JP2008294802A - Data transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To transmit data from a master unit to a slave unit and a split unit, and also to transmit data from the slave unit to the split unit without influencing network transmission. <P>SOLUTION: The master unit 2, the slave unit 6, and the split unit 8 are connected via a switching hub 4. The master unit 2 transmits data by broadcast, and the slave unit 6 transmits the data by unicast to the master unit 2. The master unit 2 synthesizes transmission data prepared by the master unit 2 and reception data received from the slave machine 6, and transmits the synthesized data by broadcast. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a data transmission system, and more particularly to a data transmission system that transmits data between a plurality of terminal devices.

  An example of a data transmission system is disclosed in Non-Patent Document 1. In this data transmission system, analog audio signals of 32 channels are input to a main transmission / reception terminal device such as a master device, and these are digitized and transmitted to a sub transmission / reception terminal device such as a slave device via a switching hub. The These digital audio signals are supplied from the slave device to the console to be mixed output of 8 channels, transmitted again from the slave device to the master device via the switching hub, converted into an analog audio signal by the master device, and the speaker system. Is transmitted. The 32-channel digital audio signal from the master device is also supplied to a receiving terminal device, for example, a split device, via the switching hub, and is supplied to the monitor console. That is, a master device, a slave device, and a split device are connected via a network, data is transmitted from the master device to the slave device and the split device via the network, and data transmission is performed from the slave device to the master device via the network. Has been done.

2005 Published by Roland Corporation Digital Snake S-4000S, page 60

  In this transmission system, the split device can receive the digital audio signal from the master device, but cannot receive the digital audio signal from the slave device. For this reason, the split device cannot record the 32-channel digital audio signal from the master device and the 8-channel mixing output from the slave device.

  This is not disclosed in Non-Patent Document 1, but since the digital audio signal data transmission from the master device is performed by broadcast, the digital audio signal from the master device is transmitted to the slave device and the split device. However, the transmission from the slave device is performed by unicast with the master device as the destination with respect to the master device, and thus is not transmitted to the split device. For example, if broadcast is transmitted from the slave device, the split device can receive the 8-channel mixing output from the slave device. However, since the broadcast is distributed throughout the network, if the frequency of use is high, an excessive load is applied to the network. Therefore, it is not desirable to transmit the broadcast from both the master device and the slave device. In addition, although it is conceivable to transmit the data to the master device and the split device by individual unicast, the number of packets existing in the network increases, so that the transmission efficiency of the entire network decreases.

  The present invention can perform data transmission between the main and sub transmission / reception terminal devices, and between the main transmission / reception terminal device and the reception terminal device, and also can receive data from the sub transmission / reception terminal devices without affecting network transmission. It is an object of the present invention to provide a data transmission system that can be transmitted to a receiving terminal device.

  In the data transmission system of one embodiment of the present invention, a main transmission / reception terminal device having a transmission / reception function, a sub transmission / reception terminal device having a transmission / reception function, and at least one reception terminal device having a reception function are connected via a network. Has been. The main transmission / reception terminal device transmits data to terminal devices other than itself, that is, a sub transmission / reception terminal device and a reception terminal device. This data transmission is performed by broadcast, for example. The sub transmission / reception terminal device transmits data to the main transmission / reception terminal device. This data transmission is performed by unicast with the main transmission / reception terminal device as a destination. A plurality of receiving terminal devices can be installed. For example, digital audio data or digital video data can be used as the data to be transmitted. The main transmission / reception terminal device synthesizes transmission data prepared by itself, for example, data supplied to the main transmission / reception terminal device and reception data received from the sub-transmission / reception terminal device, and transmits them to terminal devices other than itself. To do.

  In the data transmission system configured as described above, the main transmission / reception terminal device combines the data prepared by itself and the data transmitted from the sub transmission / reception terminal device, and transmits the synthesized data to the sub transmission / reception terminal device and the reception terminal device. . Therefore, the receiving terminal device can receive data prepared by the main transmitting / receiving terminal device and the sub transmitting / receiving terminal device, respectively. The sub-transmission / reception terminal device receives the data transmitted by itself again, but there is no problem because this can be ignored. In this data transmission system, the sub-transmission / reception terminal device does not need to transmit its own data by broadcast, and the sub-transmission / reception terminal device needs to individually transmit the same data to the main transmission / reception terminal device and the reception terminal device. Therefore, data transmission can be performed smoothly without burdening the network.

  Data transmitted by the main transmitting / receiving terminal device and the sub transmitting / receiving terminal device can be transmitted as a packet. The packet transmitted from the main transmission / reception terminal device is composed of packet data obtained by dividing the data prepared by itself into packets and packet data of packets received from the sub transmission / reception terminal device.

  If comprised in this way, since each packet contains the data prepared by the main transmission / reception terminal device and the data prepared by the sub transmission / reception terminal device, it transmits, and the number of packets transmitted on a network increases. And there is no burden on the network.

  The packet data obtained by dividing the data prepared by the main transmission / reception terminal device into packets and the packet data of the packet received from the sub transmission / reception terminal device are each composed of a plurality of channels. it can.

  If comprised in this way, the data of many channels can be smoothly transmitted, without becoming a network burden.

  As described above, in the data transmission apparatus according to the present invention, data transmission can be performed between the main and sub transmission / reception terminal apparatuses, and between the main transmission / reception terminal apparatus and the reception terminal apparatus, and without affecting network transmission. The data from the sub-transmission / reception terminal device can also be transmitted to the reception terminal device.

  The data transmission system according to the first embodiment of the present invention transmits an audio signal, and has a main transmission / reception terminal device, for example, a master device 2 as shown in FIG.

  The master device 2 has a plurality of, for example, 32 channel inputs, and is supplied with an analog audio signal from a sound source, for example, 32 microphones provided on the stage of the performance hall. These analog audio signals are converted into digital audio signals in the master device 2. These audio signals are divided into packet data, and packet transmission is performed with packet data for 32 channels included in one packet. These packets are transmitted by broadcast, and are transmitted via the switching hub 4 to the sub-transmission / reception terminal device, for example, the slave device 6 and the reception terminal device, for example, the split device 8.

  The slave device 6 is arranged, for example, in the front of house of the performance hall, restores the 32 channel digital audio signal from each received packet, and supplies it to the digital signal processing means, for example, the console 10 for mixing. The console 10 mixes these 32-channel digital audio signals into 8-channel digital audio signals and outputs them to the slave device 6. The slave device 6 divides the digital audio signal from the console 10 into packet data, and transmits the packet in a state where packet data for 8 channels is included in one packet. These packets are transmitted by unicast with the master device 2 as the destination, and are transmitted to the master device 2 via the switching hub 4.

  The master device 2 converts the packet data transmitted from the slave device 6 into an analog audio signal, supplies it to the speaker system, and amplifies it. Further, the packet data transmitted from the slave device 6 is combined with the packet data to be transmitted to the slave device 6 to generate a new packet. One new packet is a digital audio signal for 32 channels obtained by digitizing an analog audio signal from 32 microphones, followed by a digital audio signal for 8 channels transmitted from the slave device 6. It is. This packet is transmitted by broadcast to the slave device 6 and the split device 8 via the switching hub 4.

  As a result, a digital audio signal from the master device 2 and a digital audio signal from the slave device 6 are transmitted to the split device 8. The packet transmitted to the split device 8 is restored to a digital audio signal and is directly or converted into an analog signal, which is supplied to a processing means, for example, a recording device 12, and recorded. Thereby, the recording device 12 can individually record both the 32-channel audio signal from the 32 microphones and the 8-channel audio signal mixed by the console 10.

  Note that both the 32-channel audio signal from the 32 microphones and the 8-channel audio signal mixed by the console 10 are also transmitted to the slave device 6. Of these, the mixed 8-channel audio signal is transmitted. Since the audio signal is transmitted by the slave device 6 itself, it is ignored and only the 32-channel audio signal is output to the console 10.

  In this data transmission system, it is possible to transmit data from the slave device 6 to the split device 8, which is impossible with the above-described conventional technology. In addition, the data transmitted from the slave device 6 is combined with the data transmitted from the master device 2 in the master device 2 and transmitted from the master device 2 in the same packet. Therefore, in this transmission system, only a packet transmitted by broadcast from the master device 2 and a packet transmitted by unicast destined for the master device 2 from the slave device 6 are transmitted, and the split device 8 is transmitted from the slave device 6. Packets destined for are not transmitted, and the number of packets existing in the network can be reduced. Moreover, since each packet is composed of data consisting of a plurality of channels transmitted from the slave device 6 and data of a plurality of channels originally transmitted from the master device 2, the number of packets transmitted on the network is further reduced. Yes. In general, when data is packetized, a header is added to the divided data, but the configuration of this header is redundant. Further, when transmitting continuous packets, it is necessary to provide a certain interval between packets in the protocol. Therefore, when the number of packets transmitted over the network increases, transmission efficiency decreases and traffic increases more than necessary. In this data transmission system, since the number of packets transmitted to the network is reduced as described above, it is possible to prevent a decrease in transmission efficiency and an unnecessary increase in traffic.

  In the data transmission system of the second embodiment, as shown in FIG. 2, two switching hubs 4a and 4b are provided between the master device 2a, the slave device 6a, and the split device 8a. A transmission path A is formed between the master device 2a and the switching hub 4a, and a transmission path B is formed between the switching hub 4a and the slave device 6a. A transmission path C is formed between the master device 2a and the switching hub 4b, and a transmission path D is formed between the switching hub 4b and the slave device 6a. A transmission path E is formed between the switching hub 4a and the split device 8a, and a transmission path F is formed between the switching hub 4b and the split device 8a.

  Since the master device 2a transmits data by broadcasting as in the first embodiment, packets transmitted from the master device 2a via the transmission paths A and C are slave devices via the transmission path B from the switching hub 4a. 6a is transmitted to the split device 8a via the transmission path E, and similarly transmitted from the switching hub 4b to the slave device 6a via the transmission path D and to the split device 8a via the transmission path F.

  The slave device 6a determines whether it is possible to detect a carrier attached to a packet transmitted via the transmission path B and the transmission path D, for example, a preamble included in the frame of the packet, and transmission that can detect the carrier. A packet is received from the path B or D. Since this carrier detection can be performed prior to completion of packet reception, it is effective to use this carrier detection for switching the transmission path B or D. The slave device 6a transmits the packet by unicast with the master device 2a as the destination toward the master device 2a via the transmission path B or D thus switched for reception.

  The master device 2a also determines whether or not a carrier associated with a packet transmitted via the transmission paths A and C can be detected, and receives a packet from the transmission path A or C that can detect the carrier.

  The split device 8a also determines whether or not a carrier associated with a packet transmitted via the transmission path E or F can be detected, and receives the packet from the transmission path E or F that can detect the carrier.

  In the data transmission system of the second embodiment, the master device 2a transmits packets to the slave device 6a and the split device 8a via the two switching hubs 4a and 4b, and the slave device 6a also includes the two switching hubs 4a, 4a, Since the packet is transmitted toward the master device 2a via 4b, even if one of the switching hubs 4a and 4b fails, the packet is transmitted via the transmission path connected to the other switching hub. Transmission can be performed reliably. Even if a failure occurs in either of the transmission lines A and C, the packet can be transmitted through the remaining transmission line. Even if a failure occurs in any of the transmission paths B and E, a packet can be transmitted in the same manner regardless of whether a failure occurs in any of the transmission paths D and F.

  In the first embodiment, one switching hub 4 is used, but two switching hubs may be used as in the second embodiment. Conversely, in the second embodiment, a single switching hub can be used. Also, a plurality of split devices can be provided.

1 is a block diagram of a data transmission system according to a first embodiment of this invention. It is a block diagram of the data transmission system of the 2nd Embodiment of this invention.

Explanation of symbols

2 2a Master device (main transmission / reception terminal device)
6 6a Slave device (sub transmission / reception terminal device)
8 8a Split device (receiving terminal device)

Claims (3)

A main transmission / reception terminal device having a transmission / reception function, a sub transmission / reception terminal device having a transmission / reception function, and at least one reception terminal device having a reception function are connected via a network. In the data transmission system for transmitting data to the terminal device, the sub-transmission / reception terminal device transmits data to the main transmission / reception terminal device,
The main transmission / reception terminal device synthesizes transmission data prepared by itself and reception data received from the sub-transmission / reception terminal device, and transmits the resultant data to terminal devices other than itself.   2. The data transmission system according to claim 1, wherein data transmitted by said main transmission / reception terminal device and said sub transmission / reception terminal device is transmitted as a packet, and a packet transmitted from said main transmission / reception terminal device is data prepared by itself. A data transmission system comprising packet data obtained by dividing a packet into packets and packet data of packets received from the sub-transmission / reception terminal device.   3. The data transmission system according to claim 2, wherein the packet data obtained by dividing the data prepared by the main transmission / reception terminal device into packets and the packet data of the packet received from the sub transmission / reception terminal device each have a plurality of channels. A data transmission system consisting of

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