JP2005094618A - Bidirectional catv amplifying unit and catv up line switching system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a CATV up line switching system which can inexpensively and easily improve the performance of a device as a communication capacity increases and can finish an operation in a short time. <P>SOLUTION: A bidirectional CATV amplifying unit 10 synthesizes up signals inputted to a TA1 port 19a, a BR1 port 27a, and a BR2 port 27b to be inputted to an input terminal 47a of a removable duplexed card 46. Also, up signals inputted to a TA2 port 19b, a BR3 port 27c, a BR4 port 27d are synthesized to be inputted to an input terminal 47b of a duplexed card 46. The duplexed card 46 mixes the up signal inputted to the input terminals 47a and 47b to be outputted to an up optical transmission unit 62a. When a communication capacity of the above-mentioned system is increased, a port dividing card is substituted for the duplexed card 46, and the up optical transmission unit is added. The port dividing card outputs two up signals separately to two up optical transmission units. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a bidirectional CATV amplification unit and a CATV uplink switching system capable of expanding the system in stages in a bidirectional CATV system.

  Conventionally, in a CATV system, a coaxial cable is generally used as a transmission line. However, in recent years, the number of channels has increased due to the increase in satellite broadcasting and digitalization of terrestrial television broadcasting. In order to increase the speed and capacity of transmission signals, coaxial cables have been changed to optical fiber cables. (For example, refer to Patent Document 1). In the process of shifting to this optical fiber cable, HFC (Hybrid Fiber Coaxial), that is, a system configuration in which a coaxial cable and an optical fiber cable are combined is also performed.

Recently, with the introduction of the cable Internet system, the uplink communication capacity has been gradually increased. For this reason, it is necessary to improve the performance of equipment such as an amplifying apparatus in the uplink as the communication capacity increases.
JP 2003-224835 A

As described above, when the function of the amplification unit is improved as the communication capacity increases, conventionally, the amplification unit or the optical transmitter is replaced.
However, if the function is improved by exchanging the amplification unit or the optical transmitter, the equipment is very expensive and the line must be cut off for a long time when the replacement is performed. There is a problem of not becoming.

  The present invention has been made in order to solve the above-described problems, and can improve the performance of a device inexpensively and easily as the communication capacity increases, and can finish the work in a short time. It is an object to provide a bidirectional CATV amplification unit and a CATV uplink switching system.

  The bidirectional CATV amplification unit according to the present invention is a bidirectional CATV amplification unit having a plurality of input / output ports for inputting / outputting a downstream signal and an upstream signal, and mixing upstream signals input to the plurality of input / output ports. A function card that divides and outputs to the upstream transmission unit is detachably provided, and the function card can be replaced to cope with the duplication of transmission lines or the increase in communication capacity.

  In addition, the CATV uplink switching system according to the present invention provides an upstream signal input to the plurality of input / output ports with respect to a bidirectional CATV amplification unit having a plurality of input / output ports for inputting / outputting downstream signals and upstream signals. A function card that mixes / divides the signal and sends it to the upstream transmission unit is detachable, and the function card mixes the upstream signals input to the plurality of input / output ports and sends them to the upstream optical transmission unit By replacing the card having the function to transmit and the card having the function to divide the upstream signals input to the plurality of input / output ports and send them to the plurality of upstream optical transmission units, It is characterized by being able to cope with an increase in communication capacity.

  According to the present invention, since the function card can be arbitrarily attached / detached by, for example, a plug-in method, the function card has a function of mixing uplink signals inputted to a plurality of input / output ports and sending them to the uplink optical transmission unit. System functions can be expanded in stages by replacing the card and a card having a function of dividing an upstream signal input to a plurality of input / output ports and sending it to a plurality of upstream optical transmission units. .

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a standard circuit configuration diagram of a bidirectional CATV amplifier according to an embodiment of the present invention.

  In FIG. 1, reference numeral 1a denotes a downstream optical receiving unit (main) which receives an optical downstream signal (70 to 770 MHz) transmitted from a head end device (not shown) through an optical fiber cable 2a and converts it into an electrical signal. After that, the signal is amplified and input to the downstream port (main) 11a of the bidirectional CATV amplification unit 10. The amplification unit 10 is provided with a downstream port (sub) 11b for connecting a downstream downstream optical receiving unit.

  Further, the amplification unit 10 is provided with a changeover switch 12 for selecting the downstream ports 11a and 11b. The changeover switch 12 is normally switched to the downstream port 11a side. The downstream signal input from the downstream optical receiving unit 1 a to the downstream port 11 a is selected by the changeover switch 12 and input to the distributor 17 via the branching device 13, the amplifier 14, the branching device 15, and the amplifier 16.

  The distributor 17 distributes the input downstream signal into two, outputs one distribution signal to the TA1 port 19a via the high-pass filter 18a, and outputs the other distribution signal to the TA2 port 19b via the high-pass filter 20a. . The TA1 port 19a and the TA2 port 19b are trunk input / output ports.

The downstream signal branched by the branching device 13 is sent to the status unit 3 via the output terminal 21a. The status unit 3 controls, for example, downlinks and uplinks and collects various data on the basis of instructions from the headend device, and inputs the collected data to the input terminal 21b of the amplification unit 10.
The downstream optical reception unit 1a, the upstream optical transmission unit 62a, the status unit 3 and the like are mounted on a node, for example.

  The downstream signal branched by the branching unit 15 is amplified by the amplifier 22 and then divided into two by the distributor 23, and one distribution signal is amplified by the amplifier 24 and input to the distributor 25. The distributor 25 distributes the input downstream signal into two, outputs one distribution signal to the BR1 port 27a via the high-pass filter 26a, and outputs the other distribution signal to the BR2 port 27b via the high-pass filter 28a. .

  The other distribution signal distributed by the distributor 23 is input to the distributor 30 via the amplifier 29. The distributor 30 divides the input downstream signal into two, outputs one distribution signal to the BR3 port 27c via the high-pass filter 31a, and outputs the other distribution signal to the BR4 port 27d via the high-pass filter 32a. To do. The high pass filters 18a, 20a, 26a, 28a, 31a, and 32a pass, for example, a downstream signal of 70 to 770 MHz. The BR1 to BR4 ports 27a to 27d are branch (or distribution) input / output ports.

  As described above, the downstream signal input from the downstream optical receiving unit 1a to the amplification unit 10 is output to the TA1 port 19a and the TA2 port 19b, and is also branched and output to the BR1 to BR4 ports 27a to 27d.

  The TA1 port 19a and the TA2 port 19b are connected to the trunk line of the CATV system, and the BR1 to BR4 ports 27a to 27d are connected to terminal devices of system subscribers via transmission lines.

  The upstream signal input to the TA1 port 19a is input to one input terminal of the synthesizer 41 via the low-pass filter 18b. The upstream signal input to the TA2 port 19b is input to one input terminal of the synthesizer 42 via the low-pass filter 20b.

  The upstream signals input to the BR1 and BR2 ports 27a and 27b are respectively extracted through the low-pass filters 26b and 28b, synthesized by the synthesizer 43, and further input to the synthesizer 41 and from the low-pass filter 18b. Is synthesized with the downstream signal. The signal synthesized by the synthesizer 41 is input to one input terminal 47 a of a functional card, for example, the duplex card 46 via the upstream band limiting filter 44 and the amplifier 45. The duplex card 46 uses a plug-in system, is detachably provided, and can be easily exchanged with a card having other functions.

  The upstream signals input to the BR3 and BR4 ports 27c and 27d are respectively extracted through the low-pass filters 31b and 32b, synthesized by the synthesizer 51, and further input to the synthesizer 42 to be output from the low-pass filter 20b. Is synthesized with the downstream signal. The low-pass filters 18b, 20b, 26b, 28b, 31b, and 32b pass, for example, an upstream signal of 10 to 55 MHz.

  The signal synthesized by the synthesizer 42 is input to the other input terminal 47 b of the duplex card 46 via the synthesizer 52, the upstream band limiting filter 53, and the amplifier 54. The synthesizer 52 synthesizes the data input from the status unit 3 to the input terminal 21 b with the upstream signal output from the synthesizer 42.

  The duplex card 46 comprises a synthesizer 48 and a distributor 49, synthesizes the upstream signals input to the input terminals 47a and 47b, divides the combined signal into two by the distributor 49, and distributes one of the distribution signals. The output signal is output to the output terminal 50a, and the other distribution signal is output to the output terminal 50b. The output terminal 50b is grounded via the pseudo load resistor 55.

  The upstream signal output from the output terminal 50a is sent to the upstream optical transmission unit 62a via the upstream port 61a. The upstream optical transmission unit 62a converts the upstream signal transmitted from the duplex card 46 into an optical signal, and transmits the optical signal to the head end device through the optical fiber cable 63a.

  The amplification unit 10 is provided with spare upstream ports 61b to 61d in addition to the upstream port 61a. An upstream optical transmission unit is additionally connected to the spare upstream ports 61b to 61d in response to an increase in communication capacity (communication traffic). In the amplification unit 10, a power supply unit that supplies operating power to each amplifier and the like is provided, although not shown.

  In the standard configuration shown in FIG. 1, one downstream optical receiving unit 1a and one upstream optical transmitting unit 62a are provided, and TA1 port 19a, TA2 port 19b, and BR1 to BR4 ports 27a to 27d. The upstream signal input to the upstream optical transmission unit 62a is mixed by the combiners 41 to 43 and 51 and the duplex card 46, and sent from the upstream optical transmission unit 62a to the optical fiber cable 63a. To the headend device.

[Redundant optical line]
When the optical line is duplexed in the standard configuration shown in FIG. 1, a sub downstream optical receiving unit 1b is additionally installed with respect to the main downstream optical receiving unit 1a as shown in FIG. At the same time, a sub upstream optical transmission unit 62b is additionally installed with respect to the main upstream optical transmission unit 62a. In this case, in the downstream signal system, when the sub downstream optical receiving unit 1b additionally installed is connected to the downstream port (sub) 11b, and an abnormality occurs in the main downstream optical receiving unit 1a, the changeover switch 12 is connected to the downstream port. The sub downstream optical receiving unit 1b is operated by switching to the 11b side. The downstream light receiving unit 1b receives an optical downstream signal transmitted from the head end device via the optical fiber cable 2b.

  In the upstream signal system, the additionally installed sub upstream optical transmission unit 62b is connected to the spare upstream port 61b and this upstream port 61b is connected to the output terminal 50b of the duplex card 46. At this time, the pseudo load resistor 55 is used by being disconnected from the output terminal 50 b of the duplex card 46.

As a result, the upstream signals input to the TA1 port 19a, the TA2 port 19b, and the BR1 to BR4 ports 27a to 27d are mixed by the combiners 41 to 43 and 51 and the duplex card 46, and two upstream light beams are mixed. The signals are sent to the transmission units 62a and 62b and sent to the head end device via the optical fiber cables 63a and 63b, respectively.
As described above, in the configuration shown in FIG. 2, the optical lines of the downstream signal system and the upstream signal system can be duplexed, and the reliability of the transmission path can be improved.

[Split port division]
Next, in the configuration shown in FIG. 2, if it is desired to further increase the communication capacity, a port division card 46A is used instead of the duplex card 46 as shown in FIG. The port division card 46A has an input terminal 47a and an output terminal 50a connected by a signal line 71a, and an input terminal 47b and an output terminal 50b connected by a signal line 71b. That is, the signal system of the input terminal 47a and the signal system of the input terminal 47b are divided.

  When the port division card 46A is used as described above, the upstream signals input to the TA1 port 19a and the BR1 and BR2 ports 27a and 27b are combined and then transmitted to the upstream optical transmission unit 62a via the port division card 46A. And transmitted from the upstream optical transmission unit 62a to the head end device via the optical fiber cable 63a.

  On the other hand, the upstream signals input to the TA2 port 19b and the BR3 and BR4 ports 27c and 27d are combined and then sent to the upstream optical transmission unit 62b via the port division card 46A. The upstream optical transmission unit 62b Is transmitted to the head end device via the optical fiber cable 63b. That is, for the upstream signal, the six ports of the amplification unit 10 are divided into two signal systems, and the upstream optical transmission units 62a and 62b use the optical fiber cables 63a and 63b, respectively, to the headend device. Since it is transmitted, it is possible to cope with an increase in communication capacity.

[Duplicating optical lines and dividing upstream ports]
Next, in the configuration shown in FIG. 3, when the optical line of the upstream signal system is duplexed, upstream optical transmission units 62c and 62d are additionally installed as shown in FIG. Instead of the card 46A, a port division / duplex card 46B is used. The additionally installed upstream optical transmission units 62c and 62d are connected to spare upstream ports 61c and 61d.

  The port division / duplex card 46B distributes the upstream signal input to the input terminals 47a and 47b into two by the distributors 72a and 72b, respectively, and outputs each distributed signal to the output terminals 50a to 50d. And the output signal of each output terminal 50a-50d is output to the upstream optical transmission units 62a-62d via the upstream ports 61a-61d.

  When configured as shown in FIG. 4, the upstream signals input to the TA1 port 19a and the BR1, BR2 ports 27a, 27b are combined and then input to the input terminal 47a of the port division / duplex card 46B. Divided into two by the distributor 72a and sent to the upstream optical transmission units 62a and 62b via the output terminals 50a and 50b and the upstream ports 61a and 61b. The upstream optical transmission units 62a and 62b transmit the upstream signals divided by the port division / duplex card 46B to the head end devices via the optical fiber cables 63a and 63b, respectively. In this case, for example, the upstream optical transmission unit 62a operates as a main transmitter, and the upstream optical transmission unit 62b operates as a sub transmitter.

  On the other hand, the upstream signals input to the TA2 port 19b and the BR3 and BR4 ports 27c and 27d are combined and then input to the input terminal 47b of the port division / duplication card 46B and divided into two by the distributor 72b. The signals are sent to the upstream optical transmission units 62a and 62b via the output terminals 50c and 50d and the upstream ports 61c and 61d. The upstream optical transmission units 62c and 62d transmit the upstream signals divided by the port division / duplex card 46B to the head end devices via the optical fiber cables 63c and 63d, respectively. In this case, for example, the upstream optical transmission unit 62c operates as a main transmitter, and the upstream optical transmission unit 62d operates as a sub transmitter.

As described above, the upstream signal input to the TA1 port 19a and the BR1 and BR2 ports 27a and 27b of the amplification unit 10 and the upstream signal input to the TA2 port 19b and the BR3 and BR4 ports 27c and 27d are divided into two. It is possible to cope with an increase in communication capacity by using an independent optical line as a system. In addition, for each of the two upstream signal systems, it is possible to improve the reliability of the transmission path by providing two upstream optical transmission units and duplexing the optical line.
All the upgrades from the standard state of FIG. 1 to FIGS. 2 to 4 can be performed without a down signal.

In the present invention, as shown in the above-described embodiment, the system can be upgraded in stages by using the unit structure of the optical transceiver. In addition, since the function card can be arbitrarily attached and removed by a plug-in method, the uplink can be divided into two systems simply by replacing the function card, and the communication capacity is increased while maintaining the communication quality, that is, the system is subscribed. It is possible to cope with an increase in the number of persons. In addition, for example, by mounting an upstream optical transmission unit with an expansion slot, it is possible to cope with duplexing of lines when upstream port division is performed.
In addition, by installing the status unit 3, it is possible to control downlinks and uplinks, collect various data, and the like, and to significantly improve maintenance efficiency.

  In the above embodiment, the case where an optical fiber cable is used as a transmission line has been described. However, the present invention can also be implemented in the same manner when a coaxial cable is used or when a coaxial cable is used.

  Further, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying constituent elements without departing from the scope of the invention in the implementation stage.

1 is a standard configuration diagram of an amplifying apparatus for a bidirectional CATV system according to an embodiment of the present invention. In the same embodiment, it is a block diagram which shows the structure at the time of duplexing an optical line. In the same embodiment, it is a block diagram which shows the structure at the time of dividing | segmenting an upstream port. FIG. 3 is a block diagram showing a configuration when the optical line is duplexed and the upstream port is divided in the embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1a, 1b ... Downstream optical receiving unit, 2a, 2b ... Optical fiber cable, 3 ... Status unit, 10 ... Amplification unit, 11a, 11b ... Downstream port, 12 ... Changeover switch, 13 ... Branching device, 14 ... Amplifier, 15 ... Branch, 16 ... Amplifier, 17 ... Distributor, 18a, 20a, 26a, 28a, 31a, 32a ... High-pass filter, 18b. 20b, 26b. 28b, 31b, 32b ... Low-pass filter, 19a ... TA1 port, 19b ... TA2 port, 21a ... Output terminal, 21b ... Input terminal, 22, 24, 29, 45, 54 ... Amplifier, 23, 25, 30, 49 ... Distributor, 27a ... BR1 port, 27b ... BR2 port, 27c ... BR3 port, 27d ... BR4 port, 41-43, 48, 51, 52 ... Synthesizer, 44 ... Up-band limiting filter, 46 ... Duplex card, 46A ... Port division card, 46B ... Port division / duplex card, 47a, 47b ... Input terminal, 50a-50d ... Output terminal, 53 ... Up band limiting filter, 55 ... Pseudo load resistor, 61a-61d ... Up port, 62a to 62d ... Uplink optical transmission unit, 63a to 63d ... Optical fiber cable, 71a, 71b ... Signal line, 72a, 7 b ... distributor.

Claims (2)

  In a bidirectional CATV amplifying unit having a plurality of input / output ports for inputting / outputting downstream signals and upstream signals, the upstream signals input to the plurality of input / output ports are mixed or divided and output to the upstream transmission unit. A bidirectional CATV amplification unit characterized in that a function card is detachably provided, and the function card is replaced to cope with a double transmission line or an increase in communication capacity. For a bidirectional CATV amplification unit having a plurality of input / output ports for inputting / outputting downstream signals and upstream signals, the upstream signals input to the plurality of input / output ports are mixed / divided and sent to the upstream transmission unit. Function card to be detachable,
The functional card divides an upstream signal input to the plurality of input / output ports and a card having a function of mixing upstream signals input to the plurality of input / output ports and sending the mixed signals to the upstream optical transmission unit. A CATV uplink switching system characterized by being able to cope with duplication of transmission lines or an increase in communication capacity by replacing a card having a function of transmitting to a plurality of uplink optical transmission units.

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