JPS62136945A - Information transmission system - Google Patents

Abstract

PURPOSE:To expand the quantity of information sent simultaneously by utilizing a frequency again so as to utilize a limited frequency band effectively. CONSTITUTION:A television retransmitter 11 and a translater group 12 are connected via a branch device 13 on an upperstream 2-way transmission line 14 and they are arranged at the uppermost point of the network as a head end 15. Plural downstream 2-way transmission lines 17 are connected to the line 14 via a distributer 16. A conversion processing unit 19 is connected to the uppermost stream of a downstream 2-way transmission line 17 via a branching filter 18. The conversion processing unit 19 processes and converts the signal of a specific frequency band sent from the downstream into the signal of a specific downstream frequency band.

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to an information transmission system that divides uplink information and downlink information by frequency multiplexing, and particularly relates to an information transmission system that can efficiently utilize frequency bands. .

[Technical background of the invention and its problems]

BACKGROUND OF THE INVENTION Against the backdrop of recent advances in microelectronics technology and network technology, research and development of local area networks (LANs) is active. As one type of LAN, a so-called broadband network is known in which audio, data, and video information are frequency-division multiplexed and transmitted over the same transmission path. Figure 4 shows an example of the configuration of a single-cable broadband network. In this network, a television retransmission device and a translator are installed as a head end 1 at the most upstream side of the network, and a plurality of downstream bidirectional transmissions are connected to the head end 1 via an upstream bidirectional transmission path 2 and a distributor 3. A plurality of terminals 5 such as workstations, telephones, and television receivers are connected to the channel 4 via taps (not shown). Each transmission line is composed of a single coaxial cable, and since downstream information is transmitted to all downstream bidirectional transmission lines 5, the frequency of the upstream signal is adjusted to avoid interference between upstream and downstream information. The frequency of the downlink signal is assigned to the low frequency side, and the frequency of the downlink signal is assigned to the high frequency side. In addition,
Based on the exact same principle as broadband networks using heavy cables, so-called two-way CATV
Both are treated as the same here.

In such broadband networks, by inserting main amplifiers at various points along the transmission path to compensate for attenuation on the transmission path, it is possible to build a network with tens of thousands of nodes and taps over a wide range of up to 10 to 30 nodes. can.

By the way, for something that is highly broadcastable like video information, it is necessary to set up a headend at the most upstream position and send out the same information to all nodes, but audio or data information is generally highly localized and all It is not necessarily necessary to send this information to all nodes. Moreover, since such information is usually sent as a digital signal, it requires a wide bandwidth, and it is difficult to say that the current bandwidth is sufficient to send a sufficient amount of information.For example, it is difficult to allocate upstream and downstream bandwidth separately. In the sub-split system of 5 to 50 MHz, 2170 to 400 MH2, the upstream frequency band is extremely narrow, and bidirectional transmission for several channels can be performed at most at 2 M bps.
Even with the mid-split method, which allocates upstream/downstream frequency bands to 400MHz, there is a limit to transmitting 10Mbps information for several channels.For example, 100MHz of audio
Line (100 times PiIX64 kbps -64Mbp
s) It was difficult to simultaneously transmit a larger number of lines and other data.

(Purpose of the Invention) The present invention was made based on the above circumstances, and its purpose is to effectively utilize the limited frequency band and enable simultaneous transmission by reusing frequencies. The goal is to expand information.

[Summary of the invention]

The present invention connects a plurality of downstream bidirectional transmission paths to a pair of upstream bidirectional transmission paths to which a head end is connected, and transmits upstream information and downstream information on these transmission paths at specific frequencies. In an information processing method in which information is transmitted by frequency multiplexing and assigned to a frequency band, a conversion processing device that processes and converts upstream information transmitted in a specific frequency band to a specific downstream frequency band is used as a downstream bidirectional It is characterized by being connected to the most upstream point of each transmission path. Here, the specific upstream/downstream frequency bands that are converted and processed by the conversion processing device are set to frequency bands that are attenuated at the head end.

〔Effect of the invention〕

According to the present invention, upstream information transmitted from any terminal on a downstream bidirectional transmission path is frequency-converted into a specific downstream frequency band by a conversion processing device connected to the most upstream side of the transmission path. , transmission on individual downstream bidirectional transmission paths or between different downstream bidirectional transmission paths is possible. At this time, these specific upstream/downstream information is also sent to the upstream bidirectional transmission path, but since this information is attenuated at the head end, it does not affect transmission on other downstream bidirectional transmission paths. It has no effect. That is, according to the present invention, upstream information from each downstream bidirectional transmission path is processed upstream of each downstream bidirectional transmission path, and does not affect other downstream bidirectional transmission paths. Bidirectional transmission paths can use uplink information in the same band. Therefore, in a network including M downstream bidirectional transmission paths, M times the amount of information can be simultaneously transmitted with substantially the same bandwidth.

[Embodiments of the invention]

Hereinafter, details of the present invention will be explained based on illustrated embodiments.

FIG. 1 is a diagram showing one embodiment. The television retransmission device 11 and the translator group 12 are connected on an upstream bidirectional transmission path 14 via a branching device 13, and are arranged as a head end LL at the most upstream point of the network. The upstream bidirectional transmission line 14 includes a distributor 16
A plurality of downstream bidirectional transmission lines 17 are connected via. A conversion processing device 19 is connected to the most upstream end of each of these downstream bidirectional transmission lines 17 via a branching device 18 .

This conversion processing device processes and converts a signal in a specific frequency band transmitted from the downstream side into a specific downstream frequency band. Further downstream of the downstream bidirectional transmission line 17, main amplifiers 20 are provided in multiple stages at appropriate intervals to compensate for signal attenuation on the transmission line. The transmission line branched from this main amplifier 20 is branched at a branch 21 having taps for, for example, 8 to 72 nodes, and a part of each branch line is connected to a plurality of telephones 2 via a line concentration distribution terminal 22.
3, a part is connected to the television receiver 1a24, and the other part is connected to the MAU (Medium Attachment).
It is connected to a terminal device 26 such as a workstation via a modulator/demodulator (modulator/demodulator) 25.

In a network system configured in this way,
For example, digital data from the terminal device 26 is sent to the MAU
For example, PSK modulation is performed at 25, but the frequency at this time is
As shown in FIG. 2, the frequency fr (for example, 30 MH2) on the lower side to which upstream information is assigned is set. The upstream signal with frequency 1 from M A Ll 25 is
After being amplified by the main amplifier 20 via a low-pass filter,
One side is inputted to the conversion processing device 19 via the splitter 18, and the other side is sent to the upstream bidirectional transmission line 14 side. The conversion processing device 119 converts the input signal into a frequency f2 (for example, 222.25 MHz), which is a high frequency to which the downstream information shown in FIG. 2 is allocated and excludes the TV band.
) and retransmitted to the downstream bidirectional transmission line 17. Therefore, the information on fl is sent via the MAU 25 to all terminal devices 26 including the transmitting terminal connected to the downstream bidirectional transmission path 17 to which the signal on fl was retransmitted. Similarly, on all downstream bidirectional transmission lines 17,
Necessary information is transmitted as appropriate.

By the way, the signal from the conversion processing device 19 retransmitted onto each downstream bidirectional transmission path 17 is also sent to the upstream bidirectional transmission path 14 via the distributor 16°, but the signal from the head end 1
The translator group 12 built into the transmitter 5 does not correspond to the same frequency (fl, fl).

Therefore, processing such as response frequency conversion is not performed on the upstream bidirectional transmission path 14 side, and fl on the upstream bidirectional transmission path.

The fl signal is applied to the load resistor and simply disappears. Therefore, the signals sent from each downstream bidirectional transmission path 17 to the upstream bidirectional transmission path 14 do not mix into the downstream bidirectional transmission path 17, and information transmission within each downstream bidirectional transmission path 17 is prevented. Independence is maintained. For local information transmission, this means that each downstream bidirectional transmission path 17 can use a signal of the same frequency, and the utilization rate of the transmission path can be substantially increased by the number of downstream bidirectional transmission paths compared to the past. This means that it can be doubled.

On the other hand, signals of frequencies other than fl and f2 in the above example are collected in the upstream bidirectional transmission line 14 by the distributor 16 as in the conventional example, and are input to the translator group 12 via the brancher 13, and are input to the translator group 12, respectively. Processed and converted into frequency bands.

In addition, video information is also transferred from the TV retransmission device 11 to the branching device 13,
It is the same as in the conventional example that the signal is sent to the TV device via the distributor 16, the downstream bidirectional transmission line 17, and the like.

FIG. 3 is a diagram showing another embodiment.

This embodiment differs from the previous embodiment in that a modem 31 is provided at the most upstream side of each downstream bidirectional transmission line 17 via a branch 18, and these modems 3f are connected by an exchanger 32. In this embodiment, the modem 31 and the exchange 32 function as a conversion processing device.

This example was developed by the inventors in Japanese Patent Application No. 59-268824.
This is an improved version of the PCM transmission method for audio information in broadband networks proposed in No.

That is, the voice signal sent from a specific telephone 23 is
After being aggregated and PCM-modulated at the II line distribution terminal 22, the signals are input to the modem 31 via the distributor 21, trunk amplifier 20, and branch 18 as a signal of a specific upstream frequency. After being demodulated into baseband data by the modem 31, it is input to the exchange 32 and exchanged, and then modulated again to the upstream frequency by the modem 31 and retransmitted to the downstream bidirectional transmission line 17 via the branching device 18. be done.

By the way, according to the previous proposal, the audio PCM signal (64k
bps), and when transmitting by time division multiplexing, 4 M when multi-level modulation is not performed in the band for one TV channel (6 MHz).
The limit was a transmission speed of about bps. Therefore, considering the multiplexing of signals other than the original PCM signal such as frame sync, the maximum number of lines that can be multiplexed is 32 to 48 lines for both upstream and downstream transmission lines, which is 500 lines or 1
It is impossible to accommodate more than 000 lines.

In contrast, in this embodiment, for example, if the number of downstream bidirectional transmission lines 17 is 8 or 16, the number of lines that can be multiplexed is 256 to 384 lines and 512 to 768 lines, respectively. If an ADPCM signal that can be transmitted at 32t<bps is used instead, the number of lines that can be accommodated can be doubled, and more than 1000 lines can be accommodated. In this embodiment, all signals on the downstream bidirectional transmission path 17 are sent and received via the exchange 32, so the telephone W123 connected to any point on the network can be connected to any other point on the network. It is possible to communicate with the telephone 23, and changes in the arrangement of the telephone 23 due to layout changes can be easily dealt with by changing the software inside the exchange, just like in conventional exchanges, which is practical. There is no problem at all.

In addition, the present invention provides L
C8MA/CD (Carr
ier 5ence Multiple Ac
cesswith Co11ision Dete
ction) or Token-3uss. Such C8MA/CD or T
An absolute requirement for a LAN, such as the OKEN-3USS, is to be able to communicate between arbitrary stations. Therefore, in the network shown in FIG. 3, instead of the exchange 32, a bridge that has the function of bridging necessary information to other LANs, or a bridge that extracts signals from other LANs and transmits necessary information to the other LAN. By providing a bridge that has the function of bridging only information, communication can be performed even between different downstream bidirectional transmission paths. In this case, each downstream bidirectional transmission path should be used by the same group or department, especially considering that the amount of communication between the same group or department is greater than that for other groups or departments. For example, traffic does not concentrate in one place or the whole area becomes crowded, and each transmission path can be used efficiently.

In the above explanation, the bidirectional transmission path is assumed to be a single cable consisting of one coaxial cable, but it is also possible to provide one coaxial cable for each upstream/downstream and use each coaxial cable as a unidirectional transmission path. The same applies to so-called double cables.

Further, the present invention can be applied in exactly the same manner to an optical transmission type LAN. That is, it is possible to include the concept of wavelength multiplexing in the concept of frequency multiplexing in the present invention.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the configuration of a network according to an embodiment of the present invention, FIG. 2 is a diagram illustrating the bandwidth allocation of upstream/downstream information used in the network, and FIG. FIG. 4 is a block diagram showing a network system according to an embodiment of the present invention, and FIG. 4 is a block diagram showing a conventional broadband network. 1.15...Head end, 2,14...Upstream bidirectional transmission line, 3.16.21...Distributor, 4.17...
・Downstream bidirectional transmission line, 5...terminal, 13.18...
Turnout, 19...Conversion processing device, 20...Main amplifier, 22...East line distributor, 23...Telephone, 24...
... Television reception source, 26 ... Terminal equipment, 31.
...modem, 32...exchange. Applicant's agent Patent attorney Takehiko Suzue; Figure 1 Figure 2 Figure 3

Claims (6)

[Claims] (1) A plurality of downstream bidirectional transmission lines are connected to a pair of upstream bidirectional transmission lines to which the head end is connected, and upstream information and downstream information are transmitted on these transmission lines using specific frequency bands. In an information processing method in which information is transmitted by frequency multiplexing, upstream information transmitted in a specific frequency band that is attenuated at the head end is transferred to a specific downstream frequency that is attenuated at the head end. An information transmission system characterized in that a conversion processing device for processing and converting into a band is connected to the most upstream point of each of the downstream bidirectional transmission paths. (2) The information transmission system according to claim 1, wherein different downstream bidirectional transmission paths are connected to each other via a conversion processing device. (3) The conversion processing device demodulates upstream information to reproduce baseband data, and then re-modulates the reproduced baseband data in a specific downstream frequency band. An information transmission system according to claim 1 or 2. (4) After reproducing the baseband data, the conversion processing device
The information transmission system according to claim 3, characterized in that the information transmission system has a function as an exchange for exchanging information. (5) After reproducing the baseband data, the conversion processing device
4. The information transmission method according to claim 3, wherein the information transmission method has a function as a bridge for selecting a destination route. (6) The pair of upstream bidirectional transmission paths is characterized by consisting of a single bidirectional transmission path, in which upstream and downstream information is assigned to different frequency bands, and information is transmitted by frequency multiplexing. An information transmission system according to claim 1.