CN112946351B - Negative follow current monitoring circuit - Google Patents

Abstract

A negative afterflow current monitoring circuit comprises an NMOS power switch tube and an inductive load driven by the NMOS power switch tube through a first node and a second node, wherein the NMOS power switch tube is connected with a closed negative feedback current acquisition circuit; the closed negative feedback current acquisition circuit and the NMOS power switch tube jointly form a closed negative feedback current acquisition loop, the closed negative feedback current acquisition loop monitors and acquires negative follow current flowing through the NMOS power switch tube, the closed negative feedback current acquisition loop acquires the negative follow current flowing through the NMOS power switch tube and converts the negative follow current into positive current of a corresponding proportion to replace an open-loop comparator to monitor the attenuation process of the negative follow current, particularly the zero crossing point of the negative follow current after attenuation is finished, the structure is simple, the design cost is reduced, the closed-loop detection speed is high, the anti-jamming capability is high, and the converted positive current of the corresponding proportion is convenient for subsequent processing, such as comparison with reference current, and then the negative follow current is judged and controlled.

Description

Negative follow current monitoring circuit

Technical Field

The invention relates to a negative afterflow current monitoring technology, in particular to a negative afterflow current monitoring circuit.

Background

The most remarkable characteristic of the MOS power switch is that the MOS power switch has good switching characteristics, and therefore, the MOS power switch is widely used in a circuit requiring an electronic switch. As shown in fig. 1, in a circuit that drives an inductive load L with an NMOS power switching tube Mpwr, due to the fact that an inductive load current of an inductive load, such as a motor, a solenoid valve, etc., flows in a negative direction, when the NMOS power switching tube Mpwr is turned on, a negative-direction freewheeling current Iload flows from a second node B to a first node a, at this time, the on internal resistance of the NMOS power switching tube Mpwr is Rpwr, a voltage difference VAB = -wr i.e., a voltage difference between the first node a and the second node B at both ends of the NMOS power switching tube Mpwr is i.e., rpwr <0, and thus the negative-direction freewheeling current Iload is a negative-direction freewheeling current in a circuit from the first node a to the second node B at this time. Some actions of the NMOS power switch tube Mpwr need to be triggered by, for example, a zero crossing point after the attenuation is finished according to the attenuation condition of the negative-going freewheeling current Iload. In the prior art, the technical scheme for monitoring the zero crossing point of the negative afterflow current Iload after attenuation is that an open-loop comparator is used for detecting and judging the potential of a first node A, and when VAB =0V, the negative afterflow current Iload is indicated to be completely attenuated. Specifically, as shown in fig. 2, the open-loop comparator comp has a positive input connected to the first node a and a negative input set to 0V (or ground), i.e., a zero-crossing comparator is constructed by the open-loop comparator comp, and the zero-crossing comparator has a certain measurement error in the measurement mode. Therefore, the scheme has the following disadvantages: 1. because the swing range of the first node a is extremely large and the swing speed is extremely high, the requirement on the input stage of the open-loop comparator comp is high, and the design cost is increased; 2. when the on-resistance Rpwr of the NMOS power switching tube Mpwr is extremely low (possibly in the order of m omega), or the negative follow current Iload is very small, or the negative follow current Iload is attenuated to be very small, VAB = -Rpwr Iload, the voltage difference between the first node A and the second node B is very small, so that the precision requirement of the open-loop comparator comp is very high, and once the precision of the open-loop comparator does not meet the requirement, the judgment accuracy of the zero crossing point is greatly influenced; 3. the scheme is an open-loop monitoring process, has low anti-interference performance to the environment and is low in judgment speed.

Disclosure of Invention

In order to solve the problems, the invention provides a negative follow current monitoring circuit, which adopts a closed negative feedback loop to collect negative follow current and convert the negative follow current into positive current with corresponding proportion to replace an open-loop comparator to monitor the attenuation process of the negative follow current, in particular to a zero crossing point of the negative follow current after attenuation is finished.

The invention is realized by the following technical scheme:

a negative afterflow current monitoring circuit comprises an NMOS power switch tube and an inductive load driven by the NMOS power switch tube through a first node and a second node, and is characterized in that the NMOS power switch tube is connected with a closed negative feedback current acquisition circuit, the closed negative feedback current acquisition circuit and the NMOS power switch tube jointly form a closed negative feedback current acquisition loop, and the closed negative feedback current acquisition loop monitors and acquires the negative afterflow current flowing through the NMOS power switch tube.

Preferably, the closed negative feedback current collecting circuit comprises an NMOS current sampling tube, the NMOS current sampling tube is interconnected with the gate of the NMOS power switch tube and is connected to a high level, the NMOS current sampling tube is connected with the drain of the NMOS power switch tube at the first node, the source of the NMOS power switch tube is connected with the second node, and the source of the NMOS current sampling tube is connected with the third node; the third node is connected with the drain electrode of the second NMOS tube, the source electrode of the first NMOS current input tube and the substrate, and the drain electrode of the first NMOS current input tube is connected with the working voltage through a first current source; the second node is connected with a source electrode of a second NMOS current input tube, and a drain electrode of the second NMOS current input tube is connected with a working voltage through a second current source; the grid electrodes of the first NMOS current input tube and the second NMOS current input tube are interconnected; the second node is connected to the drain electrode of the second NMOS tube through a third current source, the grid electrode of the second NMOS tube is connected with the drain electrode of the second NMOS current input tube, the source electrode of the second NMOS tube is connected with the drain electrode of a third PMOS tube, the source electrode and the substrate of the third PMOS tube are connected with a working voltage, the grid electrodes of the third PMOS tube and a fourth PMOS tube are interconnected, the source electrode of the fourth PMOS tube is connected with the working voltage, the first current source, the second current source, the first NMOS current input tube, the second NMOS tube and the third PMOS tube jointly act to enable the potentials of the third node and the second node to be equal, and negative follow current is led out from the drain electrode of the fourth PMOS tube and converted into positive current in corresponding proportion.

Preferably, the size ratio of the third PMOS transistor to the fourth PMOS transistor is 1:1.

preferably, the output currents of the first current source and the third current source are much smaller than the current flowing through the NMOS current sampling tube.

Preferably, the output currents of the first current source and the second current source are equal, and the size ratio of the first NMOS current input tube to the second NMOS current input tube is 1:1.

compared with the prior art, the invention has the advantages that: the negative follow current monitoring circuit provided by the invention has the advantages that the closed negative feedback current acquisition circuit and the NMOS power switch tube jointly form a closed negative feedback current acquisition loop, the negative follow current flowing through the NMOS power switch tube is acquired and converted into the positive current with the corresponding proportion to replace an open-loop comparator to monitor the attenuation process of the negative follow current, particularly the zero crossing point of the negative follow current after the attenuation is finished, the structure is simple, the design cost is reduced, the closed-loop detection speed is high, the anti-jamming capability is strong, and the converted positive current with the corresponding proportion is convenient for subsequent processing, such as comparison with a reference current, so that the negative follow current is judged and controlled.

Drawings

FIG. 1 is a schematic diagram of a negative-going freewheeling circuit for an inductive load driven by an NMOS power switch transistor;

FIG. 2 is a diagram of a conventional method for monitoring negative freewheeling current in an inductive load driven by an NMOS power switch with an open-loop comparator;

fig. 3 is a schematic diagram of a negative-direction follow current monitoring circuit according to the present invention.

The various reference numbers in the figures are listed below: mpwr-NMOS power switch tube; an L-inductive load; iload-negative freewheeling current; a-a first node; b-a second node; c-a third node; phi-high potential point; a Msen-NMOS current sampling tube; m1 a-a first NMOS current input tube; m1 b-a second NMOS current input tube; m2-a second NMOS tube; m3-a third PMOS tube; m4-a fourth PMOS tube; isen — first sample current; i2-a second sampling current; i3-a third sampling current; i4-a fourth sampling current; ib 1-a first current source; ib 2-a second current source; ib 3-a third current source; vcc — operating voltage.

Detailed Description

In order to facilitate an understanding of the invention, the invention is described in more detail below with reference to the accompanying drawings and specific examples.

The negative follow current monitoring circuit comprises an NMOS power switch tube Mpwr driving inductive load L, wherein the NMOS power switch tube is connected with a closed negative feedback current acquisition circuit; the closed negative feedback current acquisition circuit and the NMOS power switch tube jointly form a closed negative feedback current acquisition loop, and the closed negative feedback current acquisition loop monitors and acquires negative follow current flowing through the NMOS power switch tube.

Specifically, the NMOS power switch tube Mpwr extracts the negative freewheeling current Iload through the NMOS current sampling tube Msen connected to the NMOS power switch tube Mpwr in a mirror image manner, and transmits the negative freewheeling current Iload to the drain of the fourth PMOS tube M4 through the second NMOS tube M2, the third PMOS tube M3 and the fourth PMOS tube M4. Further, the closed negative feedback current collection circuit comprises an NMOS current sampling tube Msen, the gate of the NMOS current sampling tube Msen and the gate of the NMOS power switch tube Mpwr are interconnected and connected with a high level Φ, the drain of the NMOS current sampling tube Msen and the drain of the NMOS power switch tube Mpwr are connected to the first node a, the source of the NMOS power switch tube Mpwr is connected to the second node B, and the source of the NMOS current sampling tube Msen is connected to a third node C; the third node C is connected with the drain electrode of the second NMOS transistor M2 and the source electrode and the substrate of the first NMOS current input transistor M1a, and the drain electrode of the first NMOS current input transistor M1a is connected to the working voltage Vcc through a first current source Ib 1; the second node B is connected with the source electrode of a second NMOS current input tube M1B, and the drain electrode of the second NMOS current input tube M1B is connected with the working voltage Vcc through a second current source Ib 2; the gates of the first and second NMOS current input transistors M1a, M1b are interconnected. The second node B is connected to the drain of the second NMOS transistor M2 through a third current source Ib3, and output currents of the first current source Ib1 and the third current source Ib3 are much smaller than a first sampling current Isen flowing through the NMOS current sampling transistor; the grid electrode of the second NMOS tube M2 is connected with the drain electrode of the second NMOS current input tube M2b, the source electrode of the second NMOS tube M2 is connected with the drain electrode of a third PMOS tube M3, the source electrode and the substrate of the third PMOS tube M3 are connected with a working voltage Vcc, the grid electrodes of the third PMOS tube M3 and a fourth PMOS tube M4 are interconnected, the source electrode of the fourth PMOS tube M4 is connected with the working voltage Vcc, and negative follow current is finally transmitted out from the drain electrode of the fourth PMOS tube M4. The first current source Ib1, the second current source Ib2, the first NMOS current input tube M1a, the second NMOS current input tube M1B, the second NMOS tube M2, and the third PMOS tube M3 work together to make the potentials of the third node C and the second node B equal. Since the potentials of the third node C and the second node B are equal, and the Φ point is a high level, the potentials of the source, the gate and the drain of the NMOS current sampling tube and the NMOS power switching tube are respectively equal, so that the first sampling current Isen flowing through the NMOS current sampling tube is equal to an integer K times of the negative freewheeling current Iload flowing through the NMOS power switching tube, that is, isen = K · Iload, where K is a size ratio of the NMOS current sampling tube to the NMOS power switching tube.

Since the current I2= Ib3+ (Isen-Ib 1) flowing through the second NMOS transistor, where Ib1, ib3 are much smaller than Isen, when the size ratio of the third PMOS transistor M3 to the fourth PMOS transistor M4 is 1: when 1, a third sampling current I3 flowing through the third PMOS transistor M3, a fourth sampling current I4 flowing through the fourth PMOS transistor M4, a current I2 flowing through the second NMOS transistor, and a first sampling current Isen flowing through the NMOS current sampling transistor are equal, i.e., I4= I3= I2= Isen = -K · Iload, that is, a negative follow current Iload is collected from a drain electrode of the fourth PMOS transistor M4 through a closed negative feedback current collection loop and converted into a positive current in a corresponding proportion. If no current is detected at the drain end of the fourth PMOS transistor M4, no negative freewheeling current exists in the circuit of the inductive load driven by the NMOS power switch transistor, i.e., the current collected by the closed negative feedback current collection loop is 0 at this time.

Preferably, the output currents of the first current source and the second current source are equal, and the size ratio of the first NMOS current input tube to the second NMOS current input tube is 1:1.

it should be noted that the above-described embodiments may enable those skilled in the art to more fully understand the present invention, but do not limit the present invention in any way. Therefore, although the present invention has been described in detail with reference to the drawings and examples, it should be understood by those skilled in the art that the present invention may be modified and replaced by other equivalent elements, and it should be understood that all the technical solutions and modifications which do not depart from the spirit and scope of the present invention are covered by the protection scope of the present patent.

Claims (3)

1. A negative afterflow current monitoring circuit comprises an NMOS power switch tube and an inductive load driven by the NMOS power switch tube through a first node and a second node, and is characterized in that the NMOS power switch tube is connected with a closed negative feedback current acquisition circuit, the closed negative feedback current acquisition circuit and the NMOS power switch tube jointly form a closed negative feedback current acquisition loop, and the closed negative feedback current acquisition loop monitors and acquires the negative afterflow current flowing through the NMOS power switch tube; the closed negative feedback current acquisition circuit comprises an NMOS current sampling tube, the NMOS current sampling tube is interconnected with the grid electrode of the NMOS power switch tube and is connected with a high level, the drain electrodes of the NMOS current sampling tube and the NMOS power switch tube are connected with the first node, the source electrode of the NMOS power switch tube is connected with the second node, and the source electrode of the NMOS current sampling tube is connected with the third node; the third node is connected with the source electrode of the second NMOS tube, the source electrode of the first NMOS current input tube and the substrate, and the drain electrode of the first NMOS current input tube is connected with the working voltage through a first current source; the second node is connected with a source electrode of a second NMOS current input tube, and a drain electrode of the second NMOS current input tube is connected with a working voltage through a second current source; the grid electrodes of the first NMOS current input tube and the second NMOS current input tube are interconnected; the second node is connected to the source electrode of the second NMOS tube through a third current source, the grid electrode of the second NMOS tube is connected with the drain electrode of the second NMOS current input tube, the drain electrode of the second NMOS tube is connected with the drain electrode of a third PMOS tube, the source electrode and the substrate of the third PMOS tube are connected with a working voltage, the grid electrodes of the third PMOS tube and a fourth PMOS tube are interconnected, the source electrode of the fourth PMOS tube is connected with the working voltage, the first current source, the second current source, the first NMOS current input tube, the second NMOS tube and the third PMOS tube jointly act to enable the potentials of the third node and the second node to be equal, and negative follow current is led out from the drain electrode of the fourth PMOS tube and converted into positive current in corresponding proportion; the output currents of the first current source and the third current source are far smaller than the current flowing through the NMOS current sampling tube.

2. The negative freewheeling current monitoring circuit of claim 1, wherein the size ratio of the third PMOS transistor to the fourth PMOS transistor is 1:1.

3. the negative-going freewheel current monitoring circuit according to claim 1, characterized in that, the output current of the first current source is equal to the output current of the second current source, and the size ratio of the first NMOS current input tube and the second NMOS current input tube is 1:1.

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