CN110764410B - Method for accelerating transient response of negative feedback control system - Google Patents

Abstract

The invention relates to a method for accelerating transient response of a negative feedback control system, which comprises the following steps: transmitting VFB to transconductance amplifier U₁To the transconductance amplifier U, and the inverting input terminal of the second transistor for sending VREF to the transconductance amplifier U₁The positive input end of the comparator is used for comparison; do conductive amplifier U of bed₁Flows through a resistor R and generates a voltage drop VR across the resistor R, which is a transconductance amplifier U₁Amplifying the proportion of the pressure difference between the two input ends; a voltage comparator U₂Detecting the voltage drop VR at the two ends of the resistor R, comparing the voltage drop VR at the two ends of the resistor R with a set threshold value, and when the voltage drop VR exceeds the set threshold value voltage, comparing the voltage with a voltage comparator U₂Output signal Y of₁Flipping, thereby activating the auxiliary circuit to accelerate the transient response of the system.

Description

Method for accelerating transient response of negative feedback control system

Technical Field

The invention relates to the field of electronics, in particular to a method for accelerating transient response of a negative feedback control system.

Background

The negative feedback control system is widely applied to various electronic devices, for example, the common PWM operating mode and the peak current mode DC-DC are both negative feedback control systems. For a negative feedback control system, the bandwidth of the system may limit the speed of the control loop's response to the output target transients. For example, when the output target amount deviates from the reference value by more than a certain margin, it may not be acceptable in practical use.

The most straightforward way to improve the dynamic response of the system is to increase the system bandwidth, which is limited by factors such as the allowable operating frequency of the system, the loop stability tradeoff, etc. Additional ancillary circuitry may be required to speed up the response of the system under output transient conditions.

Referring to fig. 1, fig. 1 is a circuit diagram illustrating the acceleration transient response of a conventional negative feedback control system. The sampled feedback signal VFB, which is output in a steady state, is stabilized at the level of the reference signal VREF. When the output is transient, the output sampled feedback signal VFB deviates from the reference signal VREF, and when the deviation value of the output sampled feedback signal VFB exceeds a set amplitude, for example, the deviation value exceeds VREF₁Then the comparator U₂Output voltage Y of₁Turning over, Y₁The signal is used to activate a circuit that accelerates the transient response of the system.

In an integrated circuit, the structure has oneOne disadvantage is that: because of the transconductance amplifier U₁And a comparator U₂All have input offsets and therefore VREF₁The difference from VREF must be higher than the offset voltage for the system to operate stably. E.g. U₁Input offset of VOS₁,U₂Input offset of VOS₂The following conditions are satisfied:

|VREF₁-VREF|>|VOS₁|+|VOS₂|

this can cause the acceleration circuit to act too late, thereby affecting the effect of the transient response.

Disclosure of Invention

The invention aims to provide a method for accelerating the transient response of a negative feedback control system, which can remarkably improve the transient response characteristic of the system.

The invention relates to a method for accelerating the transient response of a negative feedback control system, which is characterized by comprising the following steps:

transmitting a sampling feedback signal VFB of output quantity or output quantity to a transconductance amplifier U₁The inverting input terminal of the second stage, the reference signal VREF is sent to the transconductance amplifier U₁The positive input end of the comparator is used for comparison;

do conductive amplifier U of bed₁Flows through a resistor R and generates a voltage drop VR across the resistor R, which is a transconductance amplifier U₁Amplifying the proportion of the pressure difference between the two input ends;

a voltage comparator U₂Voltage drop VR across detection resistor R, voltage comparator U₂Comparing the voltage drop VR of two ends of the resistor R with a set threshold value, and when the voltage drop VR exceeds the set threshold voltage, a voltage comparator U₂Output signal Y of₁Flipping, thereby activating the auxiliary circuit to accelerate the transient response of the system.

Preferably, the method comprises the following steps: the implementation method of the auxiliary circuit further comprises the following steps:

first, a frequency compensation unit U is changed by changing a frequency compensation resistance value₃The zero point position of the frequency compensation unit U₃Is composed of a network of resistive and capacitive elements,the frequency compensation of the system is realized by setting the positions of the zero point and the pole;

die frequency compensation unit U₃The compensation capacitor is charged in an accelerated manner, and the charging current of the compensation capacitor is a transconductance amplifier U₁The proportion of the output current is amplified;

third, skip transconductance amplifier U₁The output error control signal increases or decreases the output energy of the system.

Preferably, the method comprises the following steps: the step is in the second in the proportion of output current enlargies can select for use: transconductance amplifier U₁And mirror image amplification of the output current, or sending the voltage drop VR between two ends of the resistor R to another transconductance amplifier to generate the output current for charging the compensation capacitor.

Preferably, the method comprises the following steps:

the output current IO of the transconductance amplifier is the product of the differential voltage of the input end of the operational amplifier (VREF-VFB) and the transconductance Gm of the operational amplifier, wherein IO is (VREF-VFB) × Gm

The voltage difference between two ends of the resistor R is VR, VR is IO R, (VREF-VFB) Gm R

From the above formula, VR is the proportional amplification of the transconductance amplifier input voltage difference VREF-VFB when Gm × R >1 is satisfied.

Compared with the prior art, the invention has the beneficial effects that:

the invention accelerates the transient response speed of the system and reduces the deviation amplitude of the output quantity relative to the reference datum.

The invention reduces the sensitivity of the circuit to the input offset voltage of the operational amplifier or the comparator.

According to the invention, by comparing whether the voltage drop VR at two ends of the resistor exceeds the set threshold voltage, higher sensitivity can be realized and the sensitivity to input offset of the operational amplifier and the comparator is reduced. When the voltage drop VR between two ends of the resistor exceeds the set threshold voltage, the voltage comparator U₂Output signal Y of₁Flipping, thereby activating the auxiliary circuit to accelerate the transient response of the system.

Drawings

FIG. 1 is a circuit schematic of a conventional negative feedback control system accelerating transient response;

FIG. 2 is a circuit of the present invention for accelerating dynamic response; where VFB is the sampled feedback signal of the output, VREF is the reference signal, U₁Is a transconductance amplifier, U₂Is a voltage comparator, U₃Is a frequency compensation unit;

FIG. 3 is a diagram illustrating the effect of the dynamic response of the acceleration system of the present invention.

Detailed Description

The invention will be described in more detail below with reference to the accompanying drawings:

referring to fig. 2, the method for accelerating the transient response of the negative feedback control system includes the following steps:

transmitting a sampling feedback signal VFB of output quantity or output quantity to a transconductance amplifier U₁The inverting input terminal of the second stage, the reference signal VREF is sent to the transconductance amplifier U₁The positive input end of the comparator is used for comparison;

do conductive amplifier U of bed₁Flows through a resistor R and generates a voltage drop VR across the resistor R, which is a transconductance amplifier U₁Amplifying the proportion of the pressure difference between the two input ends;

a voltage comparator U₂Voltage drop VR across detection resistor R, voltage comparator U₂Comparing the voltage drop VR of two ends of the resistor R with a set threshold value, and when the voltage drop VR exceeds the set threshold voltage, a voltage comparator U₂Output signal Y of₁Flipping, thereby activating the auxiliary circuit to accelerate the transient response of the system.

In this embodiment, the implementation method of the auxiliary circuit further includes:

first, a frequency compensation unit U is changed by changing a frequency compensation resistance value₃The zero point position of the frequency compensation unit U₃The system consists of a network consisting of a resistor and a capacitor element and is used for setting the positions of a zero point and a pole to realize the frequency compensation of the system;

die frequency compensation unit U₃The compensation capacitor is charged in an accelerated manner, and the charging current of the compensation capacitor is a transconductance amplifier U₁The proportion of the output current is amplified;

skipping overLead amplifier U₁The output error control signal increases or decreases the output energy of the system.

The step is in the second in the proportion of output current enlargies can select for use: transconductance amplifier U₁And mirror image amplification of the output current, or sending the voltage drop VR between two ends of the resistor R to another transconductance amplifier to generate the output current for charging the compensation capacitor.

The output current IO of the transconductance amplifier is the product of the differential voltage of the input end of the operational amplifier (VREF-VFB) and the transconductance Gm of the operational amplifier, wherein IO is (VREF-VFB) × Gm

The voltage difference between two ends of the resistor R is VR, VR is IO R (VREF-VFB) Gm R

From the above formula, VR is the proportional amplification of the transconductance amplifier input voltage difference VREF-VFB when Gm × R >1 is satisfied.

Referring to fig. 3, fig. 3 is a schematic diagram illustrating the effect of the dynamic response of the acceleration system according to the present invention; where the solid line is the VFB transient response waveform using the proposed technique of the present invention and the dashed line is the VFB transient response waveform of the conventional control system.

The above-mentioned embodiments are only preferred embodiments of the present invention, and all equivalent changes and modifications made within the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims (3)

1. A method of accelerating the transient response of a negative feedback control system comprising the steps of:

transmitting a sampling feedback signal VFB of output quantity or output quantity to a transconductance amplifier U₁The inverting input terminal of the second stage, the reference signal VREF is sent to the transconductance amplifier U₁The positive input end of the comparator is used for comparison;

the method is characterized by further comprising the following steps:

do conductive amplifier U of bed₁Flows through a resistor R and generates a voltage drop VR across the resistor R, which is a transconductance amplifier U₁Amplifying the proportion of the pressure difference between the two input ends; the output current IO of the transconductance amplifier is the product of the operational amplifier input end voltage difference (VREF-VFB) and the operational amplifier transconductance Gm:

IO＝(VREF-VFB)*Gm

the voltage difference between two ends of the resistor R is VR, VR is IO R, (VREF-VFB) Gm R

VR is the proportional amplification of the input end voltage difference VREF-VFB of the transconductance amplifier when Gm R >1 is met;

thirdly, the voltage comparator U2 detects the voltage drop VR at the two ends of the resistor R, and the voltage comparator U₂Comparing the voltage drop VR of two ends of the resistor R with a set threshold value, and when the voltage drop VR exceeds the set threshold voltage, a voltage comparator U₂Output signal Y of₁Flipping, thereby activating the auxiliary circuit to accelerate the transient response of the system.

2. The method of claim 1, wherein the method of implementing the auxiliary circuit further comprises:

first, a frequency compensation unit U is changed by changing a frequency compensation resistance value₃The zero point position of the frequency compensation unit U₃The system consists of a network consisting of a resistor and a capacitor element and is used for setting the positions of a zero point and a pole to realize the frequency compensation of the system;

die frequency compensation unit U₃The compensation capacitor is charged in an accelerated manner, and the charging current of the compensation capacitor is a transconductance amplifier U₁The proportion of the output current is amplified;

third, skip transconductance amplifier U₁The output error control signal increases or decreases the output energy of the system.

3. The method for accelerating the transient response of a negative feedback control system according to claim 2, wherein the proportional amplification of the output current is optional: transconductance amplifier U₁And mirror image amplification of the output current, or sending the voltage drop VR between two ends of the resistor R to another transconductance amplifier to generate the output current for charging the compensation capacitor.

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