JP2013223113A - Node device, signal transmission system, and signal transmission system changing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a node device that is able to change from an HFC system to an FTTH system depending on a subscriber request.SOLUTION: A node device 300 comprises: an input coaxial cable connection part 301 connected with a transmission line network at a communication station building side; and output coaxial cable connection parts 302, 303 for outputting downlink electric signals transmitted from the transmission line network at the communication station building side to a transmission line network at a subscriber house side. A multiplexer/de-multiplexer 312 de-multiplexes the downlink electric signals input to the input coaxial cable connection part 301, and multiplexes uplink electric signals input to the output coaxial cable connection parts 302, 303 and outputs the multiplexed signals to the transmission line network at the communication station building side via the input coaxial cable connection part 301. A downlink signal amplifier 331 amplifies and outputs the downlink electric signals de-multiplexed by the multiplexer/de-multiplexer 312 to the output coaxial cable connection parts 302, 303. A selection unit 350 selects the downlink signal amplifier 331 or a termination resistor as a connection destination of the multiplexer/de-multiplexer 312.

Description

  The present invention relates to a node device incorporated in a transmission line network of a signal transmission system such as a cable television, a signal transmission system incorporating the node device, and a method for changing the signal transmission system.

  Conventionally, as a CATV (cable television) signal transmission system, an HFC (Hybrid Fiber Coaxial) transmission system using both an optical transmission line network and a coaxial transmission line network has been widely used. Each CATV service area is provided with an optical node device, and upstream / downward bidirectional optical transmission by optical fiber is performed from the head end on the communication station side to the optical node device. In each service area, a signal is transmitted by a coaxial cable from the optical node device to the subscriber terminal.

  For example, Patent Document 1 describes an invention of an optical transmission system in which an FTTH (Fiber To The Home) system is added to such a conventional HFC system. Specifically, Patent Document 1 describes an invention in which a WDM filter is provided in the optical node device of the HFC transmission system described above, and an FTTH system is constructed via the WDM filter.

JP 2006-5595 A

  In the transmission system described in Patent Document 1 described above, it is possible to add an FTTH system to a conventional HFC system. However, in such a transmission system, since the FTTH system is added in the service area, the FTTH system is flexibly constructed according to the request of the subscriber while effectively utilizing the HFC system equipment in the service area. I couldn't.

  Specifically, subscribers who only receive retransmissions of terrestrial broadcast waves due to radio interference, and subscribers who view multiple channels up to the 770 MHz band that can be transmitted through coaxial cables can be accommodated with existing HFC system equipment. is there. On the other hand, for a subscriber who desires high-speed Internet communication and a subscriber who desires reception of a BS-IF signal of a band of 770 MHz or more, it is necessary to provide a service using an FTTH system using an optical fiber.

  The present invention has been proposed in view of such circumstances, and is constructed in an FTTH system flexibly according to the service requested by the subscriber while utilizing the equipment of the HFC system that has been operated in advance in the service area. An object of the present invention is to provide a node device that can be incorporated into a signal transmission path network of a signal transmission system. Another object of the present invention is to provide a signal transmission system in which the node device is incorporated, and a method for changing the signal transmission system.

  The node device according to the present invention is connected to a transmission path network on the communication station side, a first coaxial cable connection section connected via a coaxial cable, and a transmission path network on the subscriber premises side via the coaxial cable. One or more second coaxial cable connection portions for outputting a downstream electrical signal transmitted from the transmission line network on the communication station building side to the transmission line network on the subscriber premises side, and a transmission line on the communication station side The downstream electrical signal input to the first coaxial cable connection from the network is demultiplexed, and the upstream electrical signal input to the second coaxial cable connection from the subscriber premises transmission line network is multiplexed. A multiplexing / demultiplexing unit that outputs to the transmission line network on the communication station side via the first coaxial cable connecting unit, and a second coaxial cable connection by amplifying the downstream electrical signal demultiplexed by the multiplexing / demultiplexing unit The first amplifier that outputs to the unit and the connection destination of the multiplexing / demultiplexing unit from the first amplifier, Route and a first switching unit for switching the terminal resistor.

  The signal transmission system according to the present invention is a signal transmission system including a transmission system having a coaxial transmission line and an FTTH system, and a communication station connected to the optical transmission line of the FTTH system and the coaxial transmission line. A node station connected through a coaxial cable of a coaxial transmission line, and one or more subscriber terminals connected to the optical transmission line or coaxial transmission line of the FTTH system, The node device demultiplexes the downstream electrical signal input from the transmission path network on the communication station side, and combines the upstream electrical signal input from the transmission path network on the subscriber premises side to A multiplexing / demultiplexing unit that outputs to the transmission line network, a first amplifier that amplifies the downlink electrical signal demultiplexed by the multiplexing / demultiplexing unit and outputs the amplified signal to the transmission line network on the subscriber's home side, Connect the connection destination from the first amplifier to the terminal resistance of the signal line. And having a first switching unit for switching the vessel.

  The signal transmission system changing method according to the present invention is a signal transmission system changing method for changing from a transmission system having a coaxial transmission line to an FTTH system, and in a service area where the coaxial transmission line is constructed. The first step of constructing the optical transmission line of the FTTH system, and one or more subscriber houses among the first subscriber houses connected to the communication station building via the coaxial transmission line are connected to the communication station building. And a second step of changing to a subscriber's house connected via the optical transmission line of the FTTH system, and one or more coaxial amplifiers among the coaxial amplifiers for amplifying signals transmitted through the coaxial transmission line, The upstream electrical signal input from the transmission line network on the side is demultiplexed, and the upstream electrical signal input from the transmission line network on the subscriber premises side is multiplexed and output to the transmission line network on the communication station side Demultiplexing part and multiplexing / demultiplexing part A first amplifier that amplifies the downlink electric signal further demultiplexed and outputs the amplified signal to the transmission line network on the subscriber's home side, and a connection destination of the multiplexing / demultiplexing unit from the first amplifier to the terminating resistor of the signal line A third step of changing to one or more second node devices having a first switching unit to switch to the optical receiving unit of each second node device via an optical fiber A fourth step of connecting the transmission path network or the closure to the optical signal so that the optical signal can be transmitted, and switching the connection destination of the multiplexing / demultiplexing unit to a termination resistor by the first switching unit.

  In the present invention, an electrical signal is transmitted to a subscriber's home via an existing coaxial cable using a node device connected via an optical fiber to a closure provided in the optical transmission line network on the communication station building side. Partial transmission system. In this way, the present invention is capable of flexibly constructing an FTTH system according to the request of the subscriber while effectively utilizing the coaxial transmission equipment and HFC system equipment that are operated in advance in the area service. it can.

It is a figure for demonstrating the structure of the HFC transmission system constructed | assembled beforehand by the service area. It is a figure for demonstrating the step which builds the trunk line network of an FTTH system in a service area. It is a figure for demonstrating the step which reduces the existing HFC system area and builds an FTTH system area in the remaining area. It is a figure for demonstrating the step which converts the coaxial amplifier arrange | positioned in the HFC system area into the node apparatus to which this invention was applied. It is a figure for demonstrating the structure of the node apparatus which concerns on 1st Example with which this invention was applied. It is a figure for demonstrating the structure of the node apparatus which concerns on the 2nd Example to which this invention was applied. It is a figure for demonstrating the structure of the node apparatus which concerns on the 3rd Example to which this invention was applied. It is a figure for demonstrating the structure of the node apparatus which concerns on the 4th Example to which this invention was applied. It is a figure for demonstrating the step which constructs | assembles a transmission-line network using the node apparatus with which this invention was applied. It is a figure for demonstrating the other example of the step which constructs | assembles a transmission-line network using the node apparatus with which this invention was applied. It is a figure for demonstrating the step which builds a new FTTH system in the area where the FTTH system is not built.

  The present invention relates to a node device incorporated in a transmission line network of a signal transmission system, a signal transmission system in which the node device is incorporated, and a method for changing the signal transmission system.

  Specifically, the present invention provides a service that a subscriber requests a service area 1 in which an existing HFC transmission system using both an optical transmission line network and a coaxial transmission line network as shown in FIG. 1 is constructed. Depending on the situation, it is partially changed to the FTTH system. Here, there are two types of services required by subscribers: services that can be provided by existing HFC systems and services that require the construction of FTTH systems. Services that can be provided by the existing HFC system are services for retransmitting terrestrial broadcast waves and transmitting multiple channels up to the 770 MHz band. Services that require a change in the FTTH system are high-speed Internet communications and services that transmit BS-IF signals in a band of 770 MHz or higher. This is because the coaxial cable of the HFC system has a transmission band from 70 MHz to 770 MHz, and an optical fiber is required for wider band signal transmission.

  First, an existing HFC transmission system 100 constructed in the service area 1 will be described with reference to FIG. For example, the HFC transmission system 100 includes an optical node 110 connected to the communication station 2 via the optical fiber 3, one or more coaxial amplifiers 130 connected to the optical node 110 via the coaxial cable 120, It is composed of one or more paying subscriber homes 150 and one or more telephone subscriber homes 160 connected via a tap 140 provided on the cable 120.

  The communication station 2 is connected to the optical node 110 in the service area 1 through the optical fiber 3 so as to be able to transmit optical signals. Specifically, the communication station 2 is provided with a head end device 21 for digital broadcasting, a cable modem termination device 22, a plurality of optical transmitters 24, and a plurality of optical receivers 25.

  The optical transmitter 24 multiplexes the downstream electrical signal supplied from the head end device 21 for digital broadcasting and the downstream electrical signal supplied from the cable modem termination device 22 via the distributor 22a and converts it into an optical signal. The downstream optical signal is output to the optical node 110 in the service area 1 through the optical fiber 3.

  The optical receiver 25 converts an upstream optical signal transmitted from the optical node 110 in the service area 1 through the optical fiber 3 into an upstream electrical signal and supplies the upstream electrical signal to the cable modem termination device 22.

  An optical node 110 connected to be able to transmit an optical signal via the communication station 2 and the optical fiber 3 having such a configuration, for example, has two coaxial amplifiers 130 via a coaxial cable 120 as shown in FIG. Connected with. The optical node 110 includes, for example, a 60 V AC power supply apparatus 111, and performs the following operation by supplying power from the power supply apparatus 111. That is, the optical node 110 converts the downstream optical signal from the communication station 2 into a downstream electrical signal. The optical node 110 converts the upstream electrical signal transmitted from the coaxial amplifier 130 via the coaxial cable 120 into an upstream optical signal and outputs the upstream optical signal to the communication station 2. Note that the power supply device 111 is not limited to AC 60 V, and may be any device that can supply an AC power supply voltage such as AC 30 V or 90 V.

  The downstream electrical signal converted from the downstream optical signal by the optical node 110 is amplified by one or more coaxial amplifiers 130 and distributed by a tap 140 provided in the coaxial cable 120 to be charged to the paying subscriber's home 150 and the electric power subscriber. It is supplied to the person's house 160. Further, the upstream electrical signal output from the paying subscriber's home 150 is mixed with the coaxial cable 120 via the tap 140, converted into an upstream optical signal by the optical node 110, and transmitted to the communication station 2.

  The pay subscriber home 150 includes a set top box 151, a cable modem 152, and an embedded multimedia terminal adapter 153 as pay subscriber terminals, and transmits and receives electrical signals via the tap 140.

  Further, the telephone subscriber home 160 is a subscriber home that receives only a simulcast of a terrestrial digital broadcast wave due to radio wave interference, for example. This faulty subscriber home 160 has a faulty subscriber terminal 161 that only receives a downlink electrical signal via the tap 140.

  In the HFC transmission system 100 having such a configuration, it is desired to construct the FTTH system from the HFC system flexibly according to the request of the subscriber while effectively utilizing the HFC system equipment in the service area 1. . More specifically, since the subscriber home 160 is a reception-only service, the priority of building the FTTH system from the HFC system is lower than that of the pay subscriber home 150. In addition, there are cases where the cost of the service of the telephone subscriber house 160 is free or low compared with the paid subscriber house 150. In such a case, the cost recovery related to the FTTH system can be expected. Absent.

  Furthermore, an electric subscriber and a subscriber who views a multi-channel up to a 770 MHz band that can be transmitted by a coaxial cable can cope with existing HFC system equipment. On the other hand, it is necessary to provide a service using an FTTH system using an optical fiber to a subscriber who requests high-speed Internet communication or a subscriber who desires reception of a BS-IF or the like in a band of 770 MHz or higher.

  Therefore, in the signal transmission system changing method to which the present invention is applied, the FTTH system is partially constructed according to the following steps 1 to 5.

  In step 1, as shown in FIG. 2, a trunk network of the FTTH system is constructed in the service area 1. For example, the optical fiber 4 is laid from the communication station 2 in some areas in the service area 1 through a plurality of closures 210. In addition, the external modulation type optical transmitter 26, the EDFA 27, and a plurality of OLTs 281, 282, 283, and 284 are installed in the communication station 2. Further, the EDFA 27 and a plurality of OLTs 281 and 282 are connected to the optical fiber 4, respectively.

  In step 2, as shown in FIG. 3, the subscriber terminal of the paying subscriber's home 150 close to the closure 210 provided in step 1 is changed to a broadcasting optical terminal device 154 and a data communication optical terminal device 155. . Then, the optical terminal device for broadcasting 154 and the optical terminal device for data communication 155 are connected to the closure 210 via the optical fiber 4. In this manner, the FTTH system area is constructed in the remaining area while reducing the existing HFC system area in the service area 1.

  In Step 3, to improve the existing HFC system that has become old and needs to be replaced, a simultaneous operation in which the service area 1 is partially switched to the FTTH system sequentially is performed. Among the amplifiers 130, some of the coaxial amplifiers 130 are replaced with the node device 300 according to the first embodiment to which the present invention is applied. That is, in the system configuration shown in FIG. 4, the coaxial transmission line and the FTTH are shared by simultaneous operation.

  The node device 300 of the first embodiment has a configuration as shown in FIG. That is, the node device 300 includes an input coaxial cable connection unit 301, output coaxial cable connection units 302 and 303, an optical fiber connection unit 304, and an AC power supply line connection unit 305. The input coaxial cable connection unit 301 is a connection unit to which a downstream signal is input, and is connected to the transmission path network on the communication station 2 side via the coaxial cable 120. The output coaxial cable connection units 302 and 303 are connection units for outputting a downlink signal, and are connected to the transmission line network on the pay subscriber home 150 or the telephone subscriber home 160 side via the coaxial cable 120. . The optical fiber connection unit 304 is connected to the transmission path network on the communication station 2 side via the optical fiber 4 or an optical fiber 5 described later.

  In the node device to which the present invention is applied, the number of output coaxial cable connection portions is not limited to the two described above, and may be a number according to the usage form in which the node device 300 is incorporated.

  Further, the node device 300 includes a power supply separation filter 311 connected to the input coaxial cable connection unit 301, a multiplexer / demultiplexer 312 connected to the power supply separation filter 311, a downstream signal amplifier 331, and a multiplexer / demultiplexer 332. , A splitter 333, two power source separation filters 334 and 335, an upstream signal amplifier 337, and two selectors 350 and 360 connected to the multiplexer / demultiplexer 312.

  The downlink signal amplifier 331 amplifies the downlink electrical signal from the selection unit 350 or an optical reception unit described later, and outputs the amplified signal to the multiplexer / demultiplexer 332. The multiplexer / demultiplexer 332 outputs the downstream electrical signal input from the downstream signal amplifier 331 to the splitter 333 and outputs the upstream electrical signal input from the splitter 333 to the upstream signal amplifier 337. The splitter 333 demultiplexes the downstream electric signal input from the multiplexer / demultiplexer 332 and outputs the demultiplexed electric signal to the power supply separation filters 334 and 335, and combines the upstream electric signal input from the power supply separation filters 334 and 335 to combine the signals. Output to the correlator 332. The power supply separation filters 334 and 335 are band limiting filters for the purpose of transmitting and receiving AC power, and are connected to the output coaxial cable connection portions 302 and 303, respectively. The upstream signal amplifier 337 amplifies the upstream electrical signal from the splitter 333 and outputs the amplified electrical signal to the selection unit 360 or an optical transmission unit described later.

  The selection unit 350 selects, as a connection destination of the multiplexing / demultiplexing unit 312, a downstream signal amplifier 331 or a termination resistor that functions as a termination resistor of the signal path of the input coaxial cable connection unit 301. Further, the selection unit 360 selects, as the connection destination of the multiplexing / demultiplexing unit 312, an upstream signal amplifier 337 or a termination resistor that functions as a termination resistor of the signal path of the input coaxial cable connection unit 301.

  When the downstream signal amplifier 331 and the upstream signal amplifier 337 are selected as connection destinations of the multiplexing / demultiplexing unit 312, an attenuator and an equalizer / pseudo transmission network are provided inside the selection units 350 and 360. In the selection unit 350, the attenuator and the equalizer / pseudo transmission network are connected to the multiplexing / demultiplexing unit 312, the downstream signal amplifier 331, and the signal path. Similarly, in the selection unit 360, the attenuator and the equalizer / pseudo transmission network are connected to the multiplexing / demultiplexing unit 312, the upstream signal amplifier 337, and the signal path.

  When a termination resistor is selected as the connection destination of the multiplexing / demultiplexing unit 312, the termination resistor is provided inside the selection units 350 and 360. With this terminating resistor, it is possible to prevent signal reflection and signal disturbance on the coaxial cable side connected to the input coaxial cable connection portion 301.

  Furthermore, when a termination resistor is selected as a connection destination of the multiplexing / demultiplexing unit 312, a WDM filter, an optical reception unit, and an optical transmission unit are incorporated in the node device 300. Specifically, in the node device 300, a WDM filter is connected to the optical fiber connection unit 304, and an optical reception unit and an optical transmission unit are connected to the WDM filter. The WDM filter outputs a downstream optical signal input to the optical fiber connection unit 304 to the optical reception unit and outputs an upstream optical signal input from the optical transmission unit to the outside from the optical fiber connection unit 304. The optical receiving unit converts the downstream optical signal output from the WDM filter into a downstream electrical signal. The optical transmission unit outputs an upstream optical signal corresponding to the upstream electrical signal transmitted from the output coaxial cable connection units 302 and 303 to the WDM filter.

  In the optical fibers 4 and 5, unlike the coaxial cable 120, a signal having a frequency band of 770 MHz or higher, for example, a BS-IF signal having a frequency band of 1 GHz or higher is transmitted, and a CS signal having a frequency band of 2 GHz or higher is transmitted. Is done. Therefore, the downstream signal amplifier 331 connected to the optical reception unit and the upstream signal amplifier 337 connected to the optical transmission unit can perform desired amplification processing even in the frequency band of the signal transmitted to the optical fibers 4 and 5. It is particularly preferred to have properties. Further, the node device 300 may be configured such that the downstream signal amplifier 331 and the upstream signal amplifier 337 are replaced with amplifiers corresponding to the frequency band of the signal to be amplified.

  Further, the node device 300 includes an AC / DC converter 340 connected to the AC power supply line connection unit 305. The AC / DC converter 340 receives an AC voltage supplied from the outside through the AC power supply line connection unit 305 via the AC power supply wiring 341, converts it to a DC voltage, and converts the DC voltage into the node device 300 via the DC power supply wiring 342. Power is supplied to each part. The AC power supply wiring 341 is connected to the power supply separation filters 311, 334, and 335.

  The node device 300 having such a configuration can prevent signal reflection and signal disturbance on the coaxial cable 120 side connected to the input coaxial cable connection unit 301. Further, the node device 300 converts the downstream optical signal input from the optical fiber connection unit 304 into a downstream electrical signal, outputs the signal to the outside from the output coaxial cable connection units 302 and 303, and outputs to the output coaxial cable connection units 302 and 303. The input upstream electrical signal can be converted into an upstream optical signal and output from the optical fiber connection unit 304 to the outside.

  Thus, the node device 300 selects the downlink signal amplifier 331 and the uplink signal amplifier 337 as connection destinations of the multiplexer / demultiplexer 312 by the selection units 350 and 360 when there are many trouble subscribers, for example. Thus, the same function as the coaxial amplifier 130 can be realized. In addition, when the number of paying subscriber homes 150 increases and the switching to the FTTH system becomes necessary, the node device 300 uses the selection units 350 and 360 as termination resistors as connection destinations of the multiplexer / demultiplexer 312. By selecting, the HFC system can be easily changed to the FTTH system.

  A node device to which the present invention is applied can use, for example, a node device 300a according to the second embodiment as shown in FIG. The node device 300a of the second embodiment has a configuration as shown in FIG. That is, the node device 300a includes an input coaxial cable connection unit 301, output coaxial cable connection units 302 and 303, an optical fiber connection unit 304, and an AC power supply line connection unit 305. The input coaxial cable connection unit 301 is a connection unit to which a downstream signal is input, and is connected to the transmission path network on the communication station 2 side via the coaxial cable 120. The output coaxial cable connection units 302 and 303 are connection units for outputting a downlink signal, and are connected to the transmission line network on the pay subscriber home 150 or the telephone subscriber home 160 side via the coaxial cable 120. . The optical fiber connection unit 304 is connected to the transmission path network on the communication station 2 side via the optical fiber 4 or an optical fiber 5 described later.

  The node device 300 a includes a power supply separation filter 311 connected to the input coaxial cable connection unit 301, a multiplexer / demultiplexer 312 connected to the power supply separation filter 311, and two terminations connected to the multiplexer / demultiplexer 312. And resistors 313 and 314. The termination resistors 313 and 314 function as termination resistors for the signal path of the input coaxial cable connection unit 301. In this way, the node device 300a can prevent signal reflection and signal disturbance from occurring on the coaxial cable side connected to the input coaxial cable connection portion 301 by the two termination resistors 313 and 314. .

  The node device 300 a includes a WDM filter 321 connected to the optical fiber connection unit 304, an optical reception unit 322 connected to the WDM filter 321, and an optical transmission unit 323 connected to the WDM filter 321. The WDM filter 321 outputs a downstream optical signal input to the optical fiber connection unit 304 to the optical reception unit 322 and outputs an upstream optical signal input from the optical transmission unit 323 to the outside from the optical fiber connection unit 304. The optical receiving unit 322 converts the downstream optical signal output from the WDM filter 321 into a downstream electrical signal. The optical transmission unit 323 outputs an upstream optical signal that always emits light corresponding to the upstream electrical signal transmitted from the output coaxial cable connection units 302 and 303 to the WDM filter 321. Such constant light emission is possible when there is a one-to-one connection with the upstream optical signal transmission destination. Therefore, when the transmission destination of the upstream optical signal is connected to a plurality of node devices, the upstream optical signal has a different wavelength or functions as an ONU (Optical Network Unit) of an RFoG (RF over Glass) system, which will be described later. The node device 300b of the third embodiment is used.

  The node device 300a may demultiplex the upstream optical signal and the downstream optical signal using an optical coupler instead of the WDM filter 321. Further, when the upstream optical signal and the downstream optical signal are transmitted through different optical fibers, the WDM filter 321 may not be provided.

  The node device 300 a includes a downstream signal amplifier 331, a multiplexer / demultiplexer 332, a splitter 333, two power source separation filters 334 and 335, and an upstream signal amplifier 337. The downlink signal amplifier 331 amplifies the downlink electrical signal converted by the optical reception unit 322 and outputs the amplified signal to the multiplexer / demultiplexer 332. The multiplexer / demultiplexer 332 outputs the downstream electrical signal input from the downstream signal amplifier 331 to the splitter 333 and outputs the upstream electrical signal input from the splitter 333 to the upstream signal amplifier. The splitter 333 demultiplexes the downstream electric signal input from the multiplexer / demultiplexer 332 and outputs the demultiplexed electric signal to the power supply separation filters 334 and 335, and combines the upstream electric signal input from the power supply separation filters 334 and 335 to combine the signals. Output to the correlator 332. The power supply separation filters 334 and 335 are band limiting filters for the purpose of transmitting and receiving AC power, and are connected to the output coaxial cable connection portions 302 and 303, respectively. The upstream signal amplifier 337 amplifies the upstream electrical signal from the splitter 333 and outputs the amplified electrical signal to the optical transmission unit 323.

  Further, the node device 300a includes an AC / DC converter 340 connected to the AC power supply line connection unit 305. The AC / DC converter 340 inputs an AC voltage supplied from the outside through the AC power supply line connection unit 305 through the AC power supply wiring 341, converts it into a DC voltage, and converts the DC voltage into the node device 300a through the DC power supply wiring 342. Power is supplied to each part. The AC power supply wiring 341 is connected to the power supply separation filters 311, 334, and 335.

  The node device 300 a having such a configuration can prevent signal reflection and signal disturbance on the coaxial cable 120 side connected to the input coaxial cable connection unit 301. Further, the node device 300a converts the downstream optical signal input from the optical fiber connection unit 304 into a downstream electrical signal, outputs the signal to the outside from the output coaxial cable connection units 302 and 303, and outputs to the output coaxial cable connection units 302 and 303. The input upstream electrical signal can be converted into an upstream optical signal and output from the optical fiber connection unit 304 to the outside.

  In the node device 300a, the multiplexer / demultiplexer 312 is connected to the attenuator 352 and the termination resistor 313 via the changeover switch 351a. In the node device 300a, the attenuator 352 is connected to the equalizer / pseudo transmission network 353, and the equalizer / pseudo transmission network 353 is connected to the downlink signal amplifier 331 via the changeover switch 351b. In the node device 300a, the multiplexer / demultiplexer 312 is connected to the attenuator 362 and the termination resistor 314 via the changeover switch 361a. In the node device 300a, the attenuator 362 is connected to the equalizer / pseudo transmission network 363, and the equalizer / pseudo transmission network 363 is connected to the upstream signal amplifier 337 via the changeover switch 361b. With such a configuration, the node device 300a is configured so that the downlink signal amplifier 331 and the uplink signal amplifier 337 are connected to the multiplexer / demultiplexer 312 by the changeover switches 351a, 351b, 361a, and 361b when the optical fiber is not connected. By switching so as to select, the same function as the coaxial amplifier 130 of the existing HFC system described above can be realized.

  In this way, for example, when there are a large number of trouble subscribers, the node device 300a uses the changeover switches 351a, 351b, 361a, and 361b as the connection destination of the multiplexer / demultiplexer 312 and the downstream signal amplifier 331 and the upstream signal amplifier. By selecting 337, a function similar to that of the coaxial amplifier 130 is realized, and when the number of pay subscriber homes 150 increases and it is necessary to switch to the FTTH system, the changeover switches 351a, 351b, 361a, By selecting the terminating resistors 313 and 314 as the connection destination of the multiplexer / demultiplexer 312 by 361b, the HFC system can be easily changed to the FTTH system.

  The termination resistors 313 and 314 are not necessarily provided in advance, and may be connected to the connection port of the changeover switch when changing to the FTTH system. In addition, as a selection unit that selects a connection destination of the multiplexer / demultiplexer, a switching port that removes the attenuator and the equalizer / pseudo transmission network and switches the connection destination to the termination resistor may be used.

  Further, as the node device to which the present invention is applied, for example, a node device 300b according to the third embodiment as shown in FIG. 7 can be used. The node device 300b according to the third embodiment includes the following RFoG optical transmission unit 401 instead of the optical transmission unit 323, in addition to the above-described node device 300a according to the second embodiment. These parts are the same as those of the node device 300a according to the second embodiment. The node device 300b according to the second embodiment having such a configuration can function as an ONU of the RFoG system.

  Further, as the node device to which the present invention is applied, for example, a node device 300c according to the fourth embodiment as shown in FIG. 8 can be used. This node device 300c is a node device corresponding to a one-way optical transmission line in which an optical fiber connected to the optical fiber connection unit 304 transmits only a downlink signal. The node device 300c according to the second embodiment described above is included in the node device 300c. On the other hand, the configuration differs in that the termination resistor 314, the WDM filter 321, the optical transmission unit 323, and the changeover switches 361a and 361b are not provided. In this node device 300 c, the waveform of the upstream electrical signal amplified by the upstream signal amplifier 337 is adjusted by the equalizer / pseudo transmission network 353 and the attenuator 352, and passes through the multiplexer / demultiplexer 312 and the power supply separation filter 311. , Output from the input coaxial cable connection 301 to the outside.

  In this way, the node device 300c prevents the signal from being reflected or disturbed on the side of the coaxial cable connected to the input coaxial cable connection unit 301, and the upstream electrical signal from the input coaxial cable connection unit 301 to the outside. Can be output. Also, the node device 300c can convert the downstream optical signal input from the optical fiber connection unit 304 into a downstream electrical signal and output the signal to the outside from the output coaxial cable connection units 302 and 303.

  For example, for a subscriber who does not require a high-speed Internet communication and desires to receive a BS-IF downlink electrical signal, only the downlink signal can be transmitted to the subscriber's home by an optical signal. When satisfying such a requirement, the node device 300c can be used. On the other hand, the node devices 300, 300a, and 300b may be used when optical signals are used bidirectionally in the transmission line network, such as high-speed Internet communication and BS-IF downlink electrical signal distribution.

  The node devices 300, 300a, 300b, and 300c according to the first to fourth embodiments configured as described above are replaced in the above-described step 3. Hereinafter, for the sake of convenience, description will be made mainly using the node device 300.

  In step 4, as shown in FIG. 9, the node apparatus 300 is used to change the transmission path network of the HFC system. First, a new cable modem termination device 29, an optical transmitter 33 and optical receivers 34 and 35 connected to the cable modem termination device 29, and a WDM connected to the optical receivers 34 and 35 are connected to the communication station 2. A filter 36 and a WDM filter 37 are provided. Here, the WDM filter 37 is connected to the EDFA 27, the optical transmitter 33, and the WDM filter 36. In addition, the optical fiber 5 is laid from the output end of the WDM filter 37 of the communication station 2 to the service area 1 through an optical wavelength multiplexing device 38 that aggregates optical passive components such as WDM filters and couplers.

  Among the plurality of node devices 300 in which the coaxial amplifier 130 is replaced, in some node devices 300, the optical fiber connection unit 304 is connected to the optical wavelength multiplexing device 38 via the optical fiber 5, or It is connected to the closure 210 via the optical fiber 4. Further, in the node device 300 connected to these optical fibers 4 and 5, the input coaxial cable connection portion 301 is connected to the coaxial cable 120 of the transmission path on the communication station 2 side, and terminates this transmission path. Here, the termination resistors 313 and 314 are selected as connection destinations of the multiplexing / demultiplexing unit 312 by the selection units 350 and 360 described above.

  In step 4, it is not necessary to install the optical fiber 5 to the service area 1 and provide the optical wavelength multiplexing device 38 as a transmission line network different from the optical fiber 4. For example, as shown in FIG. The node device 300 may be connected to the optical fiber 4 via the closure 210. Such a modification of Step 4 shown in FIG. 10 is preferable in that the optical fiber 4 newly laid for constructing the FTTH system can be used effectively.

  In addition, among the plurality of node devices 300 in which the coaxial amplifier 130 is replaced, some of the node devices 300 in which no optical fiber is connected to the optical fiber connection unit 304 are coupled / demultiplexed by the selection units 350 and 360 described above. The downstream signal amplifier 331 and the upstream signal amplifier 337 are selected as connection destinations 312, and the communication station 2 and the subscriber are connected via a signal path between the input coaxial cable connection unit 301 and the output coaxial cable connection units 302 and 303. An electric signal can be transmitted to and from the terminal.

  That is, at the time of step 4, the selection unit 350, 360 selects the downstream signal amplifier 331 and the upstream signal amplifier 337 as the connection destination of the multiplexing / demultiplexing unit 312 for areas where switching to the FTTH system is not yet required. By doing so, the service by the existing HFC system can be provided to the subscriber's home.

  In this way, as shown by the dotted lines in FIGS. 9 and 10, a transmission path network from the communication station 2 to the optical node 110 via the coaxial cable 120 and a part from the optical node 110 via the coaxial cable 120. Each of the transmission line networks up to the node device 300 is terminated. Then, using the node device 300, an HFC system with a small area can be constructed.

  In signal transmission using a coaxial cable, transmission loss occurs when the transmission distance becomes long. However, by constructing an HFC system with a small area in Step 4, such signal deterioration can be suppressed. On the other hand, the signal transmitted through the optical fiber with respect to the coaxial cable has little degradation in signal quality even when the transmission distance is long. Therefore, by constructing the FTTH system in Step 4, the transmission loss of the entire transmission line network can be reduced. Can be reduced.

  Further, in step 5, as shown in FIG. 11, a further FTTH system is constructed in the service area 1 shown in FIG. That is, the optical fiber 4 is laid through the plurality of closures 210 in an area where no FTTH system is constructed.

  In addition, the node device 300 that is not connected to the optical fiber 4 in the step 4 and each closure 210 newly arranged in the step 5 are connected via the optical fiber 4.

  In addition, the power supply device 111 provided in the optical node 110 of the existing HFC system that has stopped transmitting signals to and from the communication station 2 is connected to a wireless communication device such as a wireless LAN router, thereby providing a service area. 1 can provide a wireless communication environment.

  Such services cannot be provided by HFC equipment for subscribers requesting high-speed Internet communication or subscribers who wish to receive BS-IF signals in a band of 770 MHz or higher, and optical fiber is used. It is necessary to provide services using the FTTH system. In response to such a request from the subscriber, the signal transmission system changing method to which the present invention is applied, as shown in steps 1 to 5 as described above, is provided in the transmission path network on the communication station side. A transmission system in which a signal is transmitted through an existing coaxial cable 120 is partialized using the node devices 300, 300a, 300b, and 300c connected to the transmission line of the closure. In this way, in this signal transmission system changing method, the FTTH system can be flexibly constructed from the HFC system according to the request of the subscriber while effectively utilizing the HFC system equipment in the service area 1. .

  Furthermore, in the method for changing a signal transmission system to which the present invention is applied, the transmission loss of the entire transmission line network can be reduced by constructing the HFC system and the FTTH system which have been reduced in area.

  In steps 4 and 5, the description has been given using the node device 300. However, the present invention is not limited to this, and the node device 300b is used when the FTTH system is constructed by RFoG. In addition, when only a faulty subscriber is connected to the downstream transmission path of the coaxial amplifier 130 to be replaced, it is sufficient to secure only a one-way transmission path for the downstream signal, and the node device 300c is used. do it.

DESCRIPTION OF SYMBOLS 1 Service area 111 Power supply apparatus 120 Coaxial cable 130 Coaxial amplifier 150 Paying subscriber's house 160 Electricity subscriber's house 2 Communication station 210 Closure 24, 33 Optical transmitter 25, 34, 35 Optical receiver 3, 4, 5 Light Fiber 300, 300a, 300b, 300c Node device 301 Input coaxial cable connection 302, 303 Output coaxial cable connection 304 Optical fiber connection 312 Multiplexer 313, 314 Termination resistor 322 Optical receiver unit 323 Optical transmitter unit 350, 360 selectors 351a, 351b, 361a, 361b changeover switch 401 optical transmission unit for RFoG

The node device according to the present invention is connected to a transmission path network on the communication station side, a first coaxial cable connection section connected via a coaxial cable, and a transmission path network on the subscriber premises side via the coaxial cable. One or more second coaxial cable connection portions for outputting a downstream electrical signal transmitted from the transmission line network on the communication station building side to the transmission line network on the subscriber premises side, and a transmission line on the communication station side The downstream electrical signal input to the first coaxial cable connection from the network is demultiplexed, and the upstream electrical signal input to the second coaxial cable connection from the subscriber premises transmission line network is multiplexed. A multiplexing / demultiplexing unit that outputs to the transmission line network on the communication station side via the first coaxial cable connecting unit, and a second coaxial cable connection by amplifying the downstream electrical signal demultiplexed by the multiplexing / demultiplexing unit The first amplifier that outputs to the unit and the connection destination of the multiplexing / demultiplexing unit from the first amplifier, Downlink Line a first switching unit for switching the end resistor, and an optical fiber connecting portion which is connected via a transmission network and optical fiber communication station building side, a downstream optical signal input to the optical fiber connecting portion An optical receiving unit that converts the signal into an electrical signal, and the second coaxial cable connection unit selects the first amplifier as a connection destination of the multiplexing / demultiplexing unit by the first selection unit. The downstream electrical signal transmitted from the transmission network on the communication station side is output to the transmission network on the subscriber premises, and the signal line is connected to the multiplexing / demultiplexing unit by the first selection unit. when you select the terminating resistors are you outputs a downstream electric signal converted by the light receiving unit to a transmission line network of the customer premises.

The signal transmission system according to the present invention is a signal transmission system including a transmission system having a coaxial transmission line and an FTTH system, and a communication station connected to the optical transmission line of the FTTH system and the coaxial transmission line. A node apparatus according to the present invention connected through a coaxial cable of a coaxial transmission line, one or more subscriber terminals connected to the optical transmission line or coaxial transmission line of the FTTH system, It is comprised from these.

The signal transmission system changing method according to the present invention is a signal transmission system changing method for changing from a transmission system having a coaxial transmission line to an FTTH system, and in a service area where the coaxial transmission line is constructed. The first step of constructing the optical transmission line of the FTTH system, and one or more subscriber houses among the first subscriber houses connected to the communication station building via the coaxial transmission line are connected to the communication station building. and a second step of changing the subscriber's home that is connected via the optical transmission path of the FTTH system, one or more coaxial amplifiers of the coaxial amplifier for amplifying the signal transmitted through the coaxial transmission line, one or more The third step of changing to the node device according to the present invention, and the optical receiving unit of each node device is connected to the transmission path network or closure of the communication station via the optical fiber so that the optical signal can be transmitted, Said And a fourth step of switching the connection destination of the multiplexing and demultiplexing unit to the terminating resistor by the switching unit.

Claims (9)

A transmission path network on the communication station side, a first coaxial cable connecting portion connected via a coaxial cable,
One or more which is connected to a transmission line network on the subscriber's home side via a coaxial cable and outputs a downstream electrical signal transmitted from the transmission line network on the communication station side to the transmission line network on the subscriber's home side A second coaxial cable connection,
The downstream electrical signal input to the first coaxial cable connection from the communication station side transmission path network is demultiplexed, and the subscriber home side transmission path network to the second coaxial cable connection A multiplexing / demultiplexing unit that multiplexes the input upstream electric signal and outputs the multiplexed signal to the transmission line network on the communication station side via the first coaxial cable connection unit;
A first amplifier that amplifies the downstream electric signal demultiplexed by the multiplexing / demultiplexing unit and outputs the amplified signal to the second coaxial cable connection unit;
A node device comprising: a first selection unit that selects a termination resistor of the first amplifier or signal line as a connection destination of the multiplexing / demultiplexing unit. A transmission line network on the side of the communication station, an optical fiber connection connected via an optical fiber,
An optical receiving unit that converts a downstream optical signal input to the optical fiber connection unit into a downstream electrical signal;
The second coaxial cable connection unit, when the termination resistor of the signal line is selected as the connection destination of the multiplexing / demultiplexing unit by the first selection unit, the downlink electrical signal converted by the optical reception unit The node device according to claim 1, wherein the node device is output to a transmission line network on the subscriber's home side. A first termination resistor connected to the first selector;
The node device according to claim 1, wherein the first selection unit includes a connection port to which the first termination resistor is connected. A second amplifier for amplifying an upstream electrical signal input to the second coaxial cable connection from the transmission line network on the subscriber premises side and outputting the amplified signal to the first coaxial cable connection;
An upstream electrical signal input from the transmission line network on the subscriber premises side to the second coaxial cable connection part is converted into an upstream optical signal, and the optical fiber connection part is transferred to the transmission line network on the communication station side. An optical transmitter for outputting;
The node device according to claim 2, further comprising: a second selection unit that selects the second amplifier or a signal line termination resistor as a connection destination of the multiplexing / demultiplexing unit. A second termination resistor connected to the second selection unit;
The node device according to claim 4, wherein the second selection unit includes a connection port to which the second termination resistor is connected.   6. The node device according to claim 4, wherein the optical transmission unit outputs an upstream optical signal in a burst state or a constant light emission in a transmission period assigned to the node device. A signal transmission system comprising a transmission system having a coaxial transmission line and an FTTH system,
A communication station connected to the optical transmission line of the FTTH system and the coaxial transmission line;
A node device connected to the communication station via a coaxial cable of the coaxial transmission line;
It comprises one or more subscriber terminals connected to the optical transmission line of the FTTH system or the coaxial transmission line,
The node device is
The downstream electrical signal input from the transmission line network on the communication station side is demultiplexed, and the upstream electrical signal input from the transmission line network on the subscriber premises side is multiplexed to transmit on the communication station side A multiplexing / demultiplexing unit that outputs to the road network;
A first amplifier that amplifies the downstream electric signal demultiplexed by the multiplexing / demultiplexing unit and outputs the amplified signal to the transmission line network on the subscriber premises side;
A signal transmission system comprising: the first amplifier or a first selection unit that selects a termination resistor of a signal line as a connection destination of the multiplexing / demultiplexing unit. A signal transmission system changing method for changing from a transmission system having a coaxial transmission line to an FTTH system,
A first step of constructing an optical transmission line of the FTTH system in a service area where the coaxial transmission line is constructed;
Among subscriber houses connected to a communication station via the coaxial transmission line, one or more subscriber houses are connected to the communication station via the optical transmission line of the FTTH system. A second step to change to home,
One or more coaxial amplifiers among the coaxial amplifiers that amplify the signal transmitted through the coaxial transmission line demultiplex an upstream electrical signal input from the transmission line network on the communication station side, and A multiplexing / demultiplexing unit that multiplexes the upstream electrical signal input from the transmission path network and outputs the multiplexed signal to the transmission path network on the communication station side, and amplifies the downstream electrical signal demultiplexed by the multiplexing / demultiplexing unit A first amplifier that outputs to the transmission line network on the subscriber's home side, and a first selection unit that selects the first amplifier or a signal line termination resistor as a connection destination of the multiplexing / demultiplexing unit; A third step of changing to one or more node devices having:
A fourth step of connecting the optical receiving unit of each node device to the optical transmission line of the FTTH system, and selecting a termination resistor as a connection destination of the multiplexing / demultiplexing unit by the first selection unit. How to change the signal transmission system.   The signal transmission system change according to claim 8, further comprising a fifth step of connecting a wireless transmission / reception device capable of communicating with a wireless communication terminal to a power supply device included in the first node after the fourth step. Method.

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