JP5727840B2 - CATV system - Google Patents

Description

  The present invention relates to a CATV system capable of transmitting BS / CS digital broadcasting by a pass-through method.

  A network system called HFC (Hybrid Fiber-Coaxial) is known (for example, Patent Document 1). This is a system in which the optical fiber transmission line is used from the head end to the main line part, and the coaxial cable transmission line is used for the branch line part from the main line to each subscriber. The optical fiber transmission line and the coaxial cable transmission line are connected by using an optical node device that mutually converts an optical signal and an electrical signal.

  In this HFC system, terrestrial digital broadcasting is transmitted to a coaxial cable transmission line by a pass-through method using the same frequency as the spatial frequency band. However, since the coaxial cable transmission line can only transmit signals in the band up to 770 MHz due to the characteristics, BS / CS digital broadcasting cannot be transmitted by the pass-through method using the frequencies of the BS-IF and CS-IF bands. For this reason, BS / CS digital broadcasting has been transmitted in a band of 770 MHz or less by a trans-modulation method in which a modulation method is converted and transmitted.

JP 2006-74193 A

  As a result, each consumer outputs terrestrial digital broadcasting to a television receiver in a pass-through manner, and BS / CS digital broadcasting to a television receiver via an STB (set top box). It was.

  Therefore, when viewing digital terrestrial broadcasting, it is necessary to operate with a remote control operation panel for a television receiver, and when viewing BS / CS digital broadcasting, it is necessary to operate with a remote control operation panel for a set top box. was there. Also, when performing program reservation, recording reservation, recording, etc., terrestrial digital broadcasting must be performed by operation on a television receiver, and BS and CS digital broadcasting must be performed by operation on a set top box. For this reason, it is necessary to switch the operation panel, and an operation according to each specification is required, and the operation is complicated.

  In addition, recent television receivers have many functions for digital broadcasting and data broadcasting, such as program reservation by data reception, recording reservation, and storage of broadcast signals in a storage device integrated with the receiver. Has been. For this reason, each consumer tended to use only the function of the television receiver and not use the function of the set top box. In order to use only the television receiver, terrestrial digital broadcasting is received from the CATV system, and BS / CS digital broadcasting is directly received from the BS-IF and CS-IF signals received from the antenna installed at the consumer. I was trying to input to John's receiver.

  As a result, consumers tend to receive spatial radio waves, including terrestrial digital broadcasting, away from the CATV system, and HFCs tend not to be used effectively.

  In addition, if the transition to the FTTH system CATV system is made, BS / CS digital broadcasting can be transmitted by the pass-through system. However, the transition from the HFC system to the FTTH system has a high hurdle in terms of cost.

  Therefore, an object of the present invention is to realize a CATV system capable of transmitting BS / CS digital broadcasting by a pass-through method.

  According to a first aspect of the present invention, a plurality of first optical fiber transmission lines connected to the head end, an optical node device connected to each optical fiber transmission line, and a plurality of branching devices are laid out from the optical node device toward the downstream side. And an HFC system having a first coaxial cable transmission line branched to a plurality of customers by branching off by tap-off, and laid from the head end to the tap-off position, A plurality of second optical fiber transmission lines for propagating light having a wavelength different from the wavelength of the propagating light, expansion tap-offs installed at tap-off positions and connected to the respective second optical fiber transmission lines, and first coaxial cable transmission lines Of these, the first coaxial cable transmission line laid between the tap-off and a plurality of customers is used as it is, and each extension tap-off is used. And a plurality of second coaxial cable transmission lines laid between a plurality of customers, an expansion protector installed outside each customer and inserted in the second coaxial cable transmission line, and installed at the head end For the second optical fiber transmission line, the terrestrial digital broadcast wave remains the same frequency as the spatial frequency band, and the BS digital broadcast wave and the CS digital broadcast wave remain BS-IF and CS-IF, respectively. A broadcast wave transmission device that outputs a downstream optical signal to the second optical fiber transmission line by optical modulation, and the second coaxial cable transmission line inserted into the second coaxial cable transmission line indoors of each consumer, The extension tap-off is connected to the second optical fiber transmission line, and the downstream optical signal propagating through the second optical fiber transmission line is converted into a downstream electrical signal. The V-ONU driven by the electric power superimposed by the power inserter, the distributor for distributing the downlink electric signal output from the V-ONU into a plurality, the V-ONU and the distributor are connected, A duplexer that outputs the downstream electrical signal from the ONU to the distributor and outputs the upstream electrical signal from the distributor to the tap-off, and the expansion protector is inserted into the second coaxial cable transmission line A CATV system comprising: a protector; and an amplifier that amplifies BS-IF and CS-IF frequency bands of a downstream electrical signal transmitted through a second coaxial cable transmission line.

  According to a second aspect, in the first aspect, the head end is a data transmission / reception device that transmits and receives an optical signal, which is a data signal having a wavelength different from that of the downstream optical signal output from the broadcast wave transmission device, from the second optical fiber transmission line. The extension tap-off further divides the downstream optical signal from the second optical fiber transmission path into a data signal wavelength band and a broadcast signal wavelength band, and outputs a downstream optical signal as a broadcast signal to the V-ONU. A third optical fiber transmission line between each of the extension tap-off optical distributors and some consumers, further comprising: a wavelength multiplexing device; and an optical distributor connected to the data signal input / output side of the wavelength multiplexing device. Is a CATV system characterized in that is further installed.

  According to a third invention, in the first to second inventions, a branching device is inserted into the first coaxial cable transmission line in the vicinity of the tap-off, and the upstream electrical signal of the duplexer is replaced with the branching device instead of the tap-off. Is connected to the branch terminal of the branching device.

  According to a fourth invention, in the first invention or the second invention, a second amplifier for amplifying an upstream electrical signal output from the duplexer is further provided in the extended tap-off, and the second amplifier and one of the tap-off branch terminals are provided. A CATV system characterized by connecting the two.

  According to a fifth aspect of the present invention, a plurality of first optical fiber transmission lines connected to the head end, an expansion tap-off connected to the first optical fiber transmission line, and a coaxial cable transmission branched by the expansion tap-off and installed to a plurality of consumers, respectively. And a second optical fiber transmission line that is branched by an extended tap-off and installed to a plurality of consumers, and is installed at the head end. The BS digital broadcast wave and the CS digital broadcast wave remain in the BS-IF and CS-IF, respectively, and are output to the first optical fiber transmission line as a downstream optical signal by optical modulation. Similarly, the wavelength is different from the downstream optical signal that is installed at the headend and output from the broadcast wave transmitting device. A data transmitter / receiver that transmits and receives an optical signal that is a data signal from a second optical fiber transmission line, and a power inserter that is inserted into a coaxial cable transmission line inside each customer and superimposes power from a power source on the coaxial cable transmission line; An expansion protector installed outside each customer and inserted in the coaxial cable transmission line, and a first amplifier inserted in the vicinity of the expansion tap-off of each coaxial cable transmission line. A downstream optical signal from one optical fiber transmission line is divided into a data signal wavelength band and a broadcast signal wavelength band for output, and connected to the data signal input / output side of the wavelength multiplexing apparatus. 2 An optical distributor connected to the optical fiber transmission line, a V-ONU that is connected to the broadcast signal output side of the wavelength division multiplexer, converts the downstream optical signal into a downstream electrical signal, and is driven without power supply, and V- A distribution device that distributes the downstream electrical signal output by the NU into a plurality of devices, and the expansion protector includes a protector inserted in the coaxial cable transmission line and a BS− of the downstream electrical signal transmitted through the coaxial cable transmission line. A CATV system comprising: a second amplifier that amplifies IF and CS-IF frequency bands and is driven by power superimposed by a power inserter.

  According to the CATV system of the present invention, BS / CS digital broadcasting can be transmitted by the pass-through method. Therefore, each customer does not need to set up an antenna for BS and CS digital broadcasting, and does not need a set-top box, but can select terrestrial digital broadcasting, BS digital broadcasting, CS digital broadcasting, program reservation, and recording reservation. Recording, etc. can be performed only with a television receiver. Therefore, convenience for consumers is improved. Moreover, since one extension tap-off with V-ONU covers a plurality of consumers, the equipment cost and the construction cost can be reduced as compared with the FTTH CATV system. In addition, the CATV system of the present invention can be transferred to the FTTH system on a subscriber basis, and the cost can be reduced as compared with the case of shifting to the FTTH system.

1 is a diagram illustrating a configuration of a CATV system according to a first embodiment. The figure which showed the structure of the CATV system of Example 2. FIG. FIG. 5 is a diagram illustrating a configuration of a CATV system according to a third embodiment. The figure which showed the structure of the CATV system of another modification. The figure which showed the structure of the CATV system of another modification.

  Hereinafter, specific examples of the present invention will be described with reference to the drawings. However, the present invention is not limited to the examples.

  FIG. 1 is a diagram illustrating a configuration of a CATV system according to the first embodiment. Among the CATV systems of the present embodiment, as an existing HFC system, a head end 10, an optical node device 23 provided in the field, and an optical fiber transmission line for a downstream signal connecting the head end 10 and the optical node device 23. 21, an optical fiber transmission line 22 for upstream signals, and a coaxial cable transmission line 40 that connects the optical node device 23 and the customer 50. The coaxial cable transmission line 40 is provided with a plurality of four-branch tap-offs 41 for branching signals to the respective consumers 51 at respective positions. As the tap-off 41 is located on the downstream side, the branching loss is reduced, and on the upstream side, the branching loss is increased. Even if there is no amplifier, the signal level branched to each branch line is large even if it is downstream. It is configured not to attenuate.

  In addition, the head end 10 includes an electrical / optical converter 11 that converts an electrical signal into an optical signal and outputs the optical signal to a downstream optical fiber transmission path 21 and an upstream optical fiber transmission path 22. An optical / electrical converter 12 that converts an optical signal propagated toward the end 10 into an electrical signal is provided. A broadcast wave transmission device 16 and a data transmission device 17 are connected to the electrical / optical converter 11. With these devices, a television broadcast signal and a downstream data signal in the conventional CATV are transmitted to each customer 51. Is output toward. The upstream data signal from each customer 51 under the existing HFC system is converted into an electrical signal by the optical / electrical converter 12 and processed by the data receiving device 18. The electrical / optical converter 11, the optical / electrical converter 12, and the optical node device 23 are devices that modulate or demodulate 1.3 μm laser light.

  In the CATV system of the first embodiment, in addition to the HFC system, a transmission system shown below is newly laid. An optical fiber transmission path 61 connecting from the head end 10 to the optical distributor 60 arranged in the field and an optical fiber transmission path 62 laid from the optical distributor 60 to the expansion tap-off 70 are newly installed. The coaxial cable transmission line 43 connecting the extension tap-off 70 to each consumer 50 uses the coaxial cable transmission line 40 laid between the tap-off 41 and the consumer of the existing HFC system as it is. The optical fiber transmission paths 61 and 62 are the second optical fiber transmission paths of the present invention, and the coaxial cable transmission path 43 is the second coaxial cable transmission path. The optical fiber transmission path 61 is connected to the electrical / optical converter 13 of the head end 10, and the broadcast wave transmission device 14 and the data transmission device 15 are connected to the electrical / optical converter 13. The broadcast wave transmission device 14 is a device that outputs the terrestrial digital broadcast wave with the same frequency as the spatial frequency band, and the BS digital broadcast wave and the CS digital broadcast wave with the BS-IF and CS-IF, respectively. is there. The broadcast wave transmission device 14 also outputs a local CATV broadcast wave at a frequency of an empty channel for terrestrial digital broadcasting.

  An extension protector 90 is provided under the eaves of each customer 50, and the coaxial cable transmission path 43 is drawn into the house through the extension protector 90. The extended protector 90 includes a protector 91, an amplifier 92 that amplifies the frequency bands of BS-IF and CS-IF, and duplexers 93 and 94, which are housed in one casing. . An upstream electrical signal and a downstream electrical signal are separated by the duplexers 93 and 94, and an amplifier 92 is inserted between the duplexer 93 and the duplexer 94 on the downstream electrical signal side.

  The consumer 50 is provided with a distributor 52 connected to the coaxial cable transmission line 43, a television receiver 53 is connected to one of the two distribution terminals of the distributor 52, and a cable modem is connected to the other distribution terminal. A personal computer (PC) 55 is connected via 54.

  The expansion tap-off 70 arranged in the field is configured by a V-ONU 71, a 4-distributor distributor 81, and a duplexer 83. The optical signal input side of the V-ONU 71 is connected to the optical fiber transmission line 62, and the electrical signal output side is connected to a 4-distributor 81 through a duplexer 83. The upstream terminal 431 of the coaxial cable transmission line 43 reaching each customer 50 is connected to each of the four distribution terminals 811 of the distributor 81. In the branching filter 83, one branching terminal is connected to the electric signal output side of the V-ONU 71, and the other branching terminal is connected to the branch terminal of the tap-off 41.

  The power inserter 100 is inserted into the coaxial cable transmission line 43 in the house of the customer 50, and the electric power from the household power supply is superimposed on the coaxial cable transmission line 43 via the power inserter 100, so that V -Power is supplied to the ONU 71.

  Next, the operation of the CATV system according to the first embodiment will be described.

  First, the operation of the existing HFC system will be described. From the electrical / optical converter 11 of the head end 10, conventional broadcast waves (terrestrial digital, analog, BS QAM modulation, CS QAM modulation, local CATV broadcast, etc.) and downstream data signals are transmitted through an optical fiber transmission line 21. Is output. These signals are transmitted through the optical node device 23, the coaxial cable transmission line 40, and the tap-off 41, input to the set top box of each consumer 51, and are selected by the television receiver and displayed as an image. At this time, the terrestrial digital broadcast is directly input to the television receiver by pass-through. On the other hand, BS, CS digital broadcasts and local CATV broadcasts are demodulated into baseband video / audio signals by a set top box and output to a video / audio input terminal of a television receiver. As a result, terrestrial digital broadcasting channel selection, recording, program reservation, and the like are operated by the television receiver, and BS and CS digital broadcasting operations such as channel selection and recording are performed by the set top box. As a result, the operation becomes two systems, and the operation is complicated.

  Next, the operation of the newly installed transmission system will be described. From the broadcast wave transmitting device 14 of the head end 10, the terrestrial digital broadcast wave remains at the same frequency as the spatial frequency band, and the BS digital broadcast wave and CS digital broadcast wave remain as BS-IF and CS-IF signals, respectively. Is output. Then, the electric / optical converter 13 modulates the laser beam having a wavelength of 1.55 μm based on these broadcast wave signals, and transmits the modulated laser beam to the optical fiber transmission line 61. The local CATV broadcast is an empty channel for terrestrial digital broadcasting, and the downlink data signal is also output to a predetermined empty channel via the electrical / optical converter 13 to the optical fiber transmission line 61. These optical signals are distributed by the optical distributor 60, propagated through the optical fiber transmission path 62, and input to the V-ONU 71 of the extension tap-off 70. Then, the downstream optical signal input via the optical fiber transmission path 62 by the V-ONU 71 supplied with power from the power inserter 100 through the coaxial cable transmission path 43 and driven is terrestrial digital broadcasting having a frequency arrangement in the spatial frequency band. , BS-IF band and CS-IF band BS digital broadcast and CS digital broadcast are converted to downstream electrical signals. Similarly, local CATV broadcasts and downlink data signals are also converted into downlink band electrical signals. These downstream band electrical signals pass through the duplexer 83, are divided into four by the distributor 81, and are output to the coaxial cable transmission line 43. Then, the BS-IF and CS-IF bands of the downstream electrical signal are amplified by the expansion protector 90, distributed by the distributor 52, and then directly input to the television receiver 53. In the television receiver 53, selection of broadcast signals input in the same frequency arrangement as the spatial frequency, BS-IF band, and CS-IF band, program reservation, recording, etc., by only operating the television receiver 53. This can be done by For this reason, operation becomes very easy.

  On the other hand, the downlink data signal is input to the modem 54 via the distributor 52 and received by the PC 55. The upstream data signal output from the PC 55 is transmitted through the coaxial cable transmission line 43 via the distributor 52, and is input to the branch terminal of the tap-off 41 via the distributor 81 and the duplexer 83. Then, the downlink data signal is output to the coaxial cable transmission line 40 via the tap-off 41. As a result, the PC 55 can perform mutual data communication with the head edge 10.

  In the above-described existing HFC system, the coaxial cable transmission line 40 connected to the optical node device 23 has an upper limit of the propagation frequency of 770 MHz, and therefore the coaxial cable transmission line 40 includes the BS-IF band and the CS- The IF digital BS digital broadcast signal and CS digital broadcast signal do not propagate. That is, since the existing coaxial cable transmission 40 is provided with a relay amplifier and a tap-off 41, a signal in a band of 770 MHz to 2.6 GHz cannot be passed. For this reason, BS digital broadcast signals and CS digital broadcast signals cannot be transmitted by the BS-IF / CS-IF pass-through method.

  On the other hand, in the newly installed transmission system, the optical fiber cables 61 and 62 can transmit BS digital broadcast signals of the BS-IF / CS-IF pass-through system and optical modulation signals of CS digital broadcast signals. The demultiplexer 83, the distributor 81, and the distributor 52, which are devices downstream from the V-ONU 71, can propagate signals up to the 2.6 GHz band. And by using the existing coaxial cable transmission line 43 and providing an expansion protector 90 that can amplify the frequency band of BS-IF / CS-IF under the eaves of each customer 50, up to 770 MHz, Transmission of the BS-IF and CS-IF bands can be realized while operating. Therefore, by adopting the system of the present invention in an existing HFC system, BS digital broadcast, CS digital broadcast, and local CATV broadcast can be transmitted by a pass-through system, and uplink data communication can also be performed. In addition, in this system, the optical fiber transmission lines 61 and 62 and the optical distributor 60 are newly laid in the field, the expansion tap-off 70 is installed at the position of the tap-off 41 of the existing HFC system, and the protector under the eaves of the customer 50 is installed. It is only necessary to replace the expansion protector 90. Each customer 50 does not need to be laid by drawing in the optical fiber transmission line, and a new transmission system can be added by simple construction.

[Modification 1]
As shown in FIG. 4, an amplifier 84 that amplifies the band of the upstream electrical signal is provided, and the amplifier 84 and one of the branch terminals of the tap-off 41 are connected.
[Modification 2]
As shown in FIG. 5, a configuration in which one branch device 44 is newly inserted into the coaxial cable transmission line 40 and the terminal on the upstream electrical signal output side of the duplexer 83 and the branch terminal of the branch device 44 are connected. And

  FIG. 2 is a diagram illustrating a configuration of the CATV system according to the second embodiment. The CATV system of the second embodiment is a modification of the CATV system of the first embodiment as follows. Instead of the extended tap-off 70, an extended tap-off 170 is newly provided. In addition, an optical fiber transmission line 63 is newly laid between the specific customer 50 </ b> A and the expansion tap-off 170 among the customers 50. An expansion protector 190 is installed under the eaves of the customer 50 </ b> A instead of the expansion protector 90.

  The extended tap-off 170 has a configuration in which a wavelength division multiplexer 73 and a 4-distribution optical distributor 72 are further added to the extended tap-off 70. The wavelength multiplexing device 73 is connected to the optical fiber transmission path 62 and separates and outputs the downstream optical signal of the broadcast signal (terrestrial digital broadcast, BS / CS digital broadcast, etc.) and the downstream optical signal of the data signal. The downstream optical signal output side of the broadcast signal of the wavelength multiplexing device 73 is connected to the V-ONU 71. Further, the downstream optical signal output side of the data signal is connected to the optical distributor 72. The downstream optical signal output side of this data signal is also the upstream optical signal input side from the optical distributor 72. The distribution terminal of the optical distributor 72 is connected to the optical fiber transmission path 63, and the optical fiber transmission path 63 is drawn into the house of the consumer 50A.

  There is no distributor 52 in the house of the customer 50A, the coaxial cable transmission line 43 is directly connected to the television receiver 53, and the optical fiber transmission line 63 is connected to the ONU 56. The ONU 56 is connected to the PC 55. Further, the power inserter 100 is inserted into the coaxial cable transmission path 43 in the house of the consumer 50A in the same manner as in the first embodiment, and the power from the household power source is passed through the power inserter 100 to the coaxial cable transmission path 43. As a result, power is supplied to the V-ONU 71. Further, the expansion protector 190 installed under the eaves of the house of the consumer 50A has a configuration in which the duplexers 92 and 93 are omitted from the expansion protector 90.

  An optical branching device 111 is inserted into the optical fiber transmission line 61 of the head end 10, and the branching side of the optical branching device 111 is connected to the data receiving device 18 via the O / E converter 112.

  In addition, the coaxial cable transmission line 43 is laid between the consumer 50 and the distribution terminal of the distributor 81 of the expansion tap-off 170 as in the first embodiment. Same as 1.

  In the CATV system according to the second embodiment, the customer 50 can receive broadcasts and perform two-way data communication as in the first embodiment. In particular, the BS / CS digital broadcast transmitted by the pass-through method can be used. Can be received.

  On the other hand, the customer 50A can receive the broadcast in the same manner as in the first embodiment, and can receive the BS / CS digital broadcast transmitted by the pass-through method. As for data communication, bidirectional communication is performed by the PON method. Therefore, a bidirectional data communication service that is faster than the consumer 50 can be used.

  As described above, in the CATV system of the second embodiment, BS / CS digital broadcasting can be transmitted by the pass-through method. Also, in the CATV system of the second embodiment, for data communication, whether to use a data communication service using an existing HFC system as in the first embodiment, or to use a higher-speed data communication of the PON method. It can be selected at the consumer.

  Note that the configurations shown in the first and second modifications of the first embodiment can also be applied to the CATV system of the second embodiment.

  FIG. 3 is a diagram illustrating a configuration of the CATV system according to the third embodiment. The CATV system of the third embodiment is obtained by changing the CATV system of the second embodiment as follows. In Example 2, all the existing HFC system parts are omitted. Then, instead of the extended tap-off 170, an extended tap-off 270 is newly provided.

  The extension tap-off 270 is configured by omitting the duplexer 83 from the extension tap-off 170 and providing a parasitic V-ONU 271 instead of the V-ONU 71. The non-powered V-ONU 271 is a V-ONU using a device that performs optical / electrical conversion without power feeding, that is, without power feeding.

  An amplifier 290 is inserted in the vicinity of the distribution terminal of the distributor 81 of the extension tap-off 270 in the coaxial cable transmission line 43. This is for compensating the distribution loss caused by the distributor 81.

  The head end 10 includes the broadcast wave transmitting device 14, the data transmitting device 15, the data receiving device 18, the electric / optical converter 13, the optical / electrical converter 112, and the optical branching unit from the head end 10 shown in the second embodiment. The configuration other than 111 is omitted.

  Other configurations are the same as those of the CATV system of the second embodiment. Also in the third embodiment, the power inserter 100 is inserted in the coaxial cable transmission line 43, but this is not for supplying power to the parasitic V-ONU 271, but for supplying power to the amplifier 92 of the expansion protector 190. It is for supply.

  In the CATV system of the third embodiment, as in the second embodiment, BS / CS digital broadcasting can be transmitted to the customer 50 by the pass-through method. As for data communication, high-speed bidirectional data communication by the PON method can be performed. In the CATV system of the third embodiment, the V-ONU 271 with the extended tap-off 270 can be driven without power supply, and the power from the power inserter 100 is supplied to the amplifier 92 of the extended protector 190. The burden can be made fair.

  The CATV system of the present invention can transmit BS / CS digital broadcasting in a pass-through manner.

10: head end 11, 13: electrical / optical converter 12, 100: optical / electrical converter 14, 16: broadcast wave transmission device 15, 17: data transmission device 18: data reception device 21, 22, 61, 62: Optical fiber transmission line 23: Optical node device 40, 43: Coaxial cable transmission line 50, 51: Customer 60: Optical distributor 70: Expansion tap-off 71: V-ONU
81: distributor 83, 93, 94: duplexer 90: expansion protector 91: protector 92: amplifier 100: power inserter

Claims (5)

A plurality of first optical fiber transmission lines connected to the head end, an optical node device connected to each of the optical fiber transmission lines, and a downstream from the optical node device, and branched into a plurality of paths by a plurality of branch devices And a first coaxial cable transmission line that is branched to a plurality of customers by branching off by tap-off,
A plurality of second optical fiber transmission lines which are laid from the head end to the tap-off position and propagate light having a wavelength different from the wavelength of light propagating through the first optical fiber transmission line;
An expansion tap-off installed at the tap-off position and connected to each of the second optical fiber transmission lines;
Among the first coaxial cable transmission lines, the first coaxial cable transmission line laid between the tap-off and a plurality of consumers is used as it is, and between each extension tap-off and the plurality of consumers. A laid second coaxial cable transmission line;
An expansion protector installed outside each consumer and inserted into the second coaxial cable transmission line;
The digital terrestrial broadcast wave is installed at the head end, and the terrestrial digital broadcast wave remains at the same frequency as the spatial frequency band, while the BS digital broadcast wave and the CS digital broadcast wave are BS-IF and CS, respectively. A broadcast wave transmission device that outputs to the second optical fiber transmission line as a downstream optical signal by optical modulation with -IF remaining;
A power inserter that is inserted into the second coaxial cable transmission line indoors of each consumer and superimposes power from a power source on the second coaxial cable transmission line;
Have
The extended tap-off is
A V-ONU connected to the second optical fiber transmission line, converting a downstream optical signal propagating through the second optical fiber transmission line into a downstream electrical signal, and driven by power superimposed by the power inserter;
A distributor for distributing a plurality of downstream electric signals output from the V-ONU;
A duplexer connected between the V-ONU and the distributor, outputting a downstream electrical signal from the V-ONU to the distributor, and outputting an upstream electrical signal from the distributor to the tap-off; ,
Have
The expansion protector is
A protector inserted into the second coaxial cable transmission line;
A first amplifier that amplifies the BS-IF and CS-IF frequency bands of the downstream electrical signal transmitted through the second coaxial cable transmission line;
Having
CATV system characterized by this. The head end further includes a data transmission / reception device that transmits / receives an optical signal, which is a data signal having a wavelength different from that of the downstream optical signal output from the broadcast wave transmission device, from the second optical fiber transmission line,
The extension tap-off divides a downstream optical signal from the second optical fiber transmission line into a data signal wavelength band and a broadcast signal wavelength band, and outputs a downstream optical signal as a broadcast signal to the V-ONU. A multiplexer, and an optical distributor connected to the data signal input / output side of the wavelength multiplexer;
A third optical fiber transmission line is further installed between the optical distributor of each of the extension tap-offs and some of the consumers.
The CATV system according to claim 1.   A branching device is inserted into the first coaxial cable transmission line near the tap-off, and a terminal for outputting the upstream electrical signal of the duplexer is connected to the branching terminal of the branching device via the branching device instead of the tap-off. The CATV system according to claim 1 or 2, characterized in that:   The second amplifier for amplifying an upstream electrical signal output from the duplexer is further provided in the extension tap-off, and the second amplifier is connected to one of the branch terminals of the tap-off. Item 3. The CATV system according to Item 2. A plurality of first optical fiber transmission lines connected to the head end;
An expansion tap-off connected to the first optical fiber transmission line;
A coaxial cable transmission line branched by the extension tap-off and laid up to a plurality of consumers,
Similarly, a second optical fiber transmission line branched by the extension tap-off and laid up to a plurality of consumers,
The digital terrestrial broadcast wave is installed at the head end, and the terrestrial digital broadcast wave remains at the same frequency as the spatial frequency band, while the BS digital broadcast wave and the CS digital broadcast wave are BS-IF and CS, respectively. A broadcast wave transmission device that outputs to the first optical fiber transmission line as a downstream optical signal by optical modulation without changing the IF;
Similarly, a data transmitting / receiving device that is installed at the head end and transmits / receives an optical signal, which is a data signal having a wavelength different from that of the downstream optical signal output from the broadcast wave transmitting device, from the second optical fiber transmission line;
A power inserter that is inserted into the coaxial cable transmission line inside each of the consumers and superimposes power from a power source on the coaxial cable transmission line;
An expansion protector installed outside each consumer and inserted into the coaxial cable transmission line;
A first amplifier inserted in the vicinity of the extension tap-off of each coaxial cable transmission line;
Have
The extended tap-off is
A wavelength multiplexing device that divides and outputs a downstream optical signal from the first optical fiber transmission path into a wavelength band of a data signal and a wavelength band of a broadcast signal;
An optical distributor connected to the data signal input / output side of the wavelength multiplexing device and connected to the plurality of second optical fiber transmission lines;
V-ONU that is connected to the broadcast signal output side of the wavelength multiplexing device, converts a downstream optical signal into a downstream electrical signal, and is driven without power supply,
A distributor for distributing a plurality of downstream electric signals output from the V-ONU;
Have
The expansion protector is
A protector inserted in the coaxial cable transmission line;
A second amplifier that amplifies the BS-IF and CS-IF frequency bands of the downstream electrical signal transmitted through the coaxial cable transmission line and is driven by the power superimposed by the power inserter;
Having
CATV system characterized by this.

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