Abstract:
A primary side controlled power converter having a voltage sensing means coupled to a transformer of the power converter and configured to provide a voltage feedback waveform representative of an output of the transformer is provided. A primary switching circuit operates to control energy storage of a primary side of the transformer. The primary switching circuit is operable during an on time and inoperable during an off time. The on and off time is switched at a system frequency. A feedback amplifier generates an error signal indicative of a difference between the voltage feedback waveform and a reference voltage. A sample and hold circuit samples the error signal at a periodic frequency during the off time. An error signal amplifier is configured to provide the sampled value to the primary switching circuit wherein the primary switching circuit controls the transformer and thereby regulates an output of the power converter.

Description:
CROSS REFERENCE TO RELATED APPLICATION 
       [0001]    This application is based on and hereby claims priority under 35 U.S.C. 119 from U.S. provisional application No. 60/748,132, filed on Dec. 7, 2005, the subject matter of which is incorporated herein by reference. 
         [0002]    This application is a continuation of, and claims priority under 35 U.S.C. §120 from, nonprovisional U.S. patent application Ser. No. 11/635,309, entitled “System and Method for a Primary Feedback Switched Mode Power Supply,” filed on Dec. 7, 2006, the subject matter of which is incorporated herein by reference. 
     
    
       [0003]    TECHNICAL FIELD 
         [0004]    This invention relates generally to the field of power conversion and, more particularly, to switching mode power supply with regulated output voltage. 
       BACKGROUND INFORMATION 
       [0005]    With the aggressive growth of cell phones and personal computers, the demand for lower cost, lighter weight and better efficiency battery chargers and small power standby supplies for personal computers is very high. Even though the linear power supply is low in cost, it becomes very difficult to compete with switching mode power supplies because of its heavy weight and low efficiency. The Flyback power converter is generally chosen among different switching mode topologies to meet this demand due to its simplicity and good efficiency. Over the years, various control ICs had been developed and used to build a Flyback power supply.  FIG. 1  shows a typical prior art primary side controlled Flyback power converter. It consists of a transformer  201  which has three windings, primary switch  105 , secondary-side rectifier  302 , output capacitor  303  and a control IC  104 . Resistor  101  and capacitor  102  provides the initial start-up energy for IC  104 . Once the Flyback converter is stable, IC  104  will be powered by the auxiliary winding (with N A  turns) of transformer  201  via rectifier  103 . The output voltage is fed back to the primary side via the auxiliary winding, rectified and filtered by rectifier  107  and capacitor  110 , and sensed by the voltage divider resistor  108  and  109 . Resistor  106  senses the current flowing through the primary, switch  105 . IC  104  is a peak current mode PWM controller. Secondary resistor  301  represents the copper loss of transformer  201 . 
         [0006]    The circuit of  FIG. 1  works well as long as the requirement of output voltage regulation is not stringent. Typically, a 10% load regulation with the loading from 10% to 100% of its rated maximum load can be met. However, the regulation becomes very poor when loading drops below 10% of its rated load. There are two factors causing the poor regulation: 1) the transformer copper loss varies with output current and input voltage; and 2) the auxiliary winding of transformer  201  contains an undesired resonant waveform when the Flyback converter operates in a discontinuous current mode (DCM). To achieve a tighter regulation requirement, others have used the prior art secondary side controlled Flyback converter shown in  FIG. 2 . This configuration generally meets a 5% load regulation over 0% to 100% of its rated load. In this circuit, the output voltage is sensed and an error signal is then fed back to the primary IC via the optical coupler. The main disadvantage of this circuit is higher cost. The additional components and a safety approved optical coupler add significant cost to the overall design. This additional material cost can be up to 10% more than the primary side converter shown in  FIG. 1 . 
         [0007]      FIG. 2  shows a typical prior art secondary side controlled Flyback converter. In this circuit, the output voltage is sensed by the voltage divider resistor  305  and  307 , and monitored by the secondary IC  306 . The error signal is then fed back to the primary IC  104  via the optical coupler  202 . The main disadvantage of this circuit is high cost. The IC  306  and the safety approved optical coupler  202  significantly increases the cost of type of converter. This cost increase can be as much as 10% of the overall material cost as compared to a primary side converter of  FIG. 1 . 
         [0008]    In view of the foregoing, there is a need for a low-cost and effective control methodology that can regulate the output voltage of a Flyback converter from the primary side with good accuracy from 0% to 100% of its rated load. 
       SUMMARY 
       [0009]    To achieve the forgoing and other objects and in accordance with the purpose of the invention, a variety of techniques for primary side controlled power converter are described. 
         [0010]    In one embodiment of the invention, a primary side controlled power converter has a voltage sensing means coupled to a transformer of the power converter and configured to provide a voltage feedback waveform representative of an output of the transformer. A primary switching circuit operable to control energy storage of a primary side of the transformer is provided. The primary switching circuit has a loop stability compensation node signal input, and the primary switching circuit is operable during an on time and inoperable during, an off time, the on time and the off time being switched at a system frequency. A feedback sample and hold circuit operable to amplify the feedback error signal and sample this error signal at a periodic frequency during the off time is described. The sample and hold circuit has a sampled value output. A timing means for generating a hold signal thereby stopping the sampling prior to a threshold detection event is provided. An error signal amplifier configured to integrate by way of the loop stability compensation node and to provide the sampled value to the primary switching circuit wherein the primary switching circuit controls the transformer and thereby regulates an output of the power converter is described. Further embodiments include a current sensing means for sensing a current in the primary side and configured to input to the primary switching circuit a value for regulation of the output current of the power converter. Also, a threshold circuit means for comparing the feedback signal to a threshold voltage, the threshold circuit means operable to activate the hold signal when the feedback signal is below the threshold voltage is described. The power converter also is provided in this embodiment as having an output current limit programming circuit being configured to enable the switch current limit level to be externally programmable with a resistor. Other embodiments also include a frequency jittering means for jittering the system frequency to reduce electromagnetic interference emissions. An embodiment also is shown as having a frequency adjusting means for adjusting the system frequency in response to the error signal. An embodiment also contains an under-voltage lock-out (UVLO), for enabling the power converter when the power supply to the power converter is within a predetermined range. Another embodiment describes the sample and hold circuit having a plurality of capacitors, a plurality of control switches and a plurality of selection switches wherein a one of the capacitors may be selected for the sampled value. A further embodiment shows the primary switching circuit further having a driver configured to modulate rise and fall times of the switching for reducing electromagnetic interference emissions. 
         [0011]    In another embodiment, primary side controlled power converter is described having a voltage sensing means for sensing a transformer output voltage, a primary switching means for controlling energy in a primary winding of the transformer, a feedback means for generating an error signal, and a control means for controlling the error signal to the primary switching means wherein the primary switching means controls the transformer and thereby regulates an output of the power converter. A further embodiment includes a frequency adjusting means for adjusting the system frequency in response to the feedback signal. Another embodiment has a driver means for modulating rise and fall times of the primary switching means for reducing electromagnetic interference emissions. 
         [0012]    In yet another embodiment, an integrated circuit device for a primary side controlled power converter is provided. The device has a primary switching circuit operable to control an energy storage of a primary side of a transformer, the primary switching circuit comprising a error signal input, and the primary switching circuit being operable during an on time and inoperable during an off time, the on time and the off time being switched at a system frequency. A feedback amplifier configured to generate an error signal indicative of a difference between the voltage feedback waveform and a reference voltage is provided. A sample and hold circuit operable to sample the error signal at a periodic frequency during the off time is described. The sample and hold circuit has a sampled value output. A timing means for generating a hold signal thereby stopping the sampling prior to the on time is provided. An error signal amplifier configured to provide the sampled value to the primary switching circuit wherein the primary switching circuit controls the transformer and thereby regulates an output of the power converter is described. 
         [0013]    In a further embodiment a method for regulating the output voltage and output current of a power supply from a primary side of a transformer is described. The method comprises sensing a feedback voltage from an auxiliary winding of the transformer, sampling the feedback voltage or feedback error voltage at a determined time, sensing a current of a primary of the transformer, regulating an output voltage of the power supply by maintaining the voltage waveform of the auxiliary winding of the transformer using the sampled feedback voltage, and regulating an output current of the power supply by controlling a fixed peak current through the primary of the transformer with a variable switching frequency. Another embodiment includes the sampling operating a plurality of sequentially connected sampling and holding capacitors and selecting the voltage of a determined one of the capacitors when the feedback voltage of the auxiliary winding of the transformer drops below a threshold voltage. A further embodiment includes the variable switching frequency being controlled proportionally to the sensed feedback voltage of the auxiliary winding of the transformer. 
         [0014]    In still another embodiment a sample and hold circuit for a power converter IC device is provided. The IC device has a feedback amplifier; for generating an error voltage. N number of capacitors for sampling and holding the error voltage signal are shown connected to N controlled sampling switches for sampling and holding the error voltage signal to one of the N capacitors. N controlled selecting switches are shown for selecting the error voltage signal from one of the N capacitors. A counter for dividing the frequency of the clock signal and generating a binary bit map is described. A decoder is described for producing control signals for the N controlled sampling switches and N controlled selecting wherein the error signal is sampled N times within a period of time and one of the sampled times may be selected for output of the sample and hold circuit. 
         [0015]    Another embodiment shows driver for driving a gate of a MOSFET device used in a power converter. The driver has switches for charging and discharging the gate terminal of the MOSFET device. The default charging path comprises a first resistor connected between the gate terminal and the charging switch. The default discharging path comprises a second resistor connected between the gate terminal and discharging switch. A first plurality of switched resistors are connected at one end to the gate terminal, and a first plurality of switches are operable to connect the other end of the first plurality of resistors to the charging switch. A second plurality of resistors are connected at one end to the gate terminal, and a second plurality of switches are operable to connect the other end of the second plurality of resistors to the discharging switch. A controller controls the first and second plurality of switches in a mariner such that the charging and discharging times of the gate-source of the MOSFET are varied and cycled over time. 
         [0016]    In an additional embodiment, a primary side controlled power converter with internal integrated circuit power switch is coupled to the emitter of a high voltage NPN bipolar transistor, whether internal or external to the IC, in order to achieve high voltage emitter-switching operation. 
         [0017]    Other features, advantages and object of the present invention will become more apparent and be more readily understood from the following detailed description, which should be read in conjunction with the accompanying drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0018]    The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements and in which: 
           [0019]      FIG. 1  shows a simple prior art primary side controlled constant output voltage Flyback converter: 
           [0020]      FIG. 2  shows a typical prior art secondary side controlled Flyback converter; 
           [0021]      FIG. 3  illustrates an exemplary primary side controlled constant output voltage Flyback converter, in accordance with an embodiment of the present invention; 
           [0022]      FIG. 4  is an exemplary top level block diagram of an IC, in accordance with an embodiment of the present invention; 
           [0023]      FIG. 5  shows exemplary idealized waveforms of the auxiliary winding voltage, primary switch current and secondary rectifier current of a Flyback converter operating in a continuous current mode (CCM); 
           [0024]      FIG. 6  shows exemplary idealized waveforms of the auxiliary winding voltage, primary switch current and secondary rectifier current of a Flyback converter operating in a discontinuous current mode (DCM); 
           [0025]      FIG. 7  illustrates an exemplary sampling method for feedback signal, in accordance with an embodiment of the present invention; 
           [0026]      FIG. 8  illustrates an exemplary feedback sampling and hold block, in accordance with an embodiment of the present invention; 
           [0027]      FIG. 9  illustrates an exemplary EMI reduction scheme by modulating the gate driver strength, in accordance with an embodiment of the present invention; and 
           [0028]      FIG. 10  shows an exemplary primary side controlled constant output voltage Flyback converter using an IC operated in accordance with an embodiment of the present invention. 
       
    
    
       [0029]    Unless otherwise indicated illustrations in the figures are not necessarily drawn to scale. 
       DETAILED DESCRIPTION 
       [0030]    The present invention is best understood by reference to the detailed figures and description set forth herein. 
         [0031]    Embodiments of the invention are discussed below with reference to the Figures. However, those skilled in the art will readily appreciate that the detailed description given herein with respect to these figures is for explanatory purposes as the invention extends beyond these limited embodiments. For example, it should be appreciated that those skilled in the art will, in light of the teachings of the present invention, recognized a multiplicity of alternate and suitable approaches, depending upon the needs of the particular application, to implement the functionality of any given detail described herein, beyond the particular implementation choices in the following embodiments described and shown. That is, there are numerous modifications and variations of the invention that are too numerous to be listed but that all fit within the scope of the invention. Also, singular words should be read as plural and vice versa and masculine as feminine and vice versa, where appropriate, and alternatives embodiments do not necessarily imply that the two are mutually exclusive. 
         [0032]    The present invention will now be described in detail with reference to embodiments thereof as illustrated in the accompanying drawings. 
         [0033]    It is to be understood that any components, exact component values, or circuit configurations indicated herein are solely provided as examples of suitable configurations and are not intended to be limiting in any way. Depending on the needs of the particular application, those skilled in the art will readily recognize, in light of the following teachings, a multiplicity of suitable alternative implementation details. 
         [0034]    One aspect of this invention is to present a low-cost, effective control methodology that can regulate the output voltage of a Flyback converter from the primary side with good accuracy for output load current ranging from 0% to 100% of its rated load. By achieving this goal, the secondary side control circuit and the optical coupler can be eliminated. This can dramatically save the cost and improve the reliability of a Flyback converter because of lower component count. Based on this methodology, two IC devices will be described in detail below. 
         [0035]    As mentioned earlier, the two factors affecting the voltage regulation of a primary side controlled Flyback converter are that the transformer copper loss varies with output current and input voltage and the voltage sensing is not accurate. To overcome the first problem, in one embodiment, a current source derived from the current of the primary switch is used to compensate the variations. In another embodiment, an adaptive sampling and hold circuit is used to capture the feedback voltage when the current of the secondary winding of the transformer discharges to zero. It is contemplated that alternative embodiments may properly combine both methods together. Two IC devices will be described below. Both IC embodiments are capable of self-starting from the input line through a large value charging resistor and an energy storage capacitor. Once the Flyback converter is stable, the auxiliary winding provides power to the ICs. The first IC is configured for an internal power MOSFET as the main switch and a current sense MOSFET. Therefore, no external MOSFET or current sense resistor is needed for low power application. The IC can also be used to drive a bipolar transistor in emitter-drive configuration, or another high voltage MOSFET in source-drive configuration to boost high voltage operating range or output power. To further increase output power handling, the second IC is configured such that its output stage circuit is capable of driving an external power MOSFET and sense switch current. 
         [0036]      FIG. 3  illustrates an exemplary primary side controlled constant output voltage Flyback converter, in accordance with an embodiment of the present invention. The converter has a transformer  219 . The transformer has three windings, a primary with N p  turns, secondary with N s  turns and auxiliary with N a  turns. A secondary-side rectifier  220  with output capacitor  221  provides regulated power output. A peak current mode PWM control IC  217  controls the power to the primary winding of the transformer via transistor  218 . By driving the bipolar transistor in emitter-drive configuration, the operating voltage of the Flyback converter is increased due to normally higher collector-base breakdown voltage than collector-emitter breakdown voltage. Resistor  207  and capacitor  208  provide the initial start-up energy for IC  217 . After the Flyback converter is stable, IC  217  is powered by the auxiliary winding of transformer  219  via rectifier  213  and capacitor  208 . The output voltage is fed back to the primary side via the auxiliary winding and the voltage divider resistors  209  and  210 . Resistors  209  and  210  may be placed inside the IC in other embodiments. The Comp and Iset pins of IC  217 , and components  211 ,  212 , and  216 , are for this exemplary embodiment and may be removed or placed inside the IC in other embodiments. 
         [0037]      FIG. 4  illustrates an exemplary top level block diagram of IC chip  217 , in accordance with an embodiment of the present invention. IC  217  contains an internal power MOSFET  420  as the main switch, a current sense MOSFET  419  and a current sense resistor  421  as shown in  FIG. 4 . 
         [0038]    Voltage regulator  401  generates internal power supply and reference voltages as well as provides voltage clamp function on Vdd. The feedback voltage is amplified against a reference voltage and then sampled and held by  403 . Error Amplifier  408  compares the output of  403  and a bias voltage (V BIAS ). The preferred embodiment has an external compensation network on the Comp pin. Comparator  413  serves as a peak current mode PWM comparator with a slope compensation input from oscillator  406 . Oscillator  406  is a system oscillator that may have frequency jittering function in some embodiments. The jittering function spreads out the frequency spectrum clock. This allows for a lower conducted electromagnetic interference (EMI) emission. The Frequency Adjuster  407  stores the FB voltage immediately after the switch turn-off plus a blanking time, and modifies the oscillator  406 &#39;s frequency proportionally to this stored FB voltage as FB goes below regulation voltage. In this manner, the power transferred across the transformer is controlled to be proportional to the output voltage, resulting in constant output current mode as the output voltage drops below regulation. In addition, the Frequency Adjuster  407  detects when the Error Amplifier  408  output is indicative of very light load, and reduces switching frequency to conserve power. The latch  412 , together with its control signals, generates the PWM waveform. High speed MOSFET gate driver  416 , in some embodiments, incorporates EMI reduction by gate drive strength modulation technique shown in  FIG. 9 , described next. The power MOSFET  420  serves as the main output switch. MOSFET  419  and resistor  421  form a current sense circuit. Timing generator  404  generates high frequency clock and sampling control signals, senses the negative going-edge of FB waveform and produces TR triggering signal for the sample-and-hold circuit  403 . The load regulation compensation block  422 , in some embodiments, sinks a current from FB based on a scaling of the primary current sense signal to compensate for output load regulation or output series resistance. The ILIM Threshold block  405  enables for external programming of the switch current limit comparator  414  threshold, while minimum pulse current comparator  415  ensures a minimum pulse current for stable voltage sensing. 
         [0039]      FIG. 5  shows exemplary idealized waveforms of the auxiliary winding voltage, primary switch current and secondary rectifier current of a Flyback converter operating in a continuous current mode (CCM). The main switch turns on at t 1 , turns off at t 2  and turns on again at t 3 . The switching period is T, the turn-on time is T on  and the turn-off time is T r . The voltage at the auxiliary winding (V A ) at the time just before t 3  can be expressed as, 
         [0000]        V   A =( N   A   /N   S )·( V   O   +V   D1   +I   S   ·R   S )   (1) 
         [0000]    where N A  is the number of turns of the transformer auxiliary winding, N S  is the number of turns of the transformer secondary winding, V O  is the output voltage, V D1  is the secondary-side rectifier diode voltage drop, I s  is the secondary current at t 3 , and R S  is the transformer secondary side copper and parasitic resistance. 
         [0040]    The shunt current sink in load regulation compensation block  422  inside the IC shown in  FIG. 4  is designed for the following relationship: 
         [0000]        I   422   β·I   P    (2) 
         [0041]    Where I P  is the primary winding current, and β is a design constant. 
         [0042]    Since 
         [0000]        I   P =( N   S   /N   P )· I   S    (3) 
         [0043]    Where I S  is the secondary winding current, and N P  is the transformer primary winding turns. 
         [0044]    The output voltage sense V FBSENSE  can be expressed by, 
         [0000]        V   FBSENSE =( R   2 /( R   1   +R   2 ))·( N   A   /N   S )−( V   O   +V   D1   +I   S   ·R   S )−(( R   1   ·R   2 )/( R   1   +R   2 ))·β· I   S ·( N   S   /N   P )   (4) 
         [0045]    Where R 1  is the resistor connected between the transformer auxiliary winding node and FB, and R 2  is the resistor connected between FB and ground. If R 1  is chosen as 
         [0000]        R   1 =( N   P   ·N   A   ·R   S )/(β ·N   S   ·N   S )   (5) 
         [0046]    Then, 
         [0000]        V   FBSENSE ( R   2 /( R   1   +R   2 ))·( N   A   /N   S )·( V   O   +V   D1 )   (6) 
         [0047]    Therefore, if the shunt current sink of  422  inside the IC shown in  FIG. 4  is designed according to equation (2) and the value of R 1  is chosen by equation (5), then output voltage sense V FBSENSE  is independent of the copper loss (I S ·R S ) of the transformer  201 . In the CCM, the value of V FBSENSE  is sampled and held at the time just before t 3 . 
         [0048]    In addition, if the value of R 1  is chosen higher than the previously calculated value, the output voltage can achieve negative load regulation. This is often useful in certain application to compensate for any additional line resistance such as due to long cord length of charger adaptors. 
         [0049]      FIG. 6  shows exemplary idealized waveforms of the auxiliary winding voltage, primary switch current and secondary rectifier current of a Flyback converter operating in a discontinuous current mode (DCM). The main switch turns on at t 1 , turns off at t 2  and turns on again at t 4 . The switching period is T, the turn-on time is T on  and the turn-off time is equal to (t 4 −t 2 ). T r  is equal to (t 3 −t 2 ). As shown in  FIG. 6 , the current at the secondary winding I S  of transformer  201  discharges to zero at t 3 . The voltage at the auxiliary winding V a  at the time between t 3  and t 4  oscillates at a frequency determined by the parasitic inductance and capacitance in the circuit. In this case the V FBSENSE  must be sampled and held at a time just before t 3  in order to obtain an accurate feedback voltage. 
         [0050]      FIG. 7  illustrates an exemplary sampling method for the feedback signal, in accordance with an embodiment of the present invention. In particular, the figure shows an embodiment for sampling of feedback voltage V FB  and sensing of t 3  in a DCM. After the power switch turns off in a switching cycle, a high frequency oscillator clock from a timing generator is enabled to repeatedly sample the feedback voltage value at each fine time step determined by this clock. At the same time, the feedback voltage is also compared to a threshold voltage V THRESHOLD . When it is detected that the feedback voltage is lower than V THRESHOLD , the signal TR goes high to stop the sampling and present a previously sampled value as the sampled feedback voltage for that switching period. Because the TR event happens asynchronously from the timing generator clock, accuracy is improved as the timing generator clock frequency increases. 
         [0051]    Two or more samples can also be used to compensate for the asynchronous TR, by weighing those samples based on the timing of TR relative to the clock edges and period. Using adjustments of the weights of the samples, the feedback signal can be sampled at time just prior to the TR event. 
         [0052]      FIG. 8  illustrates an exemplary feedback sampling block, in accordance with an embodiment of the present invention. The accuracy of the power converter in the present embodiment is further enhanced. Feedback Amplifier  501  amplifies the error difference between feedback signal FB and a reference voltage to generate an instantaneous amplified error signal FBAMP. This FBAMP signal is then sampled repeatedly at high clock frequency from a Timing Generator Clock (not shown). The high frequency clock goes to Counter  504  and Decoder  505  to generate signals Q[N: 0 ] and CQ[N: 0 ] to selectively turn on and off the different switches connected to an array of Sampling Capacitors  506 . When TR signal is detected as shown in  FIG. 7 , the Counter  504  and Decoder  505  stop cycling and the FBS output contains the amplified error signal between V FBSENSE  and V REF  values. In various embodiments, the FBS output can take any of previously stored sample prior to TR event. Because FBS is an error signal, it can be used directly as an input of the Error Amplifier  408  in  FIG. 4 . In other embodiments, the feedback signal can be sampled directly before it is amplified or compared against the reference voltage. 
         [0053]      FIG. 9  illustrates an exemplary EMI reduction scheme by modulating the strength of a gate driver  416 , in accordance with an embodiment of the present invention This reduction is achieved by modulating the gate drive strength at a modulation frequency. The buffer  601  receives the PWM latch  412  output signal and amplifies its driving strength to drive the gate charging switch  612  and discharging switch  602 . A dV/dt jitter control block  630  takes the clock frequency and generates digital control signals to cycle the strength of the driver over time. Strength modulation switches  610  and  605  vary the impedance between the gate of Power MOSFET  420  and the Power Supply and Ground rails, thereby modulating the rise and fall time of the pulses on the gate of Power MOSFET  420 . This results in spreading of high frequency electromagnetic interference due to the fast rise and fall time of SW, and resulting in reduced EMI signature. 
         [0054]      FIG. 10  shows an exemplary primary side controlled constant output voltage Flyback converter using an IC operated in accordance with an embodiment of the present invention. To better understand the motivation to  FIG. 10 , it is helpful to note that the embodiment described in  FIG. 3  uses an external high voltage NPN Bipolar Transistor  218  in an Emitter Switching configuration. By way of further context, the IC shown in  FIG. 4  can alternately be used to directly to drive the primary winding of a transformer, depending on the power requirements. To further increase the power handling capability and switching frequency, an external MOSFET may be used as the main switch.  FIG. 10  shows the application of a further embodiment of an IC. This embodiment removes the internal power MOSFET, the current sensing MOSFET and the current sensing resistor from the IC. The current driving capability of Gate Driver is further improved in order to control the larger external MOSFET.  FIG. 10  shows the application circuit of this IC with an external MOSFET and a current sense resistor. In this embodiment, the compensation network (Comp pin) and current programming function (Iset pin) are moved inside the IC. 
         [0055]    Those skilled in the art will readily recognize, in accordance with the teachings of the present invention, that any of the foregoing components and/or system modules may be suitably replaced, reordered, removed and additional components and/or system modules may be inserted depending upon the needs of the particular application, and that the systems of the foregoing embodiments may be implemented using any of a wide variety of suitable components and system modules, and is not limited to any particular implementation details that those in the art will readily recognize suitable alternatives for in light of the teachings of the present invention. 
         [0056]    Having fully described at least one embodiment of the present invention, other equivalent or alternative synchronous switches for switching regulators according to the present invention will be apparent to those skilled in the art. The invention has been described above by way of illustration, and the specific embodiments disclosed are not intended to limit the invention to the particular forms disclosed. The invention is thus to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the following claims.