CN209184565U - A kind of current detection circuit of loudspeaker - Google Patents

Abstract

The utility model discloses a kind of current detection circuit of loudspeaker, including the first detection resistance, the second detection resistance, sampling selection circuit, input selection circuit and processing circuit；One end of first detection resistance is connected with the first input end of the input selection circuit；One end of second detection resistance is connected with the second input terminal of the input selection circuit；The output end of the sampling selection circuit is connected with the switch control terminal of the input selection circuit；The input selection circuit is connected with the processing circuit.The utility model is by increasing sampling selection circuit and input selection circuit, the different half periods are according to the potential difference of the output stage VOP of D-type audio power amplifier and output stage VON, sample the voltage at corresponding detection resistance both ends, and the electric current of loudspeaker is obtained by processing, so as to realize the detection for loudspeaker electric current, and without cutting top distortion function to D-type audio power amplifier addition is anti-, it ensure that the performance of D-type audio power amplifier.

Description

A kind of current detection circuit of loudspeaker

Technical field

The utility model relates to technical field of current detection more particularly to a kind of current detection circuits of loudspeaker.

Background technique

Currently, D-type audio power amplifier is widely used due to having the advantages that high-efficient, small and performance of generating heat is good In the portable devices such as Baffle Box of Bluetooth and mobile phone.

But due to portable device pursuit is small and exquisite, internal loudspeaker cavity is smaller, so biggish in broadcast sound volume When music, when especially big supper bass song, it is excessively high that loudspeaker cavity may be displaced excessive or loudspeaker temperature because of vibrating diaphragm Reason and damage, so generally can give D-type audio power amplifier design current detection circuit, so as to according to loudspeaker electric current Size control D-type audio power amplifier output electric current size, and then protect loudspeaker will not because vibrating diaphragm be displaced it is excessive or Loudspeaker temperature is excessively high and damages.But when larger due to the output power of D-type audio power amplifier, it may occur that top phenomenon is cut, The current potential of its output stage VOP or the current potential of output stage VON may be continuous height occur in several pulse-width modulation frequencies Level or low level, general electric current detecting method is difficult accurate detection and goes out loudspeaker electric current at this time, so usually requiring that D assonance Frequency power amplifier cuts top distortion function plus anti-, i.e., actively limits the output power of D-type audio power amplifier, make its output Top is not cut.

But top distortion function is cut plus anti-in D-type audio power amplifier, D-type audio power amplifier will be reduced Output power, without playing the performance of D-type audio power amplifier to greatest extent.

Utility model content

In view of this, the utility model embodiment provides a kind of current detection circuit of loudspeaker, to solve detection loudspeaker electricity When stream, the problem of sacrificing the performance of D-type audio power amplifier.

To achieve the above object, the utility model embodiment provides the following technical solutions:

A kind of current detection circuit of loudspeaker, suitable for the loudspeaker being connected with D-type audio power amplifier, the loudspeaker Current detection circuit includes: the first detection resistance, the second detection resistance, sampling selection circuit, input selection circuit and processing electricity Road；Wherein:

One end of first detection resistance is connected with the first input end of the input selection circuit, and tie point is as institute The first input end for stating the current detection circuit of loudspeaker, the low side NMOS with the output stage VON of the D-type audio power amplifier The source electrode of transistor is connected；

One end of second detection resistance is connected with the second input terminal of the input selection circuit, and tie point is as institute The second input terminal for stating the current detection circuit of loudspeaker, the low side NMOS with the output stage VOP of the D-type audio power amplifier The source electrode of transistor is connected；

The other end and the input selection circuit of the other end of first detection resistance, second detection resistance Third input terminal, be grounded；

First output end of the input selection circuit is connected with the first input end of the processing circuit；The input choosing The second output terminal for selecting circuit is connected with the second input terminal of the processing circuit；

The output end of the processing circuit is the output end of the current detection circuit of the loudspeaker；

It is described sampling selection circuit three input terminals respectively with sampling clock, the output stage VOP and the output stage VON is connected；

The output end of the sampling selection circuit is connected with the switch control terminal of the input selection circuit；

The output end of the sampling selection circuit, the switch control of output switch control signal to the input selection circuit End；When the potential difference of the output stage VOP and the output stage VON are located at positive half period, the switch control signal control The first input end of the input selection circuit forms logical with the first output end formation access, third input terminal and second output terminal Road；When the potential difference of the output stage VOP and the output stage VON are located at negative half-cycle, the switch control signal control The third input terminal of the input selection circuit forms logical with the first output end formation access, the second input terminal and second output terminal Road.

Optionally, the input selection circuit, comprising: first switch, second switch, third switch, the 4th switch and control Molding block；Wherein:

First input end of the first end of the first switch as the input selection circuit；The of the second switch Second input terminal of the one end as the input selection circuit；The first of the first end of the third switch and the 4th switch End is connected, third input terminal of the tie point as the input selection circuit；

The second end of the first switch is connected with the second end that third switchs, and tie point is as the input selection circuit The first output end；The second end of the second switch is connected with the second end of the 4th switch, and tie point is selected as the input Select the second output terminal of circuit；

The control terminal of the first switch is connected with the control terminal of the 4th switch, and the first of tie point and the control module Output end is connected；The control terminal of the second switch is connected with the control terminal that third switchs, tie point and the control module Second output terminal is connected；

Switch control terminal of the input terminal of the control module as the input selection circuit.

Optionally, the processing circuit, comprising: active power filtering amplifying circuit and conversion module；Wherein:

First input end of the first input end of the active power filtering amplifying circuit as the processing circuit；It is described active Second input terminal of second input terminal of filter amplification circuit as the processing circuit；

First output end of the active power filtering amplifying circuit is connected with the first input end of the conversion module, described to have The second output terminal of source filter amplification circuit is connected with the second input terminal of the conversion module；

Output end of the output end of the conversion module as the processing circuit.

Optionally, the active power filtering amplifying circuit, comprising: operational amplifier, the first input resistance, the second input resistance And first filter branch and the second filter branch；Wherein:

The first end of the operational amplifier is connected with the input terminal of first filter branch, tie point and described first One end of input resistance is connected；First input of the other end of first input resistance as the active power filtering amplifying circuit End；

The second end of the operational amplifier is connected with the input terminal of second filter branch, tie point and described second One end of input resistance is connected；Second input of the other end of second input resistance as the active power filtering amplifying circuit End；

The third end of the operational amplifier is connected with the output end of first filter branch, has described in tie point conduct First output end of source filter amplification circuit；

4th end of the operational amplifier is connected with the output end of second filter branch, has described in tie point conduct The second output terminal of source filter amplification circuit.

Optionally, first filter branch, comprising: first capacitor and the first feedback resistance；Wherein:

The first capacitor is in parallel with first feedback resistance, and the one end being connected in parallel is as first filter branch Input terminal, output end of the other end being connected in parallel as first filter branch.

Optionally, second filter branch, comprising: the second capacitor and the second feedback resistance；Wherein:

Second capacitor is in parallel with second feedback resistance, and the one end being connected in parallel is as second filter branch Input terminal, output end of the other end being connected in parallel as second filter branch.

Optionally, the conversion module is Integrated Derivative analog-digital converter.

Optionally, the resistance value of first detection resistance and the second detection resistance is equal.

Optionally, the frequency of the sampling clock is the current potential of the output stage VOP and the current potential of the output stage VON 256 times of pulse-width modulation frequency.

Optionally, the resistance value of first input resistance and the second input resistance is identical.

Compared with the existing technology, the utility model is by increasing sampling selection circuit and input selection circuit, according to D assonance The potential difference of the output stage VOP and output stage VON of frequency power amplifier are in positive half period or negative half-cycle, sample corresponding detection The voltage at resistance both ends, and the electric current of loudspeaker is obtained by processing, so as to realize the detection for loudspeaker electric current, and nothing Anti- cut need to be added to D-type audio power amplifier and pushes up distortion function, ensure that the performance of D-type audio power amplifier.

Detailed description of the invention

In order to illustrate the embodiment of the utility model or the technical proposal in the existing technology more clearly, below will be to embodiment Or attached drawing needed to be used in the description of the prior art is briefly described, it should be apparent that, the accompanying drawings in the following description is only It is the embodiments of the present invention, for those of ordinary skill in the art, without creative efforts, also Other attached drawings can be obtained according to the attached drawing of offer.

Fig. 1 is a kind of schematic diagram of current detection circuit disclosed in the utility model embodiment；

Fig. 2 is the waveform diagram of switch control signal Switch_selt in (VOP-VON) positive and negative half period；

Fig. 3 is a kind of schematic diagram of current detection circuit disclosed in another embodiment of the utility model；

Fig. 4 is a kind of schematic diagram of current detection circuit disclosed in another embodiment of the utility model；

Fig. 5 is a kind of schematic diagram of current detection circuit disclosed in another embodiment of the utility model.

Specific embodiment

The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model Clearly and completely describe, it is clear that the described embodiments are only a part of the embodiments of the utility model, rather than whole Embodiment.Based on the embodiments of the present invention, those of ordinary skill in the art are without making creative work Every other embodiment obtained, fall within the protection scope of the utility model.

To keep the above objects, features, and advantages of the utility model more obvious and easy to understand, with reference to the accompanying drawing and have Body embodiment is described in further detail the utility model.

In this application, the terms "include", "comprise" or any other variant thereof is intended to cover non-exclusive inclusion, So that the process, method, article or equipment for including a series of elements not only includes those elements, but also including not having The other element being expressly recited, or further include for elements inherent to such a process, method, article, or device.Do not having There is the element limited in the case where more limiting by sentence "including a ...", it is not excluded that in the mistake including the element There is also other identical elements in journey, method, article or equipment.

In order to sacrifice the performance of D-type audio power amplifier when solving the problem of detection loudspeaker electric current, the utility model is real The current detection circuit that example discloses a kind of loudspeaker is applied, as shown in Figure 1, current detection circuit disclosed in the present embodiment and D class audio frequency Power amplifier 400 is connected with loudspeaker 500, and depending on actual conditions, the branch road of the loudspeaker 500 can may also be in series with inductance L；Current detection circuit disclosed in the present embodiment includes: the first detection resistance RSP, the second detection resistance RSN, sampling selection circuit 100, input selection circuit 200 and processing circuit 300；Wherein:

One end of first detection resistance RSP is connected with the first input end SN1 of input selection circuit 200, and tie point is as D The first input end of the current detection circuit of genus audio power amplifier 400, the output stage with D-type audio power amplifier 400 The source electrode of the low side NMOS transistor Z2 of VON is connected.

One end of second detection resistance RSN is connected with the second input terminal SN2 of input selection circuit 200, and tie point is as D Second input terminal of the current detection circuit of genus audio power amplifier 400, the output stage with D-type audio power amplifier 400 The source electrode of the low side NMOS transistor Z1 of VOP is connected.

It should be noted that the resistance value of the first detection resistance RSP and the second detection resistance RSN are equal.

The third of the other end of first detection resistance RSP, the other end of the second detection resistance RSN and input selection circuit is defeated Enter and hold SN3, is grounded.

First output end of input selection circuit 200 is connected with the first input end of processing circuit 300；Input selection circuit 200 second output terminal is connected with the second input terminal of processing circuit 300.

The output end of processing circuit is the output end of the current detection circuit of the loudspeaker.

Three input terminals of sampling selection circuit 100 are separately connected sampling clock 600, output stage VOP and output stage VON phase Even.

It should be noted that the frequency of sampling clock 600 is the pulse width of the current potential of output stage VOP and output stage VON 256 times of modulating frequency can also carry out other settings according to specific application environment in practical application, and only one kind is shown herein Example, is not limited to that, within the scope of protection of this application.

The output end of sampling selection circuit 100 is connected with the switch control terminal of input selection circuit 200.

Specific working principle are as follows:

Selection circuit 100 is sampled according to the current potential of output stage VOP and the current potential of output stage VON, VOP-VON filter is calculated Waveform after wave, by taking sine wave as an example, waveform is as shown in Fig. 2 top half；Selection circuit 100 is sampled in conjunction with sampling clock 600 frequency judges that output stage VOP and the potential difference (namely the filtered value of VOP-VON) of output stage VON are in positive half cycle Phase or negative half-cycle, and export corresponding switch control signal Switch_selt.

As shown in Fig. 2, the potential difference as output stage VOP and output stage VON is in positive half period, selection circuit is sampled The switch control signal Switch_selt of 100 outputs with certain current potential, such as high level, control input selection circuit 200 by its First input end SN1 and its first output end form access, and its third input terminal SN3 are formed with its second output terminal logical Road；So that processing circuit 300 can sample the voltage at the first both ends detection resistance RSP and be handled, PDM is obtained (Pulse Density Modulation, pulse density modulated) code.

And when the potential difference of output stage VOP and output stage VON is in negative half-cycle, sampling selection circuit 100 exports Switch control signal Switch_selt controls input selection circuit 200 for its third with another current potential, such as low level Input terminal SN3 and its first output end form access, and its second input terminal SN2 and its second output terminal are formed access；Into And enable processing circuit 300 to sample the voltage at the second both ends detection resistance RSN and handled, obtain pulse density modulated Code PDM code.

The PDM code is by cic filter (Cascaded integrator-comb filter, integral-pectination cascade Filter) loudspeaker electric current can be obtained.

The utility model is put by increasing sampling selection circuit 100 and input selection circuit 200 according to D class audio frequency power The potential difference of the output stage VOP and output stage VON of big device are in positive half period or negative half-cycle, sample corresponding detection resistance both ends Voltage, and loudspeaker electric current is obtained by processing, so as to realize the current detecting for loudspeaker, and without to D assonance The addition of frequency power amplifier is anti-to cut top distortion function, ensure that the performance of D-type audio power amplifier.

Another embodiment of the utility model additionally provides a kind of current detection circuit of specific loudspeaker, in above-described embodiment And on the basis of Fig. 1 and Fig. 2, optionally, as shown in figure 3, a kind of embodiment of its input selection circuit 200, comprising: the One switch S1, second switch S2, third switch S3, the 4th switch S4 and control module 201；Wherein:

First input end SN1 of the first end of first switch S1 as input selection circuit 200；The first of second switch S2 Hold the second input terminal SN2 as input selection circuit 200；The first end of third switch S3 is as input selection circuit 200 Third input terminal SN3.

The second end of first switch S1 is connected with the second end of third switch S3, and tie point is as input selection circuit 200 The first output end；The second end of second switch S2 is connected with the second end of the 4th switch S4, and tie point is as input selection electricity The second output terminal on road 200.

The control terminal of first switch S1 is connected with the control terminal of the 4th switch S4, and the first of tie point and control module 201 Output end is connected；The control terminal of second switch S2 is connected with the control terminal of third switch S3, and the of tie point and control module 201 Two output ends are connected.

Switch control terminal of the input terminal of control module 201 as input selection circuit 200.

Specific working principle are as follows:

When the potential difference of output stage VOP and output stage VON are in positive half period, i.e. opening when input selection circuit 200 When the current potential for closing the switch control signal Switch_selt that control terminal receives is high level, the first output of control module 201 It holds V1 to export closure signal, controls first switch S1 and the 4th switch S4 closure；And its second output terminal V2 exports cut-off signals, Second switch S2 and third switch S3 is controlled to disconnect.

When the potential difference of output stage VOP and output stage VON are in negative half-cycle, i.e. opening when input selection circuit 200 When the current potential for closing the switch control signal Switch_selt that control terminal receives is low level, the first output of control module 201 It holds V1 to export cut-off signals, controls first switch S1 and the 4th switch S4 and disconnect；And the second closure of its second output terminal V2 output Signal controls second switch S2 and third switch S3 closure.

This gives a kind of specific embodiments of input selection circuit 200, it is not limited to this, actually answers The circuit structure or chip that can be formed in other discrete devices is realized, depending on its specific application environment, as long as It can be realized the scheme of above-mentioned working principle within the scope of protection of this application.

Remaining structure and principle are same as the previously described embodiments, no longer repeat one by one herein.

Optionally, such as Fig. 4, in another embodiment of the utility model, a kind of embodiment of processing circuit 300 is wrapped It includes: active power filtering amplifying circuit 301 and conversion module 302；Wherein:

First input end of the first input end of active power filtering amplifying circuit 301 as processing circuit 300；Active power filtering is put Second input terminal of second input terminal of big circuit 301 as processing circuit 300；

First output end of active power filtering amplifying circuit 301 is connected with the first input end of conversion module 302, active power filtering The second output terminal of amplifying circuit 301 is connected with the second input terminal of conversion module 302.

Output end of the output end of conversion module 302 as processing circuit 300.

It should be noted that conversion module 300 is Integrated Derivative analog-digital converter.

Specific working principle are as follows:

When the potential difference of output stage VOP and output stage VON are in positive half period, i.e., when input selection circuit 200 receives When the current potential of the switch control signal Switch_selt arrived is high level, then active power filtering amplifying circuit 301 is to the first detection electricity The voltage at the resistance both ends RSP is sampled, and carries out active power filtering and gain amplification disposal to it；Later, 302 pairs of conversion module warps Crossing treated, voltage is converted, and obtains PDM code.

When the potential difference of output stage VOP and output stage VON are in negative half-cycle, i.e., when input selection circuit 200 receives When the current potential of the switch control signal Switch_selt arrived is low level, then active power filtering amplifying circuit 301 is to D class audio frequency function The voltage at the second both ends detection resistance RSN of rate amplifier 400 is sampled, and is carried out at active power filtering and gain amplification to it Reason；Later, conversion module 302 converts voltage after treatment, obtains PDM code.

This gives a kind of specific embodiments of processing circuit 300, it is not limited to this, in practical application The filter circuit of other forms, such as passive filter circuit can also be used, as long as can be realized corresponding filter function； Also, its conversion module 300 is also not limited to Integrated Derivative analog-digital converter, can also be using the energy of discrete device composition Enough realize the circuit of gain enlarging function；It can be depending on its specific application environment, within the scope of protection of this application.

Remaining structure and principle are same as the previously described embodiments, no longer repeat one by one herein.

Optionally, such as Fig. 5, in another embodiment of the utility model, a kind of implementation of active power filtering amplifying circuit 301 Mode, comprising: operational amplifier AMP, the first input resistance RIN1, the second input resistance RIN2 and the first filter branch 303 With the second filter branch 304；Wherein:

The first end of operational amplifier AMP is connected with the input terminal of the first filter branch 303, tie point and the first input electricity The one end for hindering RIN1 is connected；First input end of the other end of first input resistance RIN1 as active power filtering amplifying circuit 301.

The second end of operational amplifier AMP is connected with the input terminal of the second filter branch 304, tie point and the second input electricity The one end for hindering RIN2 is connected；Second input terminal of the other end of second input resistance RIN2 as active power filtering amplifying circuit 301.

The third end of operational amplifier AMP is connected with the output end of the first filter branch 303, and tie point is as active power filtering First output end of amplifying circuit 301.

The 4th end of operational amplifier AMP is connected with the output end of the second filter branch 304, and tie point is as active power filtering The second output terminal of amplifying circuit 301.

Optionally, the first filter branch 303 includes first capacitor C1 and the first feedback resistance Rf1；First capacitor C1 and One feedback resistance Rf1 and company, input terminal of the one end being connected in parallel as the first filter branch 303；The other end being connected in parallel Output end as the first filter branch 303.

Optionally, the second filter branch 304 includes the second capacitor C2 and the second feedback resistance Rf2；Second capacitor C2 and Two feedback resistance Rf2 are in parallel, input terminal of the one end being connected in parallel as the second filter branch 304；The other end being connected in parallel Output end as the second filter branch 304.

It should be noted that the resistance value of the first input resistance RIN1 and the second input resistance RIN2 are identical.

Specific working principle are as follows:

First input resistance RIN1, operational amplifier AMP and the first feedback resistance Rf1 constitute positive-feedback circuit, to having The voltage of the first input end of source filter amplification circuit 301 plays the role of gain amplification, and direct current amplification factor are as follows: AV =-Rf1/RIN1.

The second capacitor C2 in first capacitor C1 and the second filter branch 304 in first filter branch 303 is to active filter The voltage of the first output end and the voltage of second output terminal of wave amplifying circuit 301 play the role of low-pass filtering, by D class audio frequency Radio-frequency component in the current potential of the output stage VOP and output stage VON of power amplifier 400 filters out, and high-frequency noise is prevented to be folded At to the signal-to-noise ratio for reducing current detecting in audio range, and -3dB the frequency of active power filtering amplifying circuit 301 be f (- 3dB)=1/ (2 × π × R_f1×C1)。

This gives a kind of specific embodiments of active power filtering amplifying circuit 301, it is not limited to this, real Can also it be existed using the filter circuit of other forms as long as can be realized corresponding low-pass filtering function in the application of border In the protection scope of the application.

Remaining structure and principle are same as the previously described embodiments, no longer repeat one by one herein.

The foregoing description of the disclosed embodiments can be realized professional and technical personnel in the field or using originally practical new Type.Various modifications to these embodiments will be readily apparent to those skilled in the art, and determine herein The General Principle of justice can be realized in other embodiments without departing from the spirit or scope of the present utility model.Cause This, the present invention will not be limited to the embodiments shown herein, and is to fit to and principles disclosed herein The widest scope consistent with features of novelty.

It should also be noted that, herein, relational terms such as first and second and the like are used merely to one Entity or operation are distinguished with another entity or operation, without necessarily requiring or implying between these entities or operation There are any actual relationship or orders.

Claims (10)

1. a kind of current detection circuit of loudspeaker, suitable for the loudspeaker being connected with D-type audio power amplifier, which is characterized in that The current detection circuit of the loudspeaker includes: the first detection resistance, the second detection resistance, sampling selection circuit, input selection electricity Road and processing circuit；Wherein:

One end of first detection resistance is connected with the first input end of the input selection circuit, and tie point is as the loudspeaker The first input end of current detection circuit, the low side NMOS crystal with the output stage VON of the D-type audio power amplifier The source electrode of pipe is connected；

One end of second detection resistance is connected with the second input terminal of the input selection circuit, and tie point is as the loudspeaker Second input terminal of current detection circuit, the low side NMOS crystal with the output stage VOP of the D-type audio power amplifier The source electrode of pipe is connected；

The of the other end of first detection resistance, the other end of second detection resistance and the input selection circuit Three input terminals, are grounded；

First output end of the input selection circuit is connected with the first input end of the processing circuit；The input selection electricity The second output terminal on road is connected with the second input terminal of the processing circuit；

The output end of the processing circuit is the output end of the current detection circuit of the loudspeaker；

It is described sampling selection circuit three input terminals respectively with sampling clock, the output stage VOP and the output stage VON phase Even；

The output end of the sampling selection circuit is connected with the switch control terminal of the input selection circuit；

The output end of the sampling selection circuit, the switch control terminal of output switch control signal to the input selection circuit； When the potential difference of the output stage VOP and the output stage VON are located at positive half period, described in the switch control signal control The first input end of input selection circuit and the first output end form access, third input terminal and second output terminal and form access； When the potential difference of the output stage VOP and the output stage VON are located at negative half-cycle, described in the switch control signal control The third input terminal of input selection circuit and the first output end form access, the second input terminal and second output terminal and form access.

2. the current detection circuit of loudspeaker according to claim 1, which is characterized in that the input selection circuit, comprising: First switch, second switch, third switch, the 4th switch and control module；Wherein:

First input end of the first end of the first switch as the input selection circuit；The first end of the second switch The second input terminal as the input selection circuit；The first end phase of the first end of the third switch and the 4th switch Even, third input terminal of the tie point as the input selection circuit；

The second end of the first switch is connected with the second end that third switchs, tie point as the input selection circuit One output end；The second end of the second switch is connected with the second end of the 4th switch, and tie point selects electricity as the input The second output terminal on road；

The control terminal of the first switch is connected with the control terminal of the 4th switch, the first output of tie point and the control module End is connected；The control terminal of the second switch is connected with the control terminal that third switchs, and the second of tie point and the control module Output end is connected；

Switch control terminal of the input terminal of the control module as the input selection circuit.

3. the current detection circuit of loudspeaker according to claim 1, which is characterized in that the processing circuit, comprising: active Filter amplification circuit and conversion module；Wherein:

First input end of the first input end of the active power filtering amplifying circuit as the processing circuit；The active power filtering Second input terminal of second input terminal of amplifying circuit as the processing circuit；

First output end of the active power filtering amplifying circuit is connected with the first input end of the conversion module, the active filter The second output terminal of wave amplifying circuit is connected with the second input terminal of the conversion module；

Output end of the output end of the conversion module as the processing circuit.

4. the current detection circuit of loudspeaker according to claim 3, which is characterized in that the active power filtering amplifying circuit, It include: operational amplifier, the first input resistance, the second input resistance and the first filter branch and the second filter branch；Wherein:

The first end of the operational amplifier is connected with the input terminal of first filter branch, tie point and first input One end of resistance is connected；First input end of the other end of first input resistance as the active power filtering amplifying circuit；

The second end of the operational amplifier is connected with the input terminal of second filter branch, tie point and second input One end of resistance is connected；Second input terminal of the other end of second input resistance as the active power filtering amplifying circuit；

The third end of the operational amplifier is connected with the output end of first filter branch, and tie point is as the active filter First output end of wave amplifying circuit；

4th end of the operational amplifier is connected with the output end of second filter branch, and tie point is as the active filter The second output terminal of wave amplifying circuit.

5. the current detection circuit of loudspeaker according to claim 4, which is characterized in that first filter branch, comprising: First capacitor and the first feedback resistance；Wherein:

The first capacitor is in parallel with first feedback resistance, and the one end being connected in parallel is defeated as first filter branch Enter end, output end of the other end being connected in parallel as first filter branch.

6. the current detection circuit of loudspeaker according to claim 4, which is characterized in that second filter branch, comprising: Second capacitor and the second feedback resistance；Wherein:

Second capacitor is in parallel with second feedback resistance, and the one end being connected in parallel is defeated as second filter branch Enter end, output end of the other end being connected in parallel as second filter branch.

7. the current detection circuit of loudspeaker according to claim 3, which is characterized in that the conversion module is that integral-is micro- Submodular converter.

8. the current detection circuit of loudspeaker according to claim 1, which is characterized in that first detection resistance and second The resistance value of detection resistance is equal.

9. the current detection circuit of loudspeaker according to claim 1, which is characterized in that the frequency of the sampling clock is institute 256 times for stating the pulse-width modulation frequency of the current potential of output stage VOP and the current potential of the output stage VON.

10. the current detection circuit of loudspeaker according to claim 4, which is characterized in that first input resistance and The resistance value of two input resistances is identical.