JP2019126174A - Audio driving device - Google Patents

Abstract

To provide an audio driving device capable of reducing noise at low cost.SOLUTION: An audio driving device 1 is provided with: a power storage device group 10 which has a plurality of power storage device pairs 13 consisting of a first power storage device 11 in which one of a pair of powers to be applied to an acoustic signal amplifier 4 which is provided in audio equipment 3 as a power supply is stored, and a second power storage device 12 in which the other of the pair of powers to be applied to the acoustic signal amplifier 4 as the power supply is stored based on output power of an AC/DC converter 2, and of which the plurality of device pairs 13 are connected in parallel with each other between the AC/DC converter 2 and the acoustic signal amplifier 4; and input side switches 20 which are provided between the AC/DC converter 2 and each of the plurality of power storage device pairs 13 to change connection states between the AC/DC converter 2 and each of the power storage device pairs 13.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an audio drive device for supplying power to an audio device.

  Conventionally, audio equipment is widely used, but in this type of audio equipment, an acoustic signal amplifier related to the voice is amplified by an acoustic signal amplifier before the voice is output from the speaker. Although direct current power is supplied to such an acoustic signal amplifier as a power supply, when noise is superimposed on alternating current power when the supplied power is one converted from alternating current power to direct current power, an acoustic signal is generated. The noise is also superimposed on the acoustic signal amplified by the amplifier, which may affect the sound output from the speaker. Therefore, techniques for suppressing such superposition of noise have been studied (for example, Patent Documents 1 and 2).

  Patent Document 1 describes an audio signal processing circuit. In this audio signal processing circuit, a switch is provided between the output terminal of the operational amplifier that amplifies the audio signal (corresponding to the above "acoustic signal") and the inverting terminal, and the switch corresponds to the voltage value of the power supply voltage supplied to the operational amplifier. The noise is reduced by opening and closing the switch.

  Patent Document 2 describes an audio signal processing circuit that reduces noise. The audio signal processing circuit is configured to include an operational amplifier, and the operational amplifier is provided with a capacitor for supplying a bias voltage superimposed on the audio signal to the operational amplifier. Based on the comparison result of the voltage of the capacitor and the target value of the bias voltage, the value of the charging current of the capacitor is adjusted to reduce noise.

JP, 2013-110726, A JP, 2010-148182, A

  The audio signal processing circuit described in Patent Document 1 has a circuit configuration including a plurality of channels having a plurality of operational amplifiers, and the circuit configuration is complicated. Further, since it is necessary to switch the switch in accordance with the voltage value of the power supply voltage, switch control of the switch is also complicated. Further, also in the audio signal processing circuit described in Patent Document 2, since the charging circuit and the discharging circuit for controlling the capacitor are provided, the circuit configuration and the control method thereof become complicated.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an audio drive device capable of reducing noise without using a complicated control method with a simple circuit configuration.

The characteristic configuration of the audio drive device according to the present invention is that, based on the output power of the AC / DC converter, one of the pair of powers applied as a power source to the acoustic signal amplifier provided in the audio device is stored. A plurality of storage device pairs comprising a first storage device and a second storage device for storing power of the other of the pair of powers applied as a power source to the acoustic signal amplifier; A storage device pair is provided between a storage device group connected in parallel with each other between the AC / DC converter and the acoustic signal amplifier, and the AC / DC converter and each of the plurality of storage device pairs. An input-side switch for changing the connection state between the AC / DC converter and each of the storage device pair;
An output-side switch provided between each of the plurality of storage device pairs and the acoustic signal amplifier for changing a connection state between each of the storage device pair and the acoustic signal amplifier; the first storage device; The first storage of electricity based on voltage information indicating voltage values of respective output terminals of the second storage device and sound pressure information indicating sound pressure level of sound output from a speaker provided in the audio device. When storing the device and the second storage device with the output power, the storage device is provided between the storage device pair including the first storage device and the second storage device and the AC / DC converter. Closing the input-side switch and opening the output-side switch provided between the storage device pair and the acoustic signal amplifier; When discharging power as the power supply from the storage device and the second storage device, between the storage device pair including the first storage device and the second storage device and the AC / DC converter And a switch control unit for opening the provided input side switch and for closing the output side switch provided between the storage device pair and the acoustic signal amplifier. .

  With such a characteristic configuration, the AC power and the audio device are completely stored by temporarily storing AC power in the storage device pair as DC power and driving the audio device with the power stored in the storage device pair. It can be separated. Therefore, even when noise is superimposed on AC power, noiseless DC power can be supplied to the audio device, so that noise can be prevented from being superimposed on the audio signal output from the audio device. It becomes possible. Further, by connecting a plurality of power storage device pairs in parallel, it is possible to prevent an insufficient power supply to the audio device. Furthermore, with this configuration, noise can be reduced with a simple configuration as compared with the prior art, without using a complex circuit (for example, a filter) used to reduce noise superimposed on AC power. be able to. Also, in order to suppress the influence of noise, it is necessary to take into consideration the routing of the wiring, but with this configuration, the degree of freedom of the wiring can be improved. Also, in the audio equipment, when using a large output amplifier, the size of the amplifier was increased because a transformer or diode was prepared according to the required power, but in the present configuration, a storage device pair is used as a power supply Therefore, miniaturization is possible.

  When the switch control unit switches the storage device pair that discharges the power as the power supply, the first storage device and the second storage device of a predetermined storage device pair of the plurality of storage device pairs are switched. After starting the discharge of the power from the storage device, the first storage device and the second storage device of another storage device pair different from the predetermined storage device pair of the plurality of storage device pairs It is preferable to stop the discharge of the power from.

  With this configuration, the power stored in the storage device pair can always be supplied to the audio device, so that an audio signal to which noise is not superimposed can be generated. Therefore, it is possible to reproduce a sound that does not become offensive from the audio device (a sound without discomfort).

  Further, in the case where there are a plurality of storage device pairs including the first storage device and the second storage device which have been stored, the switch control unit may have a number corresponding to the magnitude of the output required for the speaker. It is preferable to simultaneously discharge the power from the storage device pair.

  With such a configuration, it is possible to output a large volume of sound from the audio device and output a sound with a deep bass effect.

  Preferably, the first storage device and the second storage device are capacitors.

  As described above, by using a capacitor as a power source of power supplied to an audio device, AC noise can be reduced, and music can be enjoyed with a good sound. In addition, by using, for example, a lithium ion capacitor or an electric double layer capacitor as the capacitor, high capacity and low impedance can be realized, and therefore, a speaker with large output power can be driven. In particular, a lithium ion capacitor has a high capacitance as compared to an electric double layer capacitor, so that the volume occupied by the capacitor can be reduced, which is further advantageous for miniaturization.

It is a figure which shows the state of the audio drive apparatus at the time of the power supply of audio. It is a figure which shows the state of the audio drive apparatus at the time of music reproduction of audio. It is a figure which shows the state of the audio drive apparatus at the time of music reproduction of audio. It is a figure which shows the state of the audio drive apparatus at the time of music reproduction of audio. It is a figure which shows the waveform of the acoustic signal output from audio. It is a flow chart which shows processing of an audio drive. It is a timing chart which shows switch change timing of a switch. It is a timing chart which shows switch change timing of a switch. It is a timing chart which shows switch change timing of a switch.

  The audio drive device according to the present invention is configured to be able to drive an audio device with low noise. Hereinafter, the audio drive device 1 of the present embodiment will be described.

  FIG. 1 is a block diagram schematically showing the configuration of the audio drive device 1. The audio drive device 1 includes a storage device group 10, an input switch 20, an output switch 30, and a switch controller 40.

  The storage device group 10 is configured such that, based on the output power of the AC / DC converter 2, one of the pair of power applied as a power supply to the acoustic signal amplifier 4 provided in the audio device 3 is stored. A plurality of power storage device pairs 13 each including the power storage device 11 and a second power storage device 12 for storing the other power of the pair of power applied as a power source to the acoustic signal amplifier 4 are provided.

  The AC / DC converter 2 has a function of converting AC power into DC power, and is configured to include a transformer 6 and a diode bridge 7 in the present embodiment. Since the AC / DC converter 2 provided with the transformer 6 and the diode bridge 7 is known, the description thereof is omitted here. Here, the output power output from the AC / DC converter 2 is applied as a power source to an acoustic signal amplifier 4 described later. Since the acoustic signal amplifier 4 requires application of a pair of voltages having different voltage values as a power supply, in the present embodiment, the AC / DC converter 2 is also provided as a pair. In the following, when the pair of AC / DC converters 2 are distinguished, one AC / DC converter 2 is described as an AC / DC converter 2A, and the other AC / DC converter 2 is described as an AC / DC converter 2B.

  The audio device 3 is a device capable of outputting sound, and includes both a stationary type without movement and a portable type capable of moving. Such audio device 3 has an acoustic signal amplifier 4 and a speaker 5. The acoustic signal amplifier 4 is a device for amplifying an audio signal output from the speaker 5, and corresponds to, for example, an operational amplifier. In this embodiment, the acoustic signal amplifier 4 is a so-called dual power supply, and the output voltage of the AC / DC converter 2A and the output voltage of the AC / DC converter 2B are used as the dual power supply. Therefore, it is preferable that the voltage value of the output voltage of the AC / DC converter 2A is a positive value, and the voltage value of the output voltage of the AC / DC converter 2B is a negative value.

  The storage device pair 13 is provided with two storage device pairs 13, and includes one first storage device 11 and one second storage device 12. Hereinafter, one storage device pair 13 will be described as a storage device pair 13A, and the other storage device pair 13 will be described as a storage device pair 13B. Here, in the present embodiment, the first power storage device 11 and the second power storage device 12 are configured using capacitors. Therefore, hereinafter, the first storage device 11 will be described as the first capacitor 11, and the second storage device 12 will be described as the second capacitor 12.

  The storage device pair 13A and the storage device pair 13B are connected in parallel with each other between the AC / DC converter 2 and the acoustic signal amplifier 4. More specifically, in this embodiment, between the AC / DC converter 2A and one of the power supply terminals of the acoustic signal amplifier 4, the first capacitor 11 of the storage device pair 13A and the first storage capacitor pair 13B Capacitor 11 is connected in parallel with each other, and between the AC / DC converter 2B and the other power supply terminal of the acoustic signal amplifier 4, the second capacitor 12 of the storage device pair 13A and the first storage device pair 13B Two capacitors 12 are connected in parallel with each other.

  Thereby, the first capacitor 11 of the storage device pair 13A and the first capacitor 11 of the storage device pair 13B can be stored based on the output voltage of the AC / DC converter 2A, and the stored power is acoustically The voltage can be applied to one power supply terminal of the signal amplifier 4. Further, the second capacitor 12 of the storage device pair 13A and the second capacitor 12 of the storage device pair 13B can each store electric power based on the output voltage of the AC / DC converter 2B, and the stored electric power is an acoustic signal The voltage can be applied to the other power supply terminal of the amplifier 4.

  The input-side switch 20 is provided between the AC / DC converter 2 and each of the plurality of storage device pairs 13, and changes the connection state between the AC / DC converter 2 and each of the storage device pair 13. In the present embodiment, two storage device pairs 13 (storage device pair 13A and storage device pair 13B) are provided. Therefore, the input side switch 20 is provided between the AC / DC converter 2 and the storage device pair 13A, and between the AC / DC converter 2 and the storage device pair 13B. Hereinafter, the input switch 20 between the AC / DC converter 2 and the storage device pair 13A is referred to as an input switch 20A, and the input switch 20 between the AC / DC converter 2 and the storage device pair 13B is an input switch It explains as 20B. The connection state is a general term for the closed state in which the input terminal and the output terminal are short-circuited and the open state in which the input terminal and the output terminal are opened for each of the input switch 20A and the input switch 20B. It is used.

  As shown in FIG. 1, in the present embodiment, when the input-side switch 20A switches the AC / DC converter 2A and the first capacitor 11 of the storage device pair 13A to one of a short circuit state and an open state, The AC / DC converter 2B and the second capacitor 12 of the storage device pair 13A are also configured as switches that are switched to one of the short circuit state and the open state. Further, when the input-side switch 20B switches the AC / DC converter 2A and the first capacitor 11 of the storage device pair 13B to one of the shorted state and the open state, the input-side switch 20B The second capacitor 12 is also configured as a switch that is switched to one of the short circuit state and the open state.

  The output side switch 30 is provided between each of the plurality of storage device pairs 13 and the acoustic signal amplifier 4, and changes the connection state between each of the storage device pair 13 and the acoustic signal amplifier 4. In the present embodiment, two power storage device pairs 13 are provided. Therefore, the output side switch 30 is provided between the storage device pair 13A and the acoustic signal amplifier 4, and between the storage device pair 13B and the acoustic signal amplifier 4. In the following, the output switch 30 between the storage device pair 13A and the acoustic signal amplifier 4 is the output switch 30A, and the output switch 30 between the storage device pair 13B and the acoustic signal amplifier 4 is the output switch 30B. explain. The connection state is a generic name of the open state in which the input terminal and the output terminal are in the open state and the input terminal and the output terminal are in the open state in which the input terminal and the output terminal are short-circuited. It is used.

  As shown in FIG. 1, in the present embodiment, when the output-side switch 30A switches the first capacitor 11 and the acoustic signal amplifier 4 of the storage device pair 13A to either the shorted state or the open state, The second capacitor 12 of the device pair 13A and the acoustic signal amplifier 4 are also configured as switches that are switched to one of the short circuit state and the open state. Also, when the output-side switch 30B switches the first capacitor 11 and the acoustic signal amplifier 4 of the storage device pair 13B to either the shorted state or the open state, the second capacitor 12 and the acoustic of the storage device pair 13B are The signal amplifier 4 is also configured as a switch that is switched to one of the short circuit state and the open state.

  Although DC power is applied to the acoustic signal amplifier 4 from each of the first and second capacitors 11 and 12 as described above, in order to obtain a DC voltage of a voltage value suitable for the acoustic signal amplifier 4 A DC / DC converter 8 is provided between the storage device pair 13 and the acoustic signal amplifier 4. The DC / DC converter 8 also includes a pair of the DC / DC converter 8A and the DC / DC converter 8B. The DC / DC converter 8A converts the voltage value of the voltage output from the first capacitor 11 of the storage device pair 13A and the first capacitor 11 of the storage device pair 13B into a constant voltage value consisting of a predetermined voltage value. It is possible to constitute using any of a terminal regulator, a step-down DC / DC converter, and a step-up / step-down DC / DC converter. Further, the DC / DC converter 8B converts the voltage value of the voltage output from the second capacitor 12 of the storage device pair 13A and the second capacitor 12 of the storage device pair 13B into a constant voltage value including a predetermined voltage value. It is possible to configure using any one of a three-terminal regulator, a step-down DC / DC converter, and a step-up / step-down DC / DC converter.

  The switch control unit 40 generates voltage information indicating voltage values of the output terminals of the first capacitor 11 and the second capacitor 12 and a sound indicating the sound pressure level of the sound output from the speaker 5 provided in the audio device 3. The connection state of the input switch 20 and the output switch 30 is switched based on the pressure information. The switch control unit 40 includes a first capacitor 11 of the storage device pair 13A, a second capacitor 12 of the storage device pair 13A, a first capacitor 11 of the storage device pair 13B, and a second capacitor 12 of the storage device pair 13B. The voltage information indicating the voltage value of each output terminal is transmitted from each of. The storage state of each of the first capacitor 11 and the second capacitor 12 can be grasped by the voltage value of the output terminal.

  Further, sound pressure information indicating the sound pressure level of the sound output from the speaker 5 is also transmitted to the switch control unit 40. The sound pressure level of the sound output from the speaker 5 corresponds to the output power required for the speaker 5.

  The switch control unit 40 sets the connection state of the input switch 20 and the output switch 30 according to the storage state of each of the first capacitor 11 and the second capacitor 12 and the output power required for the speaker 5. Switch.

  When storing the first capacitor 11 and the second capacitor 12 with the output power of the AC / DC converter 2, the switch control unit 40 is a pair of storage devices including the first capacitor 11 and the second capacitor 12. The input switch 20 provided between the power supply device 13 and the AC / DC converter 2 is closed, and the output switch 30 provided between the storage device pair 13 and the acoustic signal amplifier 4 is opened. .

  That is, switch control unit 40 stores the first capacitor 11 of storage device pair 13A with the output power of AC / DC converter 2A, and the second capacitor of storage device pair 13A with the output power of AC / DC converter 2B. When 12 is stored, as shown in FIG. 1 and FIG. 3, the input side switch 20A provided between the storage device pair 13A and the AC / DC converter 2A and the AC / DC converter 2B is closed. And, the output side switch 30A provided between the storage device pair 13A and the acoustic signal amplifier 4 is opened.

  On the other hand, when storing the first capacitor 11 of the storage device pair 13B with the output power of the AC / DC converter 2A and storing the second capacitor 12 of the storage device pair 13B with the output power of the AC / DC converter 2B: As shown in FIG. 2, the switch control unit 40 closes the input-side switch 20B provided between the storage device pair 13B and the AC / DC converter 2A and the AC / DC converter 2B, and The output switch 30B provided between the storage device pair 13B and the acoustic signal amplifier 4 is opened.

  When the switch control unit 40 discharges power from the first capacitor 11 and the second capacitor 12 as a power supply of the acoustic signal amplifier 4, a storage device including the first capacitor 11 and the second capacitor 12. The input switch 20 provided between the pair 13 and the AC / DC converter 2 is opened, and the output switch 30 provided between the storage device pair 13 and the acoustic signal amplifier 4 is closed. Do.

  That is, when the switch control unit 40 discharges the power stored in each of the first capacitor 11 of the storage device pair 13A and the second capacitor 12 of the storage device pair 13A as a power supply of the acoustic signal amplifier 4, as shown in FIG. As shown in the figure, the input side switch 20A provided between the storage device pair 13A and the AC / DC converter 2A and the AC / DC converter 2B is opened, and the storage device pair 13A and the acoustic signal amplifier are The output switch 30A provided between the terminal 4 and the terminal 4 is closed.

  On the other hand, when the power stored in each of the first capacitor 11 of the storage device pair 13B and the second capacitor 12 of the storage device pair 13B is discharged as the power supply of the acoustic signal amplifier 4, as shown in FIG. The switch control unit 40 opens the input side switch 20B provided between the storage device pair 13B and the AC / DC converter 2A and the AC / DC converter 2B, and the storage device pair 13B and the acoustic signal amplifier 4 And the output-side switch 30B provided therebetween is closed.

  As described above, the switch control unit 40 can output the audio from the speaker 5 by changing the connection state of the input switch 20 and the output switch 30. Here, depending on the sound output from the speaker 5, a larger output power may be required of the speaker 5. The switch control unit 40 can grasp that such a request has been made to the speaker 5 based on the sound pressure information.

  When there are a plurality of storage device pairs 13 including the first capacitor 11 and the second capacitor 12 stored, the switch control unit 40 has a number of storage device pairs according to the size of the output required for the speaker 5. Discharge power from 13 at the same time. That is, with respect to the power output from the storage device pair 13, the size of the output that can be output from the speaker 5 is determined in advance as the specification of the speaker 5. Therefore, the switch control unit 40 discharges the power stored in the plurality of storage device pairs 13 in order to output the power including the output (power) required for the speaker 5, and the input switch 20 and the output side. The connection state of the switch 30 is switched. In FIG. 4, an example of discharging the power stored in each of the first capacitor 11 and the second capacitor 12 of the storage device pair 13A and the first capacitor 11 and the second capacitor 12 of the storage device pair 13B Is shown.

  In such a case, as shown in FIG. 4, the switch control unit 40 opens the input side switch 20A provided between the storage device pair 13A and the AC / DC converter 2A and the AC / DC converter 2B. And the input side switch 20B provided between the storage device pair 13B and the AC / DC converter 2A and the AC / DC converter 2B is opened, and between the storage device pair 13A and the acoustic signal amplifier 4 The provided output side switch 30A is closed, and the output side switch 30B provided between the storage device pair 13B and the acoustic signal amplifier 4 is closed.

  Thereby, the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A and the first capacitor 11 and the second capacitor 12 of the storage device pair 13B can be discharged. It becomes possible.

  5, voltage waveforms relating to the power output from the first capacitor 11 and the second capacitor 12 of the audio drive device 1 and an output signal (output from the audio device 3 driven by the audio drive device 1) The waveform of the audio signal is shown.

  As shown in FIG. 5A, when noise is superimposed on AC power input to the AC / DC converter 2, as shown in FIG. 5B in the conventional audio drive device. In addition, noise is also superimposed on the outputs (voltage waveforms) of the first capacitor 11 and the second capacitor 12, and as a result, as shown in FIG. 5C, the output signal output from the audio device 3 Noise was also superimposed on (audio signal). For this reason, the noise may not be a pleasant voice.

  However, in the audio driving device 1 of the present embodiment, noise is not superimposed on the outputs (voltage waveforms) of the first capacitor 11 and the second capacitor 12 as shown in FIG. As shown in (e) of FIG. 5, noise can be prevented from being superimposed also on the output signal (audio signal) output from the audio device 3. For this reason, it becomes possible to enjoy the desired sound with the audio device 3.

  Next, processing of the audio drive device 1 will be described using the flowchart of FIG. When the audio drive device 1 is driven, the first capacitor 11 and the second capacitor 12 of the storage device pair 13A are stored (step # 1). The switch control unit 40 closes the input switch 20A and opens the output switch 30A.

  When the storage of the first capacitor 11 and the second capacitor 12 is completed (Step # 2: Yes), the switch control unit 40 causes the input switch 20A to be opened, and the output switch 30A is maintained open. . Subsequently, the first capacitor 11 and the second capacitor 12 of the storage device pair 13B are stored (step # 3). In this case, the switch control unit 40 closes the input switch 20B and opens the output switch 30B.

  When reproduction of voice (music) is started by the audio device 3 (step # 4: Yes), reproduction of music is performed by the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A. It is performed (step # 5). In this case, the switch control unit 40 maintains the open state of the input switch 20A and closes the output switch 30A. During playback of the song, the remaining amount of power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A is confirmed. If the remaining amount is sufficient (step # 6: Yes) and the tune being reproduced is not finished (step # 7: No), the process returns to step # 6 and the process is continued.

  In step # 7, the tune being reproduced is ended (step # 7: Yes), and when the reproduction is ended (step # 8: No), the audio drive device 1 ends the processing. On the other hand, when the reproduction is not finished (step # 8: Yes), the process returns to step # 6 and the process is continued.

  In step # 4, when the reproduction of the music is not started by the audio device 3 (step # 4: No) and the storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is not completed (Step # 9: No), the process returns to Step # 4 and is continued. In step # 9, when storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is completed (step # 9: Yes), the switch control unit 40 opens the input switch 20B. In this state, the output switch 30A is kept open. In this state, playback of music by the audio device 3 is awaited (step # 10: No). In step # 10, when the reproduction of the music is started by the audio device 3 (step # 10: Yes), the process returns to step # 5 and the process is continued.

  In step # 6, when the remaining amount of power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A is not sufficient during reproduction of a song by the audio device 3 (step # 6: No), music reproduction is performed by the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B (step # 11). In this case, the switch control unit 40 opens the output switch 30A and the input switch 20B and closes the output switch 30B. Since the capacitances of the first capacitor 11 and the second capacitor 12 are set to drive the audio device 3 for about 5 to 10 minutes, the storage of electricity is completed in a few seconds. Therefore, at this time, the storage amount of the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is sufficient during reproduction of a curve by the first capacitor 11 and the second capacitor 12 of the storage device pair 13A. It has become.

  During reproduction of music by the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B, the switch control unit 40 closes the input switch 20A and opens the output switch 30A. Is stored, and the first capacitor 11 and the second capacitor 12 of the storage device pair 13A are stored (step # 12).

  During reproduction of a song by the audio device 3, the remaining amount of power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is sufficient (step # 13: Yes). If the music has not ended (step # 14: No), the process returns to step # 13 and the process is continued.

  In step # 14, the tune being reproduced ends (step # 14: Yes), and when the reproduction is ended (step # 15: No), the audio drive device 1 ends the process. On the other hand, in the case where the playback is continued without ending (step # 15: Yes), the process returns to step # 5 and the process is continued.

  In step # 13, when the remaining amount of power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is not sufficient during reproduction of a song by the audio device 3 (step # 13: No), music is reproduced by the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A (step # 16). In this case, the switch control unit 40 opens the input switch 20A and closes the output switch 30A. Further, the first capacitor 11 and the second capacitor 12 of the storage device pair 13B are stored (step # 17). In this case, the switch control unit 40 closes the input switch 20B and opens the output switch 30B. Thereafter, the process returns to step # 6 and the process is continued. The audio drive device 1 performs processing in accordance with the above flow.

  An example of a timing chart for opening and closing the input switch 20 and the output switch 30 is shown in FIG. At t1, the input side switch 20A is closed, and storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13A is started. When the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A exceeds a predetermined level (t2), the input switch 20A is opened and the input switch 20B is closed. .

  When the reproduction of the music (an example of the sound) by the audio device 3 is started at t3, the output switch 30A is closed. When the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B reaches or exceeds a predetermined level (t4), the input switch 20B is opened.

  If the music changes while the music is reproduced by the audio device 3 (t5), the input switch 20A is closed, the output switch 30B is opened, and the first capacitor 11 of the storage device pair 13A and the Storage of the second capacitor 12 is started. In addition, when the reproduction of the music is continued, the output switch 30B is closed, and the music is reproduced by the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B. .

  When the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A exceeds a predetermined level (t6), the input switch 20A is opened.

  During playback of a song by the audio device 3, for example, when the song changes (t7), the output switch 30B is closed, and the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A The song is played back by the Further, the input switch 20B is closed, the output switch 30B is opened, and storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is started. As described above, the input switch 20 and the output switch 30 are opened and closed.

  Here, as described above, the capacitances of the first capacitor 11 and the second capacitor 12 are set such that the audio device 3 can be driven for about 5 to 10 minutes, but some songs may exceed 10 minutes depending on the music. is assumed. In such a case, only the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A, or only the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B. Is not enough.

  Under such circumstances, switch control unit 40 switches, for example, from storage device pair 13A to storage device pair 13B to switch storage device pair 13 that discharges power as a power source. After starting the discharge of power from the first capacitor 11 and the second capacitor 12 of the storage device pair 13B, storage of another storage device pair different from the storage device pair 13B of the plurality of storage device pairs 13 Discharge of power from the first capacitor 11 and the second capacitor 12 of the device pair 13A is stopped.

  FIG. 8 shows a timing chart in such a case. Since t1 to t4 are the same as those in FIG. 7 described above, the description will be omitted. If the electric power stored in the first capacitor 11 and the second capacitor 12 of the electric storage device pair 13A is not sufficient during reproduction of the music by the audio device 3, or if it is predicted that the electric power is not sufficient, At t10 during the playback of the song, the output switch 30B is closed. In this case, the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13A and the storage device are used to reproduce the music in the period t10 to t5 (the hatched section in FIG. 8). The power stored in the first capacitor 11 and the second capacitor 12 of the pair 13B is used.

  When utilization of the power stored in the first capacitor 11 and the second capacitor 12 of the storage device pair 13B is started, at t5, the input switch 20A is closed and the output switch 30B is opened. The storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13A is started. Thus, after the discharge of the power stored in the first capacitor 11 and the second capacitor 12 to be used next is started, the discharge of the first capacitor 11 and the second capacitor 12 to be stored next is stopped. By doing this, even when the music to be reproduced by the audio device 3 is long, it is possible to smoothly reproduce the music without interruption.

  Furthermore, although the flow is shown in FIG. 7, the timing chart in the case where the magnitude of the output required for the speaker 5 is large is shown in FIG. In the example of FIG. 9, from t1 to t2, storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13A and storage of the first capacitor 11 and the second capacitor 12 of the storage device pair 13B Has been done. Of course, both storages may be performed at different timings.

  When the magnitude of the output required for the speaker 5 is large in the stored state (the stored power of the first capacitor 11 and the second capacitor 12 of the storage device pair 13A, or the storage device pair 13B In the case where the stored power of the first capacitor 11 and the second capacitor 12 is not sufficient), the output switch 30A and the output switch 30B are closed. As a result, it becomes possible to supply power according to the output required of the speaker 5.

  When the music is finished, the input switch 20A and the input switch 20B are closed, and the output switch 30A and the output switch 30B are opened (see t4 in FIG. 9). When the storage amount reaches a predetermined value and the next music piece is reproduced (t5 in FIG. 9), the input switch 20A and the input switch 20B are opened, and the output switch 30A and the output switch 30B are closed. (See t5 in FIG. 9). When the output required of the speaker 5 is large, the opening and closing of the input switch 20 and the output switch 30 are performed according to such a timing chart.

Other Embodiments
In the above embodiment, an example in which the storage device pair 13A is switched to the storage device pair 13B in the case where the music is long, the switch control unit 40 generates power from the first capacitor 11 and the second capacitor 12 of the storage device pair 13B. It has been described that the discharge of the power from the first capacitor 11 and the second capacitor 12 of the storage device pair 13A is stopped after the discharge of the power storage device 13 is started. In the case where the storage device pair 13B is switched to the storage device pair 13A when the music is long, the switch control unit 40 causes the first capacitor 11 and the second capacitor 12 of the storage device pair 13A to start discharging power. After that, it is naturally possible to stop the discharge of the power from the first capacitor 11 and the second capacitor 12 of the storage device pair 13B. Also, when switching from the storage device pair 13A to the storage device pair 13B and switching from the storage device pair 13B to the storage device pair 13A, it is also possible to switch as described above. Of course, when switching from the storage device pair 13A to the storage device pair 13B, discharge of power from the first capacitor 11 and the second capacitor 12 of the storage device pair 13B starts simultaneously with the first capacitor of the storage device pair 13A. It is also possible to configure to stop the discharge of the power from the 11 and the second capacitor 12.

  In the above embodiment, the switch control unit 40 is described as simultaneously discharging power from the storage device pairs 13 of the number according to the size of the output required for the speaker 5. However, the first capacitor 11 and the second By increasing the capacity of the capacitor 12, it is possible to configure so as not to discharge the power at the same time.

  Although the first storage device 11 and the second storage device 12 have been described as capacitors in the above embodiment, the first storage device 11 and the second storage device 12 are configured using devices other than capacitors. It is also possible.

  The present invention can be used in an audio drive device for supplying power to an audio signal amplifier provided in an audio device. Further, according to the present invention, since a complicated control method is not required with a simple circuit configuration, it is possible to provide an audio drive device capable of reducing noise at low cost.

1: Audio driver 2: AC / DC converter 3: Audio equipment 4: Acoustic signal amplifier 5: Speaker 10: Power storage device group 11: first capacitor (first power storage device)
12: Second capacitor (second power storage device)
13: Storage device pair 20: Input side switch 30: Output side switch 40: Switch controller

Claims (4)

According to the output power of the AC / DC converter, the first power storage device for storing power of one of the pair of powers applied as a power source to the audio signal amplifier provided in the audio device and the audio signal amplifier And a plurality of power storage device pairs comprising a second power storage device for storing the other power of the pair of power applied as the plurality of power storage device pairs, the plurality of power storage device pairs being the AC / DC converter and the acoustic A storage device group connected in parallel with each other between the signal amplifier,
An input-side switch provided between the AC / DC converter and each of the plurality of storage device pairs, for changing the connection state between the AC / DC converter and each of the storage device pairs;
An output side switch provided between each of the plurality of storage device pairs and the acoustic signal amplifier, and changing a connection state between each of the storage device pair and the acoustic signal amplifier;
Based on voltage information indicating voltage values of respective output terminals of the first storage device and the second storage device and sound pressure information indicating sound pressure level of sound output from a speaker provided in the audio device When storing the first storage device and the second storage device with the output power, the storage device pair including the first storage device and the second storage device and the AC / DC converter And the output side switch provided between the storage device pair and the acoustic signal amplifier is opened, and the first storage device and the output signal switch are provided. When discharging power from the second storage device as the power supply, the storage device comprising the first storage device and the second storage device A switch for opening the input switch provided between the pair and the AC / DC converter and for closing the output switch provided between the storage device pair and the acoustic signal amplifier A control unit,
An audio drive comprising:   The switch control unit switches the first storage device and the second storage device of a predetermined storage device pair of the plurality of storage device pairs when switching the storage device pair that discharges the power as the power supply. From the first storage device and the second storage device of another storage device pair different from the predetermined storage device pair of the plurality of storage device pairs after starting the discharge of the power from the The audio driving device according to claim 1, wherein the discharge of the power is stopped.   In the case where there are a plurality of storage device pairs including the first storage device and the second storage device stored, the switch control unit stores a number of storage devices according to the size of the output required for the speaker. The audio drive device according to claim 1 or 2, wherein the power is discharged simultaneously from the pair.   The audio drive device according to any one of claims 1 to 3, wherein the first storage device and the second storage device are capacitors.

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