JPS59141849A - Bidirectional catv system - Google Patents

Abstract

PURPOSE:To shorten the waiting time to the data generated urgently by providing a function to a terminal device to detect the head code contained in the down-data signal sent to the terminal device from a center device and to transmit the own address in the form of an up-data signal. CONSTITUTION:A terminal device B generates urgently the data which is transmitted to a center device 101, and the head code 302 of the down-data 301 sent from the device 101 is received normally within the device B. Then the own address number is transmitted immediately from the device B in the form of the up- data 310. The data 310 is received by the device 101 and demodulated as an address code 305. Then it is recognized that the data to be urgently transmitted is generated. The address number corresponding to the device B is inserted to an address code 319 within the down-data 317 and transmitted in the next polling in place of the next address and out of the normal polling sequence after receiving the up-data 311 given from a terminal device A.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a line control method for data transmission in a two-way CATV system.

Conventional configuration and its problems FIG. 1 shows an example of the configuration of a conventional bidirectional 0ATV system, and FIG. 2 shows a transmission control procedure using a general polling method. In FIG. 1, when downstream transmission data 104 for performing data transmission with a terminal device is output from a center processing unit 102 in a center device 101, a modulation unit such as frequency modulation or phase modulation is used in a downlink data modulation unit 106. Modulation is performed using The modulated downlink data signal is sent out to the main cable 111 through a duplexer 108 and a mixer 109. The downlink data signal sent to the trunk cable 111 is branched by a branching device 112, and then enters the terminal device A114. Terminal device A1
14, the downlink data signal is separated from the uplink data signal by a demultiplexer 115, demodulated by a downlink data demodulation section 116, and then processed as downlink received data 118 in the terminal processing section 10. On the other hand, terminal processing section 11C
The upper transmission data 119 generated in ) is modulated in the uplink data modulation section 117 and then sent out to the trunk cable 111 via the duplexer 115 as an upper data signal. The upstream data signal follows a completely opposite route to the downstream data signal, and is sent to the mixer 10 in the center device 101.
9. The signal is input to the uplink data demodulation section 107 via the demultiplexer 108.

The uplink reception data 105 demodulated by the binary data demodulation section 1' 07 is reversely processed by the center processing section 102.

Bidirectional data transmission between the center and the terminal is thus performed. That is, in FIG. 2, a downlink data signal 201 sent out from the center device is transmitted to all terminals connected to the CATv network. The downlink data signal 201 sent from the center device usually includes a start code 202 indicating the start of the downlink data signal, an address code 203 indicating the address number of the terminal, and data 204 for transmitting other command signals. When the 0 downlink data signal 201 is received by the terminal device, it is compared with the address number specified for each terminal device (according to the address code 203 in the downlink data signal 201), and the terminal device that matches the address code 203 is compared with the address number specified for each terminal device. sends out the upper data signal.

If the address of the terminal device A is inserted in the address code 203, the terminal device A with the matching address sends out an uplink data signal 205. Like the lower υ data signal, this upstream data signal usually consists of a head code 206 indicating the head of upstream data and other data 207. Thereafter, the address number of terminal device B is inserted into the address code 210 portion of the downlink data signal 208 in the same way, and data 211 is placed after it. An upper data signal 212 is sent from the terminal device B with the matching address. 212 consists of a leading code 213 and data 214.

In this way, in the bidirectional 0 ATV system, the transmission path is a dendritic distribution network, so by sequentially changing the address numbers inserted into the address codes 203 and 210 using the polling method, the center equipment and terminal equipment Therefore, if a large number of terminals (up to several dozen units) are connected to the CA'TV system, the self-address is specified by the lower data signal, and then the address is sequentially changed and all terminals are scanned. 1, in which the self-address is designated again after the polling method is used, has the drawback that it takes about 9 hours of time. Therefore, in order to introduce functions that require emergency communication such as disaster prevention and crime prevention in a two-way GATV system, the transmission control procedure using the polling method requires increasing the transmission speed in proportion to the increase in the number of connected terminals. This results in problems such as increased cost and increased error rate. Also, due to the configuration of branchers and distributors used in CATv lines, it is impossible for other terminal devices to detect the above 9 signals from the terminal device.There is a polling method to eliminate the above drawback. It is not possible to introduce a normal contention method as a proxy transmission procedure into the system.

Purpose of the Invention The present invention is capable of immediately interrupting the conventional polling sequence in response to emergency data from a terminal device by using the polling method in data transmission in a two-way CATV system, and eliminates the drawbacks of the polling method. An object of the present invention is to provide a transmission control procedure that can significantly reduce the waiting time for emergency data. We focused on the fact that half-duplex communication was being carried out even though full-duplex communication was possible due to the line configuration, and when the center device sent out the first code part of the downlink data signal, it became normal. When a terminal device that needs to interrupt the polling sequence receives this first code, it immediately sends out only its own address number. - When the center device detects the address code from the terminal device as an upper data signal while sending the address code part of the downlink data signal, when the transmission with the terminal at the corresponding address for the downlink data currently being sent is completed, the next step in the polling sequence. Without polling the address, it immediately polls the terminal device corresponding to the address code detected as an upstream data signal in the next polling sequence, and in response to emergency data, the center device immediately collects the data.
It is designed so that it can be moved back and forth.

DESCRIPTION OF EMBODIMENTS An embodiment of the present invention will be explained using FIG. 1, which was used to explain the conventional configuration, and the transmission control procedure shown in FIG. 3. FIG. 1 is a block diagram of a bidirectional 0ATV system, which is the same as the conventional structure. In a two-way CJTV system, 1
A large number of terminals are connected to one center device, and they are connected by a single coaxial cable. Therefore, in order to exchange data between the center and the terminals, a polling method has been adopted as a normal transmission control procedure. Inside the center device 1o1, there are a head end 103 for sending out video signals, a center processing section 102 for bidirectional data transmission, and a modulation section 106 for downlink data.
, an uplink data demodulation section 107, a demultiplexer 108 for demultiplexing the lower data signal and the uplink data signal, and a video signal and a data signal for mixing, frequency division multiplexing, and sending out to one coaxial cable. It consists of a mixer 109.

Downlink transmission data 10 generated by the center processing unit 102
4 is modulated by the lower side data modulation section 106 and sent to the trunk cable 111 via the duplexer 108 and the mixer 109. The downlink data signal sent to the trunk cable 111 is distributed to all the terminal devices through the branchers 1' 12 and 113. The downlink transmission data 104 generated by the center processing unit 102 includes start codes 302 and 318 that indicate the beginning of the downlink data, as shown in downlink data 301 and 317 shown in FIG. 3, and an address code 303 that inserts the address number of the terminal device. , 319 and other data 304 for inserting command data, status data, etc.
．． 320. These lower side data signals are demultiplexed by the demultiplexer 115 of one terminal device A 114, and are inputted to the 0 lower side data demodulation section 116 to be input to the downlink data demodulation section 116. The downlink received data 118 demodulated into a baseband signal, that is, the downlink data 306 in FIG.
The data is processed by The terminal processing unit 110 compares the address code 308 with its own address, and if they match, it sends out a new data signal. In FIG. 3, address code 30 in lower data 301
If the address number of the terminal device A 114 is inserted in 3, the uplink transmission data 119 is sent from the terminal processing unit 110 of the terminal device A 114. Uplink transmission data 119
Like the upstream data 311 in FIG. 3, the data includes a leading code 312 indicating the beginning of the upstream data, and data 313 for inserting the status of the terminal. These data are modulated by the uplink data modulation section in the terminal device A 114 and then transmitted to the center device 101 through the duplexer 115 and the splitter 112. The above terminal device A
The sent uplink data 311 is demodulated by the uplink data demodulation section in the center device 101, and the uplink data 311 is demodulated by the uplink data demodulation section in the center device 101.
5, that is, input to the center processing section as upstream data 314 in FIG.

In this case, the downlink data 3 from the center device 101
01 is transmitted to all terminal devices connected to the trunk cable 111. Therefore, the terminal device A11 mentioned above
Processing similar to that performed in step 4 is performed in all terminal devices, but since the address does not match the own address within the terminal device, the upper data signal is not sent from the other terminal devices.

When data that should be urgently transmitted to the center device 101 is generated in the terminal device B 120, when the first code 302 of the downlink data 301 sent from the center device 1o1 is normally received in the terminal device B, the data is immediately transmitted from the terminal device B to the center device 101. It inserts its own address number as data 310 and transmits it.

In this case, the upper data 31 sent by terminal device B
If 0 is the interval, the lower side 301 from the center device 101 is currently being sent, so the upstream data 311 has not yet been sent from the terminal device A whose address matches the address code 303. Therefore, the uplink data 310 sent from the terminal device B1n0 is received within the center device 101 and demodulated as the address code 305 of the terminal device B. The demodulated address code 305 allows the center processing unit 102 to recognize that data to be urgently transmitted has occurred in the terminal device B120.

Therefore, after receiving the upstream data 311 from the terminal device A 114, the center processing unit 102 deviates from the normal polling sequence and uses the address number corresponding to the terminal device B in the next polling instead of the next address in the downstream data 317. It is inserted into the address code 319 and transmitted.

In the terminal device 8120, reverse demodulated data 321 is obtained as downlink data 317 sent from the center from the center device 101. Since the address number of the terminal device B 120 is inserted in the address code 323 of the lower data 321, the terminal device B knows that the upstream data 310 for emergency interrupt generated by itself has been correctly received at the center device. ○ If data to be urgently transmitted to the center equipment occurs in other terminal equipment at the same time as terminal equipment B, the center equipment will transmit the address code from each terminal equipment to the uplink. A collision of upstream data occurs. As a result, the center device cannot correctly receive the address code, so in the next polling sequence, address numbers corresponding to the two terminal devices are not inserted into the address code of the downlink data 317. Therefore, each of the two terminal devices that sent the address code as uplink data knows that the address code of the uplink data that it sent was not correctly received by the center device 101, and that a data collision has occurred.

When such a situation occurs, the terminal processing unit in each terminal device generates an arbitrary time function using random numbers, etc., and the upstream data is recovered by using the same method as above again. avoid collisions.

As described above, in the present invention, a type of contention method is mixed in the line control procedure using the normal polling method, and the normal polling sequence is interrupted for a terminal device that has generated data that needs to be transmitted urgently. It becomes possible.

Effects of the Invention According to the present invention, in a two-way GkTV system, data generated from any terminal device can be transmitted even on a low-speed line in a polling-based transmission control procedure without changing the conventional system configuration or data transmission speed. The data can be immediately transmitted to the center device without the waiting time required by the polling method, and the drawback of the polling method, which is the lack of immediate response to emergency data, can be greatly improved. is something that can be obtained.

Fig. 1 is a diagram showing the configuration of a bidirectional 0ATV system, Fig. 2 is a diagram showing a transmission control procedure using the conventional polling method, and Fig. 3 is a diagram showing the bidirectional 0ATV system configuration in an embodiment of the present invention.
It is a diagram showing a transmission control procedure of the ATV system.

101... Center device, 102... Center processing unit, 103... Head end, 106... Downlink data modulation unit, 10... Uplink data demodulation unit,
108...Brancher, 109...Mixer, 11
1...-WhtiJ-y"+V, 112, 11
3...-/;f switch, 114...terminal device A
, 116. Downlink data demodulation unit, 11. Uplink data modulation unit, 110... Falling floor processing unit, 120
−・−ShippingPsobuyb0 Agent’s name: Patent attorney Toshio Nakao and 1 other person No. 3
Figure J? δ

Claims (1)

[Claims] Data transmission between a center device and a terminal device is performed by line control called a link system, and data is transmitted between the center device and the terminal device. The terminal device has a function of transmitting its own address as an uplink data signal from the terminal device to the center device by detecting the leading code, and the terminal device detects the leading code and sends the self address as an uplink data signal from the terminal device to the center device. A two-way CATV system that allows for arbitrary interruptions to normal polling noises independent of sequential scanning of addresses.