KR20040094141A - Media Integrated Home Gateway System Using Optical Fiber - Google Patents

Abstract

PURPOSE: A multimedia integrated home gateway system using optical fibers is provided to receive cable TV signals, satellite signals and Ethernet signals and transmit the signals to subscribers through optical fibers without deteriorating a transmission speed and quality. CONSTITUTION: A multimedia integrated home gateway system includes a central part(310) and a remote part(320). The central part includes a satellite signal distributor for distributing a satellite signal received through one satellite broadcast receiving antenna into multiple satellite signals, a cable TV signal distributor for distributing a cable TV signal into multiple cable TV signals, an Ethernet signal distributor for distributing an Ethernet signal into multiple Ethernet signals, a CT(Central Terminal) optical converter for receiving the satellite signals, cable TV signal and Ethernet signals to convert the signals into optical signals and receiving an Ethernet downward signal distributed by the Ethernet signal distributor to convert the signal into an electric signal, and an optical signal multiplexer for combining or separating the optical signals input/output to/from the CT optical converter to connect the optical signals to an optical fiber. The remote part includes an optical signal demultiplexer for combining or separating optical signals transmitted/received through the optical fiber, and an RT(Remote Terminal) optical converter for converting the optical signals separated by the demultiplexer into a satellite signal, a cable TV signal and an Ethernet downward signal and converting an Ethernet upward signal into an optical signal.

Description

Media Integrated Home Gateway System Using Optical Fiber

The present invention is an integrated media system using optical fiber, which is an integrated transmission system that enables subscribers using cable TV, satellite broadcasting, and internet services to receive high-speed Internet and integrated multimedia services using optical fiber. A home gateway system.

As is well known, the cable TV network is provided through a coaxial cable that is connected to a TV in each home and provides TV broadcasting. The Internet service is provided through a cable modem using a band other than the frequency for TV broadcasting through a coaxial cable. It is either serviced or through ADSL or VDSL over a telephone line. In addition, satellite broadcasting is separately provided by satellite antennas installed in each home, and satellite signals in GHz band are received through coaxial cable to transmit more than 30m for the reason that cannot exceed 30m. A repeater must be installed, which increases the noise and makes the signal distorted.

FIG. 1 is a schematic block diagram of transmitting and receiving cable TV signals and Internet signals in a conventional fiber TV coaxial (HFC) network.

The existing cable TV and Internet data service system is a cable modem 122 or CATV of the subscriber 120 coaxially through the HFC network at the head end 110, such as the Internet service provider 112 or CATV program provider 114. A cable TV signal or an Internet signal is transmitted to 124, and serviced subscribers 120 need a separate device, such as a cable modem 122, and are also coaxially connected so that the speed decreases due to deterioration of the line. Followed by a decrease in broadcast quality.

By the way, the conventional cable TV and Internet service system configured as described above are increasingly pursuing a high-speed, high-quality image and data transmission function. Recently, the number of Internet service subscribers is increasing based on the broadband transmission characteristic of 10Mbps, and the sudden increase in traffic causes traffic congestion on the Internet, which slows down the transmission speed and transmits large data such as video service. There is a problem that the service can not be provided smoothly to the user or subscriber. In addition, although optical transmission is performed up to the ONU (Optical Node Unit) 130, the transmission to the subscriber system is inevitably deteriorated in transmission quality by using an analog coaxial amplifier.

2 is a system configuration diagram in which a conventional satellite signal receiver is individually installed in each home to receive through a coaxial, and is configured to be viewed only when each subscriber installs a separate satellite signal receiver antenna 210. In addition, by using the coaxial cable 220 as a transmission medium for the signal received from the satellite receiving antenna 210, there is a limit in the long-distance transmission, which can lead to degradation of transmission quality.

In addition, as shown in FIG. 1 and FIG. 2, each subscriber should be provided with a separate device in order to transmit and receive cable TV signals, Internet signals, and satellite signals.

Accordingly, an object of the present invention is to provide a system for transmitting existing cable TV signals, satellite signals, and high speed Ethernet signals to subscribers through optical fibers without deterioration in speed and quality. And to be compatible with each other in the transmission of digital signals to enable the transmission of all signals for future evolution of systems and networks.

In addition, singlemode optic fiber or multimode optic fiber can be used, but it is easy to install optical cable of subscriber end and cheap installation equipment by using optical fiber such as plastic optic fiber (POF). The goal is to achieve FTTH (Fiber To The Home).

1 is a schematic block diagram for transmitting and receiving cable TV and Internet signals in a conventional hybrid fiber coaxial (HFC) network.

2 is a schematic configuration diagram of receiving an existing satellite signal.

Figure 3 is a block diagram showing the configuration of a media integrated home gateway system using an optical fiber of the present invention.

4 is a block diagram of a concentrator in a media integrated home gateway system of the present invention;

5 is a block diagram of the input and output of the cable TV signal distribution apparatus in the concentrating unit of the present invention.

Figure 6 is a block diagram of the input and output of the satellite signal distribution apparatus in the concentration unit of the present invention.

Figure 7 is a block diagram of the input and output of the Ethernet signal distribution apparatus in the concentrator of the present invention.

8 is a block diagram showing all-optical conversion for satellite signals and cable TV signals in the CT optical conversion apparatus in the concentrating part of the present invention.

Fig. 9 is a block diagram showing all-optical / optoelectric conversion for an Ethernet signal in a CT optical converter in a concentrating unit and an RT optical converter in a remote unit.

10 is a block diagram of an optical signal mux at a concentrator and an optical signal demux at a remote unit for connection of an optical signal to an optical fiber of the present invention.

11 is a configuration diagram for the electrical input and output of satellite signals, cable TV signals and Ethernet signals through the photoelectric / all-optical conversion in the remote portion of the present invention.

The present invention has the following configuration to achieve the above object.

According to an aspect of the present invention, a media integrated home gateway system using an optical fiber of the present invention is a satellite signal distribution device for distributing satellite signals received through one satellite broadcast receiving antenna into a plurality of satellite signals: one cable TV signal. Cable TV signal distribution device for receiving and distributing a plurality of cable TV signals: Ethernet signal distribution device for receiving one Ethernet signal to be divided into a plurality of Ethernet signals: Satellite signal distributed in the satellite signal distribution device, and the cable A cable TV signal distributed by the TV signal distribution device and an Ethernet downlink signal distributed by the Ethernet signal distribution device are respectively received and converted into an optical signal, and a CT that receives an Ethernet uplink signal, which is an optical signal, and converts the signal into an electrical signal ( Central terminal) optical conversion device: combining or splitting the optical signal input and output from the CT optical conversion device Optical signal demux for separating or combining the optical signal transmitted and received via the optical fiber; and an optical signal demux for connecting the optical signal mux: and an optical signal separated by the optical signal demux electrical signal A remote unit including: a remote terminal (RT) optical conversion device for converting a satellite signal, a cable TV signal, an Ethernet downlink signal, and converting an Ethernet uplink signal, which is an electrical signal directed to a concentrator, into an optical signal; It is done.

Hereinafter, exemplary embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing the configuration of a media integrated home gateway system using the optical fiber of the present invention.

As shown in FIG. 3, the media integrated home gateway system using the optical fiber of the present invention includes a concentrator 310 and a remote 320.

The concentrator 310 receives a satellite signal, a cable TV signal, and an Ethernet downlink signal, converts the signal into an optical signal, and transmits the optical signal to the remote unit 320 through an optical fiber including a plastic optical fiber (POF). It receives the Ethernet uplink signal from the remote unit 320 through the optical fiber and converts it into an electrical signal.

The satellite signals in the transmission band for each medium fall in the GHz range as one of a number of bands known as the L, C, Ku and X bands. Earth station terminals downconvert signals to a range of about 950 MHz to 2150 MHz (L-band), mainly by a low noise block converter (LNB) which forms part of most satellite signal receiving antennas. These signals are difficult to transmit over long coaxial links. In this regard, when the satellite signal is converted into an optical signal and then transmitted, a long distance transmission is possible and all signals in the L-band band can be transmitted.

The transmission band of cable TV is using 450MHz or 750MHz, but it is required to use the digital broadcasting channel up to 860MHz band. In this regard, the present invention can transmit 860 MHz.

Ethernet signals also support both Gigabit Ethernet and 10 / 100Mbps.

4 is a block diagram of a concentrator in the media integrated home gateway system of the present invention.

The concentrator 310 has a cable TV signal distribution device 410, a satellite signal distribution device 420, and an Ethernet signal distribution device as described above to receive satellite and cable TV and Ethernet signals for all-optical / photoelectric conversion. 430, a CT light conversion device 440, and an optical signal mux 450 are installed. The CT light conversion device 440 includes an optical transmitter through which a signal from the concentrator 310 to the remote unit 320 passes, and an optical receiver through which a signal from the remote unit 320 to the concentrator 310 passes. do.

One cable TV signal, satellite signal, Ethernet signal is passed through the cable TV signal distribution device 410, satellite signal distribution device 420, Ethernet signal distribution device 430, respectively, N satellite signals, cable TV signal, It is distributed as an Ethernet signal. The distributed N signals are converted into optical signals through the CT optical converter 440. Optical signals converted from satellite signals and cable TV signals have a wavelength of λ ₁ , and optical signals converted from Ethernet signals It has a wavelength of λ ₂ . The optical signals are combined with each other in the optical signal mux 450. One optical signal λ ₁ converted from the cable TV signal and one downlink optical signal λ ₂ converted from the Ethernet signal are combined to form one optical fiber. And one optical signal λ ₁ converted from the satellite signal and one uplink optical signal λ ₂ converted from the incoming Ethernet signal transmitted from the remote part 320 are combined to one optical fiber. Connected. Here, satellite signals and cable TV signals have only output characteristics for the forward direction, whereas signals for Ethernet data have a bidirectional transmission and reception function. Therefore, the signal for the Ethernet data includes a downward signal from the concentrator 310 to the remote unit 320 and an upward signal from the remote unit 320 to the concentrator 310.

5 is a configuration diagram of the input and output of the cable TV signal distribution apparatus in the concentrator of the present invention.

Cable TV signal distribution device 410 is a device for receiving and receiving cable TV signal amplification and distribution of a plurality of cable TV signals, the RF amplifier 510 for receiving a cable TV signal to amplify the signal and the RF amplifier Splitter 520 for outputting the amplified RF signal through. The cable TV signal distribution device is designed to minimize noise and distortion and improve transmission quality of the cable TV signal 50 ~ 860MHz signal transmitted from the HFC network, and makes a plurality of output signals with one input.

6 is a block diagram of the input and output of the satellite signal distribution apparatus in the concentrator of the present invention.

The satellite signal distribution device 420 is a device for receiving satellite signals (950 to 2150 MHz) through a single satellite receiver antenna and distributing them into a plurality of satellite signals. The satellite signal distribution device (LNB) receives satellite signals from a satellite antenna RF amplifier 610 for amplifying the L-band signal output through the) and a splitter 620 for distributing the RF signal amplified by the RF amplifier to the N outputs.

7 is a configuration diagram of the input and output of the Ethernet signal distribution apparatus in the concentrator of the present invention.

The Ethernet signal distribution device 430 is a device for distributing a Gigabit Ethernet signal or an Ethernet signal having a 10 / 100Mbps transmission rate into N signals. The Ethernet signal distribution device 430 receives a splitter 710 that receives one Ethernet signal and distributes the signal to N Ethernet signals. Include. This allows the high-speed Internet to be used smoothly, and has a transmission speed of up to 100Mbps per subscriber.

8 is a block diagram showing all-optical conversion for satellite signals and cable TV signals in the CT optical conversion apparatus in the concentrating unit of the present invention.

The CT light conversion device 440 is a device for converting the signal coming from each distribution device into a format of data that can be transmitted to the optical fiber, such as plastic optical fiber through all-optical conversion, amplifying the signal received from each distribution device and gain It plays a role of adjusting and outputs the laser diode (LD) by driving the laser diode (820). The laser diode 820 is an element that receives an electrical signal and converts it into an optical signal.

In this case, when the converted signal is a signal output from the satellite signal distribution device 420 or the cable TV signal distribution device 410, the CT optical conversion device 440 receives the signal and amplifies the RF amplifier 810 and RF. The laser diode 820 converts the signal amplified by the amplifier into an optical signal. In contrast, when the converted signal is an Ethernet signal, the CT optical converter 440 receives the signal and converts the signal into an optical signal. 910 or a photodiode 920 for receiving an optical signal from the remote unit 320 and converting it into an electrical signal, which will be described later with reference to FIG. 9. In other words, when the converted signal is an Ethernet signal, the converted signal is immediately converted into an optical signal.

In addition, the CT optical conversion device 440 is a detector circuit 830 for adjusting the output to extract a portion of the signal passing through the RF amplifier to maintain a constant output signal of the RF amplifier 810, RF input signal After the amplification through the RF amplifier 810 includes a matching circuit 840 for the impedance matching function for minimizing the distortion of the signal to all-optical conversion through the laser diode 820.

FIG. 9 is a block diagram showing all-optical / optoelectric conversion for an Ethernet signal in a CT light conversion device in a concentrating unit and an RT light conversion device in a remote unit.

As mentioned above, satellite signals and cable TV signals have only output characteristics for the forward direction, whereas signals for Ethernet data have bidirectional transmission and reception functions. Accordingly, the signal for the Ethernet data includes an uplink signal from the remote unit 320 to the concentrator 310 along with a downlink signal from the concentrator 310 to the remote unit 320. In the CT light converter of the concentrator 310 and the RT light converter of the remote unit 320 may be converted from an electrical signal to an optical signal or an optical signal to an electrical signal. That is, in the CT optical converter of the concentrating unit 310, the Ethernet downlink signal is converted from the electrical signal to the optical signal through the laser diode 910, and the Ethernet uplink signal is converted from the optical signal to the electrical signal through the photodiode 920. Is converted. In addition, in the RT optical conversion device of the remote unit 320, the Ethernet downlink signal is converted from the optical signal to the electrical signal through the photodiode 920, and the Ethernet uplink signal is converted from the electrical signal to the optical signal through the laser diode 910. Is converted.

FIG. 10 is a block diagram illustrating an optical signal mux at a concentrator and an optical signal demux at a remote part for connecting an optical signal to an optical fiber of the present invention.

The optical signal mux 450 converts the data transmitted from the distribution device of each medium and then condenses the optical output to an optical fiber such as a plastic optical fiber (POF) and also uses a WDM (Wavelength) to use a small number of plastic optical fibers. Division Multiplexer) element 1070 is used to minimize the use of optical fiber cables.

For the condensing, two wavelengths of λ ₁ and λ ₂ are used and two optical fibers such as plastic optical fiber cables are used. An optical signal having a wavelength λ ₁ is an optical signal converted from a cable TV and a satellite signal, and an optical signal having a wavelength λ ₂ is an optical signal converted from an Ethernet signal. As described above, cable TV and satellite signals have only output characteristics for the forward direction, but signals for Ethernet data have a function of bidirectional transmission and reception. Therefore, one optical fiber 1050 of the two optical fibers is coupled to the optical signal (λ ₁ ) 1010 for cable TV transmission and the downlink optical signal (λ ₂ ) 1020 for Ethernet data transmission, and the other optical fiber 1060 The optical signal (λ ₁ ) 1030 for satellite signal transmission and the uplink optical signal (λ ₂ ) 1040 for Ethernet data reception are combined. As a result, optical signals for cable TV transmission and optical signals for satellite signal transmission are output at the same wavelength to each of the two optical fibers, and optical signals for Ethernet data are transmitted and received at the same wavelength.

11 is a block diagram of the electrical output of the satellite signal, cable TV signal and Ethernet signal through the photoelectric / all-optical conversion in the remote portion of the present invention.

The optical signals output from the concentrator 310 are transmitted to the remote unit 320 through an optical fiber such as a plastic optical fiber. The optical signal demux 1110 of the remote unit 320 receives the optical signals and separates the optical signals using a WDM device. The separation process is opposite to the combining process of the optical signals described with reference to FIG. 10. That is, in one optical fiber 1050 of the two optical fibers, the optical signal λ ₁ 1010 for transmitting the cable TV and the downward optical signal λ ₂ 1020 for transmitting the Ethernet data are separated, and the remaining optical fibers 1060 are separated. In FIG. ₁ , an optical signal (λ ₁ ) 1030 for satellite signal transmission and an uplink optical signal (λ ₂ ) 1040 for Ethernet data reception are separated. Each optical signal is input to the RT optical converter 1120 and converted into an electrical signal, a satellite signal, a cable TV signal, and an Ethernet downlink signal, by a photodiode that converts the optical signal into an electrical signal. Is transmitted to the concentrator through a laser diode that converts the electrical signal into an optical signal. The RT optical conversion device 1120 includes an optical receiver through which a signal from the concentrator 310 to the remote unit 320 passes and an optical transmitter through which a signal from the remote unit 320 to the concentrator 310 passes. do. In addition, in the remote unit 320, as in the concentrator 310, the Ethernet signal communicates in both directions. Through this process, satellite signals, cable TV signals, and Ethernet signals are transmitted to each subscriber.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As described in detail above, according to the media integrated home gateway system using the optical fiber according to the present invention, by processing a cable TV signal, a satellite signal and an Ethernet signal in one device to provide each subscriber with all the broadcast and high-speed communication Both analog and digital broadcasts and the Internet can be used to receive high-quality and high-speed services. In addition, the use of plastic optical fiber to realize the FTTH has the advantage that can significantly reduce the burden on the subscribers because it can take a cheaper installation compared to the conventional optical cable.

Claims (11)

Satellite signal distribution device for distributing satellite signals received through one satellite receiving antenna into multiple satellite signals: Cable TV signal distribution device that receives one cable TV signal and distributes it to multiple cable TV signals: Ethernet signal distribution device that receives one Ethernet signal and distributes it to multiple Ethernet signals: The satellite signal distributed by the satellite signal distribution device, the cable TV signal distributed by the cable TV signal distribution device, and the Ethernet downlink signal distributed by the Ethernet signal distribution device are respectively received and converted into optical signals, and the optical signal. CT optical converter for receiving an Ethernet uplink signal and converts it into an electrical signal: And A concentrator including: an optical signal mux for coupling or separating the optical signals input and output from the CT optical converter to be connected to the optical fiber; and Optical signal demux for separating or combining the optical signal transmitted and received through the optical fiber: And RT optical conversion device converts the optical signal separated by the optical signal demux into a satellite signal, a cable TV signal, an Ethernet downlink signal, which is an electrical signal, and converts an Ethernet uplink signal, which is an electrical signal directed to a concentrator, into an optical signal. Media integrated home gateway system using a fiber, characterized in that consisting of: a remote unit comprising a. The method of claim 1, The satellite signal distribution device includes an RF amplifier for receiving a satellite signal from a satellite receiving antenna and amplifying the signal; and a splitter for outputting the amplified RF signal through the RF amplifier. Media integrated home gateway system. The method of claim 1, The cable TV signal distribution device includes an RF amplifier receiving one cable TV signal and amplifying the signal; and a splitter outputting the amplified RF signal through the RF amplifier. Gateway system. The method of claim 1, The Ethernet signal distribution apparatus is a media integrated home gateway system using an optical fiber, characterized in that it comprises a splitter for receiving one Ethernet signal to distribute the N Ethernet signals. The method of claim 1, The CT optical conversion device may include: an RF amplifier for receiving and amplifying a signal output from the satellite signal distribution device or the cable TV signal distribution device; and a laser diode for converting the signal amplified through the RF amplifier into an optical signal; Media integrated home gateway system using an optical fiber, characterized in that the. The method of claim 1, The CT optical conversion device is a media integrated home gateway system using an optical fiber, characterized in that it comprises a laser diode for receiving the Ethernet down signal output from the Ethernet signal distribution device to convert to an optical signal. The method of claim 1, The CT optical conversion device is a media integrated home gateway system using an optical fiber, characterized in that it comprises a photodiode receiving an Ethernet uplink signal, which is an optical signal, from the remote unit and converting the signal into an electrical signal. The method of claim 1, The optical signal mux media integrated home gateway system using an optical fiber, characterized in that it comprises a WDM element for combining or separating the optical signal input and output from the CT optical conversion device. The method of claim 1, The optical signal demux is a media integrated home gateway system using an optical fiber, characterized in that it comprises a WDM device for separating or combining the optical signal transmitted and received through the optical fiber. The method of claim 1, The RT optical converting device includes a photodiode for receiving an optical signal separated from the optical signal demux and converting it into an electrical signal, a satellite signal, a cable TV signal, and an Ethernet downlink signal. Home gateway system. The method of claim 1, The RT optical conversion device is a media integrated home gateway system using an optical fiber, characterized in that it comprises a laser diode for converting an Ethernet up signal, which is an electrical signal directed to the concentrator, into an optical signal.