KR20070023596A - Analog internal soft-start and clamp circuit for switching regulator - Google Patents

Abstract

The present invention relates to analog soft-start circuits for switching regulators (eg step-down converters) comprising analog lamp circuits and open-loop analog volt clamp circuits. The voltage ramp circuit uses a capacitor comprising a two-stage current divider circuit that generates a very low and stable current signal and a relatively small integrated capacitor that generates a ramp voltage signal in accordance with the very low current signal. The analog voltage clamp circuit clamps the adjusted output signal to the ramp voltage until the ramp voltage signal increases to a predetermined voltage level, whereby the regulated output voltage exhibits soft-start characteristics. The analog clamp circuit includes a current mirror circuit that generates a clamp current that drops the error amplifier output stage through the clamping element (eg, a diode) until the ramp voltage signal is at a predetermined level.

Analog, clamp, circuit, switching, regulator

Description

Switching regulator {ANALOG INTERNAL SOFT-START AND CLAMP CIRCUIT FOR SWITCHING REGULATOR}

1 is a modified block diagram schematically illustrating a step-down converter for supplying a regulated output voltage to a load circuit in accordance with one embodiment of the present invention;

FIG. 2 is a circuit diagram illustrating an analog soft-start circuit of the step-down circuit of FIG. 1 in accordance with an embodiment of the present invention. FIG.

3 is a block diagram schematically showing a conventional switching regulator.

TECHNICAL FIELD The present invention relates to switching regulators and, in particular, to starting a step-down converter.

Switching-type regulators are typically high-current switches (such as pulse width modulators (PWMs)) and oscillators that operate the switch and change its duty cycle as a function of control voltage input or feedback. MOSFETs, for example. When combined with appropriate external components, such regulators provide a regulated DC voltage output signal. The step-down converter is a switching-type voltage regulator whose output voltage is substantially lower (“step down”) than the applied input voltage. The up-converter, on the other hand, is a switching-type voltage regulator whose regulated output exceeds the input supply voltage, while the positive-to-negative or negative to pogitive (pn) polarity converter is a switching-type voltage regulator whose inverted output is reversed. to be. With regard to the voltage supply, an efficient switching-type regulator can operate at about 90% or more.

3 shows a simplified circuit including a conventional step-down converter 10. The step-down converter 10 includes an error amplifier 50 which receives a reference voltage V _REF at its non-inverting input and a feedback signal V _FB at its inverted signal. The output signal from the error amplifier (50) (V _{EA - OUT),} a second input terminal of the oscillator ramp signal from the oscillator 80 of the is applied to one input terminal of the PWM circuit 70, PWM circuit 70 ( V _{OSC - RAMP} ) is connected to. The duty cycle associated with the voltage level of the _{- (OUT} V _EA) PWM circuit 70 is output of the error amplifier signal (V _{EA - - OUT)} and oscillation light signal by comparing (V _{OSC RAMP)} that moment value error amplifier output signal Generates a square wave signal V _PULSE . The square wave signal V _PULSE is applied to the gate of the power transistor 75 to provide a regulated output voltage applied to the load represented by the inductor L _L , the capacitor C _L , and the resistor R _L. V _OUT ). By feeding back the adjusted portion of the output voltage (V _OUT ) through an appropriate feedback circuit (eg, a divider formed by resistors R ₁ , R ₂ ), the duty cycle of the PWM circuit 70 is adjusted to the required adjustment. It can be maintained at the level to generate the duty cycle required to generate a given voltage.

A problem associated with conventional step-down converters is the voltage overshoot at start-up. Before starting, the load capacitance C _L is completely discharged and the output voltage V _OUT is '0'. At start-up (e.g., when voltage V _DD is applied), the feedback voltage V _FB is initially '0', so that the reference voltage V _REF governs the operation of the error amplifier 50, This allows the output signal V _{EA - OUT} to maximize the duty cycle of the PWM circuit 70 during the action of charging the load capacitor C _L as quickly as possible. The resulting surge may damage the output transistor 75, overshoot the normally required output voltage, overload the input voltage, and / or damage the load circuit. Large input currents are also generated, reaching the warning limits of the input voltage. Thus, some of the forms of "soft-start" are intended to avoid startup surges.

One of the prior arts to solve the startup overshoot problem is to adopt the form of "soft-start", by causing the output to gradually increase the voltage (V _OUT ) to the normal level required at "0" at startup. Avoid starting surges. A common way to achieve this soft-start function is to use an external capacitor that controls the error amplifier output signal to gradually increase the error amplifier output signal at start-up, thereby allowing the duty cycle of the PWM 70 to gradually increase. Significant overshoot is avoided when the output voltage V _OUT is achieved. Since the amplifier current in use is generally too large to support the use of a practical semiconductor (ie integrated) capacitor, an external capacitor is used to create a soft-start function. The size of the external capacitor (capacitance) is chosen to achieve the desired output characteristics (i.e., based on the load circuit impedance and the desired overshoot characteristic), and the amplifier typically in use while the external capacitor is assembled by a dedicated pin method Is connected to.

The problem of implementing the use of external capacitors to produce the desired soft-start characteristics is that the use of external capacitors increases the cost relative to both the component cost and the assembly cost associated with installing the external capacitor. In addition, external capacitors occupy valuable device pins, preventing the use of pins for other input / output signals.

One conventional technique for solving the startup overshoot problem is to use a digital soft-start circuit to control the duty cycle of the regulator during digital startup, thereby providing soft-start capability without large external capacitors. . The problem with digital soft-start circuits is that they require significantly more chip area than analog solutions, so analog soft-start solutions have advantages in simple configuration and cost.

What is needed for an analog soft-start circuit for a switching regulator is to generate a ramp voltage without dedicated device pins and external capacitors. In addition, what is needed for an analog soft-start circuit for a switching regulator is to use an analog voltage clamp circuit that ramps the regulated output voltage to the desired voltage level without significant overshoot.

The present invention utilizes an integrating circuit comprising a current divider circuit that produces a very low current signal and an internal capacitor that is charged by a relatively small, very low current signal to produce a ramp voltage signal, thereby starting without using an external capacitor. The lamp voltage analog soft-start circuit is targeted for an improved switching regulator that generates time ramp voltage. The voltage divider provides a very low current signal in a manner that is not sensitive to the supplied voltage noise, allowing the integrating capacitor to provide the ramp voltage in a manner that is insensitive to the supplied voltage noise. The analog retarding circuit also includes an open-loop analog voltage clamp circuit that clamps the regulated output signal to the ramp voltage until the ramp voltage signal increases to a predetermined voltage level, whereby the desired soft- This will create a SOFT-START and avoid significant overshoot of the regulated output voltage.

According to one embodiment of the present invention, the step-down converter uses an analog soft-start circuit that supplies the regulated output voltage to the load circuit. Like conventional step-down converters, the step-down converters of the present invention utilize power transistors, error amplifier circuits, and output control circuits that produce regulated output voltages. The error amplifier has an inverting input terminal for receiving the feedback portion of the regulated output low voltage and a non-inverting input terminal for receiving a predetermined reference voltage, and a comparator for generating an amplifier control (output) signal in response to these two signals. Include. The error amplifier also includes an output stage that includes an output transistor controlled by the amplifier control signal. For example, the output control circuit includes an oscillation ramp (sawtooth) signal generated by the internal oscillator circuit and a PWM circuit that generates a pulse output signal in response to the amplifier output signal. The pulse output signal is applied to the gate terminal of the power transistor to generate an output voltage adjusted at a level determined by a predetermined reference voltage.

According to one aspect of the present invention, an analog voltage ramp circuit includes a current source that generates a relatively high current, and a two-stage current divider that distributes a relatively high current and a relatively low current to produce stably.

According to another aspect of the present invention, the analog integrator circuit is implemented using a Miller integrator with a relatively small internal (ie assembled CMOS) Miller capacitor that generates a ramp voltage signal in response to a relatively low current. When system power is first applied (or reset) to the step-down converter, current diverges around the Miller capacitor so that the ramp voltage signal and capacitor voltage are maintained at '0' volts. When the soft-start threshold control signal is asserted (i.e. when the system voltage stabilizes and the system 'enable' control signal is asserted), the switch is turned off (opened) and a relatively small current is fed to the analog voltage divider. Pulled through the Miller capacitor, the ramp voltage signal begins to increase at a slow rate determined by the Miller capacitance and relatively low current, thereby facilitating the generation of reliable lamp voltage without the need for external capacitors and / or dedicated device pins. do. The final stage of the ramp occurs when the drain of the switch reaches the system power level.

According to another aspect of the present invention, the analog voltage clamp circuit is an open loop circuit (i.e., no internal feedback) that effectively clamps the amplifier control signal with a ramp voltage signal, whereby the regulated output voltage provides the desired soft-start characteristics. It becomes visible. The analog clamp circuit includes a current mirror circuit that generates a clamp current. The current mirror circuit is connected to the error amplifier output stage via a clamping element (ie a diode or a transistor) and also to an NMOS (switch) transistor whose gate is controlled by a ramp voltage signal. While the ramp voltage signal is low ('0' volts), the switch transistor remains turned off, drawing all clamp current through the clamp element from the error amplifier output stage, thereby pulling down and adjusting the error amplifier output signal. Ensure that the output voltage is minimized. Upon power up (or reset), while the ramp voltage signal increases from '0' volts to a predetermined voltage level, the switch transistor is gradually turned on to supply the increasing portion of the clamp current drawn by the current mirror circuit, in turn The current drawn from the error amplifier output stage through the clamp element gradually decreases, thereby increasing the amplifier control signal in response to the ramp voltage signal and allowing the step-down converter to provide the desired soft-start regulated output voltage. When the ramp voltage signal reaches a preset voltage level, the switch transistor is turned on completely to supply the entire clamp current drawn by the current mirror circuit, which in turn blocks the current flowing through the clamping element from the error amplifier output stage. . Thus, the current error amplifier output stage is effectively isolated from the analog soft-start circuitry and operates to produce a regulated output voltage in a conventional manner.

These and other aspects, features and advantages of the present invention will be better understood with reference to the following description, appended claims and drawings.

The present invention relates to an improved switching regulator, and more particularly to a switching regulator using an analog circuit providing a soft-start function. Although the present invention is described below using a step-down converter utilizing PWM, the skilled person will appreciate that analog soft-start circuits described below may use other types of switching regulators, such as boost, flyback converters or pulse frequency modulators. .

1 is a modified block diagram illustrating a step-down converter 100 for supplying a regulated output voltage V _OUT to a load circuit 190. Like the conventional step-down converter, the step-down converter 100 includes a power transistor 180 that generates a regulated output voltage V _OUT , an error amplifier circuit 150, and an output control circuit 170. The step-down converter operates in the manner described below, including the analog soft-start circuit 110, unlike the conventional step-down converter.

Error amplifier 150 generally includes an input differential stage 155 and an output stage 160. The input differential stage 155 has an inverting input terminal coupled to receive a feedback signal V _FB (in one embodiment, a portion of the regulated output voltage V _OUT ) and a non-inverting coupled to a predetermined reference voltage V _REF . It includes an input terminal. According to known techniques, the input differential stage 155 is regulated output voltage (V _OUT) is a group amplifier control signal is maintained at the set voltage level, _- a negative feedback signal (V _FB) to control (V _{EA CON)} and the reference voltage in response to (V _REF) amplifier control _signal, and generates _(EA V _CON). The output stage 160 includes an output transistor 165 connected between the voltage V _DD and the output control circuit 170. The gate terminal of the output transistor 165 is also connected to the output terminal of the comparator 155, the relatively small current source 167, and the analog soft-start circuit 110.

The output control circuit 170 controls the power transistor 180 in response to the amplifier output signal V _{EA - OUT} so that the adjusted output signal V _OUT is generated at the selected terminal of the power transistor 180. The output control circuit 170 generally includes an oscillator circuit 172 and a PWM circuit 175. The oscillator circuit generates an oscillation ramp (saw) signal (V _{OSC - RAMP} ) that varies in a linear fashion between the low and high voltage levels. PWM circuit 175 includes a first input terminal and the amplifier output signals claim coupled to receive _{- - (RAMP} V _OSC) (V _{EA OUT),} a first input terminal and the oscillation ramp signal coupled to an output transistor (165) to receive It has two input terminals. Using conventional techniques, PWM circuit 175 includes a pulse output signal (V _PULSE) duty cycle of the amplifier output signal of (V _{EA - OUT)} increases increases, and the amplifier output signal in response to the (V _{EA - OUT)} to decrease according to the decrease of the oscillation light signal (V _OSC-rAMP) and the amplifier output _signal in response to the comparison between the (V _{OUT EA)} generates a pulse output signal.

For example, the power transistor 180 has an N− having a first terminal connected to the voltage source V _DD , a second terminal connected to the load circuit 190, and a gate KS connected to the output terminal of the PWM circuit 175. It is a channel MOSFET (NMOS) transistor. According to the existing technology, the power transistor 180 is repeatedly turned on and off by the pulse output signal V _PULSE so that the output voltage V _OUT is maintained at a desired level.

In accordance with the present invention, analog soft-start circuit 110 utilizes current divider circuit 124 and current source 122 to generate a stable low current IAV1 / (mxn), and generates an appropriate ramp voltage signal (V _RAMP ). An analog voltage ramp circuit 120 that generates a ramp voltage without using an external capacitor and dedicated device pin, using an integrator circuit that includes a relatively small embedded capacitor. The soft-start circuit 110 clamps the amplifier control signal V _{EA - CON} to the ramp voltage signal V _RAMP until the ramp voltage signal V _RAMP decreases to a predetermined minimum voltage level. 130 is also included to prevent significant overshoot of the adjusted output voltage V _OUT at start-up.

Referring to the upper right portion of Fig. 1, the soft-start reset control signal SSReset is generated by an internal circuit represented by the NAND gate 115 which is simply formed. In particular, while the voltage source V _DD maintains / maintains below a predetermined voltage level and the ENABLE control signal does not appear (high), the soft-start reset control signal SSReset maintains a high voltage state. On the other hand, when the voltage source (V _DD ) reaches the preset voltage level and the ENABLE control signal appears, the soft-start reset control signal (SSReset) switches to a low voltage state. The soft-start reset control signal SSReset is the maximum associated with the ramp voltage signal V _RAMP at '0' volts when the soft-start reset control signal SSReset switches from high to low, as described below. The integrator circuit 127 is controlled to start increasing with the value.

2 is a circuit diagram illustrating an analog soft-start circuit 110A according to an embodiment of the present invention. In line with the generalized soft-start circuit 110, the analog soft-start circuit 110A includes an analog voltage ramp circuit 120A that includes a current divider circuit 125A and a Miller integrator circuit 127A. Referring to the left side of the 2, the current divider 125A includes a current source 122 that generates a relatively high (first) current I _AV1 , and a first current mirror that generates an intermediate current according to the current I _AV1 . 225-1, and a second current mirror 225-2 that produces a relatively low (second) current I _AV1 / (mxn) in accordance with the intermediate current I _AV1 / m. One current mirror 225-1 includes (first) PMOS transistor M1 and (second) PMOS transistor M2, transistor M1 is a current source 122 between voltage source V _DD and ground. Connected in series to the current source 1 such that the gate terminal of transistor M1 has a relatively high first current I _AV1 passing through transistor M1. Transistor M2 has a first terminal connected to voltage source V _DD and a gate terminal connected to current source 122 such that both transistors M1 and M2 form the same gate voltage. M2 comprises a smaller PMOS transistor, such that the size of the current I _AV1 / m flowing through the transistor M2 is m times smaller than the current I _AV1 flowing through the transistor M1. (In the embodiment m is 10.) The second current mirror 225-2 comprises (third) NMOS transistor M6 and (fourth) NMOS transistor M7, which are intermediate currents I _Is selected to produce a relatively smaller current I _AV1 / mxn according to _AV1 / m .. Transistor M6 comprises a gate terminal connected to a second (lower) terminal of transistor M2 and a first terminal and a ground. And a second terminal connected to the transistor M7 connected to the integrator circuit 127. And the first terminal, the second transistor having a second terminal coupled to the gate terminal, and a ground connected to the second terminal of (M2). Transistor M7 is smaller than transistor M6 by the coefficient of n (in this embodiment n is 10), so that current I _AV1 / (mxn) through transistor M7 has passed through transistor M1. It is mxn (e.g. 100) times smaller than the current IAV1. In both stages (i.e., current mirrors 225-1 and 225-2), the distribution current I _AV1 is substantially lower than the low current generated by another method (e.g., a single stage divider). And avoid the capture of the supplied noise. This highly stable low current signal facilitates the use of small integrated capacitors (ie capacitors fabricated on the same substrate using the same CMOS fabrication techniques as used to form the NMOS and PMOS transistors described herein).

Referring to the center portion of FIG. 2, the integrator circuit 127A is connected to the current divider 125A, and the relatively low current I _AV1 / (mxn) generated by the second current mirror 225-2 is the integrator circuit is operated to pass the (127A), is used to gradually charge the Miller capacitor (C), the error amplifier output signal (V _{EA - OUT)} for supplying a ramp voltage signal (V _rAMP), which is used to clamp The charge on the Miller capacitor will gradually increase. Integrating circuit 127A includes a (fifth) PMOS transistor M3 having a first terminal connected to voltage source V _DD and a gate terminal connected to current source 122. Transistor M3 is substantially the same size as transistor M1 so that substantially the same current I _AV1 passes through transistors M1 and M3. Miller capacitor C1 has a first (positive or "+") terminal connected to the second terminal of transistor M3, and a second ("-") terminal connected to ground. (Sixth) Transistor M12 has a first terminal connected to the second terminal of Miller capacitor C1 and a second terminal connected to ground. (Seventh) Transistor M10 includes a first terminal connected to the first terminal of Miller capacitor C1, a gate terminal connected to the first terminal of transistor M12, and a second terminal connected to ground. (Eighth) Transistor M11 is connected between the first terminal of transistor M10 and the first terminal of transistor M7. Each gate terminal of the transistors M12 and M11 is connected to receive the above-mentioned reset control signal SSReset.

Integrator circuit 127A operates as follows. At start-up, but before the reset control signal SSReset switches from 'high' to 'low', both transistors M11 and M12 are turned on, so that current flows through transistor M3 and branches to ground (ie, Pass through transistor M3 to transistor M11, and pass from transistor M11 to transistor M12 to ground). During this time, voltage source VI _AV1 increases to its normal value, whereby current divider circuit 125A passes through transistor M7 and relatively low current I _AV1 / (mxn) from analog voltage ramp circuit 127. Will be generated. When the reset control signal SSReset is switched from 'high' to 'low', the transistors M11 and M12 are turned off so that the relatively low current I _AV1 / (mxn) passes through the Miller capacitor C1. Miller capacitor C1 starts charging, and at low speed where the ramp voltage signal V _RAMP is determined by the capacitance of Miller capacitor C1 and the relatively low current I _AV1 / (mxn). It starts increasing from 0 'volts. According to one embodiment, the Miller capacitor has a capacitance of 8 pico-Farads (8pF), and the current (I _AV1 / (mxn)) has almost 14 nA (9 nano-Amp), whereby nearly 1.75 mV / μs (1.75). The ramp voltage signal (V _RAMP ) is generated to increase at a slow rate of millivolts / microsecond. This low speed is chosen to provide an output voltage that is tuned to the desired soft-start characteristics.

According to another aspect of the present invention, the analog voltage clamp circuit 160 is an open loop circuit (ie, no internal feedback) for dropping the amplifier control signal V _EA-CON to the ramp voltage signal V _RAMP . The regulated output voltage (V _OUT ) will show the desired soft-start characteristic (ie, gradually increase to the desired output level and avoid significant overshoot).

The analog clamp circuit 160 generates a preset clamp current I _CLAMP applied to the amount (twelfth) transistor M15 controlled by the ramp voltage signal V _RAM P (ninth) transistor M4. By the clamping (twelfth) transistor M16 which is executed as a clamping element when the (tenth) transistor M13 and the eleventh transistor M14 and the ramp voltage signal V _RAMP are below a predetermined voltage level. And a current mirror circuit formed. The transistor M4 has a first terminal connected to the first voltage source V _DD and a gate terminal connected to the current source 122. Transistor M4 is substantially the same size as transistor M1, so that substantially the same current I _AV1 flows through transistor M4. The transistor M13 has a gate terminal and a first terminal connected to the second terminal of the transistor M4, and has a second terminal connected to the ground. Transistor M14 has a gate terminal and a first terminal connected to the second terminal of transistor M4 and has a second terminal connected to ground. According to one aspect of the invention, transistors M13 and M14 are selected to produce a desired clamp current I _CLAMP greater than the error amplifier current I _EA (ie, current source 162 of error amplifier output stage 160). The current component produced by) is less than the clamp current (I _CLAMP ). The NMOS switch transistor M15 has a first terminal connected to the voltage source V _DD , a second terminal connected to the first terminal of the transistor M14, and a gate terminal (ie, a lamp connected to the first terminal of the Miller capacitor C1). Connected to receive a voltage signal (V _RAMP ). The clamping transistor M16 has a first terminal and a gate terminal connected to the error amplifier output stage 160 (especially to the gate terminal of the switch transistor 165A), and a second terminal connected to the first terminal of the transistor M14. Equipped.

During operation, while the ramp voltage signal V _RAMP is low ('0' volts), the switch transistor M15 remains turned off, so that all current flows through the clamping transistor M16 to the error amplifier output stage 160. so that the clamping current (I _cLAMP), and drawn from, an amplifier control signal whereby _- strengthen _(EA V _CON) and, thereby minimizing the regulated output voltage (V _OUT). On power up (or reset), while the ramp voltage signal V _RAMP increases to a predetermined voltage level at '0' volts, the switch transistor M15 gradually increases to supply an increase in the clamp current I _CLAMP portion. The portion of current that is turned on and subsequently pulled from the error amplifier output stage 160 through the clamp transistor M16 gradually decreases. The portion of the current drawn through the clamp transistor M16 decreases in response to the ramp voltage signal, and the amplifier control signals V _{EA - CON} gradually increase, such that the error amplifier output signal VEA-OUT is'0'V. By swinging at full power at, the desired soft-start characteristics are provided. When the ramp voltage signal V _RAMP reaches a preset voltage level, the switch transistor M15 is turned on completely so that the clamp current I _CLAMP is pulled entirely through the switch transistor M15, and the clamping transistor m16 is turned on. It is turned off, effectively blocking the error amplifier output stage 160. While the ramp voltage signal V _RAMP maintains a predetermined voltage level, the current error amplifier output stage 160 is conventionally in accordance with the error amplifier control signals V _{EA - CON} , and the error amplifier output voltage V _{EA - OUT.} Works to create

While the present invention has been described with respect to certain embodiments, it will be apparent to those skilled in the art that the nature of the invention may be applicable to other embodiments as well as all of the aspects of the invention.

The switching regulator according to the present invention enables the analog soft-start circuit to use an analog voltage clamp circuit that generates a ramp voltage without dedicated device pins and external capacitors and ramps the output voltage adjusted to the desired voltage level without significant overshoot. The configuration is simple and has a cost advantage.

Claims (17)

In a switching regulator for supplying a regulated output voltage to a load circuit, An error amplifier circuit having a comparator for generating an amplifier control signal in accordance with a predetermined reference voltage and a portion of the regulated output voltage, and an output stage for generating an amplifier output signal in accordance with the control signal; And A current source for generating a relatively high first current, a current divider for generating a relatively low second current in accordance with the first current, an integrated circuit for generating a lamp voltage signal in accordance with the second current, and the lamp voltage signal And an analog voltage ramp circuit having an analog voltage clamp circuit for clamping the amplifier control signal with the ramp voltage signal until increasing to a final voltage level. The method of claim 1, And an output control circuit for controlling the power transistor in accordance with the amplifier output signal such that the regulated output signal is produced at a terminal of the power transistor. The method of claim 2, The output control circuit includes an oscillator circuit for generating an oscillation ramp signal, and a pulse width modulator for generating a pulse signal in accordance with the oscillation ramp signal and the amplifier output signal, the pulse signal being at a gate terminal of the power transistor. Switching regulator, characterized in that applied. The method of claim 1, The current divider is: A current source for producing said relatively high first current; A first current mirror for generating an intermediate current in accordance with said relatively high current; And A second current mirror that generates a relatively low second current in accordance with the intermediate current, And said relatively low second current is substantially lower than said intermediate current and said intermediate current is substantially lower than said first current. The method of claim 4, wherein And the integrated circuit is coupled to the current divider such that the relatively low second current flows between the integrated circuit and the second current mirror. The method of claim 5, wherein The integrated circuit, A switching regulator comprising a Miller capacitor and means for causing said relatively low second current to gradually charge said Miller capacitor, such that gradually increasing charge with respect to said Miller capacitor supplies said ramp voltage signal . The method of claim 6, The clamp circuit, Means for drawing a relatively high current through the output stage of the error amplifier circuit until the ramp voltage signal increases to the final voltage level. The method of claim 4, wherein The first current mirror is: A first transistor connected in series with said current source between a first voltage source and a second voltage source, and A second transistor having a first terminal connected to the first voltage source and a gate terminal connected to the current source, A gate terminal of the first transistor is connected to the current source such that the relatively high first current flows through the first transistor;  The size of the second transistor is selected such that the intermediate current is lower than the first current; The second current mirror is: A third transistor having a gate terminal and a first terminal connected to a second terminal of the second transistor, and a second terminal connected to the second voltage source; And And a fourth transistor having a first terminal connected to the integrated circuit, a gate terminal connected to a second terminal of the second transistor, and a second terminal connected to the second voltage source. The method of claim 8, The integrated circuit is: A fifth transistor having a first terminal connected to the first voltage source and a gate terminal connected to the current source,  A capacitor having a first terminal and a second transistor connected to the second terminal of the fifth transistor; A sixth transistor having a first terminal connected to the second terminal of the capacitor, and a second terminal connected to the second voltage source; A seventh transistor having a first terminal connected to the first terminal of the capacitor, a gate terminal connected to the first terminal of the sixth transistor, and a second terminal connected to the second voltage source; And An eighth transistor coupled between the first terminal of the seventh transistor and the first terminal of the fourth transistor; The size of the fifth transistor is substantially the same as the size of the first transistor such that the relatively high first current flows through the fifth transistor; And the gate terminals of the sixth and eighth transistors are respectively connected to receive a reset control signal. The method of claim 9, Wherein said capacitor comprises a Miller capacitor. The method of claim 10, The analog voltage clamp circuit is: A ninth transistor having a first terminal connected to the first voltage source and a gate terminal connected to the current source, A tenth transistor having a gate terminal and a first terminal connected to the second terminal of the ninth transistor, and a second terminal connected to the second voltage source; An eleventh transistor having a first terminal, a gate terminal connected to the second terminal of the ninth transistor, and a second terminal connected to the second voltage source; A twelfth transistor having a first terminal connected to the first voltage source, a second terminal connected to the first terminal of the eleventh transistor, and a gate terminal connected to the first terminal of the capacitor; And A thirteenth transistor having a first terminal and a gate terminal connected to the output stage of the error amplifier, and a second terminal connected to the first terminal of the eleventh transistor;  The size of the ninth transistor is substantially equal to the size of the first transistor such that the first current flows through the ninth transistor. The method of claim 11, The output stage of the error amplifier is: Amplifier current source; And An output transistor having a current source of the amplifier and a gate terminal connected to the gate and a first terminal of the thirteenth transistor, And the amplifier current generated by the amplifier current source is lower than the relatively high first current flowing through the ninth transistor. In a switching regulator for supplying a regulated output voltage to a load circuit, Amplifier means for generating an amplifier control signal in accordance with the adjusted output voltage and a predetermined reference voltage; And An analog soft-start circuit comprising an analog voltage ramp circuit for generating a ramp voltage signal and an analog voltage clamping circuit for clamping the amplifier control signal with the ramp voltage signal until the ramp voltage signal rises to a predetermined voltage level. Including, The analog clamp circuit is: A current mirror for generating a predetermined clamp voltage; A clamp element connected between the amplifier means and the current mirror such that all or a portion of the clamp voltage is drawn through the clamp circuit while the ramp voltage signal is below the predetermined voltage level; And a switch connected between the voltage source and the current mirror, And the switch is controlled by the ramp voltage signal such that substantially all clamp voltages are drawn through the switch when the ramp voltage signal is equal to the preset voltage level. The method of claim 13, The current mirror is: A ninth transistor having a first terminal connected to the voltage source and a gate terminal connected to the current source; A tenth transistor having a gate terminal and a first terminal connected to a second terminal of the ninth transistor, and a second terminal connected to a second voltage source; And An eleventh transistor having a first terminal, a gate terminal connected to the second terminal of the ninth transistor, and a second terminal connected to the second voltage source, And said first terminal of said eleventh transistor is connected to said clamping element and said switch. The method of claim 14, The clamping element, And an NMOS transistor having a first terminal and a gate terminal connected to the amplifier means, and a second terminal connected to the first terminal of the eleventh transistor. The method of claim 15, The switch, And an NMOS transistor having a first terminal connected to the voltage source, a gate terminal connected to the analog voltage clamp circuit, and a second terminal connected to the first terminal of the eleventh transistor. In a switching regulator that supplies a regulated output voltage having a relatively high current to a load circuit, Means for generating an amplifier control signal in accordance with the regulated output voltage and a predetermined reference voltage; Means for generating a relatively low current; And Means for generating a ramp voltage signal in accordance with said relatively low current; And And means for clamping the amplifier control signal with the ramp voltage signal until the ramp voltage signal increases to a predetermined voltage level.

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