CN106535024A - Power amplifier circuit, control method and earphone system - Google Patents
Power amplifier circuit, control method and earphone system Download PDFInfo
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- CN106535024A CN106535024A CN201611222746.2A CN201611222746A CN106535024A CN 106535024 A CN106535024 A CN 106535024A CN 201611222746 A CN201611222746 A CN 201611222746A CN 106535024 A CN106535024 A CN 106535024A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R1/00—Details of transducers, loudspeakers or microphones
- H04R1/10—Earpieces; Attachments therefor ; Earphones; Monophonic headphones
- H04R1/1041—Mechanical or electronic switches, or control elements
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2201/00—Details of transducers, loudspeakers or microphones covered by H04R1/00 but not provided for in any of its subgroups
- H04R2201/10—Details of earpieces, attachments therefor, earphones or monophonic headphones covered by H04R1/10 but not provided for in any of its subgroups
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Abstract
The invention discloses a power amplifier circuit, a control method and an earphone system. The power amplification circuit is used for driving an earphone, and comprises an earphone working parameter detection module used for detecting a working parameter of the earphone; a signal output module used for outputting signals to the earphone; and a signal processor used for determining whether an earphone leak exists according to the working parameter of the earphone detected by the earphone working parameter detection module, and changing the signals output to the earphone by the signal output module when the earphone leak exists. The power amplifier circuit provided by the invention can also achieve good sound effect and self-adapting effect in the case that a user wears the earphone improperly, and in addition, can also prompt that the user wears improperly and adjust a wearing angle and a wearing position via warning sound or by a mode that a playing terminal displays a leak detection result, and thus the earphone can achieve better use effect.
Description
Technical Field
The invention relates to the field of earphones, in particular to a power amplifier circuit, a control method and an earphone system.
Background
The earphone is an electric-force-sound transducer, and is mainly used for mobile phones, walkmans and other devices. The headphones are typically separated from the media player and coupled using a plug. The earphone has the advantage of portability, and can listen to music independently without influencing other people. Earphones can be broadly classified into open type, semi-open type, and closed type according to the usage pattern. Wherein, the closed earphone (such as an in-ear earphone) adopts a totally closed structure, and has the advantages of accurate and clear sound positioning and the like. Some closed earphones have the sound field of an open earphone, and still keep high-quality sound while isolating noise, so that the closed earphones are helpful for people working in a recording room or in a noise environment except users who enjoy music.
The semi-closed and closed earphones have the disadvantage of high requirements on wearing conditions. If the earphone is worn improperly, sound leaks seriously, the hearing sense is poor, and the earphone leaks.
Disclosure of Invention
One object of the present invention is to provide a power amplifier circuit for improving the accuracy of adjusting an earphone.
Another objective of the present invention is to provide a method for controlling a power amplifier circuit, which improves the accuracy of adjusting the earphone.
It is a further object of this invention to provide an adaptive headphone system that adjusts the output for miswear.
To achieve the purpose, on one hand, the invention adopts the following technical scheme:
a power amplifier circuit for driving an earphone, comprising:
the earphone working parameter detection module is used for detecting the working parameters of the earphone;
the signal output module is used for outputting signals to the earphone;
and the signal processor judges whether the earphone has leakage according to the working parameters of the earphone detected by the earphone working parameter detection module, and changes the signal output to the earphone by the signal output module when the earphone has leakage.
Preferably, the operating parameter comprises a voltage across the headset, a current input to the headset and/or a frequency response of the headset.
Preferably, the earphone working parameter detection module comprises a voltage detection unit for detecting voltages at two ends of an earphone and a current detection unit for detecting current input into the earphone, the voltage detection unit and the current detection unit are both connected with the signal processor, and the signal processor is used for adjusting signals output by the signal output module to the earphone according to the voltages and currents of the earphone detected by the voltage detection unit and the current detection unit respectively; and/or the presence of a gas in the gas,
the earphone working parameter detection module comprises a microphone and a frequency response detection unit connected with the microphone, the frequency response detection unit is used for detecting the frequency response of the earphone through the microphone, and the signal processor is used for adjusting the signal output to the earphone by the signal output module according to the frequency response of the earphone detected by the frequency response detection unit.
Preferably, the voltage detection unit includes a separately provided detection terminal for direct connection with the earphone.
Preferably, the changing of the signal output by the signal output module to the earphone includes adjusting the signal output by the signal output module to the earphone or sending an additional warning signal to the earphone.
Preferably, the adjusting the signal output by the signal output module to the earphone includes boosting a low frequency voltage.
On the other hand, the invention adopts the following technical scheme:
a control method of a power amplifier circuit comprises the steps of judging whether the earphone has leakage or not according to working parameters of the earphone, and changing signals output to the earphone when the earphone has leakage.
Preferably, the determining whether the earphone has leakage according to the operating parameter of the earphone, and changing the signal output to the earphone when the earphone has leakage further comprises:
adjusting a signal output to the earphone according to the voltage and the current of the earphone; and/or the presence of a gas in the gas,
and adjusting the signal output to the earphone according to the frequency response of the earphone.
Preferably, altering the signal output to the headset comprises adjusting the signal output to the headset or issuing an additional alert signal to the headset.
Preferably, adjusting the signal output to the headset comprises boosting the low frequency voltage.
On the other hand, the invention adopts the following technical scheme:
the earphone system comprises an earphone and the power amplifier circuit, wherein the power amplifier circuit is connected with the earphone.
Preferably, the earphone comprises a first positive pole and a first negative pole;
the detection end of the voltage detection unit comprises a voltage detection anode and a voltage detection cathode;
the first positive electrode is connected with the voltage detection positive electrode, and the first negative electrode is connected with the voltage detection negative electrode.
Preferably, the earphone comprises a second positive electrode and a second negative electrode;
the signal output end of the signal output module comprises a signal anode and a signal cathode;
the second positive electrode is connected with the signal positive electrode, and the second negative electrode is connected with the signal negative electrode.
Preferably, the first positive electrode, the first negative electrode, the second positive electrode and/or the second negative electrode include a pad, a PCB, a flexible circuit board, a wire or a spring.
Preferably, the headset further comprises a voice coil;
the first positive electrode is connected with the second positive electrode, the first negative electrode is connected with the second negative electrode, one end of the voice coil is connected with the first positive electrode or the second positive electrode, and the other end of the voice coil is connected with the first negative electrode or the second negative electrode; or,
first lead wire and second lead wire are drawn forth to the one end of voice coil loudspeaker voice coil, first pin connection first anodal, second pin connection second anodal, third lead wire and fourth lead wire are drawn forth to the other end of voice coil loudspeaker voice coil, third pin connection first negative pole, fourth pin connection the second negative pole.
Preferably, the earphone working parameter detection module includes a microphone and a frequency response detection unit connected to the microphone, the frequency response detection unit is configured to detect a frequency response of the earphone through the microphone, and the signal processor is configured to adjust a signal output by the signal output module to the earphone according to the frequency response of the earphone detected by the frequency response detection unit;
a sound outlet is arranged in the earphone, and the microphone is arranged in the sound outlet.
Preferably, the earphone system further comprises a communication module, which is in communication connection with the play terminal and is used for sending the earphone working state signal to the play terminal.
The invention has the beneficial effects that:
the signal processor of the power amplifier circuit provided by the invention can judge whether the earphone has leakage according to the working parameters of the earphone detected by the earphone working parameter detection module, change the signal output from the signal output module to the earphone when the earphone has leakage, and can obtain better sound effect under the condition that a user wears the earphone improperly by adjusting the power amplifier output and filtering, thereby realizing the self-adaptive effect.
The control method of the power amplifier circuit provided by the invention judges whether the earphone has leakage according to the working parameters of the earphone detected by the earphone working parameter detection module, changes the signal output to the earphone by the signal output module when the earphone has leakage, can obtain better sound effect under the condition that a user wears the earphone improperly by adjusting the power amplifier output and filtering, realizes the self-adaptive effect, and can prompt the user to wear improperly and adjust the wearing angle and position by means of warning sound, displaying the leakage detection result by the playing terminal and the like, thereby enabling the earphone to achieve better using effect.
The earphone system provided by the invention adopts the power amplifier circuit, can obtain better sound effect under the condition that a user wears the earphone system improperly by adjusting the power amplifier output and filtering, or prompts the user to wear the earphone system improperly by means of warning sound, displaying a leakage detection result by a playing terminal and the like, and adjusts the wearing angle and position, so that the earphone achieves better using effect.
Drawings
FIG. 1 is a schematic diagram of a conventional power amplifier circuit connected to a speaker;
fig. 2 is a schematic diagram illustrating a connection between a power amplifier circuit and an earphone according to an embodiment of the present invention;
fig. 3 is a schematic diagram illustrating a connection between a power amplifier circuit and an earphone according to a second embodiment of the present invention;
fig. 4 is a result of frequency response tests in different leakage states when the earphone provided by the second embodiment of the present invention is worn;
fig. 5 is a schematic back structure diagram of an earphone according to a third embodiment of the present invention;
FIG. 6 is a schematic diagram of the structure of the earphone electrode of FIG. 5;
fig. 7 is a schematic structural diagram of a voice coil of an earphone according to a fourth embodiment of the present invention;
fig. 8 is a schematic structural diagram of an earphone according to a fifth embodiment of the present invention.
In the figure, 1', a signal processor; 2', a signal output module; 3', a current detection unit; 4', a voltage detection unit; 5', a variable gain amplifier; 6', a power amplifier; 7', a current sampling resistor; 8', a loudspeaker;
1. a signal processor; 2. a signal output module; 21. a signal positive electrode; 22. a signal cathode; 3. a current detection unit; 31. a current detection positive electrode; 32. a current detection cathode; 4. a voltage detection unit; 41. a voltage detection positive electrode; 42. a voltage detection cathode; 5. a variable gain amplifier; 6. a power amplifier; 7. a current sampling resistor; 8. an earphone; 81. a first positive electrode; 82. a first negative electrode; 83. a second positive electrode; 84. a second negative electrode; 85. a first pad; 86. a second pad; 87. a voice coil; 871. a first lead; 872. a second lead; 873. a third lead; 874. a fourth lead; 88. an earphone front shell; 89. an earphone rubber sleeve; 9. a microphone; 10. and a frequency response detection unit.
Detailed Description
The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.
The invention provides a power amplifier circuit, which is used for driving an earphone and comprises:
the earphone working parameter detection module is used for detecting the working parameters of the earphone;
the signal output module is used for outputting signals to the earphone;
and the signal processor judges whether the earphone has leakage according to the working parameters of the earphone detected by the earphone working parameter detection module, and changes the signal output by the signal output module to the earphone when the earphone has leakage.
The signal processor of the power amplifier circuit provided by the invention can judge whether the earphone leaks according to the working parameters of the earphone detected by the earphone working parameter detection module, change the signal output by the signal output module to the earphone when the earphone leaks, and can obtain a good sound effect under the condition that a user wears improperly by adjusting the power amplifier output and filtering, or prompt the user to wear improperly and adjust the wearing angle and position by means of warning sound, a playing terminal for displaying the leakage detection result and the like, so that the earphone can achieve a better using effect.
The operating parameters are not particularly limited, and may be parameters capable of representing the operating state of the earphone, for example, the voltage across the earphone, the current input to the earphone, and/or the frequency response of the earphone.
The following describes a specific structure and a control method of the power amplifier circuit with reference to an embodiment.
The first embodiment is as follows:
the intelligent power amplifier system is a system for implementing nonlinear digital control and protection in audio signal processing, and is mainly used for protecting electroacoustic transducer systems such as a loudspeaker and the like, and the service life of the system is effectively prolonged. As shown in fig. 1, a signal output module 2 'outputs a sound signal to a speaker 8' through a variable gain amplifier 5 'and a power amplifier 6' to make the speaker sound and operate, and a voltage detection unit 4 'and a current detection unit 3' are used for detecting voltage and current in the circuit, estimating an operating state of the speaker according to the result, and then feeding back information to a signal processor. The signal processor 1 'changes the output signal by filtering or adjusting voltage and transmits the changed output signal to the signal output module 2'. The audio signal finally output to the loudspeaker can be adjusted in real time, so that the aim of dynamically balancing the acoustic performance and reliability of the loudspeaker is fulfilled. Two electrodes of the current detection unit 3 ' are connected in parallel to one output electrode of the power amplifier 6 ' through a current sampling resistor 7 '. Two electrodes of the voltage detection unit 4 'are respectively connected to two output electrodes of the power amplifier 6'.
The traditional intelligent power amplifier is limited in application by only one group of electrodes on the structure of the loudspeaker, and voltage feedback of the loudspeaker close to the end part of the coil cannot be accurately obtained in practical application. As shown in fig. 1, in the schematic diagram of the conventional intelligent power amplifier circuit, a resistance R between an intersection (a, b) of two electrodes of a voltage detection unit 4 ' and two electrodes of a power amplifier 6 ' and an electrode of a speaker 8 ' is generally about 0.3 ohm, and the resistance R is used as an internal resistance of the speaker, and when the self resistance of the speaker 8 ' is small, the resistance R greatly affects a detection result of the voltage detection unit 4 ', which finally causes the detection and adjustment performance of the intelligent power amplifier on the speaker to deteriorate.
The embodiment improves the power amplifier circuit and is applied to driving the earphone. As shown in fig. 2, similar to the conventional power amplifier circuit, the power amplifier circuit provided in this embodiment includes a signal processor 1, and a signal output module 2, a current detection unit 3, and a voltage detection unit 4 respectively connected to the signal processor 1. The signal output module 2 outputs the sound signal to the earphone 8 through the variable gain amplifier 5 and the power amplifier 6 to enable the sound signal to sound and work, the current detection unit 3 is used for detecting the current of the earphone 8, the voltage detection unit 4 is used for detecting the voltage of the earphone 8, the signal processor 1 can change and transmit the output signal to the signal output module 2 through filtering or voltage regulation and other modes according to the voltage and the current of the earphone 8 detected by the voltage detection unit 4 and the current detection unit 3 respectively, and finally the signal output to the earphone 8 can be regulated in real time, so that the purpose of dynamic balance of the acoustic performance and the reliability of the earphone 8 is achieved. Specifically, when the earphone has leakage in the using process, the voltage at two ends of the earphone and the current flowing into the earphone will change, the signal processor judges whether the earphone has leakage according to the voltage and the current of the earphone 8 respectively detected by the voltage detection unit 4 and the current detection unit 3, and changes the signal output by the signal output module to the earphone according to the leakage degree. When the earphone has no leakage, the earphone does not need to be adjusted, when the earphone has slight leakage, the frequency response and the tone quality of the earphone can be the same as those of the earphone in the non-leakage state in a mode of improving low-frequency voltage, when the earphone is in a serious leakage state and the sound effect cannot be effectively adjusted through an input signal, an additional warning signal is sent to the earphone, and a user is reminded to adjust the wearing position and the wearing angle. Wherein, the signal output part of signal output module 2 and the sense terminal of voltage detection unit 4 all set up alone, and the sense terminal of voltage detection unit can directly be connected with the earphone, reduces the influence of loop resistance to voltage detection module for the voltage value at the detection earphone both ends that voltage detection module can be accurate improves power amplifier circuit's detection precision greatly, and then improves the degree of accuracy that power amplifier circuit adjusted the earphone, and have simple structure, implement conveniently, advantage that stability is good.
Specifically, as shown in fig. 2, the signal output end of the signal output module 2 includes a signal anode 21 and a signal cathode 22, wherein the signal output module 2 is connected to the variable gain amplifier 5 and the power amplifier 6 in sequence, the signal anode 21 and the signal cathode 22 are led out from the power amplifier 6, and the signal anode 21 and the signal cathode 22 are directly connected to the speaker 8 respectively. The detection end of the voltage detection unit 4 comprises a voltage detection anode 41 and a voltage detection cathode 42, and the voltage detection anode 41 and the voltage detection cathode 42 are respectively and directly connected with the earphone 8. The detection end of the current detection unit 3 comprises a current detection anode 31 and a current detection cathode 32, and the current detection anode 31 and the current detection cathode 32 are connected in parallel to the signal anode 21 or the signal cathode 22 through the current sampling resistor 7.
Example two:
the active noise reduction earphone system comprises an earphone, a microphone and a noise reduction circuit. The microphone collects noise signals of an external environment, the noise reduction circuit generates noise reduction signals which are the same as the noise signals in amplitude and opposite in phase according to the noise signals and outputs the noise reduction signals to the earphone, the earphone receives the noise reduction signals and generates sound, the noise reduction signals and the external noise are mutually offset, and the noise reduction effect is achieved.
The mems microphone used for noise reduction originally is assembled at the sound outlet of the ear-type earphone, meanwhile, a sweep frequency signal with the input amplitude of 179mVrms is input to the earphone, and the sweep frequency range is 20-20 kHz, so that a frequency response detection result of the signal sent by the earphone can be obtained. Fig. 4 shows the results of a frequency response curve test for an in-ear headphone under different leakage conditions. In fig. 4, curve C1 is the frequency response curve in the no-leakage state, curve C2 is the frequency response curve in the light-leakage state, and curve C3 is the frequency response curve in the severe-leakage state. Comparing the frequency response curves C2 and C3 in different leakage states with the frequency response curve C1 in an undisleaked state, it can be known that if the earphone leaks in the use process, the numerical value of the frequency response curve in the frequency band of 20-100 Hz is reduced, and the reduction amplitude is in positive correlation with the leakage amount; the peak at about 3.5kHz of the C3 frequency response curve would shift toward about 3 kHz.
In this embodiment, the existing active noise reduction technology is applied to real-time leakage detection of the earphone, frequency response change of the earphone is measured in real time through the microphone, and the earphone is adjusted according to the frequency response change. As shown in fig. 3, the earphone working parameter detection module includes a microphone 9 and a frequency response detection unit 10 connected to the microphone 9, the frequency response detection unit 10 is configured to detect a frequency response of the earphone 8 through the microphone 9, and the signal processor 1 is configured to adjust a signal output from the signal output module 2 to the earphone 8 according to the frequency response of the earphone 8 detected by the frequency response detection unit 10.
Specifically, as shown in fig. 3, the signal output end of the signal output module 2 includes a signal anode 21 and a signal cathode 22, wherein the signal output module 2 is connected to the variable gain amplifier 5 and the power amplifier 6 in sequence, the signal anode 21 and the signal cathode 22 are led out from the power amplifier 6, and the signal anode 21 and the signal cathode 22 are directly connected to the speaker 8 respectively. The frequency response detection unit 10 is connected to the signal processor 1 and the microphone 9, respectively. The microphone 9 is preferably arranged in the sound outlet of the earpiece 8.
Specifically, when the headphones 8 are in the state shown by C1 in fig. 4, no adjustment is necessary; c2, the low frequency voltage is increased to make the earphone 8 have the same frequency response and tone quality as the earphone in the non-leakage state; when the earphone 8 is in a serious leakage state shown by C3 and the sound effect cannot be effectively adjusted through the input signal, an additional warning signal is sent to the earphone to remind a user of adjusting the wearing position and angle.
It can be understood that the power amplifier circuits described in the first and second embodiments may be integrated into a circuit, that is, the two power amplifier circuits share a signal output module and a signal processing module, and the adjustment of the earphone is realized according to the voltage at the two ends of the earphone, the current input to the earphone, and the frequency response of the earphone, so as to further improve the accuracy of the adjustment.
Example three:
the embodiment provides an earphone system, which includes an earphone 8 and the power amplifier circuit according to the first embodiment.
The earphone 8 includes a first positive pole 81, a first negative pole 82, a second positive pole 83 and a second negative pole 84. The voltage detection positive electrode 41 is connected to the first positive electrode 81, the voltage detection negative electrode 42 is connected to the first negative electrode 82, and the voltage detection unit 4 detects the voltage of the speaker 8 through the first positive electrode 81 and the first negative electrode 82. The signal positive electrode 21 is connected to the second positive electrode 83, and the signal negative electrode 22 is connected to the second negative electrode 84. The signal output module 2 inputs a signal to the earphone 8 through the second positive pole 83 and the second negative pole 84 to drive the earphone to sound.
The arrangement of the first positive pole 81, the first negative pole 82, the second positive pole 83 and the second negative pole 84 on the earphone 8 is not limited, and may include, but is not limited to, a pad, a PCB, a flexible circuit board, a wire or a spring, and the wire has a terminal for easy installation. The first positive pole 81 and the first negative pole 82 may be directly connected in parallel with the second positive pole 83 and the second negative pole 84, or may be connected in parallel through a voice coil of the earphone 8.
For example, as shown in fig. 5, a first positive electrode 81, a first negative electrode 82, a second positive electrode 83, and a second negative electrode 84 are provided on the speaker in the form of pads. Specifically, the earphone includes two pads, namely a first pad 85 connected to one end of the voice coil of the earphone 8 and a second pad 86 connected to the other end of the voice coil, where the first pad 85 has a structure as shown in fig. 6, a first end of which is a first positive electrode 81, and a second end of which is a second positive electrode 83 opposite to the first end. The second pad is similar in structure to the first pad in that a first end thereof is a first cathode 82 and a second end opposite to the first end thereof is a second cathode 84. The first bonding pad 85 and the second bonding pad 86 are respectively injected on a plastic part on the back of the earphone 8, the first bonding pad 85 exposes two areas on the back of the earphone 8, wherein one area is an area of the first positive electrode 81, and the other area is an area of the second positive electrode 83; the second pad 86 exposes two areas on the back of the earpiece 8, one of which is the area of the first negative pole 82 and the other of which is the area of the second negative pole 84.
Further, the earphone system can also comprise a communication module in communication connection with the playing terminal, and is used for sending earphone working state signals to the playing terminal, for example, the results detected by the voltage detection unit and the current detection unit can be sent to the playing terminal such as a player and a mobile phone, the user can download related APP to realize the visualization of the earphone working state, the user can check whether the earphone leaks in the using process through the playing terminal, and the wearing position and angle are adjusted through the real-time detection result, so that an ideal sound effect is finally obtained.
Example four:
the present embodiment provides an earphone system, which has a structure substantially the same as that of the third embodiment, and includes an earphone 8 and the power amplifier circuit according to the first embodiment. Wherein the earphone comprises a first positive pole 81, a first negative pole 82, a second positive pole 83 and a second negative pole 84. The voltage detection positive electrode 41 is connected to the first positive electrode 81, the voltage detection negative electrode 42 is connected to the first negative electrode 82, and the voltage detection unit 4 detects the voltage of the speaker 8 through the first positive electrode 81 and the first negative electrode 82. The signal positive electrode 21 is connected to the second positive electrode 83, and the signal negative electrode 22 is connected to the second negative electrode 84. The signal output module 2 inputs a signal to the earphone 8 through the second positive pole 83 and the second negative pole 84 to drive the earphone to sound.
The difference is that in the present embodiment, the first positive electrode 81 and the second positive electrode 83 are separately provided, and the first negative electrode 82 and the second negative electrode 84 are also separately provided. As shown in fig. 7, one end of the earphone voice coil 87 leads out a first lead 871 and a second lead 872, and the other end of the voice coil 87 leads out a third lead 873 and a fourth lead 874. The first lead 871 is connected to the first positive electrode 81, the second lead 872 is connected to the second positive electrode 83, the third lead 873 is connected to the first negative electrode 82, and the fourth lead 874 is connected to the second negative electrode 84. The first to fourth leads may be, but are not limited to, a tinsel wire or a lacquered wire.
Example five:
the present embodiment provides an earphone system, which includes an earphone 8 and the power amplifier circuit according to the second embodiment.
Wherein the microphone 9 is arranged in the sound outlet of the earphone. The microphone 9 is preferably a MEMS microphone. Specifically, as shown in fig. 8, the earphone includes an earphone front shell 88 and an earphone rubber sleeve 89 covering the periphery of the earphone front shell 88, and the microphone 9 is disposed in a sound outlet of the earphone front shell 88 and is used for detecting a frequency response near the sound outlet. When the earphone is worn on the ear and is normally worn, the space between the earphone rubber sleeve 89 and the ear canal of the ear is in a sealing state. When local leakage is generated between the earphone rubber sleeve 89 and the ears of a person due to the wearing angle position and the like, the frequency response result detected by the microphone 9 changes correspondingly. The frequency response detected by the microphone 9 as a result of no leakage, slight leakage and severe leakage is shown in fig. 4. In fig. 4, C1 shows the result of a no-leak test, C2 shows the result of a slight-leak test, and C3 shows the result of a serious-leak test. The microphone 9 transmits the detection result to the four frequency response detection modules in the second embodiment in real time, and the power amplifier circuit in the second embodiment adjusts the voltages at the two ends of the input earphone correspondingly according to the frequency response detection result, and the adjustment mode is as follows: no leakage state needs to be adjusted; slight leakage only raises the low-frequency voltage value; severe leakage is indicated to the user by a warning tone to wear the garment correctly. The ideal tone quality is obtained through the above mode.
Similarly, the earphone system can further comprise a communication module in communication connection with the playing terminal, and is used for sending earphone working state signals to the playing terminal, for example, the result detected by the frequency response detection unit can be sent to the playing terminals such as a player and a mobile phone, the user can download related APP to realize the visualization of the earphone working state, the user can check whether the earphone leaks in the using process through the playing terminal, the wearing position and angle are adjusted through the real-time detection result, and finally an ideal sound effect is obtained.
The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.
Claims (10)
1. A power amplifier circuit for driving an earphone (8), comprising:
the earphone working parameter detection module is used for detecting the working parameters of the earphone (8);
the signal output module (2) is used for outputting signals to the earphone;
and the signal processor (1) judges whether the earphone (8) leaks or not according to the working parameters of the earphone (8) detected by the earphone working parameter detection module, and changes the signal output to the earphone (8) by the signal output module (2) when the earphone (8) leaks.
2. The power amplifier circuit according to claim 1, characterized in that the operating parameters comprise a voltage across the earpiece (8), a current input to the earpiece (8) and/or a frequency response of the earpiece (8).
3. The power amplifier circuit according to claim 1, wherein the earphone working parameter detection module comprises a voltage detection unit (4) for detecting a voltage across an earphone (8) and a current detection unit (3) for detecting a current input to the earphone (8), the voltage detection unit (4) and the current detection unit (3) are both connected to the signal processor (1), and the signal processor (1) is configured to adjust a signal output from the signal output module (2) to the earphone (8) according to the voltage and the current of the earphone (8) respectively detected by the voltage detection unit (4) and the current detection unit (3); and/or the presence of a gas in the gas,
the earphone working parameter detection module comprises a microphone (9) and a frequency response detection unit (10) connected with the microphone, the frequency response detection unit (10) is used for detecting the frequency response of the earphone (8) through the microphone (9), and the signal processor (1) is used for adjusting the signal output by the signal output module (2) to the earphone (8) according to the frequency response of the earphone (8) detected by the frequency response detection unit (10);
preferably, the voltage detection unit (4) comprises a separately arranged detection terminal for direct connection with the earphone (8).
4. The power amplifier circuit according to any of claims 1 to 3, wherein changing the signal output by the signal output module (2) to the earphone (8) comprises adjusting the signal output by the signal output module (2) to the earphone (8) or sending an additional warning signal to the earphone (8);
preferably, the adjusting the signal output by the signal output module (2) to the earphone (8) includes boosting a low-frequency voltage.
5. A control method of a power amplifier circuit is characterized in that the method comprises the steps of judging whether the earphone (8) has leakage or not according to working parameters of the earphone (8), and changing a signal output to the earphone (8) when the earphone (8) has leakage.
6. The method of claim 5, wherein determining whether the earphone (8) has a leak based on the operating parameters of the earphone (8), and wherein changing the signal output to the earphone (8) when the earphone (8) has a leak further comprises:
adjusting the signal output to the earphone (8) according to the voltage and the current of the earphone (8); and/or the presence of a gas in the gas,
the signal output to the earphone (8) is adjusted according to the frequency response of the earphone (8).
7. Control method according to claim 5, characterized in that changing the signal output to the headset (8) comprises adjusting the signal output to the headset (8) or sending an additional warning signal to the headset (8).
Preferably, adjusting the signal output to the earpiece (8) comprises boosting the low frequency voltage.
8. An earphone system comprising an earphone (8), characterized in that it further comprises a power amplifier circuit according to any one of claims 1 to 4, said power amplifier circuit being connected to said earphone (8).
9. The headset system of claim 8,
the earphone (8) comprises a first positive pole (81) and a first negative pole (82);
the detection end of the voltage detection unit (4) comprises a voltage detection positive electrode (41) and a voltage detection negative electrode (42);
the first positive electrode (81) is connected to the voltage detection positive electrode (41), and the first negative electrode (82) is connected to the voltage detection negative electrode (42).
Preferably, the earphone (8) comprises a second positive pole (83) and a second negative pole (84);
the signal output end of the signal output module (2) comprises a signal anode (21) and a signal cathode (22);
the second positive electrode (83) is connected to the signal positive electrode (21), and the second negative electrode (84) is connected to the signal negative electrode (22).
Preferably, the first positive electrode (81), the first negative electrode (82), the second positive electrode (83) and/or the second negative electrode (84) comprise a pad, a PCB, a flexible circuit board, a wire or a spring.
Preferably, the headset further comprises a voice coil (87);
the first positive electrode (81) is connected with the second positive electrode (83), the first negative electrode (82) is connected with the second negative electrode (84), one end of the voice coil (87) is connected with the first positive electrode (81) or the second positive electrode (83), and the other end of the voice coil (87) is connected with the first negative electrode (82) or the second negative electrode (84); or,
a first lead (871) and a second lead (872) are led out from one end of the voice coil (87), the first lead (871) is connected with the first positive electrode (81), the second lead (872) is connected with the second positive electrode (83), a third lead (873) and a fourth lead (874) are led out from the other end of the voice coil (87), the third lead (873) is connected with the first negative electrode (82), and the fourth lead (874) is connected with the second negative electrode (84).
10. The earphone system according to claim 8, wherein the earphone operating parameter detection module comprises a microphone and a frequency response detection unit connected to the microphone, the frequency response detection unit is configured to detect a frequency response of the earphone through the microphone, and the signal processor is configured to adjust the signal output by the signal output module to the earphone according to the frequency response of the earphone detected by the frequency response detection unit;
a sound outlet is arranged in the earphone, and the microphone is arranged in the sound outlet.
Preferably, the earphone system further comprises a communication module, which is in communication connection with the play terminal and is used for sending the earphone working state signal to the play terminal.
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