JP2003069494A - Multiplex transmission system for data signal and television signal and its optical node device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission system in which a CATV LAN can make communication with an optional band and to provide an optical node device. SOLUTION: A second optical fiber cable 21 being a bypass transmission line of a data signal is provided between a central device 22 and an optical node device 30. Further, the optical node device 30 is provided with a photoelectric converter 32 corresponding to the second optical fiber cable 21, an Ethernet (R) communication device 36, and a mixer 37 for mixing a signal to a coaxial cable 25. Thus, a bypass exclusively for the data signal is formed between the central device 22 and consumers 40. Through the bypass, the signal can be transmitted in both directions at an optional free band by means of frequency multiplexing. Particularly the consumer 40 transmits an incoming signal through an optional free band in an outgoing signal band (TV band). Since the incoming band having conventionally been narrow can be extended, the data transmission efficiency in the incoming direction can be enhanced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission system for multiplex transmission of a data signal and a television signal using an optical fiber and a coaxial cable, and an optical node device thereof. In particular, the present invention relates to a transmission system and an optical node device thereof, in which a second optical fiber cable is provided between a central device and an optical node device to enable communication in the entire band without dividing into an upstream band and a downstream band, and improve the efficiency. The present invention is a CA that enables high-speed communication at all times without affecting the TV receiving function.
It can be applied to TV network systems.

[0002]

2. Description of the Related Art Conventionally, there is a network system using a CATV system. It is generally called a local area network (hereinafter referred to as LAN),
It is a system in which a plurality of terminal devices are connected to a CATV main cable deployed in the city and data is transmitted and received between the terminal devices or between the terminal device and a central device. In this system, not only television signals but also character data, video data, audio data, etc. are transmitted in both directions.

A conventional CATV network system is shown in FIG. CATV network system, CATV
A central device 22 provided in the station 20 and the CATV station 20, and a main line optical fiber cable 2 connected to the central device 22.
3, an optical node device 30, a coaxial cable 25 extending from the optical node device 30, a relay device 50 provided at a predetermined position of the coaxial cable 25, and a customer network 40 connected to the branch cable 24. . Incidentally, C
ATV station 20 is an internet interface 16
The central unit 22 is connected to the Internet network 10 via the central unit 22. Consumer network 40
Is a splitter / distributor 4 that splits / distributes a high-frequency modulated signal (hereinafter, RF modulated signal) propagated through the branch cable 24.
1. Terminal device 42 connected to branching / dividing device 41, TV
The receiving device 43 is included. In addition, the terminal device 42,
A cable modem 44 that is a modulator / demodulator that demodulates a high-frequency signal into a baseband signal or modulates a baseband signal into a high-frequency signal is provided.

The transmission system used in this CATV network system is a broadband system for frequency-multiplexing and transmitting an RF modulated signal. For example, 10 MHz to 50 MHz band is used for upstream high frequency signals, and 9 MHz for downstream high frequency signals.
The 0 MHz to 770 MHz band is assigned. And
A data signal is transmitted and received as an upstream signal and a downstream signal using both bands. That is, the upstream data signal is from 10 MHz
It is transmitted in the 50 MHz band, and the downlink data signal is transmitted by utilizing an empty band of the 90 MHz to 770 MHz band of the television signal or the upper limit frequency band (to 900 MHz) of the coaxial cable.

FIG. 7 shows an optical node device 30. The figure is a block diagram of the configuration. The optical node device 30 includes a photoelectric converter 31 that mutually converts an optical signal and an electric signal, a transmitter (Tx) 34 that transmits an upstream signal, a receiver (Rx) 33 that receives a downstream signal, and demultiplexes both signals. It is composed of a demultiplexer 35. Television signal which is a down signal and central unit 22
When the downstream data signals from the are input from the optical fiber cable 23, the receiver (Rx) 33 receives them and transmits them to the consumer 40 via the demultiplexer 35 and the coaxial cable 25. On the contrary, when upstream signals are input from the consumer 40 via the coaxial cable 25, the signals are demultiplexed by the demultiplexer 35 to the transmitter (Tx) 34 side, and the transmitter 34 and the photoelectric converter 31. Central device 22 via optical fiber cable 23
Have been sent to. In recent years, the number of data communication users has increased due to the development of the Internet and the like, and a more efficient transmission method without waiting time is required. That is, in the CATV network system, it is required to expand the band of the upstream data signal.

[0006]

However, in the conventional transmission method, the upstream data band is 10 MHz as described above.
~ 50 MHz only. In particular, there are several channels except the channel for controlling the CATV system. That is,
When the number of customers is relatively small, it was possible to provide communication services with good transmission efficiency, but there was concern that the efficiency would decline as the number of customers increased in recent years.

The present invention has been made to solve the above-mentioned problems, and an object thereof is to lay a second optical fiber cable between a central device and an optical node device, or to install an optical fiber cable of a backup line as a first optical fiber cable. 2 optical fiber cables,
The second optical fiber cable enables free band communication over the entire band. That is, by using the second optical fiber cable for the frequency band of the upstream data signal,
It is to improve the communication efficiency by expanding the conventional TV signal free band of the downlink signal band. Another object of the present invention is to provide an optical node device that enables the transmission method.

[0008]

In order to solve the above-mentioned problems, the multiplex transmission system of the data signal and the television signal according to claim 1 has a first optical fiber extended from a central unit. A transmission method for transmitting a data signal and a television signal by frequency multiplexing using a cable, an optical node device, and a coaxial cable extended to a customer, and a second optical system between the central device and the optical node device. A fiber cable is provided, and the optical node device is provided with a photoelectric converter for converting the input / output of the second optical fiber cable, and a transceiver and a mixer for mixing the input / output of the transceiver with the coaxial cable. 1 optical fiber cable in the down direction,
The data signal is bidirectionally transmitted by the first and / or the second optical fiber cable.

The laying of the second optical fiber cable means forming a bidirectional data-only transmission line through which only data signals are transmitted from the consumer to the central unit. In the conventional system, the frequency band is the guard band band (for example, 50
.About.90 MHz). That is, the upstream data signal is transmitted in the band of 10 to 50 MHz, and the downstream data signal and the television signal are transmitted in the band of 90 to 770 MHz, for example. Further, in order to give priority to the television signal (downstream signal), the upstream signal is conventionally transmitted in a narrow band as compared with the downstream signal. In the present invention, since the data signal dedicated transmission line (second optical fiber cable) is mixed with the conventional coaxial cable by the mixer, the above restriction can be exceeded.

That is, when the transmitter / receiver of the optical node device receives the upstream data signal, the receivable band is expanded to the downstream band to receive the upstream data signal. This expansion may be expansion using a separation filter (demultiplexer) including, for example, a low-pass filter and a high-pass filter, or may be expansion using, for example, an Ethernet (registered trademark) communication device. The expansion by the demultiplexer means shifting the guard band band to the upstream side. Further, the expansion by the Ethernet communication device means that the upstream signal is received in the downstream band and is transmitted upstream as the baseband signal. That is, the upstream band may be mixed with the downstream band. By expanding the upstream band in this way, more upstream data can be transmitted. Also, since the upstream band is expanded, the communication waiting time is reduced, and the overall transmission speed can be improved. On the contrary, the downlink data signal can be transmitted in the uplink band. For example, if the downlink data signal is transmitted to the second optical fiber cable in the uplink band, it is transmitted to the terminal device of the consumer via the photoelectric converter, the transceiver, the mixer, and the coaxial cable. If the upstream band also has a free band, the downstream band may be expanded by utilizing it. That is, the expansion of the upstream band and the expansion of the downstream band include mixing both. Of course, the upper limit frequency in the downlink direction may be expanded.

According to the multiplex transmission system of the data signal and the television signal described in claim 2, the frequency band of the signal transmitted to the first and / or the second optical fiber cable is the frequency band of the television signal. In the free band, which is characterized by the free band, the data signal is not mixed with the normal television signal. Therefore, the transmission method is excellent in convenience and does not affect the conventional TV reception.

According to the multiplex transmission method of the data signal and the television signal described in claim 3, the transmitting / receiving device of the optical node device is an Ethernet communication device, and at least the second communication device is used.
The optical fiber cable is characterized in that data is transmitted by the baseband method. Adopting the baseband method for at least the second optical fiber cable is
It means to adopt optical Ethernet. Due to the characteristics of the optical fiber, RFI (Radio-Frequency-Interference) radiation and interference are removed, and transmission errors are reduced. Therefore,
Quality transmission is guaranteed. Further, when the baseband system is adopted also in the latter stage of the Ethernet communication device, that is, the customer, the customer does not need the modulator / demodulator. That is, bi-directional communication is possible with half-duplex communication. Further, since the Ethernet communication device performs address control, for example, a large number of terminal devices can be provided at the subsequent stage. Therefore, the LAN can be easily formed.

According to the multiplex transmission system of the data signal and the television signal of claim 4, a modulator / demodulator is provided in the latter stage of the Ethernet communication device, and the data is transmitted between the optical node device and the customer by the RF modulation system. Characterize. As a result, a system using a conventional modem (cable modem),
For example, full duplex communication can be supported. Further, it is possible to frequency-multiplex and simultaneously communicate with a large number of terminal devices.
That is, the transmission method provides a more efficient LAN even to a customer who has a conventional modulator / demodulator.

An optical node device according to a fifth aspect is an optical node device used in the multiplex transmission system of the data signal and the television signal according to any one of the first to third aspects, A photoelectric converter that photoelectrically converts the input and output of an optical fiber cable, an Ethernet communication device that is connected to the latter stage of the photoelectric converter and that connects the input and output using an Ethernet communication method, and a television that connects the Ethernet communication device and a coaxial cable. And a mixer for mixing the signal and the data signal.

The photoelectric converter photoelectrically converts the input and output of the second optical fiber cable. That is, if there is an upstream signal from the Ethernet communication device, the electrical signal is converted into an optical signal and transmitted to the second optical fiber cable. If it is a downlink signal from the second optical fiber cable, the optical signal is converted into an electric signal and transmitted to the Ethernet communication device. The Ethernet communication device is, for example, a device conforming to IEEE802.3. That is, the Ethernet communication device is, for example, CSMA /
The idle state of the transmission path to be transmitted by the CD method is detected, and a signal is transmitted in the up or down direction. The baseband signal transmitted in the downlink direction is mixed with the television signal by the mixer and transmitted to the terminal device of the customer. Further, the baseband signal transmitted in the downlink in the downlink band from the terminal device of the consumer is input to the Ethernet communication device through the mixer in the reverse direction. The input baseband signal is converted into, for example, the optical Ethernet specification (100BASE-F specification), and is transmitted from the photoelectric converter to the second optical fiber cable as an optical signal. That is, if the conventional optical node device is provided with the photoelectric converter, the Ethernet communication device, and the mixer as described above, the upstream band can be expanded to easily form the LAN.

An optical node device according to a sixth aspect is an optical node device used in the multiplex transmission system of a data signal and a television signal according to the fourth aspect, wherein the input / output of the second optical fiber cable is photoelectrically converted. Connect the photoelectric converter, the Ethernet communication device connected to the latter stage of the photoelectric converter and connecting its input and output by the Ethernet communication method, the modulator / demodulator connected to the latter stage of the Ethernet communication device, and the modulator / demodulator and the coaxial cable. A mixer for mixing the television signal and the data signal is provided.

According to this configuration, in the optical signal node device according to the fifth aspect, a modulator / demodulator for mutually converting a baseband signal and an RF signal is provided between the Ethernet communication device and the mixer. That is, it is effective when the customer has a modulator / demodulator such as a cable modem. For example, when a customer transmits data as an RF modulated signal, the transmitted signal traces the coaxial cable in reverse and is input from the mixer to this modulator / demodulator. Then, the input signal is demodulated into an RF modulated signal into a baseband signal by a modulator / demodulator. Then, the demodulated baseband signal is output to the Ethernet communication device. The Ethernet communication device and the photoelectric converter transmit the baseband signal as an optical signal to the second optical fiber cable, that is, the central device.

On the contrary, the baseband signal received by the photoelectric converter and the Ethernet communication device from the second optical fiber cable is input to this modulator / demodulator and converted into an RF modulated signal. Then, the RF modulated signal is mixed with the television signal by the mixer and transmitted to the customer. A customer terminal device, for example, a cable modem, demodulates the RF modulated signal to obtain data. In this way, the consumer and the modulator / demodulator of the optical node device can communicate with each other by the RF modulation signal. Therefore, it becomes a convenient optical node device applicable to the communication system using the conventional cable modem.
Further, if the carrier frequency of the RF modulated signal is made different between upstream and downstream, full duplex communication becomes possible. Therefore, more efficient communication becomes possible.

The invention according to claim 7 is any one of claims 1 to 4.
In the invention described in any one of 1 above, the coaxial cable does not separate the upstream band and the downstream band. The invention of claim 8 is the invention of claim 7, wherein the coaxial cable is a transmission device such as a demultiplexer, a mixer, a high-pass filter, or a low-pass filter for separating the upstream band and the downstream band. It is characterized in that a circuit element for limiting the band and an amplifier for limiting the transmission direction are not provided.
According to the inventions of claims 7 and 8, the communication between the optical node and the customer does not perform band separation for upstream and downstream,
Since there are no circuit elements or amplifiers that limit the band, it is possible to arrange the upstream and downstream signals in an arbitrary band.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. The present invention is not limited to the examples below. (First Embodiment) FIG. 1 shows a C for explaining a multiplex transmission system of a data signal and a television signal (hereinafter, TV signal) of the present invention.
1 shows an ATV system. The figure is an example of the configuration. The CATV system of the present embodiment is characterized in that the conventional broadband transmission system is provided with an optical fiber cable 21 dedicated to data communication and an optical node device 30 having a digital function. That is, the feature is that a bypass path dedicated to data communication is formed. The feature is that both the broadband transmission method and the baseband transmission method are enabled in communication.

The CATV system of this embodiment is a CATV system.
Central device 22 provided in station 20, CATV station 20, optical fiber cable 23 that is a first optical fiber cable extended from central device 22, optical fiber cable 21 that is a second optical fiber cable, and optical node device 30 , A coaxial cable 25 extending from the optical node device 30, a branching device 26 provided at a predetermined portion of the coaxial cable 25, and a customer network 40 connected to the branching cable 24. In addition, the optical node device 30 includes the photoelectric converter 3
1, 32, receiver (Rx) 33, transmitter (Tx) 3
4, demultiplexer 35, Ethernet communication device 36, mixer 3
It consists of 7.

The consumer network 40 includes a branch / distributor 41 that branches / distributes, for example, a baseband signal propagated through the branch cable 24, a terminal device 42 connected to the branch / distributor 41, and a TV receiver 43. Composed.
The terminal device 42 is, for example, a computer device having an Ethernet interface. Further, the CATV station 20 has an internet interface (not shown), and the central unit 22 is connected to the internet network (not shown) through the central interface 22.

In the above structure, the transmitter 34 of the optical node device 30 is a device for transmitting data to the central device 22 by an RF modulated signal. The receiver 33 is the R from the central unit 22.
It is a device that receives an F-modulated signal. RF in this down direction
The modulation signal is an RF modulation signal modulated with a TV signal and data. As a result, in the upstream direction, for example, 10 MHz
-50 MHz band, and 90 MHz-770 MHz band is transmitted in the downstream direction (Fig. 2 (a)). For example, it is transmitted in the band U ₀ in the upstream direction and in the bands D _{0 to} D _n in the downstream direction. It should be noted that the data signal in the down direction is in any one of the bands of D _{0 to} D _n , and the free band of the normal TV signal is used.
Further, 50 MHZ to 90 MHZ are guard bands for separating the upstream band and the downstream band.

The Ethernet communication device 36 of the optical node device 30 is an Ethernet standard IEEE802.3.
It is a device that transmits and receives a digital signal in a baseband system of, for example, 100BASE-X, which is compliant with the above. 100B
ASE-X means connecting optical Ethernet and normal Ethernet. In this case, ie 100 Mbps
In the case of transmission by, the customer 40 and the optical node device 30 are set to a short distance of several hundred meters and the communication is performed in half duplex.

The operation of each component will be described according to the flow of signals. In this embodiment, the transmission by the broadband method is the same as the conventional one. That is, it is assumed that the TV signal and the data signal are transmitted by the RF modulation signal in the frequency band shown in FIG. Therefore, only the case of bidirectionally transmitting a signal by the baseband method will be described here. For example, the consumer 40 transmits data from the terminal device 42 as a baseband signal (FIG. 1). Baseband signal is branched /
Distributor 41, branch cable 24, brancher 26, mixer 3
7 is reversed and the data is input to the Ethernet communication device 36. At this time, if the transmission method is 100BASE-X,
Since the transmission rate is 100 Mbps, in the frequency band, for example, the band U ₁ (an empty band of the TV band) shown in FIG. 2B is used for transmission.

The Ethernet communication device 36 receives the signal in conformity with the Ethernet standard IEEE802.3 and transmits it to the photoelectric converter 32 in the next stage by the 100BASE-X baseband method. Then, the photoelectric converter 32
Sends the signal to the central unit 22 via the second optical fiber 21.
Send to (optical Ethernet). The upstream data signal is transmitted in the band thus expanded to the TV band. A part of the baseband signal transmitted in the downlink band passes through the mixer 37 and is demultiplexed by the demultiplexer 35 into the receiver (Rx), but is attenuated because the direction is different. . Further, it does not affect the TV signals of other bands received from the central unit 22.

On the contrary, the data signal transmitted from the central unit 22 to the optical fiber cable 21 by the optical Ethernet system is converted into an electric signal by the photoelectric converter 32, and similarly inputted to the Ethernet communication unit 36. The Ethernet communication device 36 transmits a signal in a half-duplex in the downlink direction according to the Ethernet specifications. The transmitted data signal is mixed by the mixer 3
It is mixed with the TV signal at 7, and the branching device 26 and the branching cable 2
4 to the terminal device 42 of the corresponding consumer 40.

As described above, if the photoelectric converter 32, the Ethernet communication device 36, and the mixer 37 are newly added to the conventional optical node device, the consumer 40 uses the empty space of the TV band for the central device 22. , Data can be transmitted in baseband signals. That is, the number of channels in the upstream direction increases, and the communication efficiency in the upstream direction can be improved as compared with the conventional case. Further, the Ethernet communication device 36 can include a large number of terminal devices 42 at the subsequent stage. Therefore, the LAN can be easily expanded. Further, as described above, since the upstream of the Ethernet communication device 36 is the optical Ethernet, the RFI (Radio-Frequency-Interferenc
The radiation and interference of e) are eliminated and transmission errors are reduced. Therefore, the quality can be improved. In the above description, the upstream band is 100 MHz band (100 Mbp
However, it may be 700 MHz or more. In that case, the band U _{n + 1} is used (FIG. 2B). Further, the band used may be the GHz band. So-called gigabit
It may be Ethernet. As a result, the band can be expanded.

(Second Embodiment) FIG. 3 shows a second embodiment for explaining the multiplex transmission system of the present invention. The figure shows an example of a CATV
It is a system configuration diagram. Incidentally, FIG. 1 described in the first embodiment
Parts having the same functions as are given the same reference numerals. The first embodiment is an example of half-duplex communication between the optical node 30 and the customer 40 by the baseband method. The present embodiment is characterized in that a signal between the optical node 30 and the customer 40 is replaced with an RF modulation signal and full duplex communication is performed by the RF modulation method. Therefore, the modulator / demodulator 3 is provided between the Ethernet communication device 36 and the mixer 37 of the optical node device 30 of the first embodiment.
Eight. As a result, it is possible to adapt to the consumer 40 having the cable modem 44 which is a conventional modulator / demodulator.

For example, when the consumer 40 transmits data as an RF modulated signal from the terminal device 42 and the cable modem 44, the transmitted signal is sent to the branch / divider 41, the branch cable 24, the branch device 26 and the mixer 37. Via modem 38
Entered in. At this time, the frequency band used is as shown in FIG.
An empty band of the television band shown in (b) is arbitrarily selected. For example, the band U _n near 770 MHz, or 7
It is transmitted to the modulator / demodulator 38 as an RF modulated signal using the GHz band U _{n + 2} above 00 MHz.

The modulator / demodulator 38 demodulates the RF modulated signal into a baseband signal of, for example, 100BASE-X specifications, and transmits it to the Ethernet communication device 36 at the next stage. Then, the Ethernet communication device 36 and the photoelectric converter 3
2 sends it over optical Ethernet to the central unit 22.
On the contrary, the baseband signal input from the central device 22 to the Ethernet communication device 36 by optical Ethernet is converted into, for example, 100BASE-X specifications and input to the modulator / demodulator 36 at the next stage. The modulator / demodulator 36 modulates a carrier wave in a predetermined band by the baseband signal and transmits it as an RF modulated signal to the subsequent stage. The frequency band used at this time is shown in FIG.
For example, the band D _n of the free band of the television band of (b)
Is. Then, the RF modulated signal is mixed with the TV signal by the mixer 37 and transmitted to the customer 40. The cable modem 44 of the customer 40 demodulates it into a baseband signal and transmits it to the terminal device 42. In this way, full duplex communication is performed between the customer 40 and the optical node device 30 using the RF modulation signal.

As described above, in the transmission system of the present invention, the frequency structure in the downstream direction between the optical node device 30 and the customer 40 is the TV signal band, the data signal band in the downstream direction, and the data signal band in the upstream direction. Can be mixed. In this way, it is possible to set the bands of the data signals in the up direction and the data direction in the down direction to be different, so
Up to 2 can be fully duplexed. That is, customer 4
0 to the central unit 22 completely e.g. 100 BAS
Communication becomes possible by the EX method. Therefore, compared to the half-duplex baseband method of the first embodiment, the transmission method is more efficient. Furthermore, if different bands (carrier frequencies) are given to the customers 40 and they are frequency-multiplexed and communicated, a large number of terminal devices 42 can be connected. Therefore, large-scale L
It is also possible to form an AN.

In all the above embodiments, the coaxial cable 2
In 5, the upstream band and the downstream band are not separated. That is, in the coaxial cable 25 (at least the main line), a circuit element that limits the transmission band such as a duplexer, a mixer, a high-pass filter, or a low-pass filter that separates the upstream band and the downstream band, and the transmission. No direction limiting amplifier is provided. Thereby, in the communication between the optical node 30 and the customer 40, it is possible to arrange the upstream and downstream signals in an arbitrary band, and the upstream transmission capacity and the downstream transmission capacity can be set arbitrarily. It will be possible. One coaxial cable 25 connected to one optical node 30
00 terminal device can be connected.

(Modification) Although one embodiment representing the present invention has been described above, various modifications can be considered. For example, in the second embodiment, the customer 40 installs the modulator / demodulator 38 and the Ethernet communication device 36 in the optical node device 30, and
Although the F-modulated signal was used to communicate with the central unit 22, instead of the modulator / demodulator 38 and the Ethernet communication unit 36 as shown in FIG. 4, the demultiplexer 35a and the transmitter (Tx) 3 having different separation bands were used.
4a and the receiver (Rx) 33a may be provided. As a result, the frequency structure used for the transmitter (Tx) 34a, the receiver (Rx) 33a and the customer 40 is separated as shown in FIG. 5, for example. That is, the empty band of the television band of 90 to 770 MHz is the upstream band U _{0 of} 90 to 400 MHz,
.., U _n and the downlink band D _{0 of} 450 to 770 MHz,
., D _n . Where 400-450MHz
Is a so-called guard band. This structure upstream bandwidth U ₀ from customers 40, · ·, RF modulated signals transmitted by one of the band of the U _n is a branched cable 24, splitter 2
6. Transmitter (Tx) via mixer 37 and duplexer 35a
34a. That is, the conventional 10 to 50 MHz upstream band is expanded and transmitted. You may comprise in this way.

In the first and second embodiments,
Although no particular amplifier is provided in the optical node device 30, a bidirectional amplifier may be provided after the demultiplexer 35, for example. The same effect can be obtained by providing the mixer 37 at the front stage or the rear stage of the bidirectional amplifier and connecting the Ethernet communication device 36 as in the first embodiment.

In the second embodiment, the cable modem 44 directly transmits the upstream signal in the downstream band. However, the upstream signal specification of the cable modem 44 is 10 to 50 MHz.
In that case, a frequency converter (not shown) may be provided in the cable modem 44 and the carrier wave may be shifted to an empty band in the downlink band. Similarly, the upstream band can be expanded.

[Brief description of drawings]

FIG. 1 is a block diagram of a CATV system using a multiplex transmission method of a data signal and a television signal and an optical node device thereof according to a first embodiment of the present invention.

FIG. 2 is a frequency band structure diagram according to the first embodiment.

FIG. 3 is a block diagram of a CATV system using a multiplex transmission system of a data signal and a television signal and its optical node device according to a second embodiment of the present invention.

FIG. 4 is a block diagram of a CATV system using a multiplex transmission system of a data signal and a television signal and its optical node device according to a modification of the present invention.

FIG. 5 is a frequency band structure diagram according to a modification.

FIG. 6 is a block diagram of a CATV system in which a conventional transmission method is used.

FIG. 7 is a configuration block diagram of an optical node device according to a conventional example.

[Explanation of symbols]

20 ... CATV station 22 ... Central device 21, 23 ... Optical fiber cable 24 ... Branch cable 25 ... Coaxial cable 26 ... turnout 30 ... Optical node device 31, 32 ... Photoelectric converter 33 ... Receiver 34 ... Transmitter 35 ... duplexer 36 ... Ethernet communication device 37 ... Mixer 38 ... Modulator / demodulator 40 ... Consumer 41 ... Branching / Distributor 42 ... Terminal device 43 ... TV receiver 44 ... Cable modem

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04N 7/22 F term (reference) 5C063 AB03 AB07 AB09 AB11 AC01 CA23 DA03 DA07 EB07 EB32 5C064 BA02 BB05 BC10 BC11 BC14 BC16 BC20 BC21 BC25 BD02 BD08 EA01 5K002 AA05 BA04 DA01 DA04 FA01 GA01

Claims (8)

[Claims] 1. A transmission for frequency-multiplexing a data signal and a television signal by using a first optical fiber cable extended from a central device, an optical node device, and a coaxial cable extended to a customer. A system, wherein a second optical fiber cable is provided between the central device and the optical node device, and a photoelectric converter that converts input and output of the second optical fiber cable to the optical node device; A mixer for mixing the input and output of the transmitter / receiver with the coaxial cable is provided, and the television signal is transmitted in the downstream direction through the first optical fiber cable, and the data signal is transmitted through both the first and / or second optical fiber cable. A multiplex transmission system of a data signal and a television signal, which is characterized in that it is transmitted in the same direction. 2. The frequency band of the data signal transmitted to the first and / or the second optical fiber cable is an empty band of the frequency band of the television signal. A multiplex transmission system for data signals and television signals. 3. The transmission / reception device is an Ethernet communication device, and data is transmitted by a baseband method at least in the second optical fiber cable. A multiplex transmission system for data signals and television signals. 4. The data signal according to claim 3, wherein a modulator / demodulator is provided in the latter stage of the Ethernet communication device, and data is transmitted between the optical node device and the customer by an RF modulation method. A multiplex transmission method for television signals. 5. An optical node device used in the multiplex transmission system of a data signal and a television signal according to claim 1, wherein the input / output of the second optical fiber cable is photoelectric. A photoelectric converter for conversion, an Ethernet communication device connected to the latter stage of the photoelectric converter and converting its input and output into an Ethernet communication system, connecting the Ethernet communication device and the coaxial cable, the television signal and the data An optical node device comprising: a mixer for mixing signals. 6. An optical node device used in the multiplex transmission system of a data signal and a television signal according to claim 4, wherein a photoelectric converter for photoelectrically converting input and output of the second optical fiber cable; An Ethernet communication device that is connected to the rear stage of the converter and that connects its input and output by an Ethernet communication system, a modulator / demodulator connected to the rear stage of the Ethernet communication device, and the television signal by connecting the modulator / demodulator and the coaxial cable. An optical node device comprising: a mixer for mixing the data signals. 7. The multiplex transmission system for a data signal and a television signal according to claim 1, wherein an upstream band and a downstream band are not separated in the coaxial cable. 8. A circuit element for limiting a transmission band such as a demultiplexer, a mixer, a high-pass filter, or a low-pass filter for separating an upstream band and a downstream band, and a transmission direction in the coaxial cable. 8. The multiplex transmission system for a data signal and a television signal according to claim 7, wherein no limiting amplifier is provided.