KR100835955B1 - Method and audio device for volume control in speaker - Google Patents

Abstract

A control apparatus for controlling a volume of a speaker is provided to measure an external noise by using counter electromotive force generated from the speaker instead of a microphone. An amplifier(203) amplifies and reduces electromotive force of inputted sound data. A speaker(209) outputs the amplified/reduced sound data of the amplifier and feeds back the regressive electromotive force generated in the sound data outputting process. A signal processing unit(205) calculates an output electromotive force difference between the regressive electromotive force of the speaker and the outputted sound data of the amplifier in order to extract external noise and to control the electromotive force of the inputted sound data. The output electromotive force includes the electromotive force of the electromotive force and the counter electromotive force of the outputted sound data.

Description

Control method and method for adjusting output volume of speaker {Method and Audio Device for volume control in Speaker}

1 is a block diagram showing the main configuration of a control device for adjusting the output volume of a speaker according to a conventional embodiment

Figure 2 is a block diagram showing the main configuration of the control device for adjusting the output volume of the speaker according to an embodiment of the present invention

3 is a flowchart illustrating a control method of adjusting an output volume of a speaker according to an exemplary embodiment of the present invention.

The present invention relates to a speaker for outputting sound data, and more particularly, to a control device and a method for controlling and outputting the output volume of a speaker according to the degree of external noise.

Conventionally, there has been a technology for automatically adjusting the output volume of sound data according to the size of external environmental noise for a mobile terminal, a wireless headset, and a portable music listening system.

1 is a block diagram showing the main configuration of a control device for adjusting the output volume of a speaker according to a conventional embodiment.

Referring to FIG. 1, the control device includes an amplifier 103, a signal processor 105, a speaker 107, and a microphone 109.
Reference numeral 101 denotes a circuit contact.

The amplifier 203 amplifies or reduces any sound data input under the control of the signal processor 105 and provides the amplified or reduced sound data to the speaker 107.

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The signal processing unit 105 measures external noise input from the microphone 109 and measures electromotive force of the arbitrary sound data input. In addition, the signal processing unit 105 measures the electromotive force of the external noise input from the microphone 109 and controls the amplifier 103 to amplify or reduce the input acoustic data according to the measured electromotive force of the external noise.

The speaker 107 outputs sound data provided from the amplifier 103.

The microphone 109 obtains voice data or sound data including external noise and provides the same to the signal processor 105. The microphone 109 includes any noise measuring sensor or device capable of collecting voice data or sound data including the external noise and measuring external noise included in the voice data or sound data. The noise is provided to the signal processor 105.

The above-described technology adjusts the electromotive force of the input acoustic data according to the electromotive force of external noise to provide an optimum output volume according to external environmental noise without user's artificial manipulation. In addition, the technique extracts external noise from voice data or sound data input through a microphone, and adjusts the output volume of the sound data according to the extracted noise.

However, in some devices that do not require the built-in microphone, the microphone may be an unnecessary component to adjust the volume of the sound data. In addition, there is a costly problem of having to separately provide a noise sensor or a noise measuring device for measuring external noise.

Accordingly, an object of the present invention is to control the output volume of output acoustic data according to external noise.

Another object of the present invention is to remove a noise measuring sensor or a noise measuring device for measuring external noise.

Still another object of the present invention is to remove the noise measuring sensor or the noise measuring device for measuring the external noise and to extract the external noise from the acoustic data returned from the speaker.

Another object of the present invention is to adjust the volume of the acoustic data based on external noise extracted from the acoustic data returned from the speaker.

In the method for adjusting the speaker output volume of the control device to achieve the above object, the present invention, measuring the output electromotive force including the electromotive force of the acoustic data output from the amplifier and the counter electromotive force of the output acoustic data, in the speaker Measuring a regression force of regression, extracting an electromotive force of external noise by calculating a difference value between the output electromotive force of the measured output acoustic data and the measured regression electromotive force, and inputting the electromotive force of the extracted external noise And amplifying / reducing the electromotive force of the sound data to be output.

In addition, in the control device for adjusting the output volume of the speaker, the present invention, an amplifier for amplifying / reducing the electromotive force of the input sound data, outputs the amplified / reduced acoustic data from the amplifier, and occurs when the sound data output A signal processing unit for extracting external noise and calculating the electromotive force of the input acoustic data by calculating a difference value between the speaker for regressing the electromotive force and the output electromotive force for the output acoustic data output from the amplifier Include.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, it will be apparent that the control device described in the embodiment of the present invention can also be applied to earphones, headsets, hands-free, headphones, and the like including a speaker capable of outputting arbitrary sound data.

2 is a block diagram showing the main configuration of a control device for adjusting the output volume of the speaker according to an embodiment of the present invention.

2, the control device includes an amplifier 203, a signal processor 205, and a speaker 209.

Reference numerals 201 and 207 denote circuit contacts.

The amplifier 203 amplifies or reduces the electromotive force of the input acoustic data. In addition, the amplifier 203 amplifies or reduces the electromotive force of the sound data under the control of the signal processor 205 and transmits it to the speaker 209.

The signal processor 205 measures an electromotive force of the input sound data. In addition, the signal processor 205 measures the electromotive force of the output acoustic data to be amplified or reduced in the amplifier 203 and output to the speaker 209. In this case, the signal processor 205 predicts back EMF that may be generated due to the electromotive force of the output acoustic data. The electromotive force of the output acoustic data and the counter electromotive force of the predicted output acoustic data are output electromotive force. In addition, since the signal processor 205 controls the amplifier 203 to amplify or reduce the input acoustic data, the signal processing unit 205 calculates an electromotive force of the output acoustic data amplified or reduced in the amplifier 203 and output to the speaker 209. It can be measured. The signal processor 205 may predict the counter electromotive force of the output acoustic data based on the electromotive force of the output acoustic data.
In addition, the signal processor 205 measures an electromotive force (hereinafter, referred to as a regression electromotive force) with respect to the regression signal returned from the speaker 209. In this case, the return electromotive force refers to a signal in which the electromotive force of the output acoustic data, the counter electromotive force of the output acoustic data, and the electromotive force of external noise are mixed.
More specifically, the electromotive force of the output acoustic data is an electric signal generated in a coil when the output acoustic data is output to the speaker 209, and the counter electromotive force is in the coil of the speaker 209 at the output of the output acoustic data. It is an electrical signal generated. The counter electromotive force may also be a cause of lowering the sound quality of the output acoustic data. In addition, the electromotive force of the external noise is generated by the vibration generated in the diaphragm of the speaker 20 is converted into an electrical signal by the coil.
The signal processor 205 extracts an electromotive force for external noise included in the regression electromotive force by calculating a difference value between the output electromotive force and the regression electromotive force. At this time, the output electromotive force includes the electromotive force of the output acoustic data and the counter electromotive force of the electromotive force, and the regression electromotive force includes the electromotive force of the output acoustic data and the electromotive force of the electromotive force of the electromotive force and external noise.
Accordingly, when the difference between the output electromotive force and the regression electromotive force is calculated, the electromotive force and the counter electromotive force of the output acoustic data are canceled to extract only the electromotive force of the external noise.
In addition, the signal processor 205 controls the amplifier 203 to adjust the electromotive force of the input acoustic data applied to the amplifier 203 based on the extracted electromotive force of the external noise. In this case, the signal processor 205 controls the electromotive force of the input acoustic data to correspond to the extracted electromotive force of the external noise. For example, the signal processor 205 adjusts the electromotive force of the input acoustic data to correspond to the electromotive force of the external noise.

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The signal processor 205 may be a digital signal processor (DSP) and controls main components of the control device.

The speaker 209 outputs sound data amplified or reduced by the amplifier 203 under the control of the signal processor 205. In addition, the speaker 209 revolves a regression signal in which the electromotive force of the output acoustic data sensed by the coil and the electromotive force of the counter electromotive force and external noise of the electromotive force are mixed. At this time, the electromotive force of the external noise is generated by converting the vibration generated in the diaphragm of the speaker 209 into an electrical signal in the coil.

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3 is a flowchart illustrating a control method of adjusting speaker output volume according to an exemplary embodiment of the present invention.

Referring to FIG. 3, in operation S301, the signal processor 205 measures an electromotive force of input sound data. In operation S303, the signal processor 205 measures the electromotive force of the output acoustic data to be amplified or reduced in the amplifier 203 and output to the speaker 209. In this case, the signal processor 205 predicts the counter electromotive force of the output acoustic data based on the electromotive force of the output acoustic data. In addition, the electromotive force of the output acoustic data and the counter electromotive force of the output acoustic data are referred to as output electromotive force. In addition, since the signal processor 205 controls the amplifier 203 to amplify or reduce the input acoustic data, the signal processing unit 205 calculates an electromotive force of the output acoustic data amplified or reduced in the amplifier 203 and output to the speaker 209. It can be measured.
In operation S305, the signal processor 205 measures the regression electromotive force returned from the speaker 209. The return electromotive force refers to a signal in which the electromotive force of the output acoustic data, the counter electromotive force of the acoustic data, and the electromotive force of external noise are mixed. In more detail, the electromotive force of the output acoustic data is an electrical signal generated by the coil when output to the speaker 209, and the counter electromotive force is a signal generated by the electromotive force, and is an electrical signal generated by the coil. In addition, the electromotive force of the external noise is an electromotive force generated by the vibration generated from the diaphragm of the speaker 209 is converted into an electrical signal by the coil.
Subsequently, in step S307, the signal processor 205 calculates a difference value between the output electromotive force measured in step S303 and the regression electromotive force measured in step S305, and in step S309, the signal processor 205 extracts the electromotive force of external noise. In this case, the electromotive force of the output acoustic data and the counter electromotive force of the output acoustic data are included in the output electromotive force, and the electromotive force of the output acoustic data, the counter electromotive force of the output acoustic data and the electromotive force for external noise are included in the regression electromotive force. Therefore, due to the electromotive force and the counter electromotive force included in the output electromotive force, the electromotive force and the counter electromotive force included in the regression electromotive force are canceled, and only the electromotive force for the external noise can be extracted.

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In operation S311, the signal processor 205 controls the amplifier 203 to amplify or reduce the electromotive force of sound data input to the amplifier 203 in response to the electromotive force of the external noise extracted in operation S309.

In step S313, the signal processor 205 controls the speaker 209 to output sound data amplified by the amplifier 203 in step S311.

While the present invention has been described in detail above, it should be apparent that the embodiments mentioned in the process are only illustrative, and not restrictive, and the present invention provides the technical spirit or field of the present invention provided by the following claims. Within the scope not to deviate, component conversions to the extent that they can be coped evenly will fall within the scope of the present invention.

As described above, the present invention measures the external noise by the counter electromotive force generated by the speaker instead of the microphone, thereby controlling the electromotive force of the output acoustic data according to the external noise. In addition, the present invention allows the external device to measure the external noise without the noise measuring sensor or the noise measuring device for measuring the external noise in the control device, space and cost for mounting the noise measuring sensor or the noise measuring device There is an effect to save.

Claims (7)

In the control method for adjusting the output volume of the speaker, Measuring the output electromotive force of the output acoustic data including the electromotive force and the counter electromotive force of the output acoustic data output from the amplifier; Measuring a regression electromotive force returned from the speaker; Extracting an electromotive force of external noise by calculating a difference value between the output electromotive force of the measured output acoustic data and the measured return electromotive force; And And amplifying / decreasing the electromotive force of the input sound data in response to the extracted electromotive force of the external noise. The method of claim 1, wherein the return electromotive force is And an electromotive force of output acoustic data generated by the coil of the speaker, a counter electromotive force of the output acoustic data, and an electromotive force of external noise detected by vibration of the speaker. In the control device for adjusting the output volume of the speaker, An amplifier for amplifying / decreasing electromotive force of the input acoustic data; A speaker for outputting the amplified / decreased sound data from the amplifier and regressing the resonant electromotive force generated when the sound data is output; And a signal processor for extracting external noise and calculating an electromotive force of the input acoustic data by calculating a difference between a regression electromotive force returned from the speaker and an output electromotive force with respect to output acoustic data output from the amplifier. Volume control control. The method of claim 3, wherein the output electromotive force And an electromotive force of the output acoustic data and a counter electromotive force of the output acoustic data. The method of claim 3, wherein the regression electromotive force And an electromotive force of the output acoustic data generated by the coil of the speaker, a counter electromotive force of the output acoustic data, and an electromotive force of external noise detected by the vibration of the speaker. The method of claim 5, wherein the signal processing unit And outputting an electromotive force of the external noise by calculating a difference value between the output electromotive force and the regression electromotive force. The method of claim 6, wherein the signal processing unit And outputting / reducing the electromotive force of the input sound data in response to the extracted electromotive force of the external noise.

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