JP6143624B2 - Speaker switching device and audio equipment - Google Patents

Description

  The present invention relates to a speaker switching technique for switching a plurality of speakers having different frequency characteristics.

  Patent Document 1 discloses a television receiver that can suppress sound other than sound in a time zone such as midnight.

  The television receiver includes a switch and a band filter provided between the audio signal processing circuit and the speaker, and a control unit. The band filter passes only the audio signal in the voice band and filters the audio signal in the other band. The control unit controls the switch so that the audio signal processing circuit and the speaker are connected via the band filter in the preset night mode time zone. Further, the switch is controlled so that the audio signal processing circuit and the speaker are directly connected in a time zone other than the night mode time zone.

  For this reason, in the night mode time zone, while applying a band filter to enhance human sounds, suppressing other sounds can make it easier to hear human voice even if the volume is reduced. . In addition, sound can be normally output in a time zone other than the night mode time zone.

JP 2005-328177 A

  As described above, in the television receiver described in Patent Document 1, sounds other than sound are suppressed by filtering bands other than the sound band with a band filter. For this reason, in a time zone such as midnight, only the audio signal in the voice band is output from the speaker through the band filter, but the technique described in Patent Document 1 is a band that is filtered by the band filter and is not output from the speaker. Does not consider the wasted power consumed for audio signals.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a technique for reproducing an audio signal at an appropriate volume level while suppressing wasteful power consumption.

  In order to solve the above problems, the present invention switches between a plurality of speakers having different frequency characteristics. Then, the volume level of the audio signal to be reproduced is adjusted according to the speaker to be used. For example, when switching the supply destination of an audio signal between a speaker having a wideband frequency characteristic and a speaker having a narrowband frequency characteristic, in a speaker having a narrowband frequency characteristic, the volume level is the maximum. The volume level of the audio signal to be reproduced is adjusted so that the volume level is the same as the volume level in the same band in a speaker having a wideband frequency characteristic.

For example, the speaker switching device of the present invention is a speaker switching device connected to a plurality of speakers having different frequency characteristics,
Switching means for switching an audio signal supply destination from among the plurality of speakers;
When the supply destination of the audio signal is switched by the switching means, the volume of the audio signal is adjusted according to the volume level adjustment amount determined according to the difference between the frequency characteristic of the speaker before switching and the frequency characteristic of the speaker after switching. Volume adjusting means for adjusting the volume level.

  Here, when the supply destination of the audio signal is switched between a speaker having a wideband frequency characteristic and a speaker having a narrowband frequency characteristic, the volume level is maximized in the speaker having the narrowband frequency characteristic. The volume level adjustment amount may be set so that the volume level in the band is the same as the volume level in the same band in the speaker having the broadband frequency characteristics.

  In the present invention, since the volume level of the audio signal to be reproduced is adjusted according to the speaker to be used, the audio signal can be reproduced at an appropriate volume level while suppressing power consumption. In particular, a speaker having a narrow-band frequency characteristic has a higher band efficiency than a speaker having a wide-band frequency characteristic because the band is narrower than a speaker having a wide-band frequency characteristic. . For this reason, when the audio signal supply destination is switched between a speaker having a wideband frequency characteristic and a speaker having a narrowband frequency characteristic, the volume level of the speaker having the narrowband frequency characteristic is maximized. By adjusting the volume level of the audio signal so that the volume level of the audio signal is the same as the volume level in the same band in the speaker having the broadband frequency characteristic, the audio signal is reproduced by the speaker having the narrow band frequency characteristic. In this case, the audio signal can be reproduced at an appropriate volume level while reducing power consumption.

FIG. 1 is a schematic functional configuration diagram of an audio device according to the first embodiment of the present invention. FIG. 2 is a diagram showing frequency characteristics of the speakers 2A and 2B shown in FIG. FIG. 3 is a schematic functional configuration diagram of an audio device according to the second embodiment of the present invention.

Embodiments of the present invention will be described below with reference to the drawings.
<First embodiment>
FIG. 1 is a schematic functional configuration diagram of an audio device according to the first embodiment of the present invention.

  As shown in the figure, the audio device according to the present embodiment includes a speaker switching device 1 to which an audio signal is input, and two speakers 2A and 2B connected to the speaker switching device 1.

  The speakers 2A and 2B have different frequency characteristics. FIG. 2 is a diagram illustrating the frequency characteristics of the speakers 2A and 2B. In this figure, the solid line 20 indicates the frequency characteristic of the speaker 2A, and the dotted line 21 indicates the frequency characteristic of the speaker 2B.

  As shown in the figure, the speaker 2A is a wide-band speaker that maintains an output volume level that is equal to or higher than a predetermined value over a wider frequency band than the speaker 2B. This is a narrow-band speaker that maintains the output volume level. Therefore, the speaker 2A is suitable for reproducing a wide-band audio signal such as music, and the speaker 2B is suitable for reproducing a narrow-band audio signal in which sound such as news and talk programs is mostly occupied.

  As shown in the figure, the speaker 2B, which is a narrow-band speaker, has a narrower band that holds an output volume level equal to or higher than a predetermined value compared to the speaker 2A, which is a wide-band speaker, and thus the audio band that maximizes the output volume level. The output volume level at (around 1 KHz) is higher by ΔT (dB) than the output volume level in the audio band of the speaker 2A. For this reason, when the supply destination of the audio signal is switched from the speaker 2A to the speaker 2B, the output volume level of the audio band suddenly increases, and the viewer may be surprised or uncomfortable.

  Returning to FIG. 1, the description will be continued. The speaker switching device 1 switches the audio signal supply destination to one of the speakers 2A and 2B according to the audio signal to be reproduced, and reproduces the audio signal according to the audio signal supply destination speakers 2A and 2B. Adjust the volume level. As shown in the drawing, the speaker switching device 1 includes an audio signal input unit 10, a volume adjustment unit 11, a speaker switching unit 12, a calculation unit 13, a storage unit 14, and a control unit 15.

  The audio signal input unit 10 is an input terminal for inputting an audio signal.

  The volume adjustment unit 11 adjusts the volume level of the audio signal input to the audio signal input unit 10 according to the volume level adjustment amount instructed from the control unit 15.

  The speaker switching unit 12 switches the supply destination of the audio signal output from the volume adjustment unit 11 to one of the speakers 2A and 2B according to the instruction of the control unit 15.

  The calculation unit 13 performs FFT (Fast Fourier Transform) processing on the audio signal input to the audio signal input unit 10 to detect the frequency distribution of the audio signal.

  The storage unit 14 stores a volume level adjustment amount C1 when the audio signal supply destination is switched from the speaker 2A to the speaker 2B, and a volume level adjustment amount C2 when the speaker 2B is switched to the speaker 2A. Yes. As described above, the speaker 2B, which is a narrow band speaker, has an output volume level in the voice band where the output volume level is maximum at ΔT (dB relative to the output volume level in the voice band of the speaker 2A, which is a wideband speaker. )high. Therefore, when the supply destination of the audio signal is switched from the speaker 2A to the speaker 2B, the volume level of the audio signal is decreased by ΔT (dB) (volume level adjustment amount C1 = −ΔT), as indicated by reference numeral 22 in FIG. Conversely, when switching from the speaker 2B to the speaker 2A, the volume level of the audio signal is increased by ΔT (dB) (volume level adjustment amount C2 = + ΔT (dB)). In this way, when switching between the speakers 2A and 2B, the volume level of the audio signal is adjusted so that the output volume level of the audio band is the same before and after the speaker switching.

  The control unit 15 determines the supply destination of the audio signal from the speakers 2 </ b> A and 2 </ b> B based on the frequency distribution of the audio signal detected by the calculation unit 13. That is, if the frequency distribution of the audio signal shows a wideband characteristic over the entire audible band such as music, the speaker 2A is determined as the audio signal supply destination, and the audio band of news, talk programs, etc. occupies the majority. If the narrow band characteristic is shown, the speaker 2B is determined as the audio signal supply destination. Specifically, if the frequency distribution of the audio signal falls within a predetermined band including the audio band, the speaker 2B is selected as the audio signal supply destination. If the audio signal exceeds the predetermined band, the speaker 2A is selected. Select.

  In the speaker switching device 1 configured as described above, the audio signal input to the audio signal input unit 10 is input to the volume adjustment unit 11 and the calculation unit 13. The calculation unit 13 performs FFT processing on the input audio signal, detects the frequency distribution of the audio signal, and outputs the frequency distribution to the control unit 15. Based on the frequency distribution of the input audio signal, the control unit 15 determines the speakers 2A and 2B to which the audio signal is supplied.

  Here, when the supply destination of the audio signal is switched from the speaker 2 </ b> A to the speaker 2 </ b> B, the volume level adjustment amount C <b> 1 is read from the storage unit 14. Then, the speaker switching unit 12 switches the audio signal supply destination from the speaker 2 </ b> A to the speaker 2 </ b> B, and the volume adjustment unit 11 performs the volume level adjustment for the volume level adjustment amount C <b> 1 of the audio signal at the same time. The switching unit 12 and the volume adjustment unit 11 are controlled. As a result, the volume level of the audio signal input to the audio signal input unit 10 is lowered by ΔT (dB), and then reproduced from the speaker 2B.

  When the audio signal supply destination is switched from the speaker 2B to the speaker 2A, the volume level adjustment amount C2 is read from the storage unit 14. Then, the speaker switching unit 12 switches the audio signal supply destination from the speaker 2B to the speaker 2A, and the volume adjustment unit 11 performs the volume level adjustment for the volume level adjustment amount C2 of the audio signal at the same time. The switching unit 12 and the volume adjustment unit 11 are controlled. As a result, the audio signal input to the audio signal input unit 10 is increased in volume level by ΔT (dB) and then reproduced from the speaker 2A.

  The first embodiment of the present invention has been described above.

  In the present embodiment, the speaker switching device 1 switches between two speakers 2A and 2B having different frequency characteristics and adjusts the volume level of an audio signal to be reproduced according to the speakers 2A and 2B to be used. Specifically, when the audio signal supply destination is switched between the speaker 2A having a wideband frequency characteristic and the speaker 2B having a narrowband frequency characteristic, the output volume level of the speaker before and after the switching is approximately the same. Thus, for example, the volume level of the audio signal is adjusted so that the output volume level in the audio band where the output volume level is maximum in the speaker 2B is the same as the output volume level in the audio band in the speaker 2A. . Therefore, when the audio signal is reproduced while switching between the two speakers 2A and 2B, the output volume level of the speaker 2B having the larger maximum output volume level is approximately the same as that of the speaker 2A having the smaller maximum output volume level. Therefore, the power consumption can be reduced. For example, when the difference ΔT (dB) between the output volume level in the audio band of the speaker 2B and the output volume level in the audio band of the speaker 2A is 12 (dB), the output volume level of the speaker 2B is 12 (dB). By reducing the output power level, the output power from the amplifier can be reduced to a quarter compared with the case where the audio signal is reproduced from the speaker 2B without adjusting the output volume level, and the power consumption can be reduced accordingly. .

  Further, when reproducing a narrow-band audio signal in which the sound of news, talk programs, etc. occupies most, if the audio signal supply destination is switched to the narrow-band speaker 2B without filtering the audio signal. Therefore, power consumption can be further suppressed.

  Therefore, according to the present embodiment, the output volume level of the audio band is reduced when the audio signal supply destination is switched between the speakers 2A and 2B while reducing the power consumption when the audio signal is reproduced by the speaker 2B. An audio signal can be reproduced at an appropriate volume level so as not to change suddenly.

  In this embodiment, the audio signal is subjected to FFT processing to detect a frequency distribution, and the speakers 2A and 2B are switched based on the detected frequency distribution. Therefore, the speakers 2A and 2B suitable for the audio signal to be reproduced can be determined as the audio signal supply destination.

In this embodiment, the frequency distribution is detected by performing FFT processing on the audio signal, and the speakers 2A and 2B are switched based on the detected frequency distribution. However, the present invention is not limited to this. For example, if a genre code is assigned to the audio signal like a digital broadcast signal, the speakers 2A and 2B may be switched based on the genre code. Specifically, when the genre code indicates audio-based content such as news or a talk program, the speaker 2B is determined as the audio signal supply destination, and in other cases, the speaker 2A is supplied as the audio signal supply destination. To decide.
<Second embodiment>
FIG. 3 is a schematic functional configuration diagram of an audio device according to the second embodiment of the present invention.

  As illustrated, the audio device according to the present embodiment includes a speaker switching device 1A to which an audio signal is input, and two speakers 2C and 2D and a microphone 3 connected to the speaker switching device 1A. Is done.

  The speakers 2C and 2D have different frequency characteristics and are detachably connected to the speaker switching device 1A via a plug (not shown).

  The microphone 3 collects reproduced sound output from the speakers 2C and 2D connected to the speaker switching device 1A.

  The speaker switching device 1A detects the frequency distribution of the reproduced sound from each of the speakers 2C and 2D collected by the microphone 3, and stores these as frequency characteristics of the speakers 2C and 2D. Further, the audio signal supply destination is switched to one of the speakers 2C and 2D in accordance with the degree of matching between the frequency distribution of the audio signal to be reproduced and the frequency characteristics of the speakers 2C and 2D, and the audio signal supply destination speaker is switched. The volume level of the audio signal to be reproduced is adjusted according to 2C and 2D. As illustrated, the speaker switching device 1A includes an audio signal input unit 10, a volume adjustment unit 11, a speaker switching unit 12, a calculation unit 13, a storage unit 14A, a control unit 15A, and an audio signal output unit 16A. , 16B, a sound source unit 17, a first input switching unit 18A, and a second input switching unit 18B. Here, the same code | symbol is attached | subjected to what has the same function as the speaker switching apparatus 1 which concerns on 1st embodiment, and the detailed description is abbreviate | omitted.

  The storage unit 14A stores the frequency characteristics of the speakers 2C and 2D.

  The audio signal output units 16A and 16B are jacks for connecting the speakers 2C and 2D. The audio signal is output to the speaker 2C via the audio signal output unit 16A, or is output to the speaker 2D via the audio signal output unit 16B.

  The sound source unit 17 generates an audio signal (noise signal) having uniform characteristics over the entire audible range such as white noise and pink noise.

  The first input switching unit 18A switches the supply source of the audio signal to be input to the speaker switching unit 12 to one of the volume adjustment unit 11 and the sound source unit 17 in accordance with an instruction from the control unit 15A.

  The second input switching unit 18B switches the supply source of the audio signal to be input to the calculation unit 13 to one of the audio signal input unit 10 and the microphone 3 in accordance with an instruction from the control unit 15A.

  The control unit 15A operates in either the speaker characteristic detection mode or the audio reproduction mode in accordance with an operator instruction input via an operation panel (not shown).

  In the speaker characteristic detection mode, the control unit 15A controls the first input switching unit 18A and the second input switching unit 18B to input the audio signal (noise signal) generated by the sound source unit 17 to the speaker switching unit 12. At the same time, the audio signal collected by the microphone 3 is input to the calculation unit 13. Further, the speaker switching unit 12 is controlled to switch the speakers 2C and 2D in order, and the audio signal generated by the sound source unit 17 is supplied to the speakers 2C and 2D in order. Then, the reproduced sound of each speaker 2C, 2D is collected by the microphone 3, the frequency distribution of the audio signal is detected by the calculation unit 13, and these are stored in the storage unit 14A as the frequency characteristics of each speaker 2C, 2D.

  On the other hand, in the audio playback mode, the control unit 15A controls the first input switching unit 18A and the second input switching unit 18B to input the audio signal output from the volume adjustment unit 11 to the speaker switching unit 12, The audio signal input to the audio signal input unit 10 is input to the calculation unit 13. Then, based on the frequency distribution of the audio signal detected by the calculation unit 13 and the frequency characteristics of the speakers 2C and 2D stored in the storage unit 14A, the supply destination of the audio signal from the speakers 2C and 2D is determined. That is, the speakers 2C and 2D having a frequency characteristic having a high degree of matching (approximation) with the frequency distribution of the audio signal are determined as the audio signal supply destination.

  In the audio playback mode, when the audio signal supply destination is switched, the control unit 15A instructs the volume adjustment unit 11 so that the output volume level of the audio band is maintained at the same level before and after switching. Determine the adjustment amount.

  In the speaker switching device 1A having the above configuration, in the speaker characteristic detection mode, the audio signal (noise signal) generated by the sound source unit 17 is first reproduced by the speaker 2C, and the reproduced sound is collected by the microphone 3. Input to the arithmetic unit 13. The calculation unit 13 performs FFT processing on the input audio signal, detects the frequency distribution of the audio signal, and outputs the frequency distribution to the control unit 15A. The control unit 15A stores the input frequency distribution in the storage unit 14A as the frequency characteristics of the speaker 2C.

  Next, the audio signal generated by the sound source unit 17 is reproduced by the speaker 2D, and the reproduced sound is collected by the microphone 3 and input to the arithmetic unit 13. The calculation unit 13 performs FFT processing on the input audio signal, detects the frequency distribution of the audio signal, and outputs the frequency distribution to the control unit 15A. The control unit 15A stores the input frequency distribution in the storage unit 14A as the frequency characteristics of the speaker 2D.

  As described above, the frequency characteristics of the speakers 2C and 2D are stored in the storage unit 14A.

  On the other hand, in the audio playback mode, the audio signal input to the audio signal input unit 10 is input to the volume adjustment unit 11 and the calculation unit 13. The calculation unit 13 performs FFT processing on the input audio signal, detects the frequency distribution of the audio signal, and outputs the frequency distribution to the control unit 15A. The control unit 15A refers to the storage unit 14A, specifies the speakers 2C and 2D having frequency characteristics having a high degree of matching with the frequency distribution of the input audio signal, and uses the specified speakers 2C and 2D for the audio signal. Decide on the supplier.

  Here, when the audio signal supply destination is switched, the control unit 15A determines the volume level adjustment amount so that the output volume level of the audio band is maintained at the same level before and after switching. Specifically, a difference ΔT (dB) between the output sound volume levels in the sound band indicated by the frequency characteristics of the two speakers 2C and 2D stored in the storage unit 14A is obtained, and the sound band indicated by the frequency characteristics of the speaker after switching. If the output volume level is ΔT (dB) higher than the output volume level of the audio band indicated by the frequency characteristics of the speaker before switching, the volume level adjustment amount is determined to be −ΔT (dB), and the frequency of the speaker after switching is determined. If the output volume level of the audio band indicated by the characteristic is lower than the output volume level of the audio band indicated by the frequency characteristic of the speaker before switching by ΔT (dB), the volume level adjustment amount is determined to be + ΔT (dB). Then, the speaker switching unit 12 and the volume adjustment unit 11 are switched so that the switching of the speakers 2C and 2D by the speaker switching unit 12 and the volume level adjustment corresponding to the volume level adjustment amount of the audio signal by the volume adjustment unit 11 are performed simultaneously. Control. As a result, the audio signal input to the audio signal input unit 10 is adjusted in volume level according to the volume level adjustment amount, and then reproduced from the speakers 2C and 2D to which the audio signal is supplied.

  The second embodiment of the present invention has been described above.

  In the present embodiment, the speaker switching device 1A detects the frequency characteristics of the speakers 2C and 2D connected to the audio signal output units 16A and 16B and stores them in the storage unit 14A in the speaker characteristic detection mode. Then, in the audio playback mode, the speakers 2C and 2D having a frequency characteristic with a higher degree of matching with the frequency distribution of the audio signal input to the audio signal input unit 10 are determined as the audio signal supply destination and the audio signal supply. When the destination is switched, the volume level adjustment amount is determined so that the output volume level of the audio band is maintained at the same level before and after switching. For this reason, even when the speakers 2C and 2D connected to the speaker switching device 1A are changed, the sound is reduced when the audio signal supply destination is switched between the speakers 2C and 2D while reducing power consumption by reducing power consumption. An audio signal can be reproduced at an appropriate volume level so that the output volume level of the band does not change abruptly.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist.

  For example, in each of the above-described embodiments, the case where the speaker switching devices 1 and 1A switch the supply destination of the audio signal from the two speakers according to the audio signal to be reproduced has been described as an example. However, the present invention is not limited to this. Depending on the audio signal to be reproduced, the audio signal supply destination may be switched from three or more speakers.

  Moreover, the functional configuration of the speaker switching devices 1 and 1A shown in FIGS. 1 and 3 may be realized by an integrated logic IC such as ASIC (Application Specific Integrated Circuit) or FPGA (Field Programmable Gate Array). Alternatively, it may be realized in software by a computer such as a DSP (Digital Signal Processor) or a microcomputer.

  1, 1A: Speaker switching device, 2A to 2D: Speaker, 3: Microphone, 10: Audio signal input unit, 11: Volume adjustment unit, 12: Speaker switching unit, 13: Calculation unit, 14, 14A: Storage unit, 15 15A: Control unit, 16A, 16B: Audio signal output unit, 17: Sound source unit, 18A: First input switching unit, 18B: Second input switching unit

Claims (6)

A speaker switching device connected to a plurality of speakers having different frequency characteristics,
Switching means for switching an audio signal supply destination from among the plurality of speakers;
When the supply destination of the audio signal is switched by the switching means, the volume of the audio signal is adjusted according to the volume level adjustment amount determined according to the difference between the frequency characteristic of the speaker before switching and the frequency characteristic of the speaker after switching. A loudspeaker switching device, comprising: a volume control unit configured to adjust a volume level. The speaker switching device according to claim 1,
When switching the supply destination of the audio signal between a speaker having a wideband frequency characteristic and a speaker having a narrowband frequency characteristic, the volume level of the speaker having the narrowband frequency characteristic is maximized. The speaker switching device, wherein the volume level adjustment amount is set so that the volume level is the same as the volume level in the same band in the speaker having the broadband frequency characteristics. The speaker switching device according to claim 1 or 2,
Arithmetic means for detecting a frequency distribution of the audio signal;
Identifying a speaker having a frequency characteristic that most closely matches the frequency distribution detected by the computing means, and controlling the switching means to switch the supply destination of the audio signal to the identified speaker; Furthermore, the speaker switching device characterized by having. The speaker switching device according to claim 3,
A microphone for collecting reproduced sound from the plurality of speakers;
Storage means for storing frequency characteristics of each of the plurality of speakers,
The control means includes
A predetermined noise signal is supplied while switching the plurality of speakers in order by controlling the switching means, and the calculation means detects the frequency distribution of the reproduced sound collected by the microphone, and the detected reproduced sound is detected. Is stored in the storage means as a frequency characteristic of the speaker to which the noise signal is supplied,
When the audio signal supply destination is switched by the switching unit, the volume level adjustment is performed based on the difference between the frequency characteristic of the speaker before switching and the frequency characteristic of the speaker after switching stored in the storage unit. A speaker switching device characterized by determining an amount and outputting the volume level adjustment amount to the volume adjustment means. The speaker switching device according to claim 1 or 2,
The audio signal is provided with a genre code for identifying the genre of the content represented by the audio signal,
Control means for controlling the switching means so as to specify a speaker previously associated with the genre code assigned to the audio signal and switch the supply destination of the audio signal to the specified speaker. The speaker switching device characterized by this. Multiple speakers with different frequency characteristics,
An audio device comprising: the speaker switching device according to claim 1 connected to the plurality of speakers.

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