KR100249504B1 - Multi-media satellite communication system - Google Patents

Abstract

The present invention relates to a multimedia satellite communication system capable of transmitting multimedia data such as image data to a satellite communication subscriber at high speed.

The multimedia satellite communication system according to the present invention is a multimedia satellite communication system for providing a communication link between the Internet or a multimedia server and a subscriber using a satellite communication system, wherein the multimedia satellite communication system includes a central station that is physically coupled to the Internet. And a set-top box physically coupled to the communication terminal, wherein the forward link from the central station to the set-top box is made through a TDM scheme, and the return link from the set-top box to the central station is made through a CDMA scheme. do.

The central station adds and transmits PIDs to TS packets to be transmitted to the set-top box, and the set-top box executes data reception based on the PID assigned thereto, and the return link includes a plurality of frequency channels. In this case, a plurality of CDMA codes are assigned to each of these frequency channels.

According to the above configuration, communication subscribers can access the Internet or various multimedia servers through the multimedia satellite communication system, so communication network operation or construction becomes very easy.

In addition, data transmission from the central station to the set-top box is performed through the TDM method using TS packets, and data transmission from the set-top box to the central station is performed through the dual modulation of frequency allocation and CDMA allocation. It is possible to accommodate a large number of subscribers while performing data transmission at high speed.

Description

Multimedia satellite communication system

The present invention relates to a satellite communication system, and more particularly, to a multimedia satellite communication system capable of transmitting multimedia data such as image data to a satellite communication subscriber at high speed.

At present, with the rapid development of wireless communication technology, a wireless communication system that enables a subscriber to execute voice and data communication with a counterpart through a wireless network rather than a conventional wired network is rapidly spreading. Accordingly, mobile communication systems or personal communication systems that allow communication subscribers to perform communication while moving are widely used, and communication devices of general households can be transferred to existing PSTN through WLL (Wireless Local Loop) system or satellite communication system. Connections with public switched telephone networks are also becoming more common.

In particular, in the case of a satellite communication system, there is an advantage in that it is possible to enable ultra-long distance communication such as communication between countries without providing a separate communication line. Therefore, a satellite broadcasting system that can directly receive satellite broadcasting in a home by using a set top box, etc. by utilizing the advantages of the satellite communication system has already been developed and spread, and mobile communication devices or personal communication There is also a rapid research on a system for executing satellite communication through a device.

On the other hand, as the communication method based on the transport control protocol / Internet protocol (TCP / IP) has recently been established, the global Internet network has been established. Unlike the existing PSTN network, such an internet network is based on data packet transmission, so that a large number of subscribers use a single communication line in common, thereby greatly reducing communication costs and enabling multimedia services. . In addition to the construction of the Internet network, data communication using a personal computer has been activated.

However, in the conventional satellite communication system, since the network configuration is usually made of a unidirectional configuration and a closed loop, it is impossible for a general subscriber to access the Internet network using the satellite communication system. Therefore, in areas where communication networks are established based on satellite communication systems, such as mountain areas or island areas, subscribers can access the Internet or various multimedia services such as home banking or home shopping. It becomes impossible to use the light, which in turn is a great obstacle to the establishment and operation of the national network.

In general, when a communication subscriber uses the above-described Internet or a multimedia service, the amount of data to be received is much higher than that of the data transmitted to the service network, and since such received data is multimedia data, There is a problem that takes so much time.

In order to solve such a problem, it may be considered to establish a separate dedicated network for the Internet or a multimedia service. In this case, there is a problem that it is difficult to employ a realistic network, which takes a lot of time and cost.

Accordingly, the present invention has been made in view of the above circumstances, and provides a multimedia satellite communication system in which a general subscriber can access an internet network using a satellite communication network and also transmit and receive multimedia data through a satellite communication network. The purpose is.

Another object of the present invention is to provide a multimedia satellite communication system, which enables a subscriber to receive multimedia data at high speed from the Internet or a multimedia service provider.

1 is a system schematic diagram for explaining an overview of a multimedia satellite communication system according to the present invention.

2 is a diagram showing the configuration of a transponder of a multimedia satellite communication system according to the present invention;

3 is a configuration diagram showing the configuration of the central station 1 in FIG.

FIG. 4 is a block diagram showing the configuration of the transmission data processing apparatus 17 in FIG.

FIG. 5 is a memory map showing a memory configuration of the subscriber information storage unit 174 of FIG.

6 is a data packet diagram showing the configuration of each data packet processed in the multimedia satellite communication system according to the present invention.

FIG. 7 is an operation flowchart for explaining the operation of the transmission data processing apparatus 17 shown in FIG.

FIG. 8 is a block diagram showing the configuration of a demodulator 20 and a CDMA receiver 21 in FIG.

9 is a block diagram showing the configuration of the set-top box 4 in FIG.

10 is an operation flowchart for explaining the overall operation of the multimedia satellite communication system according to the present invention.

**** Brief description of the main parts of the drawing ****

1: central station, 2, 3: antenna,

4: set-top box, 5: personal computer,

6: satellite.

The multimedia satellite communication system according to the present invention for realizing the above object is to provide a communication link between the Internet or a multimedia server and the subscriber by using a satellite communication system, the multimedia satellite communication system and the Internet And a set top box physically coupled with the communication terminal, and a forward link from the center station to the set top box is performed through a TDM scheme, and the return link from the set top box to the central station is a CDMA scheme. Characterized in that made through.

The central station adds and transmits a PID to a TS packet to be transmitted to the set top box, and the set top box performs data reception based on the PID assigned to the central station.

The return link may include a plurality of frequency channels, and a plurality of CDMA codes are allocated to each of the frequency channels.

The central station may further include a router for accessing the Internet, an IP switch coupled to a plurality of multimedia servers, transmission data processing means for generating a TS packet based on transmission data output from the IP switch, and the transmission data processing. Modulation means for modulating and outputting the data output from the means, frequency demodulation means for frequency demodulating the received signal received from the set-top box, CDMA reception means for CDMA demodulation of the data output from the frequency demodulation means, and the CDMA receiving means Receiving data processing means for packetizing the received data input from the input to the IP switch, a database for storing information about the subscriber and various data, and a processor for controlling a call connection between the central station and the set-top box. It is characterized by.

The set top box may include a tuner for converting a frequency signal received from a central station into an intermediate frequency, demodulation means for recovering original TS packet data from an intermediate frequency output from the tuner, and a TS packet input from the demodulation means. A demultiplexer for receiving and outputting TS packets having a predetermined PID registered by a processor, an interface card for connecting a set-top box and a communication terminal, and a CDMA channel for CDMA modulating data to be transmitted to a central station using a predetermined CDMA code. Modulation means for frequency-modulating data applied from the CDMA channel transmission means, intermediate frequency generating means for converting a frequency signal input from the modulation means into an intermediate frequency based on predetermined frequency data, and applying from the demultiplexer Based on TS packet data For addition to also execute the processing of the traffic control process and the communication terminal, characterized in that configured by a processor constituting control the return link CDMA channel to control the transmission means and the intermediate frequency generating means.

According to the present invention having the above configuration, communication subscribers can access the Internet or various multimedia servers through the multimedia satellite communication system, so communication network operation or construction becomes very easy.

In addition, data transmission from the central station to the set-top box is performed through a TDM method using TS packets, and data transmission from the set-top box to the central station is performed through frequency allocation and CDMA allocation, thereby transmitting data from the central station to the set-top box. While running at high speed it is possible to accommodate a large number of subscribers.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings.

1 is a block diagram showing the overall system configuration of a multimedia satellite communication system according to the present invention.

In FIG. 1, reference numeral 1 denotes a central station connected to the Internet, which provides various multimedia services to terminal stations, and performs overall network operation management and control functions. In addition, reference numeral 3 is a terminal station antenna, 4 is a set top box as a terminal station providing multimedia services to a general subscriber, 5 is a personal computer as a terminal for a user to perform multimedia communication, and 6 is a satellite. to be.

In general, a user using an Internet service often downloads (downloads) multimedia data through the Internet as described above. Therefore, the amount of data received from the Internet is higher than the amount of data transmitted to the Internet. So much. Therefore, in consideration of this, in the present system, in the case of a forward link transmitted from the central station 1 to the set top box 4, a large amount of messages can be transmitted through the TDM scheme, and from the set top box 4 In case of a return link transmitted to the central station 1, a code division multiple access (CDMA) scheme is used to accommodate a plurality of subscribers.

FIG. 2 shows the configuration of a transponder of the system, which has a frequency band f _A of 40 MHz for a forward link and a frequency band f _B of 40 MHz for a return link, for example. f _T ), for example, has a bandwidth of 80 MHz, and the return link is composed of a plurality of frequency channels f1 to fn with a bandwidth of approximately 1.5 MHz. For example, 64 CDMA codes are allocated to each of the frequency channels f1 to fn, and the central station 1 has a channel frequency for each set-top box 4 corresponding to each time the subscriber uses the Internet service. And a CDMA code are allocated to form a return link.

In addition, the central station 1 is coupled to the Internet based on TCP / IP, and transmits and receives various data with the Internet through an IP packet (Internet Protocol Packet). In addition, for example, an MPEG-2 TS (Transport Stream) packet for a multimedia service is generated based on an IP packet for a subscriber received from the Internet, and the generated packet data is transmitted to the set-top box through a TDM scheme. Then, the CDMA modulated data received from the set-top box 3 is received, IP packets are generated based on the CDMA modulated data, and the IP packets are transmitted to the Internet.

In addition, the set top box 4 receives the TS packet transmitted from the central station 1 to provide multimedia data to the personal computer. Here, the reception of the TS packet is performed based on a PID (Packet Identifier), which is assigned by the central station 1 at the start of service. The set top box 4 transmits the IP packet data input from the personal computer 5 to the central station 1 through CDMA modulation and frequency modulation.

3 is a block diagram showing the configuration of the central station 1 described above.

In FIG. 3, reference numeral 1 denotes an IP switch for switching an Internet Protocol Packet. The IP switch 11 includes a Domain Name System (DNS) server 11, an E-mail server 12, and a web ( The WEB server 13, the proxy server, the multimedia service provider (MSP), the router 16, and the like are combined. In this case, the MSP includes a home banking system, a home shopping system, a distance education system, a video conference system, and the like.

In particular, the router 16 executes connection processing between the central station 1 and the Internet, which converts an IP packet input from the Internet into the central station 1 into data of an Ethernet frame and converts the data from the central station 1 to the Internet. Ethernet frame sent to IP packet is converted into IP packet.

In the figure, reference numeral 17 denotes a transmission data processing apparatus for processing transmission data input from the IP switch 10 to generate, for example, an MPEG-2 TS packet, and 18 is output from the transmission data processing apparatus 16. A modulator for outputting an intermediate frequency signal of, for example, 70 MHz by performing quadrature phase shift keying (QPSK) modulation on TS packet data, and a frequency upconversion and high output amplification of the intermediate frequency signal output from the modulator 17 It is an RF device for outputting to the antenna (2), the high-frequency signal received through the antenna (2) down-frequency conversion and low noise amplification output.

In the drawing, reference numeral 20 denotes a demodulation device for demodulating an intermediate frequency signal input from the RF device 19, and 21 denotes CDMA demodulation of CDMA modulation data input by frequency demodulation in the demodulation device 20. A CDMA receiving device for outputting packet data, 22 is a receiving data processing device for processing data input from the CDMA receiving device 21, wherein the receiving data processing device 22 is an IP packet data from the set-top box (4) If the control message is received or converted to the data of the Ethernet frame is input to the IP switch 10. In addition, the reception data processing device 22 converts, for example, 100 baseT, that is, 100 Mbps data input from the CDMA reception device 21 into data of 10 baseT, and inputs the data to the IP switch 10.

In the drawing, reference numeral 23 denotes a central international language processor which controls the entire apparatus of the central station 1, and also allocates PIDs to the set-top box 4, transmit channel frequencies and CDMA codes for transmission. 24 is a network management system for the system operator to operate and manage the entire satellite network, and 25 is a PID, frequency data and CDMA code data that can be allocated to the set-top box 4, Database that stores billing information, etc.

4 is a block diagram showing the configuration of the transmission data processing apparatus 17. In the drawing, reference numeral 171 generates and outputs an IP packet based on the Ethernet frame input from the IP switch 10 described above. In addition, the Ethernet interface converts the data of 100 baseT inputted into the data of 10 baseT and outputs the data, 172 is an input buffer for sequentially storing the IP packet data output through the Ethernet interface 171, 173 is the input buffer The type of input data is determined based on the header of the IP packet data stored in 172, and based on the determined result, the packets of the PS packet generation unit 175 and TS packet generation unit 176 to be described later. Control to generate and also control data applied from the Ethernet interface 171, for example, control input from the network management system 24 or the central international language processor 23 of FIG. An IP packet controller for controlling a transmission data processing unit 17 based on the data. Although not specifically shown in the figure, the IP packet controller 173 checks the state of each component of the transmission data processing apparatus 17 and displays the state information in the central international language processor 23 or the network management system 24. Will be sent out.

In the drawing, reference numeral 174 denotes a subscriber information storage unit for storing PIDs allocated for each set top box 4, which is a control PID corresponding to the IP address of each set top box 4 as shown in FIG. Map and store PID for traffic.

In the drawing, reference numeral 175 denotes a PS packet generation unit for generating a PS packet (Private Section Packet) based on data input from the IP packet controller 173, and 176 is input from the PS packet generation unit 175. MPEG-2 TS packet is generated based on PS packet data and PID (control PID, traffic PID or information service PID) applied from the IP packet controller 176 and the traffic data stored in the input buffer 172. TS packet generation unit for outputting

Hereinafter, the operation of the transmission data processing apparatus 17 will be described based on the data packet structure shown in FIG. 6 and the flowchart shown in FIG.

First, when an Ethernet frame as shown in FIG. 6 (a) is input through the IP switch 10, the Ethernet interface 171 generates and outputs an IP packet as shown in FIG. 6 (b) based on the Ethernet frame. The IP packets are sequentially stored in the input buffer 172.

Meanwhile, when the IP packet is input and stored in the input buffer 172 (ST1), the IP packet controller 173 refers to the header of the stored packet data to determine whether the currently input packet data is control data for the set top box. Or it is determined whether the traffic data for the personal computer 5 or the service information for the set-top box 4 (ST2). In this case, when it is determined that the control data is determined, the length data indicating the length of the data and the message data, that is, the data of the corresponding IP packet are read out from the input buffer 172 and input to the PS packet generation unit 175 (ST3). ). At this time, the IP packet controller 173 reads the control PID corresponding to the IP address from the subscriber information storage unit 174 based on the IP address of the input data and outputs it to the TS packet generation unit 176 ( ST4).

In addition, when the IP packet input in step ST2 is determined to be traffic data, the IP packet controller 173 transmits length data of the corresponding traffic data stored in the input buffer 172 to the PS packet generation unit 175. In addition, based on the IP address of the IP packet (ST5), the traffic PID is read from the subscriber information storage unit 174 and sent to the TS packet generation unit 176 (ST6).

In addition, when the IP packet input in step ST2 is determined as service information for the information service, the IP packet controller 173 may compare the length data of the corresponding traffic data and the IP packet data stored in the input buffer 172. In addition to sending to the PS packet generation unit 175 (ST7), the PID for information service included in the data field of the IP packet is read out and sent to the TS packet generation unit 176 (ST8).

Meanwhile, the PS packet generation unit 175 generates the PS packet data shown in FIG. 6C based on the length data and the message data applied from the IP packet controller 173 and outputs the PS packet data to the TS packet generation unit 176. In this case, the length data is included in the header portion of the PS packet, and the message data is allocated to the data field.

TS packet generation unit 176 is a PS packet currently applied by the PS packet generation unit 175 based on the length data registered in the header of the PS packet data applied from the PS packet generation unit 175 It is determined whether it is control data (service information) or traffic data. That is, in general, in the case of traffic data, the data length thereof is larger than that of the control data. Therefore, when the length data value included in the PS packet data is greater than or equal to a predetermined value, the traffic data is smaller than the control data. It is determined.

Next, when the PS packet input unit 176 determines that the input PS packet is the control data, the TS packet generation unit 176 generates the TS packet as shown in FIG. 6 (d) based on the PS packet applied by the PS packet generation unit 175. On the other hand, if the input PS packet is determined to be traffic data, the TS packet of FIG. 6 (d) is generated based on the header data of the PS packet and the traffic data stored in the input buffer 172. .

In FIG. 6 (d), the TS packet is composed of a 4-byte TS header, a 184-byte payload allocated to a substantial data area, and a 16-byte RS (Reed Solomon) byte for error correction. The TS header includes an 8-bit sync byte (SC) having a predetermined fixed value, a 1-bit unit start indicator (US) for indicating a start criterion of a TS packet, and a 13-bit And a 4-bit continuity counter (CC) indicating a successive number of TS packets having the same PID. In this case, the PID is applied from the IP packet controller 173. If the currently transmitted TS packet is control data, the control PID, the traffic PID if the traffic data, and the information service PID are the information service, Will be allocated.

FIG. 8 is a block diagram showing the configuration of the demodulator 20 and the CDMA receiver 21 in FIG. 3. In FIG. 8, the demodulator 20 includes a plurality of demodulators 20 _{1 to} 20n. It is configured by. Here, each of the demodulators 20 _{1 to} 20n corresponds to the respective channel frequencies f1 to fn in FIG. 2, and demodulates the corresponding channel frequency signals to the CDMA receiver 21. Done.

In addition, the CDMA receiver 21 includes a plurality of CDMA receivers 21 _{1 to} 21n, and a predetermined number of CDMA receivers 21 _{1 to} 21n are provided for each of the demodulators 20 _{1 to} 20n. To be combined. Here, the CDMA receivers 21 _{1 to} 21 n correspond to the number of CDMA codes allocated to the respective channel frequencies f1 to fn in FIG. 2. As described above, for example, 64 CDMA receivers 21 _{1 to} 21 n correspond to one channel frequency. When a CDMA code is assigned, 64 CDMA receivers 21 _{1 to} 21 n are coupled to the demodulators 20 _{1 to} 20 n, respectively. Here, the CDMA receivers 21 _{1 to} 21 _{n are} distinguished as for the access channel 21A and the traffic channel 21B, where the number for the access channel and the traffic channel is variably set according to the characteristics of the system. .

9 is a block diagram showing the configuration of the set-top box 4 in FIG.

In the drawing, reference numeral 41 denotes a frequency down-conversion and low-noise amplification of the high frequency signal transmitted from the central station 1, and a frequency up-conversion of the intermediate frequency signal output from the intermediate frequency generator 49, which will be described later. 42 is a tuner for frequency-changing a high frequency signal output from the RF device 41, and 43 is an intermediate frequency signal output from the tuner 42, that is, a QPSK at the central station 1; A demodulator demodulates a modulated signal.

In the drawing, reference numeral 44 denotes a demultiplexer for extracting a TS packet corresponding to the set-top box from the TS packet data output from the demodulator 44, which includes a register for storing PID information therein. PID applied from the processor 52 to be described later is stored in the register. The TS packet including the PID stored in the register is extracted from the TS packets applied from the demodulator 43 and applied to the processor 52.

In the drawing, reference numeral 45 denotes a network interface card (NIC) that performs an interface with the personal computer 5, which converts Ethernet packets applied from the processor 52 into IP packets to convert the personal computer 5 into an IP packet. In addition to the above), the IP packet applied by the personal computer 5 is converted into an Ethernet packet and applied to the processor 52.

In the figure, reference numeral 46 denotes a serial transmission data frame based on the transmission data applied in parallel from the processor 52, and the transmission timing applied by the transmission timing generation unit 50 to be described later. A transmission frame generation unit sequentially outputs the transmission data frame in accordance with a signal. 47 is a CDMA modulation by mixing a CDMA code applied from the processor 52 with respect to transmission data output from the transmission frame generation unit 46. A CDMA channel transmitter for executing the data, 48 a modulator for modulating and outputting the data output from the CDMA channel transmitter 47, for example, QPSK, and 49 a modulator 48 based on the frequency data applied from the processor 52. Is an intermediate frequency generating unit for converting the modulated signal output from the predetermined frequency signal into a predetermined intermediate frequency signal.

In the drawing, reference numeral 50 denotes a transmission timing generator for generating a transmission timing signal for the transmission frame generator 46 under the control of the processor 50, and 51 denotes various data, in particular, from the central station 1. It is a data memory that stores the control PID, the traffic PID and the service information PID for receiving the service information (Service Information).

In addition, reference numeral 52 denotes a processor for controlling the overall operation of the set-top box 4, which converts the TS packet for the personal computer 5 received from the demultiplexer 44 into an IP packet and converts it into an IP packet. In addition to the output box, data from the personal computer 5 input from the network interface card 45 is output to the transmission frame generation unit 46 and transmitted to the central station 1.

In addition, the processor 52 allocates a predetermined CDMA code to the CDMA transmitter 47 according to the control data transmitted from the central station 1 to the TS packet, and outputs frequency data to the intermediate frequency generator 49. As a result, CDMA modulation and frequency modulation on the data to be transmitted to the central station 1 are executed.

In addition, the processor 52 registers the control PID and the traffic PID allocated from the central station 1 to the demultiplexer 44 to receive and control the control data and traffic data transmitted from the central station 1.

Next, the overall operation of the multimedia satellite communication system having the above-described configuration will be described using the operation flowchart shown in FIG. In addition, in the multimedia satellite system according to the present invention, it is possible for a subscriber to connect to various servers including MSP such as home shopping, home banking, and the Internet using the system. An example of connecting to the Internet will be described.

First, the network management system 24 of the central station 1 has various information required when the set-top box 4 requests access to the central station 1, for example, a CDMA code for transmitting a control message to the central station 1. And an information service providing channel frequency data (step A1).

That is, the network management system 24 generates an Ethernet packet including the CDMA code, channel frequency data, and PID for information service for common reception in all set-top boxes 4, and transmits data through the IP switch 10. It is transmitted to the processing device 17.

Subsequently, in the transmission data processing apparatus 17 shown in FIG. 4, when the IP packet sent out from the network management system 24 is stored in the input buffer 172, the IP packet controller 173 refers to the header. The type of the IP packet is determined. At this time, if the IP packet is control data for the set-top box 4 and is determined to be an information service, the IP packet controller 173 reads PID information included in the data field of the corresponding IP packet to generate a TS packet. In addition to the output to the unit 176, the length data and the message data of the IP packet data is output to the PS packet generation unit 175.

Accordingly, the control data transmitted from the network management system 24 is converted into TS packets through the PS packet generation unit 175 and the TS packet generation unit 176, and the TS packets are converted into the TS packets by the modulator 18 and the RF device. It is transmitted to the set-top box (4) via (19).

In addition, the information service described above is repeatedly executed at regular intervals, for example, when the number of TS packets transmitted from the central station 1 to the set top box 4 reaches 100.

On the other hand, in the set top box 4, the processor 52 first reads the information service PID from the data memory 51 and registers it in the demultiplexer 44. When the service information transmitted from the central station 1 is received by the demultiplexer 44 and input to the processor 52, the processor 52 receives access data received through the information service, that is, the central station 1. CDMA code data and channel frequency data used when requesting a call connection are stored in the data memory 51 (step B1).

When the access request for the Internet, that is, the call connection request, is input from the personal computer 5 in the above state (step B2), the processor 52 inputs the subscriber information input through the network interface card 45, that is, the subscriber ID. After generating a predetermined control message based on a password, a subscriber address, and the like, the control message is transmitted to the transmission frame generation unit 46 and access information stored in the data memory 51, that is, the central station. The CDMA code data and channel frequency data transmitted from (1) are allocated to the CDMA channel transmitter 47 and the intermediate frequency generator 49 to execute the access request for the central station 1 (step B3).

On the other hand, in the central station 1, the control message sent from the set-top box 4 is input to the demodulation device 20 through the RF device 19, and the access control message is for access in FIG. It is input to the received data processing apparatus 22 through the assigned demodulator 20 and the CDMA receiver 21A. Then, the reception data processing apparatus 22 generates an Ethernet frame based on the control message and applies it to the central international language processor 23 through the IP switch 10 in FIG. 3.

Then, when the access request is input through the above-described process (step A2), the central international language processor 23 preferentially stores the subscriber IP and password included in the control message and the subscriber information stored in the database 25. By comparison, it is determined whether the subscriber who has been accessed currently is a legitimate subscriber (step A3).

At this time, if it is determined that the user is a legitimate subscriber, the database is searched to determine whether there is a PID currently available, and the control top, traffic PID, channel frequency, and CDMA code are assigned to the set-top box 4. That is, the central international language processor 23 generates an Ethernet frame for transmitting the PID information, the channel frequency data, and the CDMA code, and transmits the Ethernet frame to the transmission data processing apparatus 17 through the IP switch 10. The processing device 17 generates a TS packet based on the Ethernet frame and transmits the TS packet through the modulation device 18 and the RF device 19 (step A4). At this time, the information service PID is used as the PID of the TS packet transmitted to the set top box 4.

In addition, the network management system 24 transmits control data to the IP packet controller 173 of the transmission data processing apparatus 17 through the IP switch 10, thereby allocating the current access information to the subscriber information storage unit 173. The control PID and the traffic PID are registered in correspondence with one IP address.

On the other hand, in the set top box 4, when the control data is input through the demultiplexer 44, the processor 52 first determines whether it has made an access request. In addition, the processor 52 of the set-top box 4, which has made an access request, sets the control PID and the traffic PID assigned from the central station 1 to the demultiplexer 44, and the CDMA allocated from the central station 1 is assigned. The code and the channel frequency data are transmitted to the CDMA channel transmitter 47 and the intermediate frequency generator 49. Then, the personal computer 5 is notified of the successful call connection through the network interface card 45.

Subsequently, when an IP packet for transmitting to the Internet from the personal computer 5 is input, the network interface card 45 converts it into an Ethernet packet and inputs it to the processor 52, and the processor 52 converts it into an IP packet. By converting and outputting to the transmission frame generation unit 46, the corresponding traffic data is transmitted to the central station 1.

In addition, in the central station 1, when traffic data is received from the set top box 4, it is input to the demodulation device 20 through the RF device 19, and in FIG. The demodulator 20 and the CDMA receiver 21B corresponding to the channel frequency and CDMA code allocated for 4) are inputted to the reception data processing apparatus 22. Then, the reception data processing device 22 converts the input IP packet into an Ethernet frame and applies it to the router 16 through the IP switch 10, and the router 16 converts the input Ethernet frame into an IP packet. To the Internet.

On the other hand, when the IP packet for the subscriber to the call connection is input to the router 16, the router 16 converts the input IP packet into an Ethernet frame to the transmission data processing device 17 through the IP switch 10 Will be entered. In FIG. 4, the input Ethernet frame is converted into an IP packet through the Ethernet interface 171 and sequentially stored in the input buffer 171.

Subsequently, the IP packet controller 173 recognizes that the inputted IP packet is traffic data for the subscriber by determining the header of the IP packet stored in the input buffer 171, and then corresponds to the corresponding IP address. The traffic PID is read from the subscriber information storage 174 and applied to the TS packet generator 176.

Accordingly. Traffic data for a particular subscriber received from the Internet is converted into a TS packet assigned a PID for the subscriber and transmitted to the set top box 4.

In the set-top box 4, when the above-described TS packet is input through the demultiplexer 44, the processor 52 determines the received data based on the PID included in the header of the input TS packet. If it is determined that the TS packet is traffic data, an Ethernet frame is generated based on the TS packet and input to the network interface 45. In addition, the network interface card 45 converts the Ethernet frame input from the processor 52 into an IP packet and transmits it to the personal computer 5.

Therefore, through the above-described process, the subscriber can execute the network connection with the Internet through the personal PC.

On the other hand, when a call release, i.e., an access release request is input from the personal computer 5 (step B5), the processor 52 generates a control message for the call release request based on this, and outputs it to the transmission frame generation unit 46. Being. This call request message is transmitted to the central international language processor 52 of the central station 1 through the above-described method (step B6). Then, the central international language processor 23 recovers the control PID and the traffic PID assigned to the set top box 4 based on the input control message. That is, the central international language processor 23 first sends control data to the set-top box 4 to notify that call release has been made, and sets the corresponding PID of the database 25 to a non-use state. In addition, the billing information for the call usage up to now is stored in the database 25, and the control data is transmitted to the transmission data processing unit 17 so that the IP address stored in the subscriber information storage unit 174 is stored. The control PID and the traffic PID are deleted (step A5).

Further, in the set top box 4, when control data indicating call release is received from the central station 1, the processor 52 resets the control PID and the traffic PID set for the demultiplexer 44, and the information service. The call processing for the subscriber is terminated by setting the PID for the service and resetting the CDMA channel transmitter 47 and the intermediate frequency generator 49. FIG.

Therefore, in the above embodiment, communication subscribers can access the Internet or various multimedia servers through the multimedia satellite communication system, so communication network operation or construction becomes very easy.

In addition, since data transmission from the central station 1 to the set-top box 4 is performed through a TDM method using an MPEG-2 TS packet, data transmission from the set-top box to the central station is performed through frequency allocation and CDMA allocation. The data transmission from the central station 1 to the set top box 4 can be carried out at high speed while accommodating a plurality of communication subscribers.

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical scope of the present invention.

For example, in the above embodiment, the subscriber ID, password, subscriber address, etc. are input from the personal computer 5 when the call connection request from the set-top box 4 to the central office 1 is received. In the case, the set top box 4 and the personal computer 5 are connected in a one-to-one manner, and therefore it is preferable to manage the subscriber information in the set top box 4.

In the above embodiment, the network management system 24 provides the information service PID required for providing the information service. However, the information service PID is an IP packet of the transmission data processing apparatus 17. It is also possible to manage the controller 173 through a separate data memory, and conversely, it is also possible to manage the PID for control for a particular subscriber in the network management system 24 or the central station control processor 23. When the control PID is managed by the network management system 24 or the central station control processor 23 in this way, when the control data is transmitted to the specific set-top box 4, the control PID is applied to the data field of the control data. In addition, the transmission data processor 17 transmits the data to the transmission data processor 17, and the IP packet controller 173 extracts the control PID included in the data field and transmits the control PID to the TS packet generation unit 176. Just do it.

As described above, according to the present invention, the connection between the Internet or the multimedia server and the personal communication subscriber can be performed by using the satellite communication network, and the multimedia data transmission to the subscriber can be performed at high speed, and the number of communication subscribers can be accommodated. The multimedia satellite communication system can be realized.

Claims (20)

In the multimedia satellite communication system to provide a communication link between the Internet or multimedia server and the subscriber by using a satellite communication system, The multimedia satellite communication system includes a central station physically coupled with the Internet, and a set top box physically coupled with the communication terminal. The forward link from the central station to the set-top box is made through a TDM scheme, and the return link from the set top box to the central station is made through a CDMA scheme. The method of claim 1, The central station is configured to transmit the data to be transmitted to the set-top box in a TS packet multimedia multimedia communication system. The method according to claim 1 or 2, The central station adds and transmits a PID to the TS packet to be transmitted to the set top box, and the set top box executes data reception based on the PID assigned to the central station. The method of claim 3, The PID includes a control PID, a traffic PID, and an information service PID, and the control PID and the traffic PID are allocated to the set-top box through a TS packet to which the information service PID is added. Communication system. The method according to claim 1 or 4, The service information includes a channel frequency and CDMA code data to be used when requesting a call connection to the central station. The method of claim 5, And the information service is executed every time a certain number of TS packets are transmitted. The method of claim 1, And the return link has a plurality of frequency channels, and a plurality of CDMA codes are assigned to each of the frequency channels. The method of claim 1, The central station includes a router for accessing the Internet, an IP switch coupled with a plurality of multimedia servers, Transmission data processing means for generating a TS packet based on transmission data output from the IP switch; Modulation means for modulating and outputting data output from the transmission data processing means; Frequency demodulation means for frequency demodulating the received signal received from the set-top box, CDMA reception means for CDMA demodulation of data output from the frequency demodulation means, Received data processing means for packetizing the received data input from the CDMA receiving means and inputting the received data to the IP switch; A database storing information and various data about subscribers, Multimedia satellite communication system comprising a processor for controlling the call connection between the central station and the set-top box. The method of claim 8, And the data transmission in the central station is performed via an Ethernet frame. The method of claim 8, The transmission data processing means includes an Ethernet interface for interfacing with an IP switch; An input buffer means for storing an IP packet input through the Ethernet interface; PS packet generation means for generating a PS packet based on the input data, TS packet generation means for generating a TS packet based on the data input from the PS packet generation means and the input buffer means and a PID input from the IP packet controller; Subscriber information storage means for storing PID corresponding to each communication subscriber's IP address, The type of input data is determined based on the header of the IP packet stored in the input buffer means, and the length data and data of the IP packet are selectively supplied to the PS packet generation means based on the determined result. Multimedia packet communication system comprising a IP packet controller for supplying PID to the TS packet generation means. The method of claim 10, The IP packet controller is a multimedia satellite communication system, characterized in that for supplying at least one PID of the control PID, traffic PID and information service PID to the TS packet generating means. The method according to claim 10 or 11, wherein The subscriber information storage means for storing the control PID and the traffic PID corresponding to the IP address, the multimedia satellite communication system. The method according to claim 10 or 11, wherein The subscriber information storage means for storing the traffic PID corresponding to the IP address multimedia multimedia communication system. The method of claim 8 or 10, And the IP packet controller reads an information service PID added to a data field of an IP packet inputted from an input buffer means and supplies the same to the TS packet generation means. The method of claim 8 or 10, And said IP packet controller reads out a control PID added to a data field of an IP packet inputted from an input buffer means and supplies it to said TS packet generation means. The method of claim 8, The demodulation means comprises a plurality of demodulators for demodulating data of different channel frequencies, respectively. The method according to claim 8 or 16, The CDMA receiving means comprises a plurality of CDMA receiving units coupled to each of the plurality of demodulating units, wherein each CDMA receiving unit CDMA demodulates data input based on different CDMA codes, respectively. Communication system. The method of claim 1, The set top box includes a tuner for converting a frequency signal received from a central station into an intermediate frequency; Demodulation means for recovering original TS packet data from an intermediate frequency output from the tuner; A demultiplexer for receiving and outputting a TS packet having a predetermined PID registered by a processor among TS packets inputted from the demodulation means, Interface card for connecting the set-top box and the communication terminal, CDMA channel transmitting means for CDMA modulating data to be sent to the central station by using a predetermined CDMA code, Modulation means for frequency modulating data applied from the CDMA channel transmitting means; An intermediate frequency generating means for converting a frequency signal input from said modulation means into an intermediate frequency based on predetermined frequency data; A processor for performing control processing for the set-top box and traffic processing with the communication terminal based on the TS packet data applied from the demultiplexer, and controlling the CDMA channel transmitting means and the intermediate frequency generating means to configure and control a return link. Multimedia satellite communication system, characterized in that configured to include. The method of claim 18, The processor registers an information service PID with respect to the demultiplexer when the communication terminal is in an unused state, and configures a return link for accessing the central station based on data included in the received PS packet. Multimedia satellite communication system. The method of claim 18, After sending the control message for the call connection to the central station, the processor registers the control PID and the traffic PID received through the TS packet for the information service to the demultiplexer and receives the TS packet for the information service. And a return link by controlling the CDMA channel transmitting means and the intermediate frequency generating means based on the CDMA code data and the frequency data.

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