CN112260530A - Power supply soft start control circuit, control chip and control device - Google Patents

Abstract

The invention provides a power supply soft start control circuit, a control chip and a control device, wherein the power supply soft start control circuit comprises: the device comprises a voltage source, a constant current source, a capacitance amplifier, a comparator and a frequency oscillator; the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitance amplifier are combined and then connected with the positive phase input end of the comparator, the second end of the capacitance amplifier is grounded, the negative phase input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for being connected with a power device. Therefore, the capacitance value is amplified through the capacitance amplifier, the purpose of soft start of the power supply can be realized, the layout area of the chip can be saved, and the cost of the chip is reduced.

Description

Power supply soft start control circuit, control chip and control device

Technical Field

The application relates to the technical field of switching power supplies, in particular to a power supply soft start control circuit, a control chip and a control device.

Background

At the moment of starting the switching power supply, since no voltage is available on the output capacitor, the output capacitor is charged at the beginning (from 0), and a loop is not established at this moment, the control chip outputs at the maximum duty ratio, so that the relevant power device is subjected to large voltage and current stress. Therefore, in order to avoid that the power device suddenly bears a large voltage and current stress, the switching power supply is started by adopting a power supply soft start mode, and when a loop is not established, the duty ratio of Pulse Width Modulation (pwm) of a control output is enabled to be from small to large, so that the voltage input into the power device has a buffer increasing process. However, in order to obtain sufficient start time, the conventional power soft start method often needs a large enough capacitor, which makes the chip layout area occupied by the capacitor large, and increases the chip cost.

Disclosure of Invention

Based on the defects of the prior art, the invention provides a power supply soft start control circuit, a control chip and a control device, so that the capacitance value is amplified through a capacitance amplifier, the layout area of the chip is saved, and the cost of the chip is reduced.

In a first aspect, an embodiment of the present application provides a power supply soft start control circuit, where the control circuit includes: the device comprises a voltage source, a constant current source, a capacitance amplifier, a comparator and a frequency oscillator;

the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitance amplifier are combined and then connected with the positive phase input end of the comparator, the second end of the capacitance amplifier is grounded, the negative phase input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for connecting a power device;

the constant current source is used for charging an internal capacitor of the capacitor amplifier, so that the voltage of a positive phase input end of the comparator is continuously increased within a preset range, the frequency oscillator is used for outputting sawtooth wave voltage, and the comparator is used for outputting square wave signals with continuously increased duty ratio according to the voltage of the positive phase input end and the sawtooth wave voltage, so that the power supply soft start is realized.

In a second aspect, an embodiment of the present application provides a power soft-start control chip, where the power soft-start control chip includes the power soft-start control circuit in the first aspect.

In a third aspect, an embodiment of the present application provides a power soft-start control device, where the electronic device includes the power soft-start control circuit according to the first aspect.

It can be seen that the power supply soft start control circuit provided by the application comprises a voltage source, a constant current source, a capacitive amplifier, a comparator and a frequency oscillator, wherein the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitive amplifier are combined and then connected with the positive input end of the comparator, the second end of the capacitive amplifier is grounded, the negative input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for connecting a power device. Therefore, the capacitance value is amplified through the capacitance amplifier, the purpose of soft start of the power supply can be realized, the layout area of the chip can be saved, and the cost of the chip is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of a power supply soft start control circuit of the present application;

FIG. 2 is a circuit diagram of a capacitor amplifier in the power supply soft start control circuit of the present application;

FIG. 3 is a schematic diagram of the duty cycle of the control signal of the power supply soft start control circuit of the present application as a function of the voltage of the capacitive amplifier;

FIG. 4 is another circuit schematic of the power supply soft start control circuit of the present application;

FIG. 5 is a schematic diagram of a layout range of an internal capacitor of the power supply soft start control circuit of the present application;

FIG. 6 is a schematic diagram of a circuit configuration of a power soft start control chip according to the present application;

fig. 7 is a schematic composition diagram of the power supply soft start control device of the present application.

Detailed Description

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The terms "first," "second," and the like in the description and claims of the present application and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

At the moment of starting the switching power supply, since no voltage is available on the output capacitor, the output capacitor is charged at the beginning (from 0), and a loop is not established at this moment, the control chip outputs at the maximum duty ratio, so that the related power device is subjected to large voltage and current stress, and the device may be damaged. The problem can be overcome by the soft start of the power supply, and when the loop is not established, the duty ratio of the pulse width modulation of the control output can be changed from small to large, so that the increase of the voltage of the input power device has a buffering process. The voltage of the input power device can be reduced through the soft start of the power supply, the voltage overshoot of the input power device during starting is prevented, smooth starting can be realized, the starting current impact is reduced, the stress borne by the power device is reduced, and the damage to the power device is avoided.

However, in the conventional power supply soft start method, a constant current source charges a fixed capacitor, so that the power supply soft start is realized, but the soft start of a power supply chip generally needs several milliseconds, so that the capacitor charged by the constant current source is large enough, the layout area of the chip occupied by the capacitor, namely the layout range, is large, and the cost of the chip is increased.

Referring to fig. 1 in conjunction with the above description, fig. 1 is a schematic diagram of a power soft start control circuit according to the present application. As shown in the drawings, the power supply soft start control circuit provided in the embodiment of the present application includes: the device comprises a voltage source, a constant current source, a capacitance amplifier, a comparator and a frequency oscillator;

the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitance amplifier are combined and then connected with the positive phase input end of the comparator, the second end of the capacitance amplifier is grounded, the negative phase input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for connecting a power device;

the constant current source is used for charging an internal capacitor of the capacitor amplifier, so that the voltage of a positive phase input end of the comparator is continuously increased within a preset range, the frequency oscillator is used for outputting sawtooth wave voltage, and the comparator is used for outputting square wave signals with continuously increased duty ratio according to the voltage of the positive phase input end and the sawtooth wave voltage, so that the power supply soft start is realized.

The capacitor amplifier is charged by the constant current source, which is equivalent to charging a small capacitor in the capacitor amplifier by the constant current source, and then the value of the small capacitor is amplified by the capacitor amplifier, which is equivalent to charging a large enough capacitor. The Vct voltage in the figure is the voltage value of the capacitor amplifier, the Vct voltage is input into a positive phase input end of a comparator, the Vct voltage is compared with the voltage value of a negative phase input end of the comparator, the voltage of the negative phase input end is sawtooth wave voltage generated according to a frequency oscillator, when the Vct voltage is larger than the sawtooth wave voltage, the output end of the comparator outputs high level, when the Vct voltage is smaller than the sawtooth wave voltage, the output end of the comparator outputs low level, therefore, square waves with continuously increased duty ratio are obtained through the comparator, and the soft start of a power supply is realized.

For example, when the power supply is started, the output voltage is initially 0 because the output terminal is connected to a large capacitor. At this time, one constant current source in the chip internal starting module charges the capacitor amplifier. Because the constant current source continuously charges the capacitor amplifier, the Vct voltage at the positive phase input end of the comparator is gradually increased, and after the Vct voltage is compared with the sawtooth wave voltage, a rectangular wave driving signal with the gradually increased duty ratio is generated.

The charging current of the power supply system to the output large capacitor is increased along with the increase of the duty ratio of the driving signal. That is, the output current is gradually increased along with the duty ratio of the driving signal, so that the correct establishment of the output voltage has a smooth establishment, and the condition that the output overshoot is caused by the fact that the output capacitor is charged by the maximum charging current initially without a soft-start power supply system and the power device is damaged is prevented.

The time (millisecond level) of the soft start is determined by the size of a constant current source for charging the equivalent amplifying capacitor in the soft start module and the size of the equivalent capacitor. If the chip interior needs 100 Picofarads (PF) to reach the starting time in reality, the amplification capacitance is applied to amplify by 10 times, and only 10PF is needed to reach the requirement, so that the layout area is saved compared with the existing method. Compared with the existing method, the layout area is saved. Therefore, soft start of the power supply can be realized, overshoot of output voltage can be reduced, starting current impact is reduced, smooth start is realized, stress borne by the device can be reduced, damage is avoided, the layout area can be saved, and the chip cost is reduced.

In this example, the power supply soft start control circuit includes a voltage source, a constant current source, a capacitance amplifier, a comparator and a frequency oscillator; the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitance amplifier are combined and then connected with the positive phase input end of the comparator, the second end of the capacitance amplifier is grounded, the negative phase input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for being connected with a power device. The small capacitor is amplified by connecting the capacitor amplifier to the output end of the constant current source, so that the purpose of soft start can be realized, the layout area of the chip can be saved, and the cost of the chip can be reduced.

In one possible example, the capacitive amplifier includes a resistor and an operational amplifier, a first end of the resistor is connected to a positive phase input terminal of the operational amplifier, and a second end of the resistor is connected to a negative phase input terminal of the operational amplifier and an output terminal of the operational amplifier.

Referring to fig. 2, fig. 2 is a circuit diagram of a capacitor amplifier in the power soft start control circuit of the present application. As shown, the capacitor amplifier includes a resistor R and an operational amplifier a, the constant current source is connected to the positive input terminal of the operational amplifier a, and the operational amplifier a may include an internal capacitor, i.e., the small capacitor. Can be based on the charging current I output by the constant current source_inThe internal capacitor is charged, and the capacitance value of the internal capacitor is amplified according to the operational amplifier A and the resistor R, so that the equivalent capacitance of the Vct end is larger than the internal capacitor of the capacitor amplifier, and therefore under the condition of the same charging current, the increasing rate of the voltage of the Vct is smaller than that of the voltage of the internal capacitor. Therefore, the soft start of the power supply can be realized at the same time, and enough soft start time is obtained. The capacitor amplifier can be equivalent to a large capacitor when the power supply is started, namely the capacitor amplifier can be charged by the constant current source, and the capacitor amplifier can be equivalent to a large capacitor charged by the constant current source.

Therefore, in the embodiment, the internal capacitance of the capacitance amplifier is amplified through the operational amplifier and the resistor, so that the purpose of soft start can be realized, the layout area of the chip can be saved, and the cost of the chip can be reduced.

In one possible example, the power supply soft start is completed when the voltage value of the non-inverting input terminal of the comparator is greater than or equal to the maximum voltage value of the sawtooth wave voltage.

The soft start of the power supply is to reduce the voltage and current overshoot of the input power device so as to avoid the damage of the power device, therefore, in the process of the soft start of the power supply, the capacitor amplifier is charged by the constant current source, so that the voltage of the capacitor amplifier is also the voltage of the positive phase input end of the comparator, and the voltage of the positive phase input end of the comparator is slowly increased.

When the voltage value of the positive phase input end of the comparator is larger than or equal to the maximum voltage value of the sawtooth wave voltage, the constant current source can also stop charging the capacitor amplifier, so that the capacitor amplifier is open-circuited, at the moment, the power supply soft start circuit can be equivalent to grounding of the first end of the voltage source, the second end of the voltage source is connected with the input end of the constant current source, and the output end of the constant current source is connected with the power device. Because the voltage input to the positive phase input end of the comparator in the power supply soft start circuit is the output voltage of the voltage source, the output of the comparator is always a high-level signal. When the power supply is turned off, the electric quantity stored by the internal capacitor in the capacitor amplifier is released through the chip internal enabling signal, so that the capacitor can have enough space to store the electric quantity and the voltage value of the capacitor amplifier is gradually increased when the power supply is started next time.

Referring to fig. 3, fig. 3 is a schematic diagram illustrating a duty ratio of a control signal of a power soft start control circuit according to the present application varying with a voltage of a capacitor amplifier. As shown, Vasw is a sawtooth voltage generated by a frequency oscillator, i.e. a voltage input to the negative input terminal of a comparator, and V₀The voltage is the highest voltage value of the sawtooth wave voltage Vasw, Vct is the voltage of a capacitance amplifier, namely the voltage of a positive phase input end of an input comparator, clk is a clock signal, and the clock signal simultaneously indicates the pwm duty ratio of the power supply soft start control circuit. It can be known from the figure that, as the constant current source continuously charges the capacitor amplifier, the Vct voltage continuously increases according to a certain trend, and the change rule of the sawtooth wave voltage is constant, and the Vct voltage is determined as a high level when being greater than the sawtooth wave voltage, and is determined as a low level when being less than the sawtooth wave voltage. It can be seen from fig. 3 that the time for Vct voltage to be greater than the sawtooth voltage is increasing, and therefore the time for outputting high level is also increasing, when Vct voltage is greater than V₀Then the value of Vct voltage is always greater than the sawtooth voltage, which means that the comparator will output a constant high signal and the start is completed. For example, the power system output voltage is constantly 10 volts (v). Since the output end of the power supply system is connected with a large capacitor, when the power supply chip has a starting function inside, the output voltage smoothly rises from 0 until reaching a constant value of 10 v. The voltage of the capacitor amplifier and the sawtooth wave voltage in the chip starting module determine the duty ratio of the driving signal, the duty ratio of the driving signal is increased along with the increase of the voltage on Vct, and the current for charging the capacitor amplifier is also increased until the starting is finished. The starting time is determined by the capacitance value in the starting circuit and the size of the constant current source for charging the equivalent capacitor. The starting function prevents the power supply system from charging the output capacitor by using the maximum current controlled by the chip all the time when the power supply system is started, so that the output voltage of the power supply system is slowly increased until the output voltage is increased to the output voltage of the voltage source, the smooth starting of the switching power supply can be realized, and the problems of voltage overshoot and the like of an input power device are solved.

In this example, when the voltage value at the positive phase input terminal of the comparator is greater than or equal to the maximum voltage value of the sawtooth wave voltage, the soft start of the power supply is completed, and the smooth start of the switching power supply can be realized, so as to avoid the overshoot of the voltage and current of the input power device.

In one possible example, the output of the comparator is connected in series with at least one inverter for shaping the signal output by the comparator to output a square wave signal.

Referring to fig. 4, fig. 4 is another circuit schematic diagram of the power soft start control circuit of the present application. As shown in the figure, two inverters, namely inverter 1 and inverter 2, are connected in series to the output end of the comparator, and the two inverters are used for shaping the signal output by the comparator, so that the comparator can output a rectangular wave signal with an increasing duty ratio.

In this example, it can be seen that, by connecting a plurality of inverters in series at the output end of the comparator, the output signal of the comparator can be shaped to obtain a rectangular wave signal.

In one possible example, the capacitive amplifier comprises an internal capacitance, the value C of which₀The calculating method comprises the following steps: obtaining the maximum voltage value V of the sawtooth wave voltage₀(ii) a Acquiring the time delta t required by the soft start of the power supply; obtaining the amplification factor K of the capacitance amplifier; according to the maximum voltage value V₀The time Δ t and the amplification K determine a first range C of values of the internal capacitance₁(ii) a Obtaining a second range C of the value of the internal capacitance according to the layout range₂(ii) a Determining the first range C₁And said second range C₂Is the value C of the internal capacitance₀。

The internal capacitor is a small capacitor for receiving the charging current of the constant current source, and the time Δ t required for soft start of the power supply can be set according to specific requirements, for example, determined according to the magnitude of the output voltage of the voltage source and the magnitude of the minimum voltage value that can be carried by the power device. Because the power supply soft start is to be completed, the voltage of the capacitor amplifier must be higher than that of the capacitor amplifier during the preset power supply soft start timeThe maximum voltage value V₀The capacitance of the capacitor amplifier is therefore amplified sufficiently so that the calculated minimum value is at least a criterion for the voltage of the capacitor amplifier.

Because the quantity of the charges stored by the capacitor is related to the facing area between the two polar plates of the capacitor, when the capacitor is larger, the facing area between the two polar plates of the capacitor is larger, and therefore, in the power supply soft start circuit, the capacitor occupies a larger area of a domain. However, since the power supply soft start needs a large capacitor and the layout area of the power supply chip is limited, in the existing design, the power supply soft start time is usually ensured by connecting the capacitor externally to the power supply chip, but this needs to increase the pins connecting the power supply chip and the capacitor, which undoubtedly increases the manufacturing cost. In this example, the range reserved for the internal capacitance is preferentially determined in the power supply chip, and then the second area C of the value of the internal capacitance is determined according to the range₂。

In specific implementation, the power supply soft start circuit is applied to a power supply chip, the power supply chip comprises a power device, and a second range C of the value of the internal capacitor is obtained according to a domain range₂The method comprises the following steps: obtaining a first version range A reserved for the power supply soft start circuit in the power supply chip₁(ii) a Acquiring a first position of the power device in the power supply chip; according to the first version range A₁And determining a second layout range A for the first position of the power device₂The second layout range A₂Is the first version range A₁The distance between the power device and the first position of the power device is larger than the layout range of a first preset distance; determining that the constant current source is in the first layout range A₁A second position in (a); determining the second layout range A₂The layout range in which the distance from the second position is smaller than a second preset distance is the layout range of the internal capacitor in the power supply chip; determining a second range C of the value of the internal capacitor according to the layout range of the internal capacitor in the power supply chip₂。

FIG. 5 shows the soft start of the power supply of the present application, as shown in FIG. 5The layout range schematic diagram of the internal capacitor of the control circuit can determine the layout area of the power supply chip occupied by the internal capacitor according to the layout range of the internal capacitor. In a second range C for determining the value of the internal capacitance₂Firstly, a first version range A reserved for a power supply soft start circuit in a power supply chip is determined₁Then in this first version of range A₁Determining a second layout range A with the distance from the power device larger than a first preset distance₂. The reason is that the internal capacitance is easily interfered by high-power-consumption devices such as power devices, and therefore the A in the second layout range₂Each located at a distance from the power device to reduce the effect of coupling. Then according to the position of the constant current source and the second layout range A₂The layout range of the internal capacitor is determined, and the constant current source needs to charge the internal capacitor, so that the constant current source is connected with the internal capacitor through a wire, and the routing of the internal capacitor connected to the power supply chip is easily interfered by noise to influence the performance of the power supply chip, so that the internal capacitor and the constant current source are required to be within a certain distance. After determining the layout range of the internal capacitor, the layout range can be determined according to formula C₂The second range C is calculated by = (epsilon × S) ÷ (4 pi × k × d)₂A range value of (c). Wherein epsilon is a dielectric constant, d is the range of the opposite distance between two polar plates of the internal capacitor determined according to the layout range of the internal capacitor, S is the opposite area between two polar plates of the corresponding internal capacitor when any opposite distance d exists, and k is the constant of the electrostatic force.

Therefore, the capacitor can be placed inside the power supply chip, namely, the whole power supply soft start control circuit is positioned in the power supply chip, the position relation between the power supply soft start control circuit and the power supply chip can be that the voltage source of the power supply soft start control circuit is connected with the internal voltage output end of the power supply chip, and the comparator output end of the power supply soft start control circuit is connected with the power device inside the power supply chip. And a pin for connecting the power supply chip and the capacitor is not additionally arranged, so that the requirement of soft start of the power supply on the capacitor can be met, and the cost is saved.

Therefore, in the embodiment, the capacitance value of the internal capacitor of the capacitor amplifier can be determined according to the maximum voltage value of the sawtooth wave voltage, the time required by soft start, the amplification factor of the capacitor amplifier and the chip layout area, and the capacitor amplifier can be accurately and quickly designed.

In one possible example, the first range C of values of the internal capacitance₁Lower limit of C_minThe value is calculated by the following formula: c_min=Δt×Icharge÷(K×V₀) Wherein, C_minIs the first range C₁Lower limit of (C), first range C₁The upper limit of (1) is positive infinity, and Ichar is the charging current output by the constant current source.

The time of the power supply soft start is Δ t, the charging current of the constant current source is Icharge, and the charging current output by the constant current source is kept unchanged, so that Δ t × Icharge can be regarded as the charge amount obtained by the internal capacitor in the power supply soft start process. V₀Is the maximum voltage value of sawtooth wave voltage, K is the amplification factor of the capacitor amplifier, so K is multiplied by C_minNamely the capacitance value of the internal capacitor after being amplified by the capacitor amplifier. The range of the value of the internal capacitor is related to the amplification factor of the capacitor amplifier, the amplification factor of the capacitor amplifier is related to the resistance value of the resistor, and the range of the resistance value of the resistor is determined according to the layout range of the power chip because the layout range of the resistor inside the power chip needs to be considered and the resistance value of the resistor is in direct proportion to the length of the resistor. Because the resistance value of the resistor is inversely proportional to the amplification factor, the maximum amplification factor of the capacitor amplifier can be determined according to the resistance value range, and because the power supply soft start circuit is completed in a way that the voltage value of the power supply amplifier is required to be higher than the maximum value of the sawtooth wave voltage output by the frequency oscillator, the lower limit value of the internal capacitor can be determined according to the power supply soft start time, the charging current value, the maximum amplification factor and the maximum voltage value of the sawtooth wave voltage.

Therefore, in the embodiment, the minimum capacitance value of the capacitor amplifier is determined according to the maximum voltage value of the sawtooth wave voltage, the time required by soft start, the amplification factor of the capacitor amplifier and the charging current, so that the capacitor amplifier can be accurately and quickly designed.

In one possible example, the resistance value R of the resistor is calculated by:

determining the output terminal voltage U of the capacitive amplifier_outThe time domain expression of (a) is:

U_out(S)=A₀(S)÷[A₀(S)+1]×U_in(S)，

according to the output end voltage U_outDetermines the current I of the non-inverting input of the capacitive amplifier_inThe time domain expression of (a) is:

I_in(S)=[ U_in(S)- U_out(S)] ÷R=[A₀(S)+1] ÷U_in(S)÷R，

according to the output end voltage U_outAnd said current I_inDetermining the time domain expression of the impedance Z of the capacitive amplifier as follows:

Z(S)= U_in(S) ÷I_in(S)= A₀(S) ×R+R=1÷(K×C₀×j×ω) +R，

determining the resistance value R of the resistor as follows according to the time domain expression of the impedance Z:

R=1÷[K×j×ω×A₀×(j×ω) ×C₀]= 1÷(2×π×K×GB×C₀)，

wherein, U_inIs the voltage at the positive input terminal of the capacitor amplifier, S refers to the time domain, A₀For the open-loop gain value of the capacitor amplifier, GB is the gain-bandwidth product, j is the complex number, and ω is the frequency.

Wherein GB represents a Gain-bandwidth product, and the Gain-bandwidth product (GBP or GB) of the capacitive amplifier is a product of the bandwidth of the capacitive amplifier and the Gain of the bandwidth, and is a parameter for simply measuring the performance of the capacitive amplifier, and when the frequency is sufficiently large, the Gain-bandwidth product is a constant. From the above formula, GB is a constant, and K × C₀It is the capacitance value amplified by the capacitor amplifier, so that it can be measured by the maximum value V of the sawtooth wave voltage₀I.e. the minimum voltage value to be reached by the capacitive amplifier determines the resistanceThe minimum value of the value is then the minimum value of the layout area of the power supply chip occupied by the resistor can be determined according to the minimum value of the resistance value of the resistor, and meanwhile, the maximum value of the internal capacitor occupied by the layout area of the power supply can be obtained, namely the second range C₂The upper limit value of (3).

In a specific implementation, according to the first range C₁And a second range C₂Determined internal capacitance value C₀Possibly comprising a plurality, i.e. obtaining a set of internal capacitances. The amplification factor of the capacitor amplifier corresponding to each capacitance value in the internal capacitor set can be determined according to the resistance value of the resistor of the capacitor amplifier, and when the internal capacitor of the capacitor amplifier is determined to be each internal capacitance value in the internal capacitor set according to different amplification factors, the increase rate of the voltage of the capacitor amplifier is determined, and a specific internal capacitance value is determined from the internal set according to the increase rate and a power device in a power chip, so that the power supply is smoother when being started, and the stress on the power device is minimum.

It can be seen that, in this example, the magnitude of the resistance of the capacitive amplifier can be determined by the amplification factor of the capacitive amplifier, the product of the internal capacitance and the gain bandwidth, and the amplification factor of the capacitive amplifier can be changed by adjusting the resistance of the resistor of the capacitive amplifier.

In one possible example, the method for calculating the gain-bandwidth product GB comprises:

GB=f×A₀×(2×π×f)，

where f =2 × pi × w, w is the dominant pole, and w =1 ÷ (R × C)₃)，C₃Is the value of the compensation capacitance of the capacitive amplifier, f is the bandwidth of the unity gain of the capacitive amplifier, A₀Is the open loop gain of the capacitive amplifier.

The capacitance amplifier is provided with a compensation capacitor inside, because the capacitance amplifier used in practice has a corresponding phase shift function to signals with a certain frequency, and the signals are fed back to the input end to make the capacitance amplifying circuit work unstably and even oscillate, so that a corresponding compensation capacitor must be added for a certain phase compensation.

Therefore, in this example, the calculated resistance value of the resistor can be more accurate in consideration of the influence of the compensation capacitor inside the capacitor amplifier on the gain bandwidth product.

As shown in fig. 6, an embodiment of the present application further provides a power soft-start control chip, where the power soft-start control chip includes the power soft-start control circuit according to the foregoing embodiment.

As shown in fig. 7, an embodiment of the present application further provides a power soft-start control device, where the power soft-start control device includes the power soft-start control chip according to the foregoing embodiment, and the power soft-start control chip includes the power soft-start control circuit according to the foregoing embodiment.

The above embodiments are merely representative of the centralized embodiments of the present invention, and the description thereof is specific and detailed, but it should not be understood as the limitation of the scope of the present invention, and it should be noted that those skilled in the art can make various changes and modifications without departing from the spirit of the present invention, and these changes and modifications all fall into the protection scope of the present invention. Therefore, the protection scope of the present patent should be subject to the appended claims.

Claims (10)

1. A power supply soft start control circuit, comprising: the device comprises a voltage source, a constant current source, a capacitance amplifier, a comparator and a frequency oscillator;

the first end of the voltage source is grounded, the second end of the voltage source is connected with the input end of the constant current source, the output end of the constant current source and the first end of the capacitance amplifier are combined and then connected with the positive phase input end of the comparator, the second end of the capacitance amplifier is grounded, the negative phase input end of the comparator is connected with the frequency oscillator, and the output end of the comparator is used for connecting a power device;

the constant current source is used for charging an internal capacitor of the capacitor amplifier, so that the voltage of a positive phase input end of the comparator is continuously increased within a preset range, the frequency oscillator is used for outputting sawtooth wave voltage, and the comparator is used for outputting square wave signals with continuously increased duty ratio according to the voltage of the positive phase input end and the sawtooth wave voltage, so that the power supply soft start is realized.

2. The power supply soft start control circuit of claim 1, wherein the capacitive amplifier comprises a resistor and an operational amplifier, a first end of the resistor is connected to a positive phase input terminal of the operational amplifier, and a second end of the resistor is connected to a negative phase input terminal of the operational amplifier and an output terminal of the operational amplifier.

3. The power supply soft start control circuit according to claim 1, wherein the power supply soft start is completed when a voltage value at a non-inverting input terminal of the comparator is greater than or equal to a maximum voltage value of the sawtooth wave voltage.

4. The power supply soft-start control circuit of claim 3, wherein the output of the comparator is connected in series with at least one inverter for shaping the signal output by the comparator to output a square wave signal.

5. The power supply soft start control circuit according to any one of claims 1 to 4, wherein the capacitive amplifier comprises an internal capacitor, and the value C of the internal capacitor₀The calculating method comprises the following steps:

obtaining the maximum voltage value V of the sawtooth wave voltage₀；

Acquiring the time delta t required by the soft start of the power supply;

obtaining the amplification factor K of the capacitance amplifier;

according to the maximum voltage value V₀The time Δ t and the amplification K determine a first range C of values of the internal capacitance₁；

Obtaining a second range C of the value of the internal capacitance according to the layout range₂；

DeterminingThe first range C₁And said second range C₂Is the value C of the internal capacitance₀。

6. The power supply soft start control circuit of claim 5, wherein the first range C of values of the internal capacitance₁Lower limit of C_minThe value is calculated by the following formula:

C_min=Δt×Icharge÷(K×V₀)，

wherein, C_minIs the first range C₁Lower limit of (C), first range C₁The upper limit of (1) is positive infinity, and Ichar is the charging current output by the constant current source.

7. The power supply soft start control circuit according to claim 5, wherein the resistance value R of the resistor is calculated by the following method:

determining the output terminal voltage U of the capacitive amplifier_outThe time domain expression of (a) is:

U_out(S)=A₀(S)÷[A₀(S)+1]×U_in(S)，

according to the output end voltage U_outDetermines the current I of the non-inverting input of the capacitive amplifier_inThe time domain expression of (a) is:

I_in(S)=[ U_in(S)- U_out(S)] ÷R=[A₀(S)+1] ÷U_in(S)÷R，

according to the output end voltage U_outAnd said current I_inDetermining the time domain expression of the impedance Z of the capacitive amplifier as follows:

Z(S)= U_in(S) ÷I_in(S)= A₀(S) ×R+R=1÷(K×C₀×j×ω) +R，

determining the resistance value R of the resistor as follows according to the time domain expression of the impedance Z:

R=1÷[K×j×ω×A₀×(j×ω) ×C₀]= 1÷(2×π×K×GB×C₀)，

wherein, U_inIs the voltage at the positive input terminal of the capacitor amplifier, S refers to the time domain, A₀For the open-loop gain value of the capacitor amplifier, GB is the gain-bandwidth product, j is the complex number, and ω is the frequency.

8. The power supply soft start control circuit of claim 7, wherein the method for calculating the gain-bandwidth product GB comprises:

GB=f×A₀×(2×π×f)，

where f =2 × pi × w, w is the dominant pole, and w =1 ÷ (R × C)₃)，C₃Is the value of the compensation capacitance of the capacitive amplifier, f is the bandwidth of the unity gain of the capacitive amplifier, A₀Is the open loop gain of the capacitive amplifier.

9. A power supply soft start control chip, characterized in that the power supply soft start control chip comprises the power supply soft start control circuit according to any one of claims 1 to 8.

10. A power supply soft start control device, characterized in that the power supply soft start control device comprises a power supply soft start control circuit according to any one of claims 1 to 8.

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