JP4691479B2 - Network broadcasting apparatus and network signal transmission apparatus - Google Patents

Description

  The present invention relates to a network signal transmission device that transmits and receives signals using a network, for example, a network broadcasting device that performs broadcasting using a network, and particularly, backup when broadcasting using the network becomes impossible. About.

  For example, Patent Document 1 discloses a local broadcasting device that can broadcast an emergency message when broadcasting becomes impossible. In this private broadcasting apparatus, audio signals from a plurality of broadcast sound sources are supplied to the input side of the matrix circuit. A plurality of output sides of the matrix circuit are respectively supplied to the speakers. The CPU controls the connection between the input side and the output side of the matrix circuit so that the audio signal of the broadcast sound source specified in advance can be supplied to the specified speaker. A line for transmitting an audio signal from the microphone for emergency message broadcasting is laid to each speaker separately from the matrix circuit, and a changeover switch for connecting one of the line and the output side of the matrix circuit to the speaker is provided. It is provided in each speaker. Each changeover switch is simultaneously switched to the output side or the line side of the matrix.

JP-A-10-303837

  In the technique disclosed in Patent Document 1, since a line from a specific microphone is laid to each speaker, if it is desired to increase the number of microphones, it is necessary to lay the same number of lines as that microphone to each speaker. Laying is troublesome.

  It is an object of the present invention to provide a network broadcasting device that can be laid and can be used for emergency broadcasting. Other objects of the present invention will become clearer from the following description.

The network broadcasting device of one embodiment of the present invention includes a plurality of input devices. These input devices are connected to an analog sound source such as a microphone. These input devices convert an analog audible sound signal from an analog sound source into a digital audible sound signal and supply it to a network. Digital audible sound signals are supplied to a plurality of output devices via a network. Each output device converts the supplied digital audible sound signal into an analog audible sound signal and outputs the analog audible sound signal. The control device controls via the network which of the input devices to which of the output devices the digital audible sound signal is transmitted. One backup transmission line of analog audible sound signal is wired in common to each input device, each output device, and the control device. One control line is wired in common to each input device, each output device, and the control device. Each of the input devices generates a control signal according to an operation of a switch operated when emergency broadcasting is necessary, and supplies the control signal to the one control line, the one backup transmission line, A first opening / closing switch interposed between the analog sound source, the first opening / closing switch, and a second opening / closing switch interposed between the first opening / closing switch and a closing signal generating means for closing the first opening / closing switch; Opening / closing means connected to the control signal generating means and the control line, and closing the second opening / closing switch when receiving the control signal via the control line or from the control signal generating means. Each of the output devices includes a third switch interposed between the backup transmission line and a speaker, and a closing unit that receives the control signal transmitted through the control line and closes the third switch. It has. When the control device receives the control signal transmitted through the control line, the control device stops transmitting the digital audible sound signal through the network.

  In the network broadcasting device configured as described above, when a control signal is supplied to the control line in any of the input devices, for example, when broadcasting cannot be performed via the network, each input device and the control device are connected. Each output device transmits the analog audible sound signal from the backup transmission line via the control line. In this state, when an analog audible sound is generated by the input device to which the control signal is supplied, this is supplied to each output device via the backup transmission line between each input device and the control device, and is output. Therefore, emergency broadcasting can be performed from any input device. Moreover, the emergency broadcast line is only a backup transmission line and a control line laid to cascade each input device, control device and each output device, and each input device backs up to each output device individually. There is no need to lay a transmission line for installation, and laying work can be performed easily.

  The backup transmission line and the control line can be configured as an integrally formed cable. With this configuration, it is only necessary to install one cable between each input device, control device, and each output device, and there is no need to separately install a backup transmission line and a control line. Become.

  Alternatively, an uninterruptible power supply device can be connected to each input device, each output device, the network, and the control device so that operating power can be supplied during a power failure. In this case, an activation line is laid between the input devices, the output devices, and the control device. Further, the control device sets each input device and each output device in a standby mode at the time of a power failure, and reduces power consumption in each input device and output device. When an activation signal is supplied to the activation line, each input device and each output device shifts from the standby mode to the normal mode.

  With this configuration, during a power failure, operating power is supplied by the uninterruptible power supply device, but the input device, the output device, and the network line (such as a hub) are in a standby mode, and power consumption is suppressed. In this state, when the emergency broadcast is necessary, the emergency broadcast can be performed using the control line and the backup transmission line described above. That is, in the standby mode, broadcasting using the control line and the backup transmission line is possible. Therefore, in the standby mode, the output device and the input device do not consume much power, and emergency broadcasting is possible. In addition, during a power outage, in case of failure detection between devices and devices, information transmission, broadcasting other than simultaneous broadcasting, etc., when a startup signal is supplied to the startup line to temporarily connect to the network, Returning to the normal mode, the digital audible sound signal from each input device can be supplied to a predetermined output device through the network. At that time, each device can be returned to the standby mode again through the network.

  The activation line may be configured integrally with the backup line and the control line. If comprised in this way, a starting line, a backup transmission line, and a control line can be laid only by laying one cable, and laying work becomes easy.

  As described above, according to the network broadcasting apparatus according to the present invention, emergency broadcasting can be performed only with easy laying work of a line. Moreover, the network signal transmission device according to the present invention can suppress power consumption during a power failure, and can send and receive signals via the network when necessary.

  As shown in FIG. 1, the network broadcasting apparatus according to an embodiment of the present invention includes a plurality of, for example, n terminal devices, for example, input devices 2-1 to 2-n. These input devices 2-1 to 2-n are all connected to a network, for example, a switching hub (hereinafter referred to as a hub) 4 with the same configuration. The hub 4 is also connected to a plurality of, for example, m terminal devices, for example, the output devices 6-1 to 6-m. The output devices 6-1 to 6-m all have the same configuration. Further, a control device such as a system manager 8 is also connected to the hub 4.

  Digital signals from any of these input devices 2-1 to 2-n are transmitted via the hub 4 to desired ones of the output devices 6-1 to 6-m. For example, when a digital signal is transmitted from the input device 2-1 to the output device 6-1, the input device 2-1 requests the system manager 8 via the hub 4 to transmit the digital signal to the output device 6-1. To do. The system manager 8 checks whether transmission to the output device 6-1 is possible. If it is possible, the system manager 8 grants transmission permission to the input device 2-1, and sends the output device 6-1 from the input device 2-1. Request the reception of digital signals. The other input devices 2-2 to 2-n can be similarly transmitted to the output devices 6-1 to 6-m.

  As shown in FIG. 2, digital signals from the input devices 2-1 to 2-n are, for example, a plurality of sound sources connected to each of the input devices 2-1 to 2-n, for example, microphones 10 (in FIG. 2). An analog audible sound signal, for example, an audio signal is amplified by a microphone amplifier 11 and then converted to a digital audible signal, for example, a digital audio signal by an A / D converter 12. . This digital audio signal is supplied to a network processing circuit such as a CPU 14 provided in each of the input devices 2-1 to 2 -n, and is supplied from there to the hub 4.

  In each of the output devices 6-1 to 6-m, as shown in FIG. 3, the digital audio signal supplied from the hub 4 is supplied to a network processing circuit, for example, the CPU 16, and is supplied from there to the D / A converter 18. Then, it is restored to an analog audible sound signal, for example, an analog audio signal, and supplied to a loudspeaker, for example, a speaker 21 through a buffer amplifier 20a and a power amplifier 20b through an open / close switch 19 that is normally closed.

  As shown in FIG. 1, each input device 2-1 to 2-n is connected to the backup cable 22, and the final input device 2-n is connected to the system manager 8 by the backup cable 22. The output device 6-1 is connected via the backup cable 22. The output devices 6-1 to 6-m are connected in order from the output device 6-1 to the output device 6-m via the backup cable 22. That is, the input devices 2-1 to 2-n, the system manager 8, and the output devices 6-1 to 6-m are connected in cascade.

  Each backup cable 22 is integrally provided with the four lines shown in FIGS. 2 to 4, and each line includes an analog backup transmission line, for example, an analog line 22a, a control line, for example, a CPU OFF line 22b, The start line includes, for example, a reset / standby start line 22c and a connection check line 22d.

  The analog line 22a and the CPUOFF line 22b are used when emergency broadcasting is performed. In other words, the microphone 10 connected to each of the input devices 2-1 to 2-n is provided with a CPUOFF switch 24 as shown in FIG. The CPUOFF switch 24 is operated when it is desired to perform emergency broadcasting in a state where broadcasting cannot be performed for some reason in the network broadcasting device. When the CPUOFF switch 24 is operated in a certain input device, the CPUOFF output unit 26 in the input device outputs a control signal, for example, a CPUOFF signal in response to this operation. The CPUOFF signal is transmitted to other input devices, the system manager 8, and the output devices 6-1 to 6-m via the CPUOFF line 22b.

  The CPUOFF signal is supplied as it is to the CPUOFF detection unit 28 of the input device that has generated the CPUOFF signal. The CPUOFF detection unit 28 of each input device 2-1 to 2-n generates a CPUOFF detection signal in response to the CPUOFF signal. The CPUOFF detection signal is supplied to the CPU 14. The CPU 14 knows that the network broadcast is not normally performed by supplying the CPUOFF detection signal, and stops the network processing. Further, the opening / closing switch 30 between the microphone amplifier 11 and the buffer amplifier 11a is closed by the generation of the CPUOFF detection signal. At the same time, the open / close switch 34 that transmits the talk switch 32 provided in the microphone 10 is closed by the CPUOFF detection signal. In this state, when the talk switch 32 of the input device in which the CPU OFF switch 24 is operated is operated, a close signal is supplied to the open / close switch 36 on the output side of the buffer amplifier 11a via the closed open / close switch 34. The open / close switch 36 is closed. In this state, when the voice is sent to the microphone 10, an analog audio signal is supplied to the audio output unit 38 via the microphone amplifier 11, the open / close switch 30, the buffer amplifier 11 a, and the open / close switch 36. It is transmitted to other input devices 2-1 to 2-n and output devices 6-1 to 6-m via the line 22a.

  In each of the output devices 6-1 to 6-m, as shown in FIG. 3, the CPUOFF signal transmitted through the CPUOFF line 22b is supplied to the CPUOFF detection unit 40, and the CPUOFF detection unit 40 generates a CPUOFF detection signal. . The CPUOFF detection signal is supplied to the CPU 16. Thereby, the CPU 16 learns that the network broadcast is not normally performed, and stops the network processing. On the other hand, the CPUOFF detection signal closes the open / close switch 44 between the input side of the buffer amplifier 20a and the output side of the audio input unit 42 for inputting the audio signal from the analog audio line 22a. At the same time, the open / close switch 19 is opened. When the open / close switch 44 is closed, an analog audio signal transmitted via the analog line 22a is supplied to the speaker 21 via the audio input unit 42, the open / close switch 44, and the buffer amplifier 20a and the power amplifier 20b. Is done. Therefore, emergency broadcasting can be performed even when network broadcasting cannot be performed.

  In the above description, the emergency broadcast is performed from one input device. However, the emergency broadcast is performed by operating the CPU OFF switch 24 and the talk switch 32 in the other input devices as well. be able to. When an emergency broadcast is performed from a certain input device, since the CPUOFF signal is already supplied to the CPUOFF line 22b, the open / close switches 30, 34 are already closed in each input device, and the talk switch 32 is operated. You can make emergency broadcasts from other input devices.

  When the CPUOFF signal is supplied to the CPUOFF line 22b, the CPUOFF signal is supplied to the CPUOFF detection unit 46 of the system manager 8 shown in FIG. In response to this, the CPUOFF detection unit 46 supplies a CPUOFF detection signal to the CPU48. The CPU 48 learns that the network broadcast is not normally performed, and stops the network processing.

  In this way, emergency broadcasting can be performed from any of the input devices 2-1 to 2-n, and the lines laid for this purpose are the input devices 2-1 to 2-n and the system manager. 8. Only the backup cable 22 connecting the output devices 6-1 to 6-m, and emergency broadcasting from the input devices 2-1 to 2-n individually to the output devices 6-1 to 6-m There is no need to lay a line. In addition, since the analog line 22a and the CPUOFF line 22b, which are two lines used for the emergency broadcast, are provided in one cable 22, the laying is further facilitated.

  The reset / standby activation line 22c provided in the cable 22 is used for resetting the CPU 14 of each of the input devices 2-1 to 2-n and the CPU 16 of each of the output devices 6-1 to 6-m, for example. . For example, when the system manager 8 determines that the network broadcast is not performed satisfactorily due to noise or a software bug, the system manager 8 gives a reset command from the CPU 48 to the RESET output unit 50 to reset the network broadcast. The output unit 50 supplies a reset signal to the reset / standby activation line 22c. In each of the input devices 2-1 to 2-n, the reset detection unit 52 connected to the reset / standby activation line 22 c detects the reset signal, supplies the reset detection signal to the CPU 14, and resets the CPU 14. Similarly, in each of the output devices 6-1 to 6-m, the reset detection unit 54 connected to the reset / standby activation line 22c detects the reset signal, supplies the reset detection signal to the CPU 16, and resets the CPU 16. To do. The reset CPUs 14 and 16 of the input devices 2-1 to 2-n and the output devices 6-1 to 6-m communicate with the system manager 8 to reconstruct the network. Alternatively, the reset switches 55, 56, 58 provided in the input devices 2-1 to 2-n, the output devices 6-1 to 6-m, the system manager 8, or any place on this line can be installed. When the switch is pressed by a person, a reset detection signal is supplied to the CPUs 14 and 16 and a reset instruction is supplied to the CPU 48, so that the reset can be performed. By resetting in this way, network broadcasting may be able to be resumed.

  The reset / standby activation line 22c is also used to activate the input devices 2-1 to 2-n and the output devices 6-1 to 6-m in a standby state, for example, in a standby state. That is, as shown in FIG. 1, this network broadcasting device is provided with an uninterruptible power supply device 44, and in the event of a power failure, the input devices 2-1 to 2-n, the hub 4, Operating power is supplied to each of the output devices 6-1 to 6-m and the system manager 8. However, if the input devices 2-1 to 2-n, the hub 4, the output devices 6-1 to 6-m and the system manager 8 are fully operated, the power consumption in these devices is large, and the uninterruptible power supply The operating power can be supplied from the supply device 44 only for a short time.

  Therefore, when the power supply by the uninterruptible power supply device 44 is started, the system manager 8 detects that the power supply is disclosed from the uninterruptible power supply device 44, and each input device 2-via the hub 4. 1 to 2-n and the output devices 6-1 to 6-m are set to the standby mode, and the system manager 8 is also set to the standby mode.

  In the standby mode, the input devices 2-1 to 2 -n are supplied with the minimum power that can be operated when an activation signal is supplied to the CPU 14 via the reset / standby activation line 22 c. Also in the output devices 6-1 to 6-m, in the standby mode, the minimum power that can be operated when the activation signal is supplied to the CPU 16 via the reset / standby activation line 22c is supplied. The system manager 8 is the same.

  Therefore, in the standby mode, analog emergency broadcast can be performed by operating the CPU OFF switch 24 and the talk switch 32 as described above. Moreover, since the supply of operating power from the uninterruptible power supply device 44 is the minimum, power can be supplied over a long period of time. For example, a time during which the uninterruptible power supply device 44 can supply power is determined. Even in such a case, an uninterruptible power supply device 44 having a small capacity can be used.

  When the power supply is restored, the activation signal is supplied from the system manager 8 to the reset / standby activation line 22c, and in response thereto, the input devices 2-1 to 2-n and the output devices 6-1 to 6- The CPUs 14 and 16 of m return to the normal operation mode. Therefore, when the CPU 48 of the system manager 8 gives an activation instruction to the standby activation output unit 60 via the normally closed open / close switch 62, the standby activation output unit 60 supplies an activation signal to the reset / standby activation line 22c. . In each of the input devices 2-1 to 2-n and each of the output devices 6-1 to 6-m, the standby activation detection units 64 and 66 connected to the reset / standby activation line 22c detect the activation signal, and the activation detection signal Is supplied to the CPUs 14 and 16. As a result, the input devices 2-1 to 2-n and the output devices 6-1 to 6-m return to the normal operation mode.

  The open / close switch 62 is opened when a reset instruction is given to the reset output unit 50 or when the reset switch 58 is operated, and the open / close switches 72 and 74 are reset by the reset detectors 52 and 54. Opened when it occurs or when the reset switches 55, 56 are operated. In these, the reset signal and the start signal are transmitted using the reset / standby start line 22c which is the same signal line, and the reset priority is higher than the start, so when the reset signal is transmitted, This is to prevent the activation signal from being transmitted.

  In the state where the uninterruptible power supply device 44 is operating, the clock signal provided in the system manager 8, for example, a timer, times up, so that the activation signal is supplied from the system manager 8 in the same manner as described above. May be temporarily restored to the normal operation mode. This is performed, for example, when it is necessary to perform some broadcasting at regular intervals even in a state where the uninterruptible power supply device 44 is operating. Further, even when a start command is supplied from the outside to the system manager 8, the system manager 8 supplies a start signal in the same manner as described above, and returns to the normal operation mode.

The start command is supplied not to the system manager 8 but to a specific input device or a specific output device, and accordingly, the specific input device or the specific output device supplies a start signal to the reset / standby start line 22c. There is also. In this case, in each of the input devices 2-1 to 2-n or each of the output devices 6-1 to 6-m, each of the input devices 2-1 to 2-n and each of the output devices 6-1 to 6-m The CPU 14 or 16 gives a start instruction to the standby start output unit 68 or 70 via the open / close switch 72 or 74 that is normally closed, and the standby start output unit 68 or 70 enters the reset / standby start line 22c. Supply activation signal. This activation signal is supplied to the other input devices 2-1 to 2-n or the output devices 6-1 to 6-m, where they are processed in the same manner as described above to return to the normal mode. In this case, the activation signal is supplied to the standby activation detection unit 76 of the system manager 8 via the reset / standby activation line 22c. The standby activation detection unit 76 supplies the activation detection signal to the CPU 48, and the CPU 48 also returns to the normal mode. .

  Alternatively, operating power is also supplied to the hub 4 by the uninterruptible power supply device 44 so that the hub 4 can communicate with the system manager 8 via the hub 4 from a specific input device or a specific output device. Alternatively, when the output device detects a start command, this is supplied to the system manager 8 via the hub 4, and a start signal is supplied from the system manager 8 to the reset / standby start line 22c to return to the normal mode. You can also.

  In any case, since the operation power is not supplied from the uninterruptible power supply device 44 to all the devices constituting the network broadcasting device, the uninterruptible power supply device 44 supplies the operation power for a long time. Is possible.

  The connection check line 22d provided in the cable 22 is normally connected to the input devices 2-1 to 2-n, the system manager 8, and the output devices 6-1 to 6-m in terms of hardware. It is for checking whether or not. Each of the input devices 2-1 to 2-n and each of the output devices 6-1 to 6-m has a terminal unit 80. These terminal units 80 are adjacent to each of the input devices 2-1 to 2-n and the output. The devices 6-1 to 6-m and the connection detector 82 in the system manager 8 are connected via the connection check line 22d. The termination unit 80 is composed of, for example, a diode and a resistor, and each connection detection unit 82 is connected to either a disconnection or a short circuit depending on whether the resistance value of the connected termination unit 50 is within a specified range. Whether the cable 22 is present or not is detected, and the result is input to each of the input devices 2-1 to 2-n, the system manager 8 and the output devices 6-1 to 6- m to the CPUs 14, 48 and 16. These detection results are transmitted to the system manager 8 via the hub 4, and in each input device 2-1 to 2 -n, each output device 6-1 to 6 -m, and the system manager 8, which device and which device It is possible to know whether the cable 22 is disconnected or short-circuited.

  In this network broadcasting apparatus, it is also possible to check whether the output side of the audio input unit 42 of each output device 6-1 to 6-m is connected from the buffer amplifier 11a of each input device 2-1 to 2-n. it can. For example, at the normal time, an instruction is given from the system manager 8 to the output devices 6-1 to 6-m via the hub 4 and the inspection signal via the analog line 22a. At this time, an inspection instruction is simultaneously given to a certain input device from the system manager 8, and the CPU 14 of this input device causes the D / A converter 84 to generate an analog inspection signal. This inspection signal is supplied to the buffer amplifier 11a via the open / close switch 86 closed by the CPU 14 (this open / close switch 86 is normally opened, but is closed at the time of this inspection instruction), and is closed by this inspection instruction. The audio signal is supplied to the audio output unit 38 via the open / close switch 36 and supplied to the output devices 6-1 to 6-m via the analog line 22a.

  In each of the output devices 6-1 to 6-m, the output signal of the voice input unit 42 is digitized by the A / D conversion unit 88 and input to the CPU 16. The CPU 16 determines whether the inspection signal is supplied to the voice input unit 42 and notifies the result to the system manager 8 via the hub 4. By transmitting such an inspection signal from all input devices to each output device, it is possible to determine which analog line has a failure.

  Further, in each of the input devices 2-1 to 2-n, it can be checked whether the operation from the output side of the microphone 10 to the output side of the buffer amplifier 11a is normally performed. Although not shown, the microphone 10 is provided with an analog oscillation signal generator. When this oscillation signal is input to the microphone amplifier 11a, the output signal of the buffer amplifier 11a is digitally converted by the A / D converter 12. And supplied to the CPU 14. If the CPU 14 determines whether the digital signal is a digital signal of the analog oscillation signal and can determine that it is an analog oscillation signal, it can be confirmed that the input side of the microphone amplifier 11 to the output side of the buffer amplifier 11a is normal. Since a plurality of microphones 10 are provided as described above, it is possible to inspect from the output side of each microphone to the output side of the buffer amplifier 11a if an analog oscillation signal is generated in order for each microphone. In addition, if the analog oscillation signal is picked up by the microphone 10, the inspection including the microphone 10 can be performed.

  In the above embodiment, each of the input devices 2-1 to 2-n and each of the output devices 6-1 to 6-m are connected in cascade with the backup cable 22. For example, each output device is connected to a plurality of systems from the system manager 8. A plurality of output devices can be cascaded on each line. For example, if there are five output devices 6-1 to 6-5, the system manager connects to the output device 6-1 and the output device 6-1 connects to the output device 6-2. Separately, the system manager 8 connects to the output device 6-3, and the output device 6-3 connects to the output device 6-4. In addition, the system manager 8 connects to the output device 6-5. If the connection is made in this way, for example, if a disconnection occurs in the line between the output device 6-3 and the system manager 8, signal transmission to the output device 6-4 is impossible. Signal transmission to the devices 6-1, 6-2, and 6-5 becomes possible.

  In the above-described embodiment, the case where one microphone 10 is installed in one input device has been described in order to simplify the description. However, the present invention is not limited to this, and a plurality of input devices each have a plurality of input devices. In some cases, a microphone is installed.

  In the above embodiment, the packet signal based on the digital audio signal via the hub 4 from the predetermined one of the input devices 2-1 to 2-n to the predetermined one of the output devices 6-1 to 6-m. However, the present invention is not limited to this. For example, one packet signal is transmitted from the input device 2-1 to the input device 2-n via the hub 4, and each of the input devices 2-1 to 2-m is transmitted. When a packet signal is transmitted, if there is a digital audio signal to be transmitted, one of a plurality of divided digital audio signals obtained by dividing the digital audio signal is arranged in one of a plurality of blocks of the packet signal, and finally The input device 2-n to which the packet signal is transmitted transmits the packet signal in which the divided digital audio signals from the input devices 2-1 to 2-n are arranged via the hub 4 by multicasting to the output devices 6-1. Thru It may be repeated to transmit the -m. In this case, each of the input devices 2-1 to 2-n notifies the system manager 8 via the hub 4 in advance of the output device to which its own digital audio signal is to be transmitted. Each time a packet signal is transmitted to 6-1 to 6-m, an instruction is given on which block of the packet signal to extract the divided digital audio signal and assemble the extracted divided digital audio signal. deep.

  In the above embodiment, the present invention is implemented in a network broadcasting device. However, the present invention is not limited to this. For example, a plurality of communication terminal devices are communicably connected via a network, and a system manager is connected to the network for communication control. A backup line for startup is provided between each communication terminal device and the system manager, and each communication terminal device and system manager are operated in standby mode in the event of a power failure with an uninterruptible power supply. The communication terminal device and the system manager can be returned to the normal mode using the line.

It is a block diagram of the network broadcasting apparatus of one Embodiment of this invention. It is a block diagram of the input device of the network apparatus of FIG. It is a block diagram of the output device of the network apparatus of FIG. FIG. 2 is a block diagram of a system manager of the network device in FIG. 1.

Explanation of symbols

2-1 to 2-n input device (terminal device)
4 Hub (network)
6-1 to 6-m Output device (terminal device)
8 System manager (control device)
22a Analog line 22a (Analog backup transmission line)
22b CPUOFF line (control line)
22c Reset / standby start-up line (start-up line)

Claims (4)

A plurality of input devices connected to an analog sound source, converting an analog audible sound signal from the analog sound source into a digital audible sound signal, and supplying the signal to the network;
A plurality of output devices for converting a digital audible sound signal supplied via the network into an analog audible sound signal and outputting the analog audible sound signal;
A control device for controlling via which the digital audible sound signal is transmitted from which of the input devices to which of the output devices;
In the network broadcasting device provided,
A backup transmission line of one analog audible sound signal wired in common to each input device, each output device and the control device;
A single control line wired in common to the input devices, the output devices and the control device;
Each input device comprises:
Control signal generating means for generating a control signal in response to an operation of a switch operated when emergency broadcasting is necessary, and supplying the control signal to the one control line;
A first opening / closing switch interposed between the one backup transmission line and the analog sound source;
A second open / close switch interposed between the first open / close switch and a closing signal generating means for closing the first open / close switch;
Opening / closing means connected to the control signal generating means and the control line, and closing the second opening / closing switch when receiving the control signal via the control line or from the control signal generating means,
Equipped,
Each output device includes a third switch interposed between the backup transmission line and a speaker;
Closing means for closing the third switch in response to the control signal transmitted through the control line;
Equipped,
The network broadcasting device that stops transmission of the digital audible sound signal through the network when the control device receives the control signal transmitted through the control line .   2. The network broadcasting device according to claim 1, wherein the backup transmission line and the control line are configured as an integral cable. The network broadcasting device according to claim 1, wherein
Uninterruptible power supply devices connected to the input devices, the output devices, the network, and the control device so as to be able to supply operating power during a power failure,
Each input device, each output device and a starting line laid between the control device,
And the control device sets each input device and each output device to a standby mode at the time of the power failure, and sets each input device and each output device to a normal mode when an activation signal is supplied to the activation line. Network broadcasting device that   4. The network broadcasting device according to claim 3, wherein the startup line forms a set together with the backup line and the control line.

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