CN208754539U - A kind of digital audio power amplification system - Google Patents

Abstract

The utility model provides a kind of digital audio power amplification system, including the first subsystem, the first division module and the first gain adjustment module；The digital audio power amplification system passes through the first division module of setting, in the case where guaranteeing the first subsystem output high pressure, the high-voltage signal for feeding back to the first subsystem is subjected to voltage division processing, so that the internal circuit of the first subsystem can work normally, and then digital audio power amplification system is made to have the function of High voltage output.Also, it is realized by the first gain adjustment module of setting and gain adjustment is carried out to the output signal of first subsystem, and then gain adjustment is carried out to the output signal of digital audio power amplification system.

Description

A kind of digital audio power amplification system

Technical field

The utility model relates to semiconductor integrated circuit technology fields, more specifically to a kind of digital audio-power amplifier System.

Background technique

D-type audio power amplifier is widely applied since it is more than 80% efficiency at present, especially efficiently Rate is most important for mobile device, can not only lengthen working hours, and can also reduce the calorific value of the handheld devices such as mobile phone.

In application fields such as mobile phones, volume and sound quality can have an important influence on user experience, and current trend is audio Power amplifier exports higher power to obtain bigger volume and preferable sound quality.

But digital audio power amplification system can not support High voltage output, and the gain of digital audio power amplification system at present It can not adjust.

Utility model content

To solve the above problems, the utility model provides a kind of digital audio power amplification system, High voltage output can be supported, And has the function of gain adjustment.

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

A kind of digital audio power amplification system, comprising: the first subsystem, the first division module and the first gain adjustment module；

First subsystem includes: the first current source module and the first power amplifier loop, first current source module Output end is connect with the first input end of the first power amplifier loop, and the input terminal of first current source module is as described The signal input part of one subsystem, for receiving PWMP signal, the output end of the first power amplifier loop is as first son The output end of system；

The first end of first division module is connect with the output end of first subsystem, first division module Second end connect with the first end of first gain adjustment module, the second end of first gain adjustment module with it is described The first input end of first power amplifier loop connects；

The voltage that first division module is used to feed back to first subsystem carries out voltage division processing；

First gain adjustment module is used to carry out gain adjustment to the output signal of first subsystem, and then right The output signal of digital audio power amplification system carries out gain adjustment.

Preferably, first division module, comprising: first resistor and second resistance；

The first end of the first resistor is connect with the output end of first subsystem, the second end of the first resistor It is connect with the first end of the second resistance, the second end grounding connection of the second resistance；

Second end of the connecting node of the first resistor and the second resistance as first division module.

Preferably, the resistance value of the second resistance is twice of the resistance value of the first resistor.

Preferably, first gain adjustment module, comprising: the first feedback resistance, the second feedback resistance and switch；

The first end of first feedback resistance is connect with the second end of first division module, the first feedback electricity The second end of resistance is connect with the first end of second feedback resistance, the second end of second feedback resistance and first function Put the first input end connection of loop；

The first end of the switch is connect with the connecting node of first feedback resistance and second feedback resistance, institute The second end for stating switch is connect with the second end of second feedback resistance；

The control terminal of the switch is for receiving first control signal, and the first control signal is for controlling the switch Switch state, and then to the output signal of first subsystem carry out gain adjustment；

Second end of the connecting node of the switch and second feedback resistance as first gain adjustment module.

Preferably, the switch, comprising: the first metal-oxide-semiconductor, the second metal-oxide-semiconductor and third metal-oxide-semiconductor；

The drain electrode of first metal-oxide-semiconductor connects with the connecting node of first feedback resistance and second feedback resistance It connects；

The source electrode of first metal-oxide-semiconductor is connect with the source electrode of second metal-oxide-semiconductor；

The drain electrode of second metal-oxide-semiconductor is connect with the second end of second feedback resistance；

The grid of first metal-oxide-semiconductor is connect with the grid of second metal-oxide-semiconductor, for receiving the first control letter Number；

The drain electrode of the third metal-oxide-semiconductor is connect with the source electrode of first metal-oxide-semiconductor, the source electrode ground connection of the third metal-oxide-semiconductor Connection, the grid of the third metal-oxide-semiconductor is for receiving second control signal, and the second control signal is for controlling the third The working condition of metal-oxide-semiconductor.

Preferably, first metal-oxide-semiconductor, second metal-oxide-semiconductor and the third metal-oxide-semiconductor are N-type metal-oxide-semiconductor.

Preferably, the digital audio power amplification system, further includes: common-mode voltage generation module；

Second input terminal of the second input terminal of the first power amplifier loop and the second power amplifier loop with it is described total The output end of mode voltage generation module connects.

Preferably, the common-mode voltage generation module, comprising: 3rd resistor, the 4th resistance, the 5th resistance, the 6th resistance And capacitor；

The first end of the 3rd resistor is connect with voltage input end, the second end of the 3rd resistor and the 4th electricity The first end of resistance connects, and the second end of the 4th resistance is connect with the first end of the 5th resistance, the 5th resistance Second end grounding connection；

The first end of 6th resistance is connect with the first end of the 5th resistance, the second end of the 6th resistance with The first end of the capacitor connects, and the second end of the capacitor is connect with the second end of the 5th resistance；

Output end of the connecting node of 6th resistance and the capacitor as the common-mode voltage generation module.

Preferably, the 3rd resistor, the 4th resistance are identical with the resistance value of the 5th resistance.

Preferably, the digital audio power amplification system, further includes: the second subsystem, the second division module and the second gain Adjustment module；

Second subsystem is identical with the circuit structure of first subsystem, the signal input of second subsystem For receiving PWMN signal, the PWMN signal is identical with the period of the PWMP signal at end, and timing is different；

The first end of second division module is connect with the output end of second subsystem, second division module Second end connect with the first end of second gain adjustment module, the second end of second gain adjustment module with it is described The first input end of the second power amplifier loop in second subsystem connects；

Second division module is identical with the circuit structure of first division module, and second division module is used for The voltage for feeding back to second subsystem is subjected to voltage division processing；

Second gain adjustment module is identical with the circuit structure of first gain adjustment module, second gain Adjustment module is used to carry out gain adjustment to the output signal of second subsystem, and then to the defeated of digital audio power amplification system Signal carries out gain adjustment out.

As can be seen from the above description, a kind of digital audio power amplification system provided by the utility model passes through first point of setting Die block divides the high-voltage signal for feeding back to the first subsystem in the case where guaranteeing the first subsystem output high pressure Processing so that the internal circuit of the first subsystem can work normally, and then makes digital audio power amplification system have High voltage output Function.

Also, it is realized by the first gain adjustment module of setting and gain tune is carried out to the output signal of first subsystem Section, and then gain adjustment is carried out to the output signal of digital audio power amplification system.

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 the structural schematic diagram of digital power amplifier system provided by the embodiment of the utility model；

Fig. 2 is another structural schematic diagram of digital power amplifier system provided by the embodiment of the utility model；

Fig. 3 is the structural schematic diagram of switch provided by the embodiment of the utility model；

Fig. 4 is the structural schematic diagram of common-mode voltage generation module provided by the embodiment of the utility model；

Fig. 5 is the waveform diagram of first capacitor charge and discharge provided by the 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.

With reference to Fig. 1, Fig. 1 is the structural schematic diagram of digital power amplifier system provided by the embodiment of the utility model, and effect will Treated that pwm signal is converted into analog signal for digital module, comprising: the first subsystem, the first division module 13, the first gain Adjustment module 14, the second subsystem, the second division module 17 and the second gain adjustment module 18；

Wherein, first subsystem is identical with the circuit structure of second subsystem, first division module 13 It is identical with the circuit structure of second division module 17, first gain adjustment module 14 and the second gain adjustment mould The circuit structure of block 18 is identical.

First subsystem includes: the first current source module 11 and the first power amplifier loop 12, the first current source mould The output end Vip of block 11 is connect with the first input end of the first power amplifier loop 12, first current source module 1112 Signal input part of the input terminal as first subsystem, for receiving PWMP signal, the first power amplifier loop 12 it is defeated Output end VOP of the outlet as first subsystem；

The first end of first division module 13 is connect with the output end VOP of first subsystem, and described first point The second end of die block 13 is connect with the first end of first gain adjustment module 14, first gain adjustment module 14 Second end is connect with the first input end of the first power amplifier loop 12；

The voltage that first division module 13 is used to feed back to first subsystem carries out voltage division processing；

First gain adjustment module 14 is used to carry out gain adjustment to the output signal of first subsystem.

Second subsystem includes: the second current source module 15 and the second power amplifier loop 16, the second current source mould The output end Vin of block 15 is connect with the first input end of the second power amplifier loop 16, second current source module 15 it is defeated Enter signal input part of the end as second subsystem, for receiving PWMN signal, the output of the second power amplifier loop 16 Hold the output end VON as second subsystem；

The first end of second division module 17 is connect with the output end VON of second subsystem, and described second point The second end of die block 17 is connect with the first end of second gain adjustment module 18, second gain adjustment module 18 Second end is connect with the first input end of the second power amplifier loop 16；

The voltage that second division module 17 is used to feed back to second subsystem carries out voltage division processing；

Second gain adjustment module 18 is used to carry out gain adjustment to the output signal of second subsystem.

It should be noted that the PWMP signal is identical with the period of the PWMN signal, and timing is different.

As can be seen from the above description, which is guaranteeing the first son by the first division module of setting In the case that system exports high pressure, the high-voltage signal for feeding back to the first subsystem is subjected to voltage division processing, so that the first subsystem Internal circuit can work normally, and then digital audio power amplification system is made to have the function of High voltage output.

Also, it is realized by the first gain adjustment module of setting and gain tune is carried out to the output signal of first subsystem Section, and then gain adjustment is carried out to the output signal of digital audio power amplification system.

Similarly, by the way that the second division module is arranged, in the case where guaranteeing the second subsystem output high pressure, the will be fed back to The high-voltage signal of two subsystems carries out voltage division processing, so that the internal circuit of the second subsystem can work normally, and then makes to count Word audio power amplification system has the function of High voltage output.

Also, it is realized by the second gain adjustment module of setting and gain tune is carried out to the output signal of second subsystem Section, and then gain adjustment is carried out to the output signal of digital audio power amplification system.

Further, as shown in Figure 1, the digital audio power amplification system, further includes: common-mode voltage generation module 19；

Second input terminal of the second input terminal of the first power amplifier loop 12 and the second power amplifier loop 16 is and institute State the output end VREF connection of common-mode voltage generation module 19.

The common-mode voltage generation module 19 is for generating common mode voltage signal, for maintaining first current source module 22 and second current source module 26 output signal stability.

Further, as shown in Fig. 2, first current source module 22 includes the first current source IDAC1, the second current source IDAC2, switch A and switch B.

The input terminal and power supply of first current source IDAC1 for pressure side VDD connection, the output end of the first current source IDAC1 with The input terminal of switch A connects, and the output end of switch A is connect with the input terminal of switch B, and the output end of switch B passes through the second electric current Input terminal of the control terminal of source IDAC2 grounding connection, switch A and switch B as first current source module 11, for receiving PWMP signal.

Further, as shown in Fig. 2, the first power amplifier loop 12 includes the first operational amplifier 21, the drive of power amplifier loop Dynamic model block 23, first capacitor C1, the first field-effect tube P1 and the second field-effect tube N1；

The inverting input terminal of first operational amplifier 21 is connect with the output end of first current source module 11, the first fortune The non-inverting input terminal for calculating amplifier 21 is connect with the output end of common-mode voltage generation module 19, the output of the first operational amplifier 21 End is connect with the input terminal of the power amplifier loop drive module 23, the first output end of the power amplifier loop drive module 23 and institute State the grid connection of the first field-effect tube P1, the second output terminal and second field-effect of the power amplifier loop drive module 23 The grid of pipe N1 connects.

The source electrode of the first field-effect tube P1 is connect with voltage input end PVDD, the drain electrode of the first field-effect tube P1 It is connect with the drain electrode of the second field-effect tube N1, the source electrode grounding connection of the second field-effect tube N1, first effect Should pipe P1 and the second field-effect tube N1 output end of the connecting node as the first power amplifier loop 12.

The first end of the first capacitor C1 is connect with the output end of first operational amplifier 21, second end with it is described The inverting input terminal of first operational amplifier 21 connects.

Further, as shown in Fig. 2, second current source module 15 includes third current source IDAC3, the 4th current source IDAC4, switch C and switch D.

The input terminal and power supply of third current source IDAC3 for pressure side VDD connection, the output end of third current source IDAC3 with The input terminal of switch C connects, and the output end of switch C is connect with the input terminal of switch D, and the output end of switch D passes through the 4th electric current Input terminal of the control terminal of source IDAC4 grounding connection, switch C and switch D as second current source module, for receiving PWMN signal.

Further, as shown in Fig. 2, the second power amplifier loop 16 includes second operational amplifier 22, the drive of power amplifier loop Dynamic model block 24, the second capacitor C2, third field-effect tube P2 and the 4th field-effect tube N2；

The inverting input terminal of second operational amplifier 22 is connect with the output end of second current source module 15, the second fortune The non-inverting input terminal for calculating amplifier 22 is connect with the output end of common-mode voltage generation module 19, the output of second operational amplifier 22 End is connect with the input terminal of the power amplifier loop drive module 24, the first output end of the power amplifier loop drive module 24 and institute State the grid connection of third field-effect tube P2, the second output terminal and the 4th field-effect of the power amplifier loop drive module 24 The grid of pipe N2 connects.

The source electrode of the third field-effect tube P2 is connect with voltage input end PVDD, the drain electrode of the third field-effect tube P2 It is connect with the drain electrode of the 4th field-effect tube N2, the source electrode grounding connection of the 4th field-effect tube N2, the third field effect Should pipe P2 and the 4th field-effect tube N2 output end of the connecting node as the second power amplifier loop 16.

The first end of the second capacitor C2 is connect with the output end of the second operational amplifier 22, second end with it is described The inverting input terminal of second operational amplifier 22 connects.

Since first subsystem is identical with the circuit structure of second subsystem, first division module and institute The circuit structure for stating the second division module is identical, the circuit of first gain adjustment module and second gain adjustment module Structure is identical, therefore, is illustrated below with the first subsystem, the first division module and the first gain adjustment module.

Further, as shown in Fig. 2, first division module 13, comprising: first resistor R1 and second resistance R2；

The first end of the first resistor R1 is connect with the output end VOP of first subsystem, the first resistor R1 Second end connect with the first end of the second resistance R2, the second end grounding connection of the second resistance R2；

The connecting node of the first resistor R1 and the second resistance R2 as first division module 13 second End.

Optionally, the resistance value of the second resistance R2 is twice of the resistance value of the first resistor R1.

In the present embodiment, by adding first resistor R1 and second resistance R2, such as the resistance of the second resistance R2 Value is twice of the resistance value of the first resistor R1, and the voltage of the second end of the first division module 13 is up to voltage input at this time 2/3 times for holding PVDD, then the voltage VREF of the second input terminal of the first power amplifier loop 12 becomes the 1/3 of voltage input end PVDD Times, that is to say, that when voltage input end PVDD is 10V, the voltage of VREF is 3.33V, in the first current source module 11 and the When the supply voltage of one power amplifier loop 12 is equal in the case where 5V, the circuit structure of the first subsystem remains to work normally.

In turn, which has the function of High voltage output.

Further, as shown in Fig. 2, first gain adjustment module 14, comprising: the first feedback resistance RF1, second are instead Feed resistance RF2 and switch S；

The first end of the first feedback resistance RF1 is connect with the second end of first division module 13, and described first The second end of feedback resistance RF1 is connect with the first end of the second feedback resistance RF2, and the of the second feedback resistance RF2 Two ends are connect with the first input end of the first power amplifier loop 12；

The connecting node of the first end of the switch S and the first feedback resistance RF1 and the second feedback resistance RF2 Connection, the second end of the switch S are connect with the second end of the second feedback resistance RF2；

The control terminal of the switch S is for receiving first control signal, and the first control signal is for controlling described open The switch state of S is closed, and then gain adjustment is carried out to the output signal VOP of first subsystem.

The connecting node of the switch S and the second feedback resistance RF2 are as first gain adjustment module 14 Second end.

Further, as shown in figure 3, the switch S, comprising: the first metal-oxide-semiconductor M1, the second metal-oxide-semiconductor M2 and third metal-oxide-semiconductor M3；

The drain electrode V of the first metal-oxide-semiconductor M1_HIWith the company of the first feedback resistance RF1 and the second feedback resistance RF2 Connect node connection；

The source electrode of the first metal-oxide-semiconductor M1 is connect with the source electrode of the second metal-oxide-semiconductor M2；

The drain electrode V of the second metal-oxide-semiconductor M2_LOIt is connect with the second end of the second feedback resistance RF2；

The grid of first metal-oxide-semiconductor is connect with the grid of second metal-oxide-semiconductor, for receiving the first control signal EN；

The drain electrode of the third metal-oxide-semiconductor M3 is connect with the source electrode of the first metal-oxide-semiconductor M1, the source of the third metal-oxide-semiconductor M3 Pole grounding connection, the grid of the third metal-oxide-semiconductor M3 are used for receiving second control signal ENN, the second control signal ENN In the working condition for controlling the third metal-oxide-semiconductor M3.

Optionally, the first metal-oxide-semiconductor M1, the second metal-oxide-semiconductor M2 and the third metal-oxide-semiconductor M3 are N-type metal-oxide-semiconductor.

The first metal-oxide-semiconductor M1 is high-pressure N-shaped metal-oxide-semiconductor, and the second metal-oxide-semiconductor M2 is isolating n-type metal-oxide-semiconductor, when the voltage of PVDD When for 10V, the ceiling voltage of the second end of the first division module 13 is 6.67V, and the first metal-oxide-semiconductor M1 is asymmetric high-pressure N-shaped MOS Pipe, drain V_HIIt can bear high voltage.The drain electrode V of second metal-oxide-semiconductor M2_LOConnect the second of the second feedback resistance RF2 End, to eliminate body bias effect, subtracts at this point, the substrate of the first metal-oxide-semiconductor M1 and the second metal-oxide-semiconductor M2 link together with its source electrode The threshold voltage of few metal-oxide-semiconductor guarantees that PVDD first metal-oxide-semiconductor M1 and the second metal-oxide-semiconductor M2 when lower can work in linear zone, obtains Lesser conducting resistance.

Further, as shown in figure 4, the common-mode voltage generation module 19, comprising: 3rd resistor R3, the 4th resistance R4, 5th resistance R5, the 6th resistance R6 and capacitor C；

The first end of the 3rd resistor R3 is connect with voltage input end PVDD, the second end of the 3rd resistor R3 and institute The first end connection of the 4th resistance R4 is stated, the second end of the 4th resistance R4 is connect with the first end of the 5th resistance R5, The second end grounding connection of the 5th resistance R5；

The first end of the 6th resistance R6 is connect with the first end of the 5th resistance R5, and the of the 6th resistance R6 Two ends are connect with the first end of the capacitor C, and the second end of the capacitor C is connect with the second end of the 5th resistance R5；

Output of the connecting node of the 6th resistance R6 and capacitor C as the common-mode voltage generation module 19 End.

Optionally, the 3rd resistor R3, the 4th resistance R4 are identical with the resistance value of the 5th resistance R5.

Based on the digital audio power amplification system of above-mentioned offer, its principle with gain adjustment function is explained below It states.

It is illustrated by taking the first subsystem, the first division module and the first gain adjustment module as an example.

Assuming that switch S is on state, pass through the relationship between analysis input duty cycle and output signal, it is found that As shown in figure 5, charge and discharge of the first capacitor C1 within a PWMP period are divided into 4 stages.

In the T1 stage: PWMP=" 1 " is high level, and VOP=" 1 " is high level, and the first current source IDAC1 is to the first electricity Hold C1 charging, the output end VOP of the first subsystem passes through the first feedback resistance R_F1It charges to first capacitor C1, at this time first capacitor The electric current of C1 are as follows:

In the T2 stage: PWMP=" 1 " is high level, and VOP=" 0 " is low level, and the first current source IDAC1 is to the first electricity Hold C1 charging, the output end VOP of the first subsystem passes through the first feedback resistance R_F1It discharges to first capacitor C1, at this time first capacitor The electric current of C1 are as follows:

In the T3 stage: PWMP=" 0 " is low level, and VOP=" 0 " is low level, and the second current source IDAC2 is to the first electricity Hold C1 electric discharge, the output end VOP of the first subsystem passes through the first feedback resistance R_F1It discharges to first capacitor C1, at this time first capacitor The electric current of C1 are as follows:

In the T4 stage: PWMP=" 0 " is low level, and VOP=" 1 " is high level, and the second current source IDAC2 is to the first electricity Hold C1 electric discharge, the output end VOP of the first subsystem passes through the first feedback resistance R_F1It charges to first capacitor C1, at this time first capacitor The electric current of C1 are as follows:

Due in the first subsystem course of normal operation, the charge and discharge electric equilibrium of first capacitor C1, that is,

I_{C1_T1}×t1+I_{C1_T2}× t2=-I_{C1_T3}×t3-I_{C1_T4}×t4

Wherein, t1, t2, t3, t4 are respectively the time for being in each stage, I_DACFor the electricity of the first current source IDAC1 and second The electric current of stream source IDAC2.

It can be obtained by arranging above-mentioned formula,

Wherein, t1+t2=D_IN× T, t3+t4=(1-D_IN) × T, t1+t4=D_OUT× T, t2+t3=(1-D_OUT)×T

Wherein, D_INFor the duty ratio of PWMP, D_OUTFor the duty ratio of VOP, T is the period of PWMP and VOP.

Arrangement can obtain,

It follows that

The output voltage V of so the first subsystem_OUTPAre as follows:

V_OUTP=D_OUT×PVDD

That is,

By the above formula, V_OUTPBe one withFor common-mode point, 50% input duty cycle D_INCentered on Signal.

The output voltage V of second subsystem known to similarly_OUTN, no longer illustrate herein.

So, total output voltage V of digital audio power amplification system_OUTFor,

V_OUT=V_OUTP-V_OUTN

That is,

V_OUT=3 × R_F1×I_DAC(2×D_IN-1)

It follows that the gain of digital audio power amplification system is 3 × R_F1×I_DAC。

When switch S is in OFF state, due to the second feedback resistance R_F2Circuit structure is added, at this time digital audio-power amplifier The gain of system is 3 × (R_F1+R_F2)×I_DAC。

As can be seen from the above description, which can carry out gain adjustment to its output signal.

A kind of digital audio power amplification system provided by the utility model is described in detail above, it is used herein Specific case is expounded the principles of the present invention and embodiment, and the explanation of above example is only intended to help Understand the method and its core concept of the utility model；At the same time, for those skilled in the art, according to the utility model Thought, there will be changes in the specific implementation manner and application range, in conclusion the content of the present specification should not be understood For limitations of the present invention.

It should be noted that all the embodiments in this specification are described in a progressive manner, each embodiment weight Point explanation is the difference from other embodiments, and the same or similar parts between the embodiments can be referred to each other. For the device disclosed in the embodiment, since it is corresponded to the methods disclosed in the examples, so being described relatively simple, phase Place is closed referring to method part illustration.

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.Moreover, the terms "include", "comprise" or its any other variant are intended to contain Lid non-exclusive inclusion, so that the element that the process, method, article or equipment including a series of elements is intrinsic, It further include either the element intrinsic for these process, method, article or equipments.In the absence of more restrictions, The element limited by sentence "including a ...", it is not excluded that in the process, method, article or equipment including the element In there is also other identical elements.

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.

Claims (10)

1. a kind of digital audio power amplification system characterized by comprising the first subsystem, the first division module and the first gain Adjustment module；

First subsystem includes: the first current source module and the first power amplifier loop, the output of first current source module End is connect with the first input end of the first power amplifier loop, and the input terminal of first current source module is as first son The signal input part of system, for receiving PWMP signal, the output end of the first power amplifier loop is as first subsystem Output end；

The first end of first division module is connect with the output end of first subsystem, and the of first division module Two ends are connect with the first end of first gain adjustment module, the second end of first gain adjustment module and described first The first input end of power amplifier loop connects；

The voltage that first division module is used to feed back to first subsystem carries out voltage division processing；

First gain adjustment module is used to carry out gain adjustment to the output signal of first subsystem, and then to number The output signal of audio power amplification system carries out gain adjustment.

2. digital audio power amplification system according to claim 1, which is characterized in that first division module, comprising: the One resistance and second resistance；

The first end of the first resistor is connect with the output end of first subsystem, the second end of the first resistor and institute State the first end connection of second resistance, the second end grounding connection of the second resistance；

Second end of the connecting node of the first resistor and the second resistance as first division module.

3. digital audio power amplification system according to claim 2, which is characterized in that the resistance value of the second resistance is described Twice of the resistance value of first resistor.

4. digital audio power amplification system according to claim 1, which is characterized in that first gain adjustment module, packet It includes: the first feedback resistance, the second feedback resistance and switch；

The first end of first feedback resistance is connect with the second end of first division module, first feedback resistance Second end is connect with the first end of second feedback resistance, the second end of second feedback resistance and the first power amplifier ring The first input end on road connects；

The first end of the switch is connect with the connecting node of first feedback resistance and second feedback resistance, described to open The second end of pass is connect with the second end of second feedback resistance；

The control terminal of the switch is for receiving first control signal, and the first control signal is for controlling opening for the switch Off status, and then gain adjustment is carried out to the output signal of first subsystem；

Second end of the connecting node of the switch and second feedback resistance as first gain adjustment module.

5. digital audio power amplification system according to claim 4, which is characterized in that the switch, comprising: the first metal-oxide-semiconductor, Second metal-oxide-semiconductor and third metal-oxide-semiconductor；

The drain electrode of first metal-oxide-semiconductor is connect with the connecting node of first feedback resistance and second feedback resistance；

The source electrode of first metal-oxide-semiconductor is connect with the source electrode of second metal-oxide-semiconductor；

The drain electrode of second metal-oxide-semiconductor is connect with the second end of second feedback resistance；

The grid of first metal-oxide-semiconductor is connect with the grid of second metal-oxide-semiconductor, for receiving the first control signal；

The drain electrode of the third metal-oxide-semiconductor is connect with the source electrode of first metal-oxide-semiconductor, the source electrode grounding connection of the third metal-oxide-semiconductor, The grid of the third metal-oxide-semiconductor is for receiving second control signal, and the second control signal is for controlling the third metal-oxide-semiconductor Working condition.

6. digital audio power amplification system according to claim 5, which is characterized in that first metal-oxide-semiconductor, described second Metal-oxide-semiconductor and the third metal-oxide-semiconductor are N-type metal-oxide-semiconductor.

7. digital audio power amplification system according to claim 1, which is characterized in that the digital audio power amplification system, also It include: common-mode voltage generation module；

Second input terminal of the first power amplifier loop is connect with the output end of the common-mode voltage generation module.

8. digital audio power amplification system according to claim 7, which is characterized in that the common-mode voltage generation module, packet It includes: 3rd resistor, the 4th resistance, the 5th resistance, the 6th resistance and capacitor；

The first end of the 3rd resistor is connect with voltage input end, the second end of the 3rd resistor and the 4th resistance First end connection, the second end of the 4th resistance are connect with the first end of the 5th resistance, and the second of the 5th resistance Hold grounding connection；

The first end of 6th resistance is connect with the first end of the 5th resistance, the second end of the 6th resistance with it is described The first end of capacitor connects, and the second end of the capacitor is connect with the second end of the 5th resistance；

Output end of the connecting node of 6th resistance and the capacitor as the common-mode voltage generation module.

9. digital audio power amplification system according to claim 8, which is characterized in that the 3rd resistor, the 4th electricity It hinders identical with the resistance value of the 5th resistance.

10. digital audio power amplification system according to claim 1, which is characterized in that the digital audio power amplification system, also It include: the second subsystem, the second division module and the second gain adjustment module；

Second subsystem is identical with the circuit structure of first subsystem, and the signal input part of second subsystem is used In receiving PWMN signal, the PWMN signal is identical with the period of the PWMP signal, and timing is different；

The first end of second division module is connect with the output end of second subsystem, and the of second division module Two ends are connect with the first end of second gain adjustment module, the second end of second gain adjustment module and described second The first input end of the second power amplifier loop in subsystem connects；

Second division module is identical with the circuit structure of first division module, and second division module is used for will be anti- The voltage for being fed to second subsystem carries out voltage division processing；

Second gain adjustment module is identical with the circuit structure of first gain adjustment module, second gain adjustment Module is used to carry out gain adjustment to the output signal of second subsystem, and then believes the output of digital audio power amplification system Number carry out gain adjustment.