JP6507893B2 - Amplification device and speaker device - Google Patents

Description

  The present invention relates to an amplification device that amplifies an audio signal, and a speaker device that includes the amplification device and a speaker.

  Some amplification devices that amplify audio signals are manufactured for electric stringed instruments such as electric guitars and electric basses. In addition, among the amplification devices for electric stringed instruments, there is one manufactured as a speaker device in which the amplification device and the speaker are housed in one case (see, for example, Patent Document 1). Such a speaker device or the like rectifies a voltage from an AC power supply and uses it as a power supply voltage. In a speaker device or the like using an AC power supply, for example, a current generated by electromagnetic induction caused by an electromagnetic wave generated from a power supply line routed around in a room mixes in, and this becomes noise (hereinafter referred to as "ham noise"). It may be output as voice.

  In particular, a speaker device for an electric stringed instrument or the like has a problem that considerably offensive ham noise is output as voice when not playing. In order to solve this, an effect circuit such as a noise gate that attenuates an audio signal below a certain level may be used. FIG. 16 is a graph showing an audio signal etc. output from the noise gate. The noise gate reduces the output level (closes the gate) when the input signal goes below a threshold. Also, the noise gate restores the output level (opens the gate) when the input signal becomes equal to or higher than the threshold. The noise gate generally specifies parameters such as the rate of attenuation, the switching envelope of the gate, and the frequency band to which the gate responds, in addition to the threshold. The noise gate has almost the same mechanism as an expander intended to artificially expand musical dynamics, but the expander has a difference in operation such as attenuating the input signal in proportion to the amount below the threshold.

JP, 2008-236406, A

  However, when a noise gate is used, an attack is delayed at the moment when the gate is opened, so that there is a problem that when the performance is resumed, the audio of cueing output from the speaker device or the like is interrupted. In addition, there is a problem that the listener can hear the output signal unnaturally because the output signal fluctuates. In addition, since the circuit hangs on the signal line and the sound changes, there is a problem that the player is disliked.

  An object of the present invention is to reduce the output of hum noise as speech.

  An amplifying apparatus according to a first aspect of the present invention includes: a battery; an amplifying unit for amplifying an audio signal; a charging circuit for supplying a voltage from an AC power supply to the battery or supplying each unit constituting the apparatus; When the switch connected between the power supply, the signal detection circuit for detecting the audio signal, and the signal detection circuit detect the audio signal having a predetermined volume or more, the switch is turned on, and the AC is switched on. When the voltage from the power supply is supplied to each unit constituting the apparatus and the signal detection circuit detects the audio signal smaller than a predetermined volume, the switch is turned off and the voltage from the battery is And a control circuit to be supplied to each unit constituting the own apparatus.

  A conventional amplification device using an AC power supply is connected to earth via the AC power supply. For this reason, the ground level of the amplification device is fixed at the ground level. For example, when an electric stringed instrument is connected to a conventional amplification device, ham noise mixed into the circuit of the electric stringed instrument with high impedance by electromagnetic induction is input to the amplification device. As a result, the difference between the output of the amplification device and the ground level (earth ground level) of the amplification device can be produced as a hum noise, so that the hum noise is output as voice.

  When the amplification device is operated with the voltage from the battery instead of the voltage from the AC power supply, the amplification device floats from the ground level because it is not connected to the ground via the AC power supply. ing. For this reason, for example, since the hum noise contained in the audio signal output from the electric stringed instrument and the ground of the amplifier vibrate in phase, it is considered that the hum noise is less likely to be output as audio.

  In the present invention, when the signal detection signal detects an audio signal smaller than a predetermined sound volume, the control circuit turns off the switch and supplies the voltage from the battery to each unit constituting the apparatus. As a result, as described above, since the amplification device is not connected to the ground, the output of hum noise as sound is reduced. In particular, when an electric stringed instrument is connected to the amplification device, it is reduced that the hum noise is output as sound when the electric stringed instrument is not played.

  In addition, when an electric stringed instrument is connected to the amplification device, there is no need to use a noise gate or the like to reduce hum noise, so there is no problem that the sound of cueing at the time of resuming performance is interrupted. In addition, since the battery is operated only when an audio signal having a predetermined volume or more is not detected, a small battery may be used.

  An amplifying apparatus according to a second aspect of the present invention is the amplifying apparatus according to the first aspect, wherein an amplifier gain control for adjusting a gain by the amplifier, a volume control for adjusting a volume, and an operation of the amplifier gain control. The apparatus further includes a gain detection circuit that detects a gain, and a volume detection circuit that detects a volume by the volume control, and the control circuit causes the gain detection circuit to detect a gain equal to or less than a predetermined value, and the volume When the detection circuit detects a volume equal to or lower than a predetermined value, the switch is turned on regardless of whether the signal detection circuit detects the audio signal equal to or higher than a predetermined volume, and the AC power supply is turned on. Is supplied to the respective units constituting the own apparatus.

  The amplifying device according to the first aspect of the invention supplies the voltage from the AC power supply to each portion constituting the device (battery charging) if the audio signal is equal to or higher than a predetermined volume. That is, for example, if the input source of the audio signal is an electric stringed instrument, there is a problem that the battery can be charged only when the electric stringed instrument is playing.

  Here, when the volume and gain are small, it is also difficult to hear hum noise. For this reason, in the present invention, when the gain detection circuit detects a gain equal to or less than a predetermined value and the volume detection circuit detects a volume equal to or less than a predetermined value, the control circuit The switch is turned on to supply the voltage from the AC power supply to each part constituting the apparatus regardless of whether an audio signal equal to or higher than the volume is detected. Therefore, even if the amplification device operates with the voltage from the AC power supply, the battery can be charged even when, for example, the electric stringed instrument is playing, without the hum noise being heard by the listener.

  An amplification device according to a third aspect of the invention is the amplification device according to the second aspect, wherein the control circuit detects that the gain detection circuit has a gain larger than a predetermined value, and the volume detection circuit has a magnitude larger than the predetermined value. When a volume is detected and the signal detection circuit detects the audio signal smaller than a predetermined volume, the switch is turned off to supply the voltage from the battery to each part constituting the apparatus. It is characterized by

  An amplification device according to a fourth aspect of the present invention is the amplification device according to the first aspect, wherein the control circuit turns off the switch and detects a voltage from the battery when the audio signal having a predetermined volume or more is not detected for a predetermined time. Are supplied to the respective units constituting the own apparatus.

  An amplification device according to a fifth aspect of the present invention is the amplification device according to any of the first to fourth aspects, further comprising an input terminal for connecting an electric stringed instrument, wherein the amplification unit is connected to the input terminal via the input terminal. The audio signal input from the electric stringed instrument is amplified.

  A speaker device according to a sixth aspect of the invention is characterized by comprising a speaker and the amplification device according to any of the first through fifth aspects of the invention.

  According to the present invention, the output of hum noise as voice is reduced.

It is a block diagram showing composition of a speaker apparatus concerning a 1st embodiment of the present invention. It is a figure which shows the audio | voice signal input, the ground, the audio | voice signal output, and earth ground in the amplifier in the case of operate | moving with the voltage from AC power supply. It is a figure which shows the audio | voice signal input, the ground, the audio | voice signal output, and earth ground in the amplifier in the case of operate | moving with the voltage from a battery. It is a graph which shows the audio | voice signal etc. which are output from a speaker apparatus. It is a block diagram which shows the structure of the speaker apparatus based on 2nd Embodiment of this invention. It is a figure for demonstrating detection of the gain by a gain detection circuit. It is a figure for demonstrating detection of the volume by a volume detection circuit. It is a figure which shows the truth table of a relay control circuit. It is a flowchart which shows the processing operation of a speaker apparatus. It is a figure which shows the state etc. of the battery in a speaker apparatus. It is a figure which shows the audio | voice signal output from a speaker apparatus. It is a figure which shows the audio | voice signal output from the speaker apparatus at the time of no signal. It is a figure which shows the audio | voice signal etc. which are output from the speaker apparatus which concerns on 1st Embodiment. It is a block diagram which shows the structure of the speaker apparatus which concerns on a modification. It is a block diagram which shows the structure of the speaker apparatus which concerns on a modification. It is a graph which shows the audio | voice signal etc. which are output from a noise gate.

First Embodiment
Hereinafter, embodiments of the present invention will be described. FIG. 1 is a diagram showing a circuit configuration of a speaker device according to a first embodiment of the present invention. The speaker device 1 includes an amplification device 2 and a speaker 3. The amplification device 2 amplifies an audio signal input from an electric stringed instrument such as an electric guitar, for example, and outputs the amplified audio signal to the speaker 3. The speaker 3 outputs an audio according to the audio signal input from the amplification device 2.

  The amplification device 2 includes a plug 4, a battery 5, an amplification unit 6, a charging circuit 7, a switch 8, a signal detection circuit 9, and a control circuit 10. The plug 4 is for connecting the amplification device 2 to an AC power supply. The battery 5 is charged by the voltage supplied from the charging circuit 7. The amplification unit 6 amplifies the input audio signal and outputs the amplified audio signal to the speaker 3. The amplification device 2 includes an input terminal (not shown) for connecting an electric stringed instrument such as an electric guitar and an electric bass. The amplification unit 6 amplifies an audio signal input from the electric stringed instrument via the input terminal.

  The charging circuit 7 rectifies the AC voltage from the AC power supply and supplies it to the battery 5. In addition, the charging circuit 7 rectifies the alternating voltage from the alternating current power supply and supplies the rectified voltage to each unit constituting the amplifying device 2. The switch 8 is connected between the AC power supply. The switch 8 is controlled by the control circuit 10 and turned on and off. The signal detection circuit 9 detects an input audio signal.

  The control circuit 10 controls each part constituting the amplification device 2. The control circuit 10 turns on the switch 8 when the signal detection circuit 9 detects an audio signal having a predetermined volume or more. Then, the control circuit 10 supplies the voltage from the alternating current power supply to each unit constituting the amplification device 2. That is, the amplification device 2 operates with the voltage from the AC power supply. The control circuit 10 also turns off the switch 8 when the signal detection circuit 9 detects an audio signal smaller than a predetermined volume. Specifically, the control circuit 10 turns the switch 8 off when the signal detection circuit 9 detects an audio signal smaller than a predetermined volume for a predetermined time. Then, the control circuit 10 supplies the voltage from the battery 5 to each part constituting the amplification device 2. That is, the amplification device 2 operates with the voltage from the battery 5.

  The reason why the hum noise is output as voice in the amplification device 2 will be described. FIG. 2 shows an input audio signal (Guitar Signal), a ground (Amp GND), an output audio signal (Amp output), and an earth ground (Amp GND) in the amplification device 2 when operating with a voltage from an AC power supply. It is a figure which shows Earth GND). The amplification device 2 is connected to the ground via the AC power supply because it operates with the voltage from the AC power supply. For this reason, as shown in FIG. 2, the ground level of the amplification device 2 is fixed at the ground level. For example, when an electric stringed instrument is connected to the amplifying device 2, a ham noise mixed in the circuit of the electric stringed musical instrument with high impedance by electromagnetic induction is output to the amplifying device 2. As a result, a difference between the hum noise is made between the output of the amplification device 2 and the ground level (earth ground level) of the amplification device 2, so that the hum noise is output as voice.

  The reason why the output of the hum noise as sound is reduced when the amplification device 2 operates with the voltage from the battery 5 will be described. FIG. 3 shows an input audio signal (Guitar Signal), a ground (Amp GND), an output audio signal (Amp output), and an earth ground (Amp GND) in the amplification device 2 when operating with the voltage from the battery 5. It is a figure which shows Earth GND). When the amplification device 2 is operated with the voltage from the battery 5 instead of the voltage from the AC power supply, the amplification device 2 floats (floats) from the ground level because it is not connected to the ground via the AC power supply. It is in the state. As a result, for example, since the hum noise contained in the audio signal output from the electric stringed instrument and the ground of the amplification device 2 vibrate in phase, it is considered that the hum noise is less likely to be output as audio.

  In the present embodiment, when the signal detection circuit 9 detects an audio signal smaller than a predetermined volume, the control circuit 10 turns off the switch 8 and sets the voltage from the battery 5 to the amplification device 2. Supply to As a result, as described above, since the amplification device 2 is not connected to the ground, the output of hum noise as voice is reduced (about 20 to 40 dB). In particular, when an electric stringed instrument is connected to the amplification device 2, it is reduced that the hum noise is output as sound when the electric stringed instrument is not played.

  FIG. 4 is a graph showing an audio signal and the like output from the speaker device 1. As illustrated, according to the speaker device 1, no change occurs in the output signal, and only hum noise can be removed. In addition, when an electric stringed instrument is connected to the amplification device 2, there is no need to use a noise gate or the like to reduce hum noise, as shown in FIG. Absent. In addition, since the battery 5 is operated only when an audio signal having a predetermined volume or more is not detected, the small battery 5 may be used.

Second Embodiment
FIG. 5 is a diagram showing a circuit configuration of a speaker device according to a second embodiment of the present invention. The speaker device 11 includes an amplification device 12 and a speaker 13. The amplification device 12 includes an AC adapter 14, a relay 15, a battery 16, a charge and discharge circuit 17, a DC / DC up converter 18, a preamplifier 19, a main amplifier 20, a signal detection circuit 21, a gain detection circuit 22, a volume detection circuit 23, and a relay. A control circuit 24 is provided.

  The AC adapter 14 rectifies, transforms, etc. the alternating voltage from the alternating current power supply, and supplies a direct voltage. The relay 15 is connected between the AC power supply. The relay 15 has switches SW1 to SW3. The switches SW1 to SW3 are controlled by the relay control circuit 24 to be turned on / off. The battery 16 is charged by the voltage supplied from the charge and discharge circuit 17. The charge and discharge circuit 17 (charging circuit) supplies the battery 16 with the voltage supplied from the AC adapter 14. In addition, the charge and discharge circuit 17 supplies the voltage supplied from the battery 16 to each part constituting the amplification device 12. The DC / DC up converter 18 boosts the voltage from the charge / discharge circuit 17 and supplies it to the preamplifier 19, the main amplifier 20 and the like.

  The preamplifier 19 (amplifying unit) amplifies the audio signal. The preamplifier 19 includes a buffer amplifier 25, a tone control 26, an amplifier gain control 27, a volume control 28, a DSP 29, and an effect mixer 30. The buffer amplifier 25 is for converting a high impedance audio signal from the guitar 31 into a low impedance audio signal. The tone control 26 is for adjusting the tone of the audio signal. The tone control 26 has, for example, a base knob for adjusting the bass range of the audio signal, a middle knob for adjusting the midrange of the audio signal, and a treble knob for adjusting the treble range of the audio signal. The tone control 26 adjusts the low range, mid range and high range of the audio signal based on the operation of the base knob, middle knob and treble knob, respectively.

  The amplifier gain control 27 is for adjusting the gain by the preamplifier 19. The amplifier gain control 27 has an amplifier gain knob for adjusting the gain. The amplifier gain control 27 amplifies the audio signal with a gain based on the operation of the amplifier gain knob. Volume control 28 is for adjusting the volume. The volume control 28 has a volume knob for adjusting the volume. Volume control 28 attenuates the audio signal to a volume based on the operation of the volume knob.

  The DSP 29 performs audio processing on the audio signal from the volume control 28. The DSP 29 receives an audio signal analog-to-digital converted by an A / D converter (not shown). Further, the audio signal output from the DSP 29 is converted from digital to analog by a D / A converter (not shown). An audio signal from the volume control 28 and an audio signal from the DSP 29 (D / A converter) are input to the effect mixer 30.

  The main amplifier 20 amplifies the audio signal from the preamplifier 19 and supplies it to the speaker 13.

The signal detection circuit 21 detects an input audio signal. The signal detection circuit 21 outputs a low level (L) signal as the signal detection signal V _{Det (Signal)} when the input audio signal V _in is smaller than the predetermined sound volume V _th (V _in <V _th ⇒ L). Further, when the input audio signal V _in is equal to or higher than the predetermined sound volume V _th , the signal detection circuit 21 outputs a high level (H) signal as the signal detection signal V _{Det (Signal)} (V _in VV _th H H).

The gain detection circuit 22 detects the gain by the operation of the amplifier gain control 27. FIG. 6 is a diagram for explaining the detection of the gain by the gain detection circuit 22. As shown in FIG. 6A, the amplifier gain control 27 is provided with a variable resistor VR1 for adjusting the gain. In the present embodiment, one of the dual volumes is used as the variable resistor VR1, and as shown in FIG. 6B, the other variable resistor VR2 is used to detect the gain V _Gain . The gain detection circuit 22 has a comparator 32. The comparator 32 compares the gain V _Gain with the predetermined value V _{th (Gain)} , and when the gain V _Gain is smaller than the predetermined value V _{th (Gain)} , the low level (L L _{) is used} as the gain detection signal V _{Det (Gain).} ) (V _Gain <V _{th (Gain))} L). The comparator 32 outputs a high level (H) signal as the gain detection signal V _{Det (Gain)} when the gain V _Gain is equal to or greater than the predetermined value V _{th (Gain)} (V _Gain VV _{th (Gain) )} H H).

The volume detection circuit 23 detects a volume by the volume control 28. FIG. 7 is a diagram for explaining detection of a volume by the volume detection circuit 23. As shown in FIG. 7A, the volume control 23 is provided with a variable resistor VR3 for adjusting the volume. In this embodiment, one of the dual volumes is used as the variable resistor VR3, and as shown in FIG. 7B, the other variable resistor VR4 is used to detect the volume V _Vol . The volume detection circuit 23 has a comparator 33. The comparator 33 compares the volume _{V Vol} and the predetermined value _{V th (Vol),} if the volume _{V Vol} is smaller than the predetermined value _{V th (Vol),} as a volume detection signal _{V Det (Gain),} low level (L Output the signal of (V _Vol <V _{th (Vol)} L L). Further, when the volume V _Vol is equal to or more than the predetermined value V _{th (Vol)} , the comparator 33 outputs a high level (H) signal as the volume detection signal V _{Det (Vol)} (V _Vol VV _{th (Vol )} H H).

When the gain control circuit 22 detects a gain equal to or less than a predetermined value (V _{Det (Gain)} = L), and the volume detection circuit 23 detects a volume equal to or less than a predetermined value, the relay control circuit 24 Regardless of whether the signal detection circuit 21 detects an audio signal having a predetermined volume or more, the switches SW1 to SW3 are turned on to supply the voltage from the AC power supply to each part constituting the amplification device 12.

Further, in the relay control circuit 24, the gain detection circuit 22 detects a gain larger than a predetermined value (V _{Det (Gain)} = H), and the volume detection circuit 23 detects a volume larger than the predetermined value (V _{When Det (Vol)} = H) and the signal detection circuit 21 detects an audio signal smaller than a predetermined volume (V _{Det (Signal)} = L), the relay 15 (switches SW1 to SW3) is turned off. The voltage from the battery 16 is supplied to each unit constituting the amplification device 12.

  The relay control circuit 24 is configured by a logic circuit that performs the operation of the truth table shown in FIG.

When a high level (H) signal is supplied from the relay control circuit 24 to the relay 15 as the control signal V _Contorol , the switches SW1 to SW3 are turned off. For this reason, the voltage from the battery 16 is supplied to each part which comprises the amplifier 12 (battery discharge). When a low level (L) signal is supplied from the relay control circuit 24 to the relay 15 as the control signal V _Contorol , the switches SW1 to SW3 are turned on. Therefore, the battery 15 is charged by the voltage from the AC adapter 14 (battery charging).

Hereinafter, the processing operation of the speaker device 11 will be described based on the flowchart shown in FIG. In the speaker device 11, when the power is turned on (S1), the relay control circuit 24 determines whether the volume is larger than 80% (predetermined value) and the gain is larger than 50% (predetermined value). It judges (S2). The relay control circuit 24 can determine S2 based on the volume detection signal V _{Det (Vol)} from the volume detection circuit 23 and the gain detection signal V _{Det (Gain)} from the gain detection circuit 22. . When the relay control circuit 24 determines that the volume is greater than 80% (predetermined value) and the gain is greater than 50% (predetermined value) (S2: Yes), the audio signal V _in has a predetermined volume V _th It is judged whether it is above or not (S3). The relay control circuit 24 can make the determination of S3 based on the signal detection signal V _{Det (signal)} from the signal detection circuit 21.

When the relay control circuit 23 determines that the audio signal V _in is not equal to or higher than the predetermined volume V _th , that is, the audio signal V _in is smaller than the predetermined volume V _th (S3: No), the switches SW1 to SW3 of the relay 15 Turn off (S4). Then, the relay control circuit 24 supplies the voltage from the battery 16 to each part constituting the amplification device 12 (battery discharge) (S5).

In the relay control circuit 24, the volume is not larger than 80% (predetermined value), that is, the volume is 80% (predetermined value) or less, and the gain is not larger than 50% (predetermined value), that is, When it is determined that the gain is 50% (predetermined value) or less (S2: No), and when it is determined that the audio signal V _in is more than a predetermined volume V _th (S3: Yes), the switch SW1 of the relay 15 is -Turn on SW3 (S6). Then, the relay control circuit 24 supplies the voltage from the alternating current power supply to each unit constituting the amplification device 12. At this time, the battery 16 is charged (battery charging) (S7).

  FIG. 10 is a diagram showing the state of the battery 16 in the speaker device 11 and the like. In the state where the guitar 31 is connected, the power of the speaker device 11 is turned on, and the setting is performed by the performer, the switches SW1 to SW3 of the relay 15 are turned off and the battery 16 is discharged. It becomes a state. For this reason, the hum noise is reduced (ham noise reduction: on). When the player starts to play the guitar 31 after setting the volume 100% (> 80%) and gain 80% (> 50%) in the speaker device 11, the switches SW1 to SW3 of the relay 15 are turned on. The battery 16 is charged. For this reason, the hum noise is not reduced (ham noise reduction: off). Thereafter, when the player's performance of the guitar 31 is stopped and the signal is not in the signal state, the switches SW1 to SW3 of the relay 15 are turned off, and the battery 16 is in the discharge state. For this reason, the hum noise is reduced (ham noise reduction: on). Also, after setting the volume to 50% (≦ 80%) and the gain to 10% (≦ 50%) in the speaker device 11, when the player's performance of the guitar 31 is resumed, the switches SW1 to SW3 of the relay 15 are turned on. Is turned on, and the battery 16 is charged. For this reason, the hum noise is not reduced (ham noise reduction: off).

  FIG. 11 is a diagram showing an audio signal output from the amplification device 12. FIG. 12 is a diagram showing an audio signal output from the amplification device 12 when there is no signal. The lower side of the bar graph is a hum noise, and the upper side is an audio signal to be input. In the amplification device 12 for an electric stringed instrument, since the audio signal is clipped and used, the ratio of the hum noise to the audio signal changes depending on the gain. Furthermore, the volume changes the absolute amount of hum noise and audio signal.

  The amplification device 2 according to the first embodiment, as shown in FIG. 13, supplies the voltage from the AC power supply to each portion constituting the amplification device 2 (battery charging) if the audio signal is equal to or higher than a predetermined volume. That is, for example, if the input source of the audio signal is an electric stringed instrument, there is a problem that the battery 5 can be charged only when the electric stringed instrument is playing.

  Here, when the volume and gain are small, it is also difficult to hear hum noise. For this reason, in the present embodiment, the relay control circuit 24 detects a gain equal to or less than a predetermined value, and the volume detection circuit 23 detects a volume equal to or less than a predetermined value. Regardless of whether the detection circuit 21 detects the audio signal having a predetermined volume or more, the switches SW1 to SW3 are turned on to supply the voltage from the AC power supply to each part constituting the amplification device 12. Therefore, even if the amplifying device 12 operates with the voltage from the AC power supply, the battery 16 can be charged even when, for example, the electric stringed instrument is playing, without the hum noise being heard by the listener.

  As mentioned above, although embodiment of this invention was described, the form which can apply this invention is not restricted to the above-mentioned embodiment, As it illustrates below, it is suitably in the range which does not deviate from the meaning of this invention. It is possible to make changes.

  In the above embodiment, the threshold value to be compared with the volume of the audio signal for determining whether to reduce the hum noise is constant. Instead of this, as shown in FIG. 14, a threshold control 40 may be added to the signal detection circuit 21, and the above threshold may be changed by the threshold control 21. Further, as shown in FIG. 15, in the example shown in FIG. 14, a microcomputer 41 may be added and only the hum level may be detected by the BPF.

  In the above-mentioned embodiment, the case where the audio signal from an electric stringed instrument was inputted into amplification device 2 and 12 was illustrated. Not limited to the electric stringed instrument, audio signals from other audio output devices may be input.

  The present invention can be suitably adopted for an amplification device for amplifying an audio signal, and a speaker device provided with the amplification device and a speaker.

DESCRIPTION OF SYMBOLS 1 and 11 Speaker apparatus 2 12 amplification apparatus 3 13 speaker 4 plug 5 16 battery 6 amplification part 7 charge circuit 8 SW1-SW3 switch 9 21 signal detection circuit 10 control circuit 15 relay 17 charge / discharge circuit (charge circuit )
18 DC / DC up converter 19 preamp (amplification section)
20 main amplifier 22 gain detection circuit 23 volume detection circuit 24 relay control circuit 27 amplifier gain control 28 volume control

Claims (6)

With a battery,
An amplification unit for amplifying an audio signal;
A charging circuit which supplies a voltage from an AC power supply to the battery or supplies each part constituting the own device;
A switch connected between the AC power supply and
A signal detection circuit for detecting the audio signal;
When the signal detection circuit detects the audio signal having a predetermined volume or more, the switch is turned on to supply the voltage from the AC power supply to each unit constituting the apparatus.
A control circuit that turns off the switch and supplies the voltage from the battery to each unit of the apparatus when the signal detection circuit detects the audio signal smaller than a predetermined volume;
An amplification apparatus comprising: Amplifier gain control for adjusting the gain by the amplification unit;
Volume control for adjusting the volume of the audio signal ;
A gain detection circuit for detecting a gain by the operation of the amplifier gain control;
A volume detection circuit for detecting a volume by the volume control;
When the gain detection circuit detects a gain equal to or less than a predetermined value, and the volume detection circuit detects a volume equal to or less than a predetermined value, the control circuit detects that the volume has a predetermined value or less. regardless of whether or not detection of the speech signal, the switch is turned on, the voltage from the AC power supply, amplifier according to claim 1, characterized in that to supply to each unit constituting the own device .   In the control circuit, the gain detection circuit detects a gain larger than a predetermined value, the volume detection circuit detects a volume larger than a predetermined value, and the signal detection circuit is smaller than a predetermined volume. 3. The amplification device according to claim 2, wherein when the audio signal is detected, the switch is turned off, and a voltage from the battery is supplied to each unit constituting the device.   When the control circuit detects the audio signal smaller than a predetermined volume for a predetermined period of time, the control circuit turns off the switch to supply the voltage from the battery to each unit constituting the apparatus. The amplification device according to Item 1. It also has an input terminal for connecting an electric stringed instrument,
The amplification device according to any one of claims 1 to 4 , wherein the amplification unit amplifies the audio signal input from the electric stringed instrument via the input terminal. With a speaker,
The amplification device according to any one of claims 1 to 5,
A speaker device comprising: