JP2022013261A - Control device - Google Patents

Abstract

To provide a control device miniaturized by using in common most of circuits for a 2-wire method and a 4-wire method.SOLUTION: A control device 4 in a voice communication system, which performs voice communication between a wired intercom 2 and a slave unit 3, includes: one commonly used connector (XLR connector 41) connected to the wired intercom 2; and a switch circuit 421 provided in the latter stage of the commonly used connector to switch between the 2-wire method and the 4-wire method.SELECTED DRAWING: Figure 2

Description

The present invention relates to a control device in a voice communication system that performs voice communication between a wired intercom and a slave unit.

Conventionally, unbalanced transmission and balanced transmission have been known as voice communication methods. Unbalanced transmission is realized by a two-wire system in which the input and output of an audio signal is composed of two common conductors, and has an advantage that the configuration is simple. On the other hand, balanced transmission is realized by a 4-wire system in which the input and output of an audio signal are each composed of two conductors. Balanced transmission, for example, as disclosed in Patent Document 1, can reduce the noise of an audio signal by generating a signal from the difference between a positive phase audio signal and a negative phase audio signal. In a voice communication system using an intercom, balanced transmission is widely adopted from the viewpoint of improving voice quality.

However, even in a voice communication system using an intercom, there is a demand to properly use a 2-wire system and a 4-wire system. For example, when the control device of a voice communication system is reused in multiple broadcasting stations, the wired intercom or slave unit used in each broadcasting station supports only one of the 2-wire system and the 4-wire system. If not, a situation may occur in which only a 2-wire system can be used at one broadcasting station and only a 4-wire system can be used at another broadcasting station. In such a case, the control device of the voice communication system includes a circuit used for the 2-wire system and a circuit used for the 4-wire system, in addition to the combined connector having both the 2-wire system connector and the 4-wire system connector. Two independent circuits were installed.

Japanese Patent Publication No. 2007-501545

However, since the control device of such a voice communication system is equipped with two circuits independent of each other, the circuit scale has increased, and the control device has tended to increase in size accordingly. For example, when one control device is reused between a plurality of broadcasting stations, it is a considerable effort to transport a large-sized control device.

An object of the present invention is to provide a miniaturized control device by sharing most of the circuits used in the 2-wire system and the circuits used in the 4-wire system in order to solve the above problems.

The control device of the present invention has the following configuration.
(1) A control device in a voice communication system that performs voice communication between a wired intercom and a slave unit.
(2) One dual-purpose connector connected to the wired intercom.
(3) A switching circuit provided after the dual-purpose connector to switch between a 2-wire system and a 4-wire system.

Further, the control device of the present invention may further include the following configurations.
(1) The combined connector includes a first pin, a second pin, and a third pin. The 1st pin and the 3rd pin are connected to the switching circuit. In the two-wire system, an audio signal is input and output via the third pin. In the 4-wire system, an audio signal is input via the 1st pin and the 3rd pin.

(2) The changeover circuit is a CMOS analog switch and includes a first switch, a second switch, a third switch, and a fourth switch. A first input side operational amplifier and a second input side operational amplifier are provided in the subsequent stage of the switching circuit. In the two-wire system, the first switch connects the GND of the switching circuit and the second input-side operational amplifier, and the second switch and the fourth switch are the three of the combined connector. The pin number and the first input side operational amplifier are connected. In the 4-wire system, the first switch connects the first pin of the combined connector to the second input side operational amplifier, and the third switch and the fourth switch are of the combined connector. The third pin and the first input side operational amplifier are connected.

(3) A first output-side operational amplifier provided in parallel with the first input-side operational amplifier and the second input-side operational amplifier, and the output side is connected to the second pin of the dual-purpose connector, and the first output-side operational amplifier. A second output-side operational amplifier, which is provided in parallel with the output-side operational amplifier and whose output side is connected to the first pin of the dual-purpose connector, is further provided. In the two-wire system, the audio signal from the slave unit is output to the third pin of the dual-purpose connector via the switching circuit, and in the four-wire system, the first output side operational amplifier and the said It is output to the second output side operational amplifier.

(4) An AD converter provided after the first input-side operational amplifier and the second input-side operational amplifier to convert an audio signal from the wired intercom into a digital signal, and an AD converter after the AD converter. An RF block for transmitting and receiving audio signals to and from the slave unit, and a DA converter provided in parallel with the AD converter and after the RF block to convert the audio signal from the slave unit into an analog signal. , Are further provided.

The present invention can provide a miniaturized control device by sharing most of the circuit used in the 2-wire system and the circuit used in the 4-wire system.

The schematic diagram which shows the voice communication system which concerns on embodiment. The block diagram which shows the control apparatus which concerns on embodiment. The block diagram which shows the switching circuit which concerns on embodiment.

[Embodiment]
[Constitution]
[1. Voice communication system]
As shown in FIG. 1, the voice communication system 1 of the present embodiment is connected to the wired intercom 2 and the slave unit 3, and the wired intercom 2 and the slave unit 3 and exchanges voice signals between the two. A control device 4 for controlling is provided. The wired intercom 2 and the control device 4 are connected by wire, and the slave unit 3 and the control device 4 are wirelessly connected. As the frequency of wireless communication between the slave unit 3 and the control device 4, for example, a 2.4 GHz band corresponding to a general wireless LAN, a 1.9 GHz band corresponding to the DECT standard, or the like can be used.

[2. Wired intercom]
The wired intercom 2 transmits / receives an audio signal to / from the slave unit 3 via the control device 4. The wired intercom 2 is compatible with both the 2-wire system and the 4-wire system. When the 2-wire system is used for voice communication, one XLR type cable is used, and when the 4-wire system is used, the 4-wire system is used. It is connected to the control device 4 by two XLR type cables. One of the two XLR cables is responsible for the input from the wired intercom 2 and the other is responsible for the output to the wired intercom 2. The two XLR type cables of the present embodiment are connected to the control device 4 via a bifurcated cable that bundles the ends thereof. That is, the two XLR type cables are connected to one XLR type connector (XLR type connector 41 described later) via the bifurcated cable.

[3. Cordless handset]
The slave unit 3 transmits and receives an audio signal to and from the wired intercom 2 via the control device 4. The number of slave units 3 may be one or a plurality, but will be described below assuming that the number of slave units is one.

[4. Control device]
The control device 4 controls an audio signal exchanged between the wired intercom 2 and the slave unit 3. As shown in FIG. 2, the control device 4 includes an XLR type connector 41, a 2W / 4W circuit 42, an AD converter 43, an MCU 44, a DA converter 45, and an RF block 46.

The XLR type connector 41 is connected to the wired intercom 2 via one XLR type cable in the two-wire system and two XLR type cables in the four-wire system. That is, the XLR type connector 41 is a dual-purpose connector that doubles as a 2-wire type connector and a 4-wire type connector. As shown in FIG. 3, the XLR type connector 41 includes a first pin P1, a second pin P2, and a third pin P3. When voice communication is performed by the two-wire method, the third pin P3 is connected to the 2W / 4W circuit 42, and the first pin P1 is connected to the GND. That is, the input of the audio signal to the 2W / 4W circuit 42 and the output of the audio signal from the 2W / 4W circuit 42 are both performed via the pin 3 P3. On the other hand, when voice communication is performed by the 4-wire method, such input and output are performed via different pins. Explaining from the input, the 3rd pin P3 is connected to the 2W / 4W circuit 42 as a HOT and the 1st pin P1 is connected as a COLD. On the other hand, pin 2 P2 is not used at the time of input. That is, the input of the audio signal to the 2W / 4W circuit 42 is performed via the 3rd pin P3 and the 1st pin P1. Next, in the output, the 2nd pin P2 is connected to the 2W / 4W circuit 42 as the HOT and the 1st pin P1 is connected as the COLD. On the other hand, pin 3 P3 is not used at the time of output. That is, the output of the audio signal from the 2W / 4W circuit 42 is performed via the 2nd pin P2 and the 1st pin P1.

The 2W / 4W circuit 42 is a circuit that switches between a 2-wire system and a 4-wire system according to the connection method of the wired intercom 2. The 2W / 4W circuit 42 is provided after the switching circuit 421, the input side operational amplifier 4221 and the input side operational amplifier 4222 provided after the switching circuit 421, and the DA converter 45, and is connected to the XLR type connector 41. A side operational amplifier 423 and an output side operational amplifier 424 are provided. As shown by the arrow in FIG. 2, the audio signal from the wired intercom 2 is input to the switching circuit 421, the input side operational amplifier 4221 and the input side operational amplifier 4222, and the audio signal to the wired intercom 2 is a two-wire system. From the switching circuit 421, in the 4-wire system, the output side operational amplifier 423 and the output side operational amplifier 424 output to the XLR type connector 41.

The switching circuit 421 will be described with reference to FIGS. 3A and 3B. FIG. 3A shows a case where unbalanced transmission using a two-wire method is performed. FIG. 3B shows a case where balanced transmission using the 4-wire method is performed. The switching circuit 421 is a CMOS analog switch including the first to fourth switches SW1 to SW4, and switches between unbalanced transmission and balanced transmission.

The first switch SW1 switches between contacts S1A and S1B. That is, the first switch SW1 connects the first pin P1 of the XLR type connector 41 on the contact S1A side or the GND of the switching circuit 421 on the contact S1B side to the input side operational amplifier 4222.

The second switch SW2 switches between contacts S2A and S2B. That is, the second switch SW2 connects the lead wire on the contact S2A side or the lead wire on the contact S2B side to the third pin P3 of the XLR type connector 41. The conductor on the contact S2A side is not connected, and the conductor on the contact S2B side is connected to the contact S4B of the fourth switch SW4 and the DA converter 45.

The third switch SW3 switches between contacts S3A and S3B. That is, the third switch SW3 connects the lead wire on the contact S3A side or the lead wire on the contact S3B side to the third pin P3 of the XLR type connector 41. The lead wire on the contact S3A side is connected to the contact S4A of the fourth switch SW4, and the lead wire on the contact S3B side is not connected.

The fourth switch SW1 switches between contacts S4A and S4B. That is, the fourth switch SW4 connects the lead wire on the contact S4A side or the lead wire on the contact S4B side to the input side operational amplifier 4221. The lead wire on the contact S4A side is connected to the contact S3A of the third switch SW3, and the lead wire on the contact S4B side is connected to the contact S2B of the second switch SW2.

When performing unbalanced transmission using the two-wire method, as shown in FIG. 3A, the first to fourth switches SW1 to SW4 are connected to the contacts S1B to S4B, respectively. As a result, the third pin P3 of the XLR type connector 41 is connected to the input side operational amplifier 4221 via the contact S2B and the contact S4B. Further, the GND of the switching circuit 421 is connected to the input side operational amplifier 4222 via the contact S1B.

When performing balanced transmission using the 4-wire method, as shown in FIG. 3B, the first to fourth switches SW1 to SW4 are connected to the contacts S1A to S4A, respectively. As a result, the third pin P3 (HOT) of the XLR type connector 41 is connected to the input side operational amplifier 4221 via the contact S3A and the contact S4A. Further, the first pin P1 (COLD) of the XLR type connector 41 is connected to the input side operational amplifier 4222 via the contact S1A.

Returning to FIG. 2, the input side operational amplifiers 4221 and 4222 are provided after the switching circuit 421 and amplify the audio signal input from the switching circuit 421. The output-side operational amplifier 423 inputs the audio signal input from the DA converter 45 to the output-side operational amplifier 423 to the second pin P2 (HOT) of the XLR type connector 41. In the 4-wire system, the 3rd pin P3 of the XLR type connector 41 is a HOT on the input side, but the 2nd pin P2 of the XLR type connector 41 is a HOT on the output side. The output-side operational amplifier 424 inputs an audio signal input from the DA converter 45 to the output-side operational amplifier 424 to pin 1 P1 (COLD) of the XLR type connector 41. The pin 1 P1 of the XLR type connector 41 is COLD on both the input side and the output side of the 4-wire system.

The AD converter 43 is provided after the input side operational amplifiers 4221 and 4222, and converts the analog audio signal input from the input side operational amplifiers 4221 and 4222 into a digital audio signal. Further, in the case of the 4-wire system, the AD converter 43 of the present embodiment generates a difference between the HOT and COLD signals input in a balanced manner from the input side operational amplifiers 4221 and 4222, and eliminates the influence of noise. The MCU 44 is a microcontroller configured by a processor such as a CPU, and is provided after the AD converter 43 to perform various signal processing such as equalization on the audio signal input from the AD converter 43 or the RF block 46. It is a signal processing unit. The DA converter 45 is provided after the MCU 44 and converts the digital audio signal input from the MCU 44 into an analog audio signal. The RF block 46 is provided after the MCU 44, modulates the audio signal processed by the MCU 44, and transmits the signal to the slave unit 3. Further, the RF block 46 receives the audio signal transmitted from the slave unit 3, demodulates it, and transmits it to the MCU 44.

[Action]
The operation of the voice communication system 1 in the present embodiment will be described with reference to FIGS. 2 and 3. First, the voice communication from the wired communication intercom 2 to the slave unit 3 will be described in the order of the 2-wire system and the 4-wire system, and then the voice communication from the slave unit 3 to the wired intercom 2 will be described in the 2-wire system and 4-wire system. The methods will be described in order.

(1) Voice communication from the wired intercom to the slave unit (1-1) 2-wire system In the 2-wire system, the wired intercom 2 and the control device 4 are connected by one XLR type cable. Further, as shown in FIG. 3A, the first to fourth switches SW1 to SW4 are connected to the contacts S1B to S4B, respectively. The switching of this switch shall be performed in advance by the user via a setting screen (not shown), a physical button, or the like provided on the control device 4.

The audio signal input from the wired intercom 2 is input to the XLR type connector 41 of the control device 4 via one XLR type cable. More specifically, it is input to the 3rd pin P3 of the XLR type connector 41. As shown in FIG. 2, the audio signal input to the 3rd pin P3 of the XLR type connector 41 is input to the switching circuit 421 of the 2W / 4W circuit 42.

As shown in FIG. 3A, the audio signal input to the switching circuit 421 is input to the input side operational amplifier 4221 via the contact S2B and the contact S4B.

Returning to FIG. 2, the audio signal input to the input side operational amplifier 4221 is input to the AD converter 43. The AD converter 43 converts this audio signal into a digital audio signal. This digital audio signal is input to the RF block 46 after various signal processing is performed in the MCU 45. The RF block 46 modulates this digital audio signal and transmits it to the slave unit 3. When the slave unit 3 demodulates this voice signal, voice communication becomes possible.

(1-2) 4-wire system In the 4-wire system, the wired intercom 2 and the control device 4 are two XLR type cables used for input from the wired intercom 2 and output to the wired intercom 2, respectively. And these two XLR type cables are connected by a bifurcated cable that bundles one end of the cable. That is, two XLR type cables are individually connected to the wired intercom 2, and the bifurcated cable is connected to the XLR type connector 41 of the control device 4. Further, as shown in FIG. 3B, the first to fourth switches SW1 to SW4 are connected to the contacts S1A to S4A, respectively. The switching of this switch shall be performed in advance by the user via a setting screen (not shown), a physical button, or the like provided on the control device 4.

The audio signal input from the wired intercom 2 is input to the XLR type connector 41 of the control device 4 via the XLR type cable on the input side of the two XLR type cables. More specifically, it is input to the 3rd pin P3 (HOT) and the 1st pin P1 (COLD) of the XLR type connector 41. As shown in FIG. 2, the audio signal input to the 3rd pin P3 (HOT) and the 1st pin P1 (COLD) of the XLR type connector 41 is input to the switching circuit 421 of the 2W / 4W circuit 42. The audio signal input to the 1st pin P1 (COLD) is out of phase with the audio signal input to the 3rd pin P3 (HOT).

As shown in FIG. 3B, among the audio signals input to the switching circuit 421, those input to the 3rd pin P3 (HOT) are input to the input side operational amplifier 4221 via the contacts S3A and S4A. Will be done. On the other hand, among the audio signals input to the switching circuit 421, the audio signal input to the 1st pin P1 (COLD) is input to the input side operational amplifier 4222 via the contact S1A.

Returning to FIG. 2, the audio signals input to the input side operational amplifier 4221 and the input side operational amplifier 4222 are input to the AD converter 43, respectively. The AD converter 43 converts these audio signals into digital audio signals and generates an audio signal of the difference between these audio signals. The digital audio signal of this difference is input to the RF block 46 after various signal processing is performed in the MCU 45. The RF block 46 modulates this digital audio signal and transmits it to the slave unit 3. When the slave unit 3 demodulates this voice signal, voice communication becomes possible.

(2) Voice communication from the slave unit to the wired intercom (2-1) 2-wire system In the 2-wire system, the slave unit 3 and the control device 4 are wirelessly connected. The audio signal input from the slave unit 3 is modulated and transmitted to the RF block 46 of the control device 4. As shown in FIG. 2, the audio signal demodulated in the RF block 46 is input to the MCU 44. The MCU 44 performs various signal processing on this audio signal and inputs it to the DA converter 45. The DA converter 45 converts this audio signal into an analog audio signal and inputs it to the switching circuit 421.

As shown in FIG. 3A, the audio signal input from the DA converter 45 to the switching circuit 421 is input to the pin 3 P3 of the XLR type connector 41 via the contact S2B. The audio signal input to the 3rd pin P3 of the XLR type connector 41 is transmitted to the wired intercom 2 via the XLR type cable. This enables voice communication. The audio signal input from the DA converter 45 to the switching circuit 421 is not input to the input side operational amplifier 4221 via the contact S4B. This is achieved, for example, by an echo canceling circuit (not shown).

(2-2) 4-wire system In the 4-wire system, the slave unit 3 and the control device 4 are wirelessly connected. The audio signal input from the slave unit 3 is modulated and transmitted to the RF block 46 of the control device 4. As shown in FIG. 2, the audio signal demodulated in the RF block 46 is input to the MCU 44. The MCU 44 performs various signal processing on this audio signal and inputs it to the DA converter 45. The DA converter 45 converts this audio signal into an analog audio signal and inputs it to the output side operational amplifier 423 and the output side operational amplifier 424.

The audio signal input to the output side operational amplifier 423 is input to the second pin P2 (HOT) of the XLR type connector 41. The audio signal input to the output side operational amplifier 424 is input to the 1st pin P1 (COLD) of the XLR type connector 41. In the 4-wire system, the 3rd pin P3 of the XLR type connector 41 is a HOT on the input side, but the 2nd pin P2 of the XLR type connector 41 is a HOT on the output side, and both on the input side and the output side. , The first pin P1 of the XLR type connector 41 is COLD. The audio signal input to the 2nd pin P2 and the 1st pin P1 of the XLR type connector 41 is transmitted to the wired intercom 2 via the XLR type cable on the output side of the two XLR type cables. This enables voice communication.

[effect]
(1) The control device 4 of the present embodiment includes a switching circuit 421 for switching between unbalanced transmission and balanced transmission. As a result, instead of the conventional circuit for the 2-wire system and the circuit for the 4-wire system, one switching circuit 421 can support both the 2-wire system and the 4-wire system, so that the control device 4 can be miniaturized. You can. Further, in the past, it was necessary to mount two circuits, but since it is sufficient to mount one circuit, the manufacturing cost can be reduced.

(2) The switching circuit 421 of the present embodiment is a CMOS analog switch. As a result, the control device 4 can be downsized as compared with the case where the switching circuit is configured by, for example, a mechanical relay.

(3) The switching circuit 421 of the present embodiment includes the first to fourth switches SW1 to SW4, and in unbalanced transmission, the first switch SW1 connects the GND of the switching circuit 421 and the input side operational amplifier 4222. The second switch SW2 and the fourth switch SW4 connect the XLR type connector 41 and the input side operational amplifier 4221, and in the balanced transmission, the first switch SW1 has the XLR type connector 41 and the input side operational amplifier 4222. The third switch SW3 and the fourth switch SW4 connect the XLR type connector 41 and the input side operational amplifier 4221. As a result, it is possible to switch between the 2-wire system and the 4-wire system with a simple configuration of four switches SW1 to SW4, so that the manufacturing cost can be reduced.

(4) Since the control device 4 of the present embodiment includes an AD converter 43, a DA converter 45, and an RF block 46, a switching circuit can be used regardless of whether the analog input / output is a 2-wire system or a 4-wire system. By using 421, it is possible to connect to a digital wireless intercom system, and it is possible to construct a wireless communication system according to various operating conditions such as a broadcasting station.

[Other embodiments]
The present invention is not limited to the above embodiment, and at the implementation stage, the components can be modified and embodied within a range that does not deviate from the gist thereof. In addition, various inventions can be formed by an appropriate combination of the plurality of components disclosed in the above-described embodiment. For example, some components may be removed from all the components shown in the embodiments. Specifically, it also includes other embodiments such as the following.

(1) The switching circuit 421 of the above embodiment is configured by a CMOS analog switch, but may be configured by a mechanical relay.

(2) In the above embodiment, the XLR type connector 41 having three pins is adopted as the dual-purpose connector, but the present invention is not limited to this. For example, a connector having five pins may be adopted. With such a connector, both the input and output from the wired intercom 2 can be supported even with the 4-wire method, so that it is possible to save the trouble of changing the cable between the 2-wire method and the 4-wire method.

(3) The wired intercom 2 of the above embodiment is supposed to perform wireless communication with the slave unit 3, but may perform wired communication.

1 ... Voice communication system 2 ... Wired intercom 3 ... Slave unit 4 ... Control device 41 ... XLR type connector 42 ... 2W / 4W circuit 421 ... Switching circuit 4221 ... Input side operational amplifier 4222 ... Input side operational amplifier 423 ... Output side operational amplifier 424 ... Output side operational amplifier 43 ... AD converter 44 ... MCU
45 ... DA converter 46 ... RF block P1 ... 1st pin P2 ... 2nd pin P3 ... 3rd pin SW1 ... 1st switch SW2 ... 2nd switch SW3 ... 3rd switch SW4 ... 4th switch S1A to S4A , S1B to S4B ... contacts

Claims (5)

It is a control device in a voice communication system that performs voice communication between a wired intercom and a slave unit.
One dual-purpose connector connected to the wired intercom,
A switching circuit provided after the dual-purpose connector to switch between the 2-wire system and the 4-wire system,
A control device equipped with. The dual-purpose connector is
Pin 1 and
Pin 2 and
Pin 3 and
Equipped with
The 1st pin and the 3rd pin are connected to the switching circuit and are connected to the switching circuit.
In the two-wire system, an audio signal is input and output via the third pin.
In the 4-wire system, an audio signal is input via the 1st pin and the 3rd pin.
The control device according to claim 1. The changeover circuit is a CMOS analog switch.
The first switch and
The second switch and
With the third switch,
With the 4th switch
Equipped with
A first input side operational amplifier and a second input side operational amplifier are provided in the subsequent stage of the switching circuit.
In the two-wire method,
The first switch connects the GND of the switching circuit and the second input side operational amplifier.
The second switch and the fourth switch connect the third pin of the combined connector to the first input side operational amplifier.
In the 4-wire method,
The first switch connects the first pin of the combined connector to the second input side operational amplifier.
The third switch and the fourth switch connect the third pin of the combined connector to the first input side operational amplifier.
The control device according to claim 2. A first output-side operational amplifier provided in parallel with the first input-side operational amplifier and the second input-side operational amplifier, and the output side is connected to the second pin of the dual-purpose connector.
A second output-side operational amplifier, which is provided in parallel with the first output-side operational amplifier and whose output side is connected to the first pin of the dual-purpose connector,
Further prepare
The audio signal from the handset is
In the two-wire system, the output is output to the third pin of the dual-purpose connector via the switching circuit.
In the 4-wire system, the output is output to the first output-side operational amplifier and the second output-side operational amplifier.
The control device according to claim 2 or 3. An AD converter provided after the first input-side operational amplifier and the second input-side operational amplifier to convert an audio signal from the wired intercom into a digital signal.
An RF block provided after the AD converter and transmitting and receiving an audio signal to and from the slave unit,
A DA converter provided in parallel with the AD converter and after the RF block to convert an audio signal from the slave unit into an analog signal.
The control device according to any one of claims 1 to 4.

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