JP6829458B2 - Tube preamplifier, tube microphone - Google Patents

Description

The present invention relates to a preamplifier and a microphone using a vacuum tube connected to a mixer having a phantom power supply.

A mixer that processes an acoustic signal is provided with a constant voltage source of usually DC 48 V called a phantom power supply. As a microphone that operates with this phantom power supply, there is a technique described in Patent Document 1. Patent Document 1 takes up the device of Non-Patent Document 1 as a pulse width modulation type DC-DC converter, and describes that it cannot be used because it increases the noise of the microphone. In Non-Patent Document 1, switching is performed at a maximum of 1.2 MHz, the input voltage range is 2.7 to 5.5 V, and the output voltage range is 1.25 to 2.0 V. Is described.

Techniques that have become known since the filing of Patent Document 1 include the techniques described in Patent Documents 2 and 3 as a vacuum tube that operates as an analog amplifier at a low voltage. Further, as a DC-DC converter that switches at a higher frequency than the DC-DC converter of Non-Patent Document 1, for example, there is a DC-DC converter of Non-Patent Document 2. In Non-Patent Document 2, it is typically switched at 2.25 MHz, the input voltage range is 3 to 17 V, and the output voltage range is 0.9 to 6.0 V. Have been described.

Japanese Unexamined Patent Publication No. 2004-221919 JP-A-2016-134298 Japanese Unexamined Patent Publication No. 2016-134299

"MAX1733", Maxim Integrated Products, [Searched August 4, 2016], Internet <https://datasheets.maximintegrated.com/en/ds/MAX1733-MAX1734.pdf>. "TPS62170", TEXAS INSTRUMENTS, [Searched August 4, 2016], Internet <http://www.ti.com/lit/ds/symlink/tps62170.pdf>.

A DC-DC converter as shown in Non-Patent Document 2 can also be used for an analog circuit that processes an acoustic signal. Further, since the range of the input voltage and the range of the output voltage are wide, there is a possibility that the vacuum tube preamplifier using the vacuum tube shown in Patent Documents 2 and 3 can be operated by the phantom power supply. However, even when I actually configured and operated the vacuum tube preamplifier, it did not work properly.

Therefore, an object of the present invention is to provide a vacuum tube preamplifier that operates normally using a vacuum tube and a DC-DC converter.

The vacuum tube preamplifier of the present invention includes an interface having a conductive wire to which power is supplied from a predetermined DC voltage source and an output signal is output, and a ground wire. The preamplifier of the present invention includes an amplification unit, a separation unit, and a filament power supply unit. The amplification unit has a filament that emits thermoelectrons, a vacuum tube having a grid and an anode, a pretreatment unit that converts an input signal into a voltage input to the grid, and a post-processing unit that converts an anode voltage into an output signal. .. The separation unit takes out a part of the electric power supplied from the interface. The filament power supply unit has a DC-DC converter and a control unit, and converts the electric power taken out by the separation unit so as to meet the conditions for the filament to emit thermions and supplies it to the filament. The control unit operates the DC-DC converter when the input voltage to the DC-DC converter is in a predetermined high voltage state. The vacuum tube microphone of the present invention includes the vacuum tube preamplifier of the present invention and a microphone that converts an acoustic signal into the input signal and outputs the microphone.

According to the vacuum tube preamplifier of the present invention, the control unit limits the operation of the DC-DC converter only when the input voltage is at an appropriate height, so that the power that must be input to the DC-DC converter is obtained. The current required for this can be reduced. Therefore, the current on the input side of the DC-DC converter, that is, the current required to obtain the power taken out by the separation unit can be reduced. Therefore, the voltage drop due to the resistor arranged between the predetermined DC voltage source and the DC-DC converter can be reduced, and the vacuum tube preamplifier can be operated normally.

The figure which shows the relationship between the vacuum tube microphone equipped with the vacuum tube preamplifier of this invention, and a mixer. The figure which showed the interface part of the mixer and the part of the separation part of the vacuum tube preamplifier of Example 1 in more detail than FIG. The figure which shows the structural example of the vacuum tube preamplifier of Example 1. FIG. The figure which shows the concrete circuit structure of a vacuum tube. It is the figure which showed the interface part of the mixer and the separated part part of the vacuum tube preamplifier of the modification in more detail than FIG. The figure which shows the structural example of the vacuum tube preamplifier of a modification.

Hereinafter, embodiments of the present invention will be described in detail. The components having the same function are given the same number, and duplicate description is omitted.

FIG. 1 shows the relationship between a vacuum tube microphone equipped with the vacuum tube preamplifier of the present invention and a mixer. FIG. 2 is a diagram showing the interface portion of the mixer and the separated portion of the vacuum tube preamplifier of the first embodiment in more detail than in FIG. The vacuum tube microphone 10 includes a signal generation unit 200 and a vacuum tube preamplifier 100, and is connected to the mixer 900. The signal generation unit 200 converts the acoustic signal into an input signal of the vacuum tube preamplifier 100 and outputs it. The signal generation unit 200 may be configured by a circuit including, for example, a condenser microphone. The vacuum tube preamplifier 100 includes a separation unit 110, a filament power supply unit 120, and an amplification unit 130.

In FIG. 1, solid arrows indicate signal flow and dotted arrows indicate power supply. The mixer 900 is generally provided with a phantom power source which is a DC voltage source of 48 V, supplies power to a connected microphone or the like, and receives an output signal output from the microphone or the like. The physical layer of the interface has a conductive wire to which power is supplied from a predetermined DC voltage source (phantom power supply) and an output signal of a vacuum tube microphone equipped with a vacuum tube preamplifier is output, and a ground wire. In the example of FIG. 2, the output signals are two signals having opposite phases. In this case, the DC voltage source (phantom power supply) 910 is branched into two, resistors 920-1 and 920-2 are connected to each, and further connected to the conductive wire 941-1 and the conductive wire 941-2. Further, the output signal is branched at the connection points 944-1 and 944-2 provided on the conductive wire 941-1 and the conductive wire 941-2, and passes through the signal lines 945-1,945-2 to the signal processing unit 930. Entered. Further, the ground wire 990 is connected so as to be common to the mixer 900, the vacuum tube preamplifier 100, and the signal generation unit 200. The resistors 920-1 and 920-2 are generally 6.8 kΩ.

The separation unit 110 takes out a part of the electric power supplied from the interface. Specifically, the conductive wires 111-1 and 111-2 of the vacuum tube preamplifier 100 are connected to the conductive wires 941-1 and 941-2 of the mixer 900, respectively. Then, in the separation unit 110, the conductive lines 111-1 and 111-2 are connected to the power lines 113-1 and 113-2 at the connection points 112-1 and 112-2. The power lines 113-1 and 113-2 are connected to the filament power supply unit 120. The conductive wires 111-1 and 111-2 are connected to the amplification unit 130 to supply electric power to the amplification unit 130 and propagate the output signal output from the amplification unit 130 to the mixer 900 side.

In the example of FIG. 2, the signal generation unit 200 and the amplification unit 130 are connected by a power line 220 to a signal line 210-1,210-2 that propagates signals having opposite phases. The signal is output from the signal generation unit 200 and input to the amplification unit 130, and the electric power is supplied from the amplification unit 130 to the signal generation unit 200. The filament power supply unit 120 supplies electric power for the filament of the vacuum tube included in the amplification unit 130. The grounding of the filament power supply unit 120 and the amplification unit 130 is the same as the grounding of the ground wire 990.

FIG. 3 shows a configuration example of the vacuum tube preamplifier of the first embodiment, and FIG. 4 shows a specific circuit configuration of the vacuum tube. The amplification unit 130 includes a vacuum tube 131, a pretreatment unit 136, and a posttreatment unit 138. The vacuum tube 131 has filaments 132-1 and 132-2 that emit thermions, grids 133-1, 133-2, and anodes 134-1 and 134-2. A predetermined voltage is applied to the filaments 132-1 and 132-2 from the filament power supply unit 120 via the power line 129, a current flows, and thermions are emitted. For example, if it is necessary to apply a voltage of 0.7 V to one filament, a voltage of 1.4 V may be applied in the case of FIG. The current is, for example, 17 mA. The preprocessing unit 136 converts the input signal from the signal lines 210-1,210-2 into a voltage to be input to the grids 133-1, 133-2, and the grid 133 via the signal lines 137-1, 137-2. Apply to -1,133-2. The post-processing unit 138 is connected to the anodes 134-1 and 134-2 via signal lines 135-1 and 135-2, and converts the voltage of the anodes 134-1 and 134-2 into two output signals. , Output from conductive wires 111-1 and 111-2. Further, the post-processing unit 138 receives power from the conductive lines 111-1 and 111-2, supplies power to the pre-processing unit 136 via the power lines 139-1 and 139-2, and supplies the signal generation unit 200 with electric power. Power is supplied via the power line 220.

Here, the specific wiring of the vacuum tube 131 will be described with reference to FIG. The terminal 1326 at one end of the filament 132-1 is connected to the power line 129, and the terminal 1328 at one end of the filament 132-2 is grounded. Although the terminal 1327 is not used in the first embodiment, for example, when the filament 132-2 side is not used, the terminal 1327 may be grounded. In this case, the voltage of the power line 129 may be halved when both are used. The signal from the preprocessing unit 136 is applied to the grid 133-1, 133-2 via the signal lines 137-1 and 137-2. The anodes 134-1 and 134-2 are connected to the DC voltage source 1346 via resistors 1347-1 and 1347-2, and the anode voltage is output from the signal lines 135-1 and 135-2. The resistors 1347-1 and 1347-2 and the DC voltage source 1346 may be provided in the post-processing unit 138. Further, the DC voltage source 1346 also uses the electric power supplied from the DC voltage source (phantom power supply) 910 of the mixer 900.

Returning to FIG. 3, the filament power supply unit 120 will be described. The filament power supply unit 120 has a DC-DC converter 121 and a control unit 122, and converts the electric power taken out by the separation unit 110 so as to meet the conditions for the filaments 132-1 and 132-2 to emit thermions. It is supplied to filaments 132-1 and 132-2. The control unit 122 operates the DC-DC converter 121 when the input voltage to the DC-DC converter 121 is in a predetermined high voltage state. Further, the filament power supply unit 120 has an input adjustment unit 123 for generating and stabilizing an input voltage to the DC-DC converter 121, and an output adjustment unit 124 for stabilizing the output voltage from the DC-DC converter. Also prepare. The input adjusting unit 123 is composed of, for example, a capacitor 1232 and a Zener diode 1233 arranged between the resistors 1231-1 and 1231-2 connected in series with the power lines 113-1 and 113-2 and the ground. When the power supply of the vacuum tube preamplifier 100 is turned on, a current flows from the separation unit 110 in the direction of the capacitor 1232, and the electric charge is stored in the capacitor 1232, so that the voltage at the connection point 125 rises. The voltage at the connection point 125 is the input voltage of the DC-DC converter 121. The Zener diode 1233 plays a role of preventing the input voltage from becoming too high. The output adjusting unit 124 may be composed of, for example, an RC circuit of a resistor 1241 and a capacitor 1242.

Next, the necessity and configuration of the control unit 122 will be described. Even if it is operated without the control unit 122, the voltage at the connection point 125 increases as the electric charge is accumulated in the capacitor 1232 after the power is turned on, and the maximum voltage is limited by the Zener diode 1233. it is conceivable that. However, when the power is turned on without actually providing the control unit 122, when the voltage at the connection point 125 reaches the allowable input voltage of the DC-DC converter 121, the DC-DC converter 121 starts operating from the output side. The supply of electric power to the filaments 132-1 and 132-2 starts. A current flows on the input side of the DC-DC converter 121 in order to obtain the electric power, and the electric charge of the capacitor 1232 does not increase. Therefore, the voltage at the connection point 125 becomes stable near the minimum allowable input voltage of the DC-DC converter 121. For example, in the case of the DC-DC converter of Non-Patent Document 2, since the allowable input voltage is 3 to 17V, it becomes constant in the vicinity of 3V. Since relationship power = voltage × current, when the voltage is low will require a large current, resistance 920-1,920- 2, it becomes to consume power at 1231-1,1231-2. Further, since the resistance 920-1,920- 2 generally are determined to 6.8Keiomega, when thus a large current flows, the voltage of the conductive wire 111-1 and 111-2 decreases, sufficient power It becomes impossible to supply to the amplification unit 130 and the signal generation unit 200. Therefore, even if the vacuum tube preamplifier is configured without the control unit 122, it does not operate normally.

Therefore, the control unit 122 operates the DC-DC converter 121 when the input voltage to the DC-DC converter 121 is in a predetermined high voltage state. For example, the control unit 122 may detect an input voltage to the DC-DC converter 121, set a predetermined high voltage state when the voltage is equal to or higher than a predetermined voltage, and operate the DC-DC converter 121. The resistance 920-1,920- 2, based on the time constant of the RC circuit constituted by 1231-1,1231-2 and capacitor 1232, the input voltage from the ON power to DC-DC converter 121 It is possible to obtain the time until a predetermined high voltage state is reached. Therefore, the control unit 122 may operate the DC-DC converter 121 after waiting for a predetermined time after the power is turned on. A specific example of the control unit 122 of FIG. 3 is an example in which the DC-DC converter 121 is operated by detecting an input voltage and setting a predetermined high voltage state when the voltage is equal to or higher than a predetermined voltage. The input voltage is divided by the resistor 1221 and the resistor 1222. Then, when the voltage between both ends of the resistor 1221 becomes the voltage at which the transistor 1223 is turned on, the voltage is applied to the NE terminal of the DC-DC converter 121 via the power line 1224. The DC-DC converter 121 operates by applying this voltage.

For example, a predetermined DC voltage source is a 48 V phantom power source, and the condition for the filament 132-1 to emit thermoelectrons is within the range of 10 to 20 mW for the filament for one signal, the DC-DC converter 121. When the input voltage to is 14 V or more and higher than the specified voltage, the above-mentioned “predetermined high voltage state” may be set, and it is desirable that about 15 V or more is set to the specified voltage. In the case of the DC-DC converter of Non-Patent Document 2, the input voltage to the DC-DC converter 121, which was 3V without the control unit 122, can be changed to, for example, 15V. Then, simply, the current may be 1/5 as compared with the case of 3V. Therefore, the voltage drop at the resistor 920-1,920- 2 also decreases, able to supply sufficient power to the amplifier 130 and the signal generator 200.

As described above, according to the vacuum tube preamplifier 100 of the present invention, the control unit 122 limits the operation of the DC-DC converter 121 only when the input voltage is at an appropriate height, so that the DC-DC converter 121 can be used. The current required to obtain the power that must be input can be reduced. Therefore, the current on the input side of the DC-DC converter 121, that is, the current required to obtain the power taken out by the separation unit 110 can be reduced. Therefore, the the resistor 920-1,920- 2 disposed between a predetermined DC voltage source 910 and the DC-DC converter 121 described above, can reduce the voltage drop due 1231-1,1231-2, the tube preamp 100 It can be operated normally.

[Modification example]
In Example 1, the signal generation unit 200 generates two signals having opposite phases, and the vacuum tube preamplifier 100 amplifies the two signals. In this modification, the case where the signal generation unit 200'generates one signal is shown. The relationship between the vacuum tube microphone provided with the vacuum tube preamplifier and the mixer is the same as in FIG. FIG. 5 is a diagram showing the interface portion of the mixer and the separated portion of the vacuum tube preamplifier of the present modification in more detail than in FIG. FIG. 6 is a diagram showing a configuration example of the vacuum tube preamplifier of this modified example. The difference from the first embodiment is that the signal generation unit 200'generates only one signal, so that the signal line, the power line, and the conductive line are one.

In the example of FIG. 5, the resistor 920-1 is connected to the DC voltage source (phantom power supply) 910, and further connected to the conductive wire 941-1. Further, the output signal from the vacuum tube microphone 10'is branched at the connection point 944-1 provided on the conductive line 941-1 and input to the signal processing unit 930' via the signal line 945-1. Further, the ground wire 990 is connected so as to be common to the mixer 900', the vacuum tube preamplifier 100', and the signal generation unit 200'.

Separation unit 110'takes out a part of the electric power supplied from the interface. Specifically, the conductive wire 111-1 of the vacuum tube preamplifier 100'is connected to the conductive wire 941-1 of the mixer 900'. Then, in the separation unit 110', the conductive wire 111-1 is connected to the power line 113-1 at the connection point 112-1. The power line 113-1 is connected to the filament power supply unit 120'. The conductive wire 111-1 is connected to the amplification unit 130', supplies power to the amplification unit 130', and propagates the output signal output from the amplification unit 130' to the mixer 900'side.

In the example of FIG. 5, the signal generation unit 200'and the amplification unit 130' are connected by a signal line 210-1 and a power line 220. The signal is output from the signal generation unit 200'and input to the amplification unit 130', and the electric power is supplied from the amplification unit 130'to the signal generation unit 200'. The filament power supply unit 120'supplys power for the filament of the vacuum tube included in the amplification unit 130'. The grounding of the filament power supply unit 120'and the amplification unit 130' is the same as the grounding of the ground wire 990.

The amplification unit 130'has a vacuum tube 131, a pretreatment unit 136', and a posttreatment unit 138'. In this modification, the case where the same vacuum tube 131 as in the first embodiment is used will be described. A predetermined voltage is applied from the filament power supply unit 120'to the filament 132-1 via the power line 129, a current flows, and thermions are emitted. Specifically, the terminal 1326 at one end of the filament 132-1 in FIG. 4 is connected to the power line 129, and the terminal 1327 at the other end of the filament 132-1 is grounded. For example, if it is necessary to apply a voltage of 0.7 V to one filament, a voltage of 0.7 V may be applied in the case of FIG. By doing so, the current becomes the same as that of the first embodiment. The preprocessing unit 136'converts the input signal from the signal line 210-1 into a voltage to be input to the grid 133-1 and applies it to the grid 133-1 via the signal line 137-1. The post-processing unit 138'is connected to the anode 134-1 via the signal line 135-1, converts the voltage of the anode 134-1 into an output signal, and outputs the voltage from the conductive line 111-1. Further, the post-processing unit 138'receives electric power from the conductive wire 111-1, supplies electric power to the pre-processing unit 136' via the power line 139-1, and supplies the signal generation unit 200' via the power line 220. Supply power.

In the filament power supply unit 120', since only the power line 113-1 is connected to the input adjustment unit 123', the resistance is only the resistor 1231-1 and the output voltage from the DC-DC converter 121 is the filament 132-1. The difference is that the voltage is the voltage that supplies power only. Others are the same as in Example 1. The necessity and configuration of the control unit 122 are the same as those in the first embodiment. Therefore, the same effect as that of the first embodiment can be obtained in this modified example.

10,10'Vacuum tube microphone 100,100'Vacuum tube preamplifier 110 Separation part 111,941 Conductive wire 112,125,944 Connection point 113,129,139,220,1224 Power line 120,120' Filament power supply part 121 DC-DC converter 122 Control unit 123, 123'Input adjustment unit 124 Output adjustment unit 130, 130' Amplification unit 131 Vacuum tube 132 Filament 133 Grid 134 Ahead 135, 137, 210, 945 Signal line 136, 136' Pre-processing unit 138, 138' Post-processing unit 200, 200'Signal generator 900, 900' Mixer 910, 1346 DC voltage source 920, 1221,222, 1231, 1241, 1347 Resistance 930 Signal processing unit 990 Earth wire 1223 Transistor 1232,1242 Capacitor 1233 Zener diode 1326, 1327, 1328 terminal

Claims (4)

A vacuum tube preamplifier having an interface having a conductive wire to which power is supplied from a predetermined DC voltage source and an output signal is output, and a ground wire.
Amplification with a filament that emits thermoelectrons, a vacuum tube having a grid and an anode, a pretreatment unit that converts an input signal into a voltage input to the grid, and a post-processing unit that converts the voltage of the anode into the output signal. Department and
A separation unit that takes out a part of the power supplied from the interface,
It has a DC-DC converter and a control unit, and includes a filament power supply unit that converts the electric power taken out by the separation unit so as to meet the conditions for the filament to emit thermions and supplies it to the filament.
Wherein the control unit, the vacuum tube preamplifier, characterized in that operating the DC-DC converter when the input voltage to the DC-DC converter is in a state of lowest voltage higher predetermined voltage than the allowable input voltage. The vacuum tube preamplifier according to claim 1.
Wherein, tube preamp, wherein said detecting an input voltage to the DC-DC converter, a time of more than a predetermined voltage and the state of the predetermined voltage of the. The vacuum tube preamplifier according to claim 1 or 2.
The predetermined DC voltage source is a 48 V phantom power supply.
The conditions under which the filament emits thermions are in the range of 10-20 mW for the filament for one signal.
Tube preamp, characterized in that when the input voltage to the DC-DC converter is not less than a predetermined voltage above 14V the state of said predetermined voltage. A vacuum tube microphone including the vacuum tube preamplifier according to any one of claims 1 to 3 and a signal generation unit that converts an acoustic signal into the input signal and outputs the signal.

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