions, the present disclosure provides the power converter. Each power conversion unit of the power converter includes the signal processor. The signal processor generates a plurality of PWM driving signals according to the PWM control signal from the controller. Consequently, the main switching circuit and the synchronous rectifier circuit are driven by the plurality of PWM driving signals. Due to the arrangement of the signal processor, the number of the PWM control signals to be outputted from the controller is reduced. In this way, the number of the signal lines on the system board of the power converter is reduced, and the wiring area on the system board is reduced. Moreover, the resources of the controller for outputting PWM control signals are also reduced. Even if the power converter is the multi-phase circuit, it is not necessary to increase the size of the controller and the method of designing the controller is simplified. 
     While the disclosure has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the disclosure needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.