KR101454854B1 - RF PON base duplex transmission system - Google Patents

Abstract

An ARP phone based bi-directional transmission system is disclosed. The ARP-based bidirectional transmission system according to the present invention transmits an RF broadcast and a PON Internet signal to a subscriber terminal in a single optical core with a separate wavelength, converts broadcasts received in an RF system from an OMT at a subscriber terminal to IP, The IP terminal STB provides the broadcast, and the downlink broadcasting information such as the EPG and the uplink data signal such as the VoD request are transmitted to the PON Internet path together with the Internet data, and the home IP terminal apparatus transmits the tuner , Demodulator, and MPEG When the OMT requests a new IP function, the OMT tunes, de-modulates, and encapsulates the channel and sends it to the IP terminal device.
Also, a protocol for exchanging channel change information between the OMT and the IP terminal apparatus is provided for this purpose.
Accordingly, it is possible to simultaneously transmit the RF broadcasting and the PON Internet signal through the single optical core, thereby maintaining the advantage of cable broadcasting in which all channels are transmitted to the subscriber side, thereby providing a gigabit Internet transmission speed.

Description

Technical Field [0001] The present invention relates to an RF PON base duplex transmission system,

The present invention relates to a bi-directional transmission system based on a radio frequency (PON) passive optical network, and more particularly, to a high-quality, high-quality broadcast and gigabit internet service based on a fiber to the home (FTTH) It is possible to simultaneously implement RF optical transmission technology and PON technology to provide simultaneously and transmit data that can provide a service to a home terminal device in the home or an IP (internet protocol) terminal device in the home, And more particularly, to an ARP phone-based bi-directional transmission system.

Generally, digital cable broadcasting adopts a scheme of transmitting all channels from a broadcasting signal through a hybrid fiber coax (HFC) to a set top box (STB) in the home using an RF system.

The Internet is provided through the same HFC network using broadcast data service interface specifications (DOCSIS) technology. The cable modem termination system (CMTS) ), The transmission speed is determined according to the specification of the CM of the subscriber unit and the bandwidth of the frequency band, and the service can be provided up to 300 Mbps downlink and 100 Mbps uplink.

On the other hand, prior art related to cable broadcasting is disclosed in Korean Patent Application No. 2005-0082234 and Korean Patent Application No. 2006-0124795.

Meanwhile, bidirectional service of cable broadcasting is provided through CMTS used for cable Internet.

Since the cable broadcasting is transmitted through the RF system, it is possible to receive the cable broadcasting only from the RF STB.

In addition, in order to increase the speed of the cable Internet, it is necessary to transmit data by bundling several frequency bands, but it is difficult to secure additional frequency band due to a shortage of cable broadcasting channels.

Especially, in case of upward internet, it is necessary to provide both bidirectional broadcasting and internet service using 5 ~ 42 MHz, so that the uplink internet bandwidth is insufficient.

In addition, CMTS, which is used for internet and bi - directional data broadcasting, is still dependent on expensive foreign equipment.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems of the prior art described above, and it is an object of the present invention to provide a single interface of RF optical transmission technology and PON technology for providing high quality, high quality broadcast and gigabit internet service on FTTH basis, And it is an object of the present invention to provide an ARP phone-based bidirectional transmission system for simultaneously transmitting data capable of providing a service to a terminal device or an IP terminal device to provide a broadcast to an IP terminal device.

According to an aspect of the present invention, there is provided a broadcast signal receiving apparatus including: a broadcast signal unit including a QAM modulator for modulating a broadcast signal, an AM light transmitter, and an optical amplifier; A distribution center including an L3 switch connected to an internet cable and an internet signal unit composed of an OLT; A multiplexer connected to the distribution center for receiving the optical amplifier and the OLT signal; An optical media terminal connected to the meltdyper via an optical cable and receiving RF broadcast and PON signals and broadcasting information and Internet transmission; And a set-top box receiving the signal from the optical media terminal and transmitting the channel selection information of the viewer to the subscriber terminal device.

The optical media terminal includes a WDM multiplexer connected to the optical cable, a burst mode optical transceiver for bidirectional communication with the WDM multiplexer, a PON MAC processor for bidirectional communication with the burst mode optical transceiver, and a gigabit An RF video converter including an Ethernet switch and receiving a signal from the WDM multiplexer; a tuner unit receiving a signal from the RF video converter; and a demodulator, a main process, and a Ts-to-IP processor.

The optical media terminal recovers an electrical RF signal from a broadcasting optical signal received through an optical cable and processes it internally for a broadcasting service. The optical media terminal tunes a corresponding frequency according to input channel information, demodulates it into MPEG2-TS Converted into an IP packet and transmitted to the set-top box.

The optical media terminal receives the received downlink PON data, decomposes the received downlink PON data into a corresponding subscriber terminal device after processing the PON MAC protocol, receives the uplink data received from each subscriber terminal device, and transmits the uplink data to the network after processing the PON protocol according to the service ranking .

The set top box reconstructs the MPEG2-TS in the received IP packet, processes the conditional reception and decoding, and displays the MPEG2-TS on the TV.

The optical media terminal is provided with an RF port for monitoring the quality of broadcasting transmitted from the distribution center.

And the internet service supplied from the optical media terminal is of the 1 Gbps class.

A private IP address is assigned when a user's PC is connected to the optical media terminal, and a network address is converted to a public IP address when a PC having a private IP address attempts to access the Internet.

The set-top box includes a network input port, a data processing unit connected thereto, a CAS processing unit, a video / audio processing unit, and a video / audio input port. The set-top box includes a data processing unit, a CAS processing unit and a video / audio processing unit And a peripheral device control unit for bidirectional communication with the operation / management processing unit, and a peripheral device input port and a user input input port for bidirectional communication with the peripheral device control unit.

And a channel change protocol function for transferring the CSQ message including the channel frequency information and the PID value to the optical media terminal when the subscriber terminal receives the channel change input.

The optical media terminal tunes and demodulates the corresponding frequency through the received frequency information and the PID value, and then transmits the MPEG to IP stream to the subscriber terminal device and transmits the CSR message.

The subscriber terminal device receives PMT / PSIP information after receiving and parsing an MPEG to IP stream, and performs PAQ transmission for video / audio / data PID reception of a channel desired to be viewed.

The optical media terminal receives and processes the PAQ, transmits the resultant PAR message, and transmits the MPEG to IP stream of the requested channel to the subscriber terminal device.

The subscriber terminal device includes a TV and a PC.

And a wireless repeater connected to the optical media terminal to transmit a radio signal to enable viewing of cable broadcasting and use of the Internet in the IP terminal device.

The IP terminal device includes a tablet PC and a smart phone.

The data server, the CAS, and the EPG are connected to the L3 switch.

According to the present invention, RF broadcasting and PON Internet signals can be simultaneously transmitted through a single optical core, thereby providing a gigabit internet transmission speed while maintaining the advantages of cable broadcasting in which all channels are transmitted to the subscriber side.

Also, it is possible to provide internet and interactive broadcasting without CMTS, which can reduce reliance on foreign equipment.

Also, it is possible to provide an N screen service that allows cable broadcasts that can be viewed only in an existing RF set-top box to be viewed on various IP terminal devices, and that multiple terminal devices simultaneously watch different channels.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram illustrating an RF-based bidirectional transmission system according to the present invention. FIG.
2 is a schematic diagram of an 'optical media terminal' in an RF-based bidirectional transmission system according to the present invention.
3 is a schematic diagram of a 'set-top box' in an RF-based bidirectional transmission system according to the present invention.
FIG. 4 is a structural view illustrating a 'real-time broadcasting service' using an RF-based bidirectional transmission system according to an embodiment of the present invention; FIG.
FIG. 5 is a structural view illustrating a 'gigabit Internet service' using an RF-based bidirectional transmission system according to the present invention.
FIG. 6 is a schematic diagram illustrating an embodiment of 'QoS support' using an RF-based bidirectional transmission system according to the present invention. FIG.
FIG. 7 is a structural diagram illustrating an embodiment of a 'VoD service' using an RF telephone-based bidirectional transmission system according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a structural view of an 'optical media terminal' in an ARP phone-based bidirectional transmission system according to the present invention, and FIG. 3 is a diagram illustrating a structure of an 'ARP phone-based bidirectional transmission system according to the present invention. Top box 'in an RF-based bidirectional transmission system according to the present invention.

1 to 3, an RF PON-based bi-directional transmission system according to an embodiment of the present invention tunes and demodulates a broadcast signal received through an RF scheme in an optical media terminal 600, (MPEG: Moving Picture Experts Group: TS: Transport Stream) signal is IP-encapsulated (the process of packaging data when data is transferred from PC to PC) and then connected to the IP-based set top box 700 by IP method And transmits the broadcast to the subscriber terminal device 800. [

For this purpose, the present invention provides a broadcast signal receiver comprising a quadrature amplitude modulation (QAM) unit 110 for modulating a broadcast signal, an amplitude modulation (AM) unit 120 and an optical amplifier 130 (100); A distribution center 300 including an L3 switch 210 connected to an Internet cable and an Internet signal unit 200 composed of an optical line terminal (OLT); A multiplexer 400 connected to the distribution center 300 and receiving an optical amplifier 130 and an OLT 220 signal; An optical media terminal 600 connected to the multiplexer 400 and the splitter 500 through an optical cable and receiving RF broadcasting and PON signals to transmit broadcasting information and Internet transmission; And a set top box 700 receiving the signal from the optical media terminal 600 and transmitting the channel selection information of the viewer to the subscriber terminal 800.

The distribution center 300 includes a broadcasting signal unit 100 and an Internet signal unit 200.

The broadcast signal unit 100 includes a QAM modulator 110, an AM optical transmitter 120, and an optical amplifier 130. The QAM modulates a digital signal by changing a carrier signal and phase by dividing the digital signal by a predetermined amount .

The L3 switch 210 is connected to the data server 211, the CAS 212, and the EPG 213.

CAS (Conditional Access System) is a system that supports only a person paying a subscription fee after watching a specific program.

EPG (Electronic Program Guide) is an electronic program guide. It is a schedule of broadcasting programs to be displayed on the screen of digital TV through data broadcasting using free frequency band or free channel.

As shown in FIG. 2, an optical media terminal (OMT) 600 includes a wavelength division multiplexer (WDM) 610 connected to a splitter 500 via an optical cable, a WDM multiplexer 610 A PON MAC processing unit 630 for bidirectional communication with the burst mode optical transceiver 620 and a gigabit Ethernet switch 640 for bidirectional communication with the PON MAC processing unit 630. The burst mode optical transceiver 620, A tuner unit 660 that receives a signal from the RF video converter 650, a demodulator 670, and a main process and a Ts-to-T converter (not shown). The RF video converter 650 receives a signal from the WDM multiplexer 610, And an IP processing unit 680.

In addition, the optical media terminal 600 restores an electrical RF signal from the optical signal for broadcasting received through the optical cable from the splitter 500 and processes it internally for broadcasting service, and tunes the corresponding frequency according to the inputted channel information. Demodulates it into MPEG2-TS, converts it into an IP packet, and transmits it to the set top box 700. [

The optical media terminal 600 receives the downlink PON data, decomposes the downlink PON data into a corresponding subscriber terminal 800 after processing the PON MAC protocol, receives the uplink data from each subscriber terminal 800, and processes the PON protocol To the network.

On the other hand, the optical media terminal 600 has an RF port for monitoring the quality of broadcasting transmitted from the distribution center 300.

In addition, the Internet service supplied from the optical media terminal 600 is preferably 1 Gbps.

When the PC 840 is connected to the optical media terminal 600, a private IP address is assigned. When the PC 840 having a private IP address attempts to access the Internet, the network address is converted to a public IP address, .

In addition, the optical media terminal 600 receives and processes a PAQ (packet identifier) add request, and transmits a resultant PAR (PID Add Response) message, and transmits an MPEG to IP stream of the requested channel to a subscriber terminal (800).

And a wireless repeater 750 connected to the optical media terminal 600 to transmit a radio signal to enable viewing of cable broadcasting and use of the Internet in the IP terminal device 820.

The IP terminal device 820 includes a tablet PC and a smart phone.

The set top box 700 restores the MPEG2-TS from the received IP packet as an IP-based set top box (STB), processes the conditional reception and decoding, and displays the MPEG2-TS on the subscriber terminal 800.

3, the set top box 700 includes a network input port 710, a data processing unit 720 connected thereto, a CAS processing unit 730, a video / audio processing unit 740, a video / audio An operation / management processor 760 that includes an input / output port 750 and performs bidirectional communication with the data processor 720, the CAS processor 730 and the video / audio processor 740, and the operation / management processor 760, And a peripheral input / output port 780 and a user input / output port 790 for bidirectional communication with the peripheral device control unit 770. The peripheral device control unit 770 includes a peripheral device control unit 770,

Meanwhile, when a subscriber terminal 800 such as a TV or a PC receives a channel change input, a channel change request for transmitting a channel set reQuest (CSQ) message including a channel frequency information and a PID value to the optical media terminal 600 Protocol functionality.

The optical media terminal 600 tunes and demodulates the corresponding frequency through the received frequency information and the PID value, and then transmits the MPEG to IP stream to the subscriber terminal 800 and transmits a CSR (Channel Set Response) message .

The subscriber terminal 800 receives and parses the MPEG-to-IP stream and obtains PMT (program map table) / PSIP (program and system information protocol) information and transmits video / audio / data And transmits PAQ (PID Add reQuest) for PID reception.

Hereinafter, the operation of the present invention will be described.

The broadcasting signal received in the RF system is tuned and demodulated in the optical media terminal 600, the MPEG2-TS signal is encapsulated in the IP, and the subscriber terminal device 800).

Thereafter, the broadcast information includes a PSIP signal transmitted together with the broadcast in the RF mode and a SI (service information) signal transmitted in the IP mode. The optical media terminal 600 bypasses both the signals, .

The IP terminal apparatus 820 obtains the broadcast channel information by checking the broadcast information (PSIP signal and SI signal), and when the optical terminal 600 requests the desired channel, the optical media terminal 600 transmits the corresponding channel Tuning, demodulation, and IP encapsulation, and transmits the resultant to IP terminal apparatus 820.

The channel change information between the optical media terminal 600 and the IP terminal apparatus 820 is exchanged by the channel change protocol.

Hereinafter, another embodiment of the present invention will be described.

4 is a block diagram illustrating an embodiment of a 'real-time broadcasting service' using a bi-directional transmission system based on an RF PON according to the present invention.

4, broadcast streams (channels for broadcasting and other data services ranging from 54 MHz to 1.022 MHz), broadcast service / system information (PSIP), and entitlement control messages (ECM) Multiplexed by the multiplexer 112 and then transmitted to the QAM modulator 110 and modulated into an RF signal of 6 MHz bandwidth and then transmitted to the optical media terminal 600 through the AM optical transmitter 120 and the optical amplifier 130 .

The service / system information SI and the entitlement management message (EMM) are transmitted to the optical media terminal 600 through the OLT 220 in the form of an IP multicast packet.

The optical media terminal 600 delivers the broadcast information (PSIP signal, SI signal) and the conditional access information (ECM, EMM) to the IP based set top box 700. The set top box 700 transmits the broadcast information And transmits selection information to the optical media terminal 600. [

The optical media terminal 600 tunes the corresponding frequency according to the inputted channel information, demodulates it into MPEG2-TS, converts it into an IP packet, and transmits it to the set top box 700. The set top box 700 receives Restores the MPEG2-TS in the IP packet, processes the conditional reception and decoding, and displays the MPEG2-TS on the subscriber terminal device 800.

At home, four different IP-based set-top boxes can watch different channels simultaneously.

Meanwhile, FIG. 5 is a block diagram illustrating an embodiment of a 'gigabit internet service' using a bi-directional transmission system based on an RF PON according to the present invention.

5, the Internet data is transmitted to the optical media terminal 600 through the L3 switch 210 and the OLT 220 of the Internet signal part, and a maximum 1 Gbps Internet service is provided to the subscriber.

The optical media terminal 600 provides Internet service to four or more IP terminal devices 820 through four gigabit Ethernet ports.

Meanwhile, FIG. 6 is a structural diagram illustrating one embodiment of 'QoS support' using a bi-directional transmission system based on RF PON according to the present invention.

As shown in FIG. 6, priorities are set for various services in the home, such as Voice over Internet Protocol (VoIP), video streaming, web browsing, and direct connection between users (P to P) Quality of service (QoS) that can guarantee the quality of service by providing the service in a priority order.

Meanwhile, FIG. 7 is a block diagram illustrating an embodiment of a 'VoD service' using a bi-directional transmission system based on RF PON according to the present invention.

7, an RF / IP video on demand (VoD) server transmits VoD content information in the form of IP packets to the set top box 700 through the OLT 220 and the optical media terminal 600 send.

When the user selects the VoD content, the set top box 700 delivers the selection information to the optical media terminal 600, and the optical media terminal 600 delivers the selected information to the VoD server through the OLT 220.

 The RF VoD server modulates the VoD contents selected by the user in a QAM modulator 110 together with RF channel information in the form of MPEG2-TS and transmits the modulated VoD contents to the optical media terminal 600 via the AM optical transmitter 120 and the optical amplifier 130 And the optical media terminal 600 transmits the RF channel information to the set top box 700.

After receiving the received RF channel information, the set top box 700 transmits the frequency information to the optical media terminal 600. The optical media terminal 600 tunes the corresponding frequency, demodulates the frequency into MPEG2-TS, And transmits it to the set top box 700.

The set top box 700 restores the MPEG2-TS in the received IP packet, processes the decoding, and displays the MPEG2-TS on the subscriber terminal 800. [

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

100: broadcast signal unit 110: QAM modulator
120: AM optical transmitter 130: optical amplifier
200: Internet signal part 210: L3 switch
220: OLT 300: Distribution center
400: Multiplexer 500: Optical cable
600: optical media terminal 700: set-top box

Claims (16)

A broadcast signal unit including a QAM modulator for modulating a broadcast signal, an AM optical transmitter, and an optical amplifier;
A distribution center including an L3 switch connected to an internet cable and an internet signal unit composed of an OLT;
A multiplexer connected to the distribution center for receiving the optical amplifier and the OLT signal;
An optical media terminal connected to the meltdyper via an optical cable and receiving RF broadcast and PON signals and broadcasting information and Internet transmission;
And a set top box receiving a signal from the optical media terminal and delivering channel selection information of a viewer to a subscriber terminal,
The optical media terminal includes a WDM multiplexer connected to the optical cable, a burst mode optical transceiver for bidirectional communication with the WDM multiplexer, a PON MAC processor for bidirectional communication with the burst mode optical transceiver, and a gigabit And an Ethernet switch. The optical network unit includes an Ethernet switch, processes an internal RF signal from a broadcasting optical signal received through the optical cable, processes it for broadcasting service, receives received downlink PON data, processes the PON MAC protocol, And transmits the uplink data received from each subscriber terminal device to the network after processing the PON protocol according to the service order to implement the RF optical transmission technology and the PON technology as a single interface. .
The method according to claim 1,
The optical media terminal
An RF video converter receiving a signal from the WDM multiplexer; a tuner unit receiving a signal from the RF video converter; and a demodulator, a main process, and a Ts-to-IP processor.
The method according to claim 1,
Wherein the optical media terminal tunes the corresponding frequency according to the input channel information, demodulates it into MPEG2-TS, converts the MPEG2-TS into an IP packet, and transmits the IP packet to the set-top box.
delete The method according to claim 1,
Wherein the set-top box restores the MPEG2-TS in the received IP packet, processes the conditional reception and decoding, and displays the MPEG2-TS on the TV.
The method according to claim 1,
Wherein the optical media terminal comprises an RF port for monitoring the quality of broadcasting transmitted from the distribution center.
The method according to claim 1,
A private IP address is assigned when a user's PC is connected to the optical media terminal, and a network address is converted to a public IP address when a PC having a private IP address attempts to access the Internet, thereby providing an Internet service. Based bi-directional transmission system. The method according to claim 1,
The set-
A network input port, a data processing unit connected thereto, a CAS processing unit, a video / audio processing unit, and a video / audio input port,
An operation / management processor for bidirectional communication with the data processor, the CAS processor and the video / audio processor, a peripheral device controller for bidirectional communication with the operation / management processor, a peripheral device input port for bidirectional communication with the peripheral device controller, An input / output port, and an input / output port.
The method according to claim 1,
And a channel change protocol function for delivering a CSQ message including a channel frequency information and a PID value to an optical media terminal when the subscriber terminal device receives a channel change input.
10. The method of claim 9,
Wherein the optical media terminal tunes and demodulates the corresponding frequency through the received frequency information and the PID value, and then transmits the MPEG to IP stream to the subscriber terminal device and transmits the CSR message.
11. The method of claim 10,
Wherein the subscriber terminal device receives the PMT / PSIP information after receiving and parsing the MPEG-to-IP stream, and performs PAQ transmission for video / audio / data PID reception of a channel desired to be viewed. system.
10. The method of claim 9,
Wherein the optical media terminal receives and processes the PAQ and transmits the resultant PAR message, and transmits the MPEG to IP stream of the requested channel to the subscriber terminal device.
13. The method of claim 12,
Wherein the subscriber terminal device is a TV or a PC.
10. The method of claim 9,
And a wireless repeater connected to the optical media terminal to transmit a radio signal to enable viewing of cable broadcasting and use of the Internet in the IP terminal apparatus.
15. The method of claim 14,
Wherein the IP terminal device includes a tablet PC and a smart phone.
The method according to claim 1,
And the data server, the CAS, and the EPG are connected to the L3 switch.

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