CN212086056U - Power tube driving circuit and switching circuit - Google Patents

Abstract

The utility model discloses a power tube drive circuit and switch circuit, when the power tube is shut off, the drain-source voltage of the power tube is detected, when the power tube is an N-type device, the power tube is pulled down by a first current when the change rate of the drain-source voltage of the power tube along with time is less than a first slope threshold value; then, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value, and a driving pole of the power tube is pulled down by second current; and then when the change rate of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, the pull-down switch is conducted or the driving electrode of the power tube is pulled down by a third current.

Description

Power tube driving circuit and switching circuit

Technical Field

The utility model relates to a power electronic technology field, concretely relates to power tube drive circuit and switch circuit.

Background

The control of the turn-off process of the power devices in the switching power supply directly affects the reliability of the switching power supply. When the shutdown process of the power device is not properly processed, not only the system efficiency is low, but also the power device is damaged, and the reliability of the system is affected. Therefore, how to reliably turn off the switching device is an important issue in driving the power device.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention provides a power transistor driving circuit and a switching circuit for solving the problem that the reliability of the turn-off process of the power device in the prior art is high.

The technical solution of the present invention is to provide a power tube driving method, when the power tube is turned off, detecting the drain-source voltage of the power tube, when the power tube is an N-type device, and when the change rate of the drain-source voltage of the power tube along with time is smaller than a first slope threshold, pulling down the power tube with a first current; then, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value, and a driving pole of the power tube is pulled down by second current; then when the change rate of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, the pull-down switch is conducted or the driving electrode of the power tube is pulled down by a third current;

when the power tube is a P-type device, and the change rate of the absolute value of the drain-source voltage of the power tube along with time is smaller than a first slope threshold, a driving electrode of the power tube is pulled up by first current; then, when the change rate of the absolute value of the drain-source voltage of the power tube along with the time is larger than a first slope threshold, a driving electrode of the power tube is pulled up by second current; then, when the change rate of the absolute value of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, the pull-up switch is switched on or the driving electrode of the power tube is pulled up by a third current;

the third current is greater than the second current.

Another technical solution of the present invention is to provide a power tube driving circuit, wherein when the power tube is turned off, the power tube driving circuit detects a drain-source voltage of the power tube, and when the power tube is an N-type device, a change rate of the drain-source voltage of the power tube with time is smaller than a first slope threshold, the power tube driving circuit pulls down the power tube with a first current; then, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value, and the power tube driving circuit pulls down a driving electrode of the power tube by second current; then when the change rate of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, a pull-down switch of the power tube driving circuit is conducted or a driving electrode of the power tube is pulled down by a third current;

when the power tube is a P-type device, and the change rate of the absolute value of the drain-source voltage of the power tube along with time is smaller than a first slope threshold, the power tube driving circuit pulls up the driving electrode of the power tube by a first current; then, when the change rate of the absolute value of the drain-source voltage of the power tube along with time is larger than a first slope threshold, the power tube driving circuit pulls up the driving electrode of the power tube by a second current; then, when the change rate of the absolute value of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, a pull-up switch of the power tube driving circuit is switched on or a driving electrode of the power tube is pulled up by a third current;

the third current is greater than the second current.

Optionally, a slope detection circuit is included to detect a rate of change of the drain-source voltage of the power tube with time.

Optionally, a third pull-down circuit and a first pull-up circuit are included, and the third pull-down circuit pulls down the driving pole of the power tube with the first current;

the first pull-up circuit receives the output voltage of the slope detection circuit, and when the change rate of the drain-source voltage of the power tube along with time is smaller than a first slope threshold value, the drive electrode of the power tube is not pulled up; and when the change rate of the drain-source voltage of the power tube along with the time is larger than a first slope threshold value, pulling up the driving electrode of the power tube.

Optionally, the first pull-up circuit includes a fourth transistor and a fifth transistor, sources of the fourth transistor and the fifth transistor are connected to a driving electrode of the power tube, and a drain of the fourth transistor is connected to the driving electrode and receives the output voltage of the slope detection circuit.

Optionally, the first pull-up circuit further includes a second conduction element and a first current limiting circuit, the first current limiting circuit is connected to the drain of the fifth transistor, the second conduction element is connected between the drain of the fourth transistor and the drain of the fifth transistor, and the second conduction element is a transistor or a diode with the drain connected to the driving electrode.

Optionally, the slope detection circuit is a first capacitor, the third pull-down circuit is a fourth current source, the first current is equal to the third current, and the fourth current source is equal to the third current.

Optionally, the power tube driving circuit includes a sixth transistor, a driving electrode of the power tube is connected to a ground reference through the sixth transistor, and the sixth transistor is turned on when the driving voltage of the power tube is lower than a first voltage threshold.

Optionally, the power supply further comprises a first pull-down circuit and a second pull-down circuit, wherein the first pull-down circuit pulls down the driving electrode of the power tube with the second current; the second pull-down circuit comprises the pull-down switch;

and during the turn-off period of the power tube, when the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value and then smaller than the first slope threshold value, the pull-down switch of the second pull-down circuit is switched on.

Optionally, the second pull-down circuit includes a first transistor, a second transistor, a third transistor, a second current source, a first switch, and a first resistor, the second current source is connected in series with the first switch to form a first series circuit, a drain of the first transistor is connected to a driving electrode of the power transistor, a drain of the second transistor is connected to a driving electrode of the first transistor, the first series circuit is connected to a driving electrode of the first transistor, the driving electrode of the second transistor is connected to a reference ground through the first resistor, sources of the first transistor and the second transistor are connected to the reference ground, the driving electrode of the second transistor receives the output voltage of the slope detection circuit, the third transistor is connected between the driving electrode of the first transistor and the reference ground, when the power transistor is turned off, when the change rate of the drain-source voltage of the power tube along with the time is smaller than a first slope threshold value, the first switch is turned off, the third transistor is turned on, the second pull-down circuit is not enabled, and the first transistor does not pull down the driving electrode of the power tube; then, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value, the first switch is turned on, the third transistor is turned off, and the second pull-down circuit is enabled; then, the change rate of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold value again, and the second pull-down circuit is enabled continuously; the first transistor is the pull-down switch.

Optionally, the second pull-down circuit further includes a first conduction element, the first conduction element is connected between the driving electrode and the drain electrode of the second transistor, and the first conduction element is a transistor or a diode with the drain electrode connected to the driving electrode.

Optionally, the slope detection circuit is a first capacitor, the first pull-down circuit is a first current source, a second resistor, or a seventh transistor, and the first current source has the magnitude of the second current.

Optionally, the first capacitor is implemented by a power tube of the same type as the power tube, the first power tube has a source connected to the second pull-down circuit, and a drain connected to the drain of the power tube.

Optionally, when the power tube driver voltage is lower than a first voltage threshold, the first transistor is turned on.

Another technical solution of the present invention is to provide a switching circuit.

Adopt the utility model discloses a circuit structure and method, compared with the prior art, have following advantage: the turn-off process is fast, the reliability is high and the electromagnetic compatibility is good.

Drawings

FIG. 1 is a voltage waveform of a driver electrode with respect to a source electrode and a drain electrode with respect to the source electrode when an N-type power tube is turned off;

FIG. 2 is a voltage waveform of a driver electrode with respect to a source electrode and a drain electrode with respect to the source electrode when the P-type power transistor is turned off;

fig. 3 is a schematic circuit diagram of a power transistor driving circuit according to an embodiment of the present invention;

fig. 4 is a circuit schematic diagram of a second pull-down circuit according to an embodiment of the present invention;

fig. 5(a) is a schematic circuit diagram of a first pull-down circuit according to an embodiment of the present invention;

fig. 5(b) is a circuit schematic diagram of a first pull-down circuit according to another embodiment of the present invention;

fig. 6 is a schematic circuit diagram of a power transistor driving circuit according to another embodiment of the present invention;

fig. 7 is a schematic circuit diagram of a power transistor driving circuit according to another embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings, but the present invention is not limited to only these embodiments. The present invention covers any alternatives, modifications, equivalents, and alternatives falling within the spirit and scope of the present invention.

In the following description of the preferred embodiments of the present invention, specific details are set forth in order to provide a thorough understanding of the present invention, and it will be apparent to those skilled in the art that the present invention may be practiced without these specific details.

The invention is described in more detail in the following paragraphs by way of example with reference to the accompanying drawings. It should be noted that the drawings are simplified and in non-precise proportion, and are only used for the purpose of conveniently and clearly assisting in explaining the embodiments of the present invention.

The utility model provides a power tube driving method, please refer to fig. 1, the driver when N type power tube is turn-off is relative to source Vgs and the drain electrode is relative to the voltage waveform of source Vds. When the power tube is turned off, detecting drain-source voltage Vds of the power tube, and when the power tube is an N-type device, in an interval of t01-t02, and when the change rate of the drain-source voltage Vds of the power tube along with time is smaller than a first slope threshold value, pulling down the power tube by first current; then, in an interval from t02 to t03, the change rate of the drain-source voltage Vds of the power tube along with the time is larger than a first slope threshold value, and a driving pole of the power tube is pulled down by a second current; then after t03, when the change rate of the drain-source voltage Vds of the power tube with time is smaller than the first slope threshold value again, the pull-down switch is turned on or the driving electrode of the power tube is pulled down by a third current;

referring to fig. 2, when the power transistor is a P-type device, in an interval t11-t12, when a time-dependent change rate of an absolute value of a drain-source voltage of the power transistor is smaller than a first slope threshold, a driving electrode of the power transistor is pulled up by a first current; then, in a period t12-t13, when the change rate of the absolute value of the drain-source voltage of the power tube along with the time is larger than a first slope threshold value, the driving pole of the power tube is pulled up by a second current; then, after t13, when the time-dependent rate of change of the absolute value of the drain-source voltage of the power tube is smaller than the first slope threshold again, the pull-up switch is turned on or the driving electrode of the power tube is pulled up by a third current;

and when the power tube is of an N type or a P type, the third current is larger than the second current. The first current may be equal to the second current, or may be any fixed current value.

By detecting the slope of the drain-source voltage of the power tube and adopting different currents to drive the power tube according to different stages of the power tube, the turn-off process of the power tube is reliable and fast, and the electromagnetic compatibility of the system is excellent.

Another technical solution of the present invention is to provide a power tube driving circuit, please refer to fig. 1, when the power tube is turned off, the power tube driving circuit detects a drain-source voltage Vds of the power tube, and when the power tube is an N-type device, in a range from t01 to t02, a rate of change of the drain-source voltage Vds of the power tube with time is smaller than a first slope threshold, the power tube driving circuit pulls down the power tube with a first current; then, in an interval from t02 to t03, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold, and a power tube driving circuit pulls down a driving electrode of the power tube by a second current; then, after t03, when the time-dependent rate of change of the drain-source voltage of the power tube is again smaller than the first slope threshold, the pull-down switch of the power tube driving circuit is turned on or the driving electrode of the power tube is pulled down by a third current.

Referring to fig. 2, when the power transistor is a P-type device, in an interval t11-t12, when a time-dependent change rate of an absolute value of a drain-source voltage of the power transistor is smaller than a first slope threshold, the power transistor driving circuit pulls up a driving electrode of the power transistor with a first current; then, in a period t12-t13, when the change rate of the absolute value of the drain-source voltage of the power tube along with the time is larger than a first slope threshold, the power tube driving circuit pulls up the driving electrode of the power tube by a second current; then, after t13, when the time-dependent rate of change of the absolute value of the drain-source voltage of the power tube is again smaller than the first slope threshold, the pull-up switch of the power tube driving circuit is turned on or the driving electrode of the power tube is pulled up by a third current.

And when the power tube is of an N type or a P type, the third current is larger than the second current. The first current may be equal to the second current, or may be any fixed current value.

It should be noted that, in an N-type device, the source is generally connected to a ground reference or connected to the ground reference through a resistor, so that the drain-source voltage of the power transistor can be characterized by detecting the drain voltage of the power transistor. In the P-type device, the source is generally connected to the power supply terminal or connected to the power supply terminal through a resistor, and the drain-source voltage of the power transistor can also be characterized by detecting the drain voltage of the power transistor.

In one embodiment, the power tube driving circuit comprises a slope detection circuit which detects the change rate of the drain-source voltage of the power tube along with time. The slope detection circuit is a first capacitor.

In one embodiment, for an N-type power tube, the power tube driving circuit further comprises a first pull-down circuit and a second pull-down circuit, wherein the first pull-down circuit pulls down a driving electrode of the power tube at the second current; the second pull-down circuit comprises the pull-down switch; and during the turn-off period of the power tube, when the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value and then smaller than the first slope threshold value, the pull-down switch of the second pull-down circuit is switched on. That is to say, when the power tube is turned off and the change rate of the drain-source voltage of the power tube along with the time is smaller than the first slope threshold, the second pull-down circuit does not pull down the driving electrode of the power tube; then, the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold, and the second pull-down circuit does not pull down the driving electrode of the power tube; and then when the change rate of the drain-source voltage of the power tube along with time is smaller than a first slope threshold value, a pull-down switch of the second pull-down circuit is switched on. The first pull-down circuit is a first current source, and the magnitude of the first current source is the second current. In another embodiment, the first pull-down circuit is a second resistor or a seventh transistor.

Referring to fig. 3, in an embodiment, the second pull-down circuit includes a first transistor M11, a second transistor M12, a third transistor M13, a second current source I12, a first switch K11 and a first resistor R11, the second current source I12 is connected in series with the first switch K11 to form a first series circuit, a drain of the first transistor M11 is connected to a driving electrode of the power transistor, a drain of the second transistor M12 is connected to a driving electrode of the first transistor M11, the first series circuit is connected to a driving electrode of the first transistor M11, the driving electrode of the second transistor M12 is connected to a reference ground through the first resistor R11, sources of the first transistor M11 and the second transistor M12 are connected to a reference ground, the driving electrode of the second transistor M12 receives an output voltage of the slope detection circuit, the third transistor M39m 13 is connected between the driving electrode of the first transistor and the reference ground, when the power tube is turned off, in an interval t01-t02 of fig. 1, when the rate of change of the drain-source voltage of the power tube with time is smaller than a first slope threshold, the first switch K11 is turned off, the third transistor M13 is turned on, the second pull-down circuit is not enabled, and the first transistor M11 does not pull down the driving electrode of the power tube; the first pull-down circuit pulls down a driving electrode of a power tube M01 by a first current, then, in an interval of t02-t03, the change rate of the drain-source voltage Vds of the power tube along with time is larger than a first slope threshold value, the first switch K11 is turned on, the third transistor M13 is turned off, and the second pull-down circuit is enabled; however, since the rate of change of the drain-source voltage Vds of the power transistor with time is greater than the first slope threshold, the slope detection circuit pulls up the second pull-down circuit, the driving electrode of the second transistor M12 is pulled up, the second transistor is turned on, the first transistor M11 is turned off, the second pull-down circuit still does not pull down the driving electrode of the power transistor M01, and only the first pull-down circuit pulls down the driving electrode of the power transistor M01 with the second current. Preferably, the first current is equal to the second current. Then, after t03, the change rate of the drain-source voltage of the power tube along with the time is smaller than a first slope threshold value, and the second pull-down circuit is enabled continuously; the slope detection circuit does not pull up the second pull-down circuit, the driving electrode of the second transistor M12 is pulled down by the first resistor R11, the second transistor M12 is turned off, the second current source I12 pulls up the driving electrode of the first transistor M11, the first transistor M11 is turned on, and the driving electrode of the power tube M01 is pulled down rapidly through the first transistor M11. The first transistor M11 is the pull-down switch.

The second pull-down circuit further includes a first logic circuit that receives the output voltage of the slope detection circuit and controls the first switch K11 and the third transistor M13 to be turned on and off, thereby controlling the enable of the second pull-down circuit.

In one embodiment, the first capacitor C11 is implemented by a power transistor of the same type as the power transistor, and the first power transistor has a source connected to the second pull-down circuit and a drain connected to the drain of the power transistor. The driving electrode and the source electrode of the first power tube are short-circuited or the source electrode of the first power tube is connected to the reference ground.

As shown in fig. 3, the power transistor driving circuit further includes a comparison circuit, the comparison circuit receives the voltage of the M01 driver, the first logic circuit receives the output voltage of the comparator, the comparison circuit compares the voltage of the M01 driver with a first voltage threshold, when the voltage of the M01 driver is lower than the first voltage threshold, the output of the comparison circuit is inverted, the first logic circuit controls the third transistor to turn off, the first switch K11 to turn on, and the first transistor M11 to turn on.

As shown in fig. 3, the second pull-down circuit further includes a first conducting element, which can be implemented by a transistor M14, a gate and a drain of the transistor M14 are connected, a source of the transistor M14 is connected to a drain of the second transistor M12, and a drain of the transistor M14 is connected to a gate of the second transistor M12. The transistor M14 is connected in the form of a diode. In the interval from t02 to t03, the transistor M14 acts as a diode to pull the driving electrode of the first transistor M11 to the vicinity of the turn-on threshold voltage, so that the first transistor M11 is turned on more quickly at time t 03. Referring to fig. 4, the first turn-on element may also be connected between the drain and the gate of the second transistor M12 with a diode D11.

Referring to fig. 5(a) and 5(b), in one embodiment, the first pull-down circuit is the second resistor R12 or the seventh transistor M17.

Referring to fig. 6, in an embodiment, the power transistor includes a third pull-down circuit and a first pull-up circuit, where the third pull-down circuit pulls down the driver of the power transistor with the first current; the first pull-up circuit receives the output of the slope detection circuit, and does not pull up the driving electrode of the power tube when the change rate of the drain-source voltage of the power tube M01 along with the time is smaller than a first slope threshold value; when the change rate of the drain-source voltage of the power tube M01 along with the time is larger than a first slope threshold value, the driving pole of the power tube is pulled up.

Referring to fig. 6, the slope detection circuit is a first capacitor, the third pull-down circuit is a fourth current source I21, the first current is equal to the third current, and the magnitude of the fourth current source I21 is equal to the third current.

With continued reference to fig. 6, the first pull-up circuit includes a fourth transistor M21 and a fifth transistor M22, the fourth transistor M21 and the fifth transistor M22 form a mirror current mirror, sources of the fourth transistor M21 and the fifth transistor M22 are connected to a driving electrode of the power transistor M01, and a drain of the fourth transistor M21 is connected to the driving electrode, and receives the output voltage of the slope detection circuit. When the power transistor M01 is turned off, in the interval t01-t02 of fig. 1, the slope detection circuit does not pull up the drain of the fourth transistor M21, no current flows through the fourth transistor M21 and the fifth transistor M22, the first pull-up circuit does not pull up the driving electrode of the power transistor, and the third pull-down current pulls down the driving electrode of the power transistor by the first current; in the interval t02-t03 in fig. 1, when the change rate of the drain-source voltage of the power tube M01 with time is greater than a first slope threshold, the slope detection circuit pulls up the drain of the fourth transistor M21, the first pull-up circuit pulls up the driving electrode of the power tube M01, the third pull-down circuit pulls down the driving electrode of the power tube M01, and the difference between the pull-down current of the third pull-down circuit and the pull-up current of the first pull-up circuit is a second current; after the interval t03 in fig. 1, since the rate of change of the drain-source voltage of the power transistor M01 with time is smaller than the first slope threshold, the slope detection circuit does not pull up the drain of the fourth transistor M21, no current flows through the fourth transistor M21 and the fifth transistor M22, the first pull-up circuit does not pull up the driver of the power transistor, the third pull-down current pulls down the driver of the power transistor with the third current, and the third current is equal to the first current.

With continued reference to fig. 6, in order to increase the turn-off speed after t03 when the voltage of the power tube driver is lower than the first voltage threshold, the power tube driver circuit further includes a sixth transistor M24, the driver of the power tube is connected to the ground reference through the sixth transistor M24, and when the voltage of the power tube driver is lower than the first voltage threshold, the sixth transistor is turned on. The power tube driving circuit further comprises a comparison circuit, the comparison circuit receives the voltage of a driving electrode of the power tube M01, the comparison circuit compares the voltage of the driving electrode of the power tube M01 with a first voltage threshold value, when the voltage of the driving electrode of the power tube is lower than the first voltage threshold value, the output of the comparison circuit controls the conduction of the sixth transistor, and therefore the pull-down speed of the driving electrode of the power tube M01 is greatly increased.

As shown in fig. 6, the first pull-up circuit further includes a second conducting element and a first current limiting circuit, the first current limiting circuit is connected to the drain of the fifth transistor M22, the second conducting element can be implemented by a transistor M23, the gate and the drain of the transistor M23 are connected, the source of the transistor M23 is connected to the drain of the transistor M22, and the drain of the transistor M23 is connected to the drain of the transistor M21. The transistor M23 is diode connected so that the gate of the current mirror does not rise too high, thereby turning off the pull-up current faster when the output current of the slope detection circuit is low. The second pass element may also be implemented as a diode connected between the drain of transistor M22 and the drain of transistor M21. The first current limiting circuit may be a current source or a resistor or a transistor.

Fig. 7 shows another embodiment of a power transistor driving circuit. The power tube driving circuit comprises a first pull-down circuit, a second pull-down circuit and a slope detection circuit. The slope detection circuit receives the drain voltage of the power tube M01, the first pull-down circuit receives the output voltage of the slope detection circuit, and the first pull-down circuit and the second pull-down circuit are both connected to the driving electrode and the source electrode of the power tube M01. The first pull-down circuit comprises a current source I31, the second pull-down circuit comprises a transistor M31, the output of the slope detection circuit is connected to the gate of the transistor M31, the source of the transistor M31 is connected to the source of the power tube M01, and the drain of the transistor M31 is connected to the driving electrode of the power tube M01.

When the power transistor M01 is turned off, in the interval t01-t02 of fig. 1, the output of the slope detection circuit is low, the transistor M31 is turned off, the first pull-down circuit pulls down the driving electrode of the power transistor M01, and the second pull-down circuit does not pull down the driving electrode of the power transistor M01; in the interval t02-t03 in fig. 1, when the change rate of the drain-source voltage of the power tube M01 along with time is greater than the first slope threshold, the output of the slope detection circuit is low, the second pull-down circuit does not pull down the driving electrode of the power tube M01, the first pull-down circuit pulls down the driving electrode of the power tube, and the pull-down current is the second current; after the interval t03 in fig. 1, since the rate of change of the drain-source voltage of the power transistor M01 with time is smaller than the first slope threshold, the output of the slope detection circuit is high, and the second pull-down circuit and the first pull-down circuit both pull down the driving electrode of the power transistor. It should be noted that after the interval t01-t02 and the interval t03 in fig. 1, the rate of change of the drain-source voltage of the power tube M01 with time is smaller than the first slope threshold, but in the interval t01-t02, the output of the slope detection circuit is low; after the interval t03, the slope detection circuit output is high. That is, the slope detection circuit not only adjusts the output according to the drain-source voltage of the power transistor M01, but also adjusts the output according to the timing. For example, the slope detection circuit needs to output a high voltage when the change rate of the drain-source voltage of the power transistor M01 with time is greater than a first slope threshold and then smaller than the first slope threshold.

Another technical solution of the present invention is to provide a switching circuit, including the driving circuit of the above power transistor.

Although the embodiments have been described and illustrated separately, it will be apparent to those skilled in the art that some common techniques may be substituted and integrated between the embodiments, and reference may be made to one of the embodiments not explicitly described, or to another embodiment described.

The above-described embodiments do not limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the above-described embodiments should be included in the protection scope of the technical solution.

Claims (9)

1. A power tube driving circuit is characterized in that: the power tube driving circuit comprises a slope detection circuit, a third pull-down circuit and a first pull-up circuit;

when the power tube is switched off, the power tube driving circuit detects the drain-source voltage of the power tube, when the power tube is an N-type device,

the slope detection circuit detects the change rate of the drain-source voltage time of the power tube;

the third pull-down circuit pulls down the driving pole of the power tube by a first current;

the first pull-up circuit receives the output voltage of the slope detection circuit, and when the slope detection circuit detects that the change rate of the drain-source voltage of the power tube along with time is smaller than a first slope threshold value, the drive electrode of the power tube is not pulled up; the power tube driving circuit pulls down the power tube by a first current; when the slope detection circuit detects that the change rate of the drain-source voltage of the power tube along with time is larger than a first slope threshold value, the first pull-up circuit pulls up the driving electrode of the power tube, and the power tube driving circuit pulls down the power tube with a second current.

2. The power transistor driving circuit of claim 1, wherein: the first pull-up circuit comprises a fourth transistor and a fifth transistor, sources of the fourth transistor and the fifth transistor are connected to a driving electrode of the power tube, and a drain electrode of the fourth transistor is connected with the driving electrode and receives the output voltage of the slope detection circuit.

3. The power transistor driving circuit of claim 2, wherein: the first pull-up circuit further includes a second turn-on element and a first current limiting circuit, the first current limiting circuit being connected to the drain of the fifth transistor, the second turn-on element being connected between the drain of the fourth transistor and the drain of the fifth transistor, the second turn-on element being a transistor or a diode having a drain connected to the driver.

4. The power transistor driving circuit of claim 3, wherein: the slope detection circuit is a first capacitor, and the third pull-down circuit is a fourth current source.

5. The power transistor driving circuit of claim 2, wherein: the power tube driving circuit comprises a sixth transistor, a driving electrode of the power tube is connected to the reference ground through the sixth transistor, and when the driving electrode voltage of the power tube is lower than a first voltage threshold value, the sixth transistor is conducted.

6. A power tube driving circuit is characterized in that: the power tube driving circuit comprises a slope detection circuit, a first pull-down circuit and a second pull-down circuit;

the slope detection circuit detects the change rate of the drain-source voltage time of the power tube;

the first pull-down circuit pulls down a driving pole of the power tube by a second current; the second pull-down circuit comprises a pull-down switch;

and during the turn-off period of the power tube, when the slope detection circuit detects that the change rate of the drain-source voltage of the power tube along with the time is larger than a first slope threshold value and then smaller than the first slope threshold value, the pull-down switch of the second pull-down circuit is switched on.

7. The power transistor driving circuit of claim 6, wherein: the second pull-down circuit comprises a first transistor, a second transistor, a third transistor, a second current source, a first switch and a first resistor, the second current source is connected in series with the first switch to form a first series circuit, the drain electrode of the first transistor is connected to the driving electrode of the power tube, a drain of the second transistor is connected to a driver of the first transistor, the first series circuit is connected to the driver of the first transistor, a driving electrode of the second transistor is connected to a reference ground through the first resistor, sources of the first transistor and the second transistor are connected to the reference ground, the driving electrode of the second transistor receives the output voltage of the slope detection circuit, the third transistor is connected between the driving electrode of the first transistor and the reference ground, and the first transistor is the pull-down switch.

8. The power transistor driving circuit of claim 7, wherein: the second pull-down circuit further comprises a first conduction element, the first conduction element is connected between the driving electrode and the drain electrode of the second transistor, and the first conduction element is a transistor or a diode with the drain electrode connected with the driving electrode.

9. A switching circuit, characterized by: the power tube driving circuit comprises the power tube driving circuit as claimed in any one of claims 1 to 5.

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