JP2005072886A - Asymmetric digital subscriber line access system, access method and access program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform acceleration and band widening of a subscriber line access line. <P>SOLUTION: A multiplex / demultiplex part 51 distributes a plurality of IP packets from terminal equipment 80-1 to each of a plurality of ADSL line interfaces 60-1, 60-2 and 60-3 for each IP packet. Each of the plurality of ADSL line interfaces 60-1, 60-2 and 60-3 converts the distributed IP packets to ATM cells, converts them to ADSL line signals further and sends them to a DSLAM 20 through each of a plurality of ADSL lines 203-1, 203-2 and 203-3. The DSLAM 20 takes out the IP packets from the respective ADSL line signals transmitted from each of the plurality of ADSL lines 203-1, 203-2 and 203-3 and multiplexes the IP packets. Inversely, the multiplex / demultiplex part 51 takes out the IP packets from the respective ADSL line signals transmitted from the DSLAM 20 through the plurality of ADSL lines 203-1, 203-2 and 203-3, multiplexes the IP packets and sends them to the terminal equipment 80-1 by line signals. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a subscriber access system that accesses the Internet through an ADSL line (asymmetric digital subscriber line), and more particularly to a subscriber access system that can be accessed at high speed using a plurality of ADSL lines.

  A conventional subscriber access system is configured such that a subscriber terminal device accesses a subscriber line access device (DSLAM) provided in a station through a single ADSL line (asymmetric digital subscriber line). In order to provide high-traffic Internet services in recent years, it is not sufficient to use only one ADSL line bandwidth. For this reason, there is a technique for increasing the speed of the ADSL line (for example, Patent Document 1).

JP 2000-138733 A

  In Japanese Patent Laid-Open No. 2000-138733, a plurality of subcarriers are multiplexed in one ADSL line to form a high-speed line. Therefore, the multiplicity of subcarriers in one ADSL line is limited by the bandwidth of one ADSL line. In order to provide a high traffic Internet service in recent years, there is a problem that it is necessary to further increase the bandwidth of the access line.

  An object of the present invention is to solve the conventional problems as described above and provide a technique capable of increasing the speed and bandwidth of a subscriber line access line.

The asymmetric digital subscriber line access system of the present invention includes a plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, the subscriber terminal device and the digital subscriber line access. A plurality of downstream ADSL line signals flowing from the digital subscriber line access apparatus to the subscriber terminal apparatus and an upstream ADSL line signal flowing from the subscriber terminal apparatus to the digital subscriber line access apparatus. An asymmetric digital subscriber line access system having an asymmetric digital subscriber line (ADSL line) comprising:
Multiplexing means for multiplexing downstream ADSL line signals flowing through each of the plurality of ADSL lines from the digital subscriber line access apparatus, and signals from the subscriber terminal apparatus are distributed to a plurality of upstream ADSL line signals. A demultiplexer having a demultiplexing unit for transmitting each of the upstream ADSL line signals to each of the plurality of ADSL lines is provided in the subscriber premises.

  In the asymmetric digital subscriber line access system of the present invention, the subscriber terminal device generates a plurality of packets for communication, converts the packets into a terminal line signal, and sends the packet to the demultiplexer. The multiplexer / demultiplexer receives a terminal line signal from the subscriber terminal device, extracts a plurality of packets from the terminal line signal, and extracts the extracted packets into a plurality of routes for each packet. The digital subscriber line access device comprises means for distributing and converting each of the distributed packets into each of an upstream ADSL line signal and transmitting each of the upstream ADSL line signals to each of a plurality of ADSL lines, , Receiving each of the upstream ADSL line signals carried via each of the plurality of ADSL lines from the demultiplexer, and receiving the upstream ADSL line signal The packet is taken out from each other, and a plurality of packets to be sent to the subscriber terminal device are generated, and the plurality of packets are distributed to a plurality of routes for each packet. Means for converting each of the packets into a downlink ADSL line signal and sending each of the downlink ADSL line signals to each of a plurality of ADSL lines; and the demultiplexer further includes the digital subscriber line Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the access device, a packet is extracted from each of the downlink ADSL line signals, the plurality of extracted packets are multiplexed, and the multiplexed packet Is converted into a terminal line signal and the terminal line signal is sent to the subscriber terminal device, and the subscriber terminal device further includes: Receiving a terminal line signal from the demultiplexer, and having means for receiving removed packet from the terminal line signal.

  Further, the asymmetric digital subscriber line access system of the present invention is characterized in that the packet is an IP (Internet Protocol) packet.

  In the asymmetric digital subscriber line access system of the present invention, the packet is an ATM (Asynchronous Transfer Mode) cell.

  Furthermore, in the asymmetric digital subscriber line access system according to the present invention, the subscriber terminal device generates a plurality of IP packets for IP (Internet Protocol) communication, and converts these IP packets into terminal line signals. Means for sending to the multiplexer / demultiplexer, the multiplexer / demultiplexer receiving a terminal line signal from the subscriber terminal device, extracting a plurality of IP packets from the terminal line signal, and extracting the extracted plurality of IP packets; Each packet is distributed to a plurality of routes, and each of the distributed IP packets is divided into ATM (Asynchronous Transfer Mode) cells, and further converted into each uplink ADSL line signal. Is sent to each of a plurality of ADSL lines, and the digital subscriber line access device is the demultiplexer or the demultiplexer. Receiving each of the upstream ADSL line signals carried via each of the plurality of ADSL lines, taking out IP packets from each of the upstream ADSL line signals, multiplexing the IP packets, and addressing the subscriber terminal device Generating a plurality of IP packets to be sent to the plurality of IP packets, distributing the plurality of IP packets into a plurality of routes for each packet, dividing each of the distributed IP packets into ATM (Asynchronous Transfer Mode) cells, Means for converting each of the downlink ADSL line signals and sending each of the downlink ADSL line signals to each of a plurality of ADSL lines; and the demultiplexer further includes: Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received, and an IP packet is received from each of the downlink ADSL line signals. And a means for multiplexing the extracted plurality of IP packets, converting the multiplexed IP packet into a terminal line signal, and sending the terminal line signal to the subscriber terminal device. Further includes means for receiving a terminal line signal from the multiplexer / demultiplexer and extracting and receiving an IP packet from the terminal line signal.

  Furthermore, the asymmetric digital subscriber line access system of the present invention is characterized in that the terminal line signal is a signal for an ETHER line interface defined by IEEE 802.3.

  In the asymmetric digital subscriber line access system of the present invention, the terminal line signal is ITU-TG. It is a signal for a VDSL (Very High Bit Rate Digital Subscriber Line) interface defined in 993.1.

  Furthermore, the access method of the present invention comprises a plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, the subscriber terminal device and the digital subscriber line access device. A plurality of asymmetric digital subscriptions connecting and carrying a downstream ADSL line signal flowing from the digital subscriber line access device to the subscriber terminal device and an upstream ADSL line signal flowing from the subscriber terminal device to the digital subscriber line access device; A method for accessing an asymmetric digital subscriber line access system having a subscriber line (ADSL line), a multiplexing step for multiplexing downstream ADSL line signals flowing from the digital subscriber line access device through each of a plurality of ADSL lines And dividing the signal from the subscriber terminal apparatus into a plurality of upstream ADSL line signals. , And having a separation step of transmitting each of the distribution was upstream ADSL line signal to each of a plurality of asymmetric digital subscriber line.

  Further, the access method of the present invention includes a plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, and a plurality of asymmetric digital subscriber lines connecting the subscriber and the station ( Asymmetric digital subscriber line access system access method having an ADSL line) and a demultiplexing device provided in a subscriber premises and demultiplexing a plurality of ADSL lines. Generating a plurality of packets, converting the packets into terminal line signals and sending them to the multiplexer / demultiplexer, wherein the multiplexer / demultiplexer receives a terminal line signal from the subscriber terminal device, Multiple packets are extracted from the line signal, and the extracted packets are distributed to multiple routes for each packet. Each of the received packets is converted into each of the upstream ADSL line signals, and each of the upstream ADSL line signals is sent to each of the plurality of ADSL lines, and in the digital subscriber line access apparatus, the demultiplexing Receiving each of the upstream ADSL line signals carried from each of the plurality of ADSL lines, extracting the packets from each of the upstream ADSL line signals, multiplexing these packets, and addressing the subscriber terminal device Generating a plurality of packets to be sent to each of the plurality of packets, distributing the plurality of packets into a plurality of routes for each packet, converting each of the distributed packets into each of the downlink ADSL line signals, and each of the downlink ADSL line signals Is sent to each of the plurality of ADSL lines, and in the demultiplexing device, the digital Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the subscriber line access device, a packet is extracted from each of the downlink ADSL line signals, and the plurality of extracted packets are multiplexed and multiplexed. Converting the received packet into a terminal line signal and sending the terminal line signal to the subscriber terminal device. The subscriber terminal device further receives a terminal line signal from the demultiplexer, A step of extracting and receiving the packet from the terminal line signal;

  Furthermore, the access program of the present invention includes a plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, and a plurality of asymmetric digital subscriber lines ( An access program for controlling an asymmetric digital subscriber line access system having an ADSL line) and a demultiplexer provided in a subscriber premises and demultiplexing a plurality of ADSL lines. Generating a plurality of packets for the terminal, converting the packets into terminal line signals and sending them to the demultiplexing apparatus, and receiving the terminal line signals from the subscriber terminal apparatus in the demultiplexing apparatus, Multiple packets are extracted from the line signal, and the extracted packets are distributed to multiple routes for each packet. Each of the distributed packets is converted into each of the upstream ADSL line signals, and each of the upstream ADSL line signals is transmitted to each of the plurality of ADSL lines, and in the digital subscriber line access apparatus, A process of receiving each of the upstream ADSL line signals carried via each of the plurality of ADSL lines from the separation device, extracting packets from each of the upstream ADSL line signals, and multiplexing these packets; and the subscriber terminal device Generating a plurality of packets to be sent to the destination, distributing the plurality of packets into a plurality of routes for each packet, converting each of the distributed packets into each of the downlink ADSL line signals, A process of sending each to a plurality of ADSL lines, and in the demultiplexing apparatus, Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the line access device, the packet is extracted from each of the downlink ADSL line signals, and the plurality of extracted packets are multiplexed and multiplexed. A process of converting the packet into a terminal line signal and sending the terminal line signal to the subscriber terminal device; and in the subscriber terminal device, further receiving the terminal line signal from the demultiplexer, and from the terminal line signal It is characterized by causing a computer to execute processing for extracting and receiving a packet.

  As an effect of the present invention, a terminal device and a digital subscriber line access device (DSLAM) are constituted by a multiple ADSL line formed by multiplexing a plurality of ADSL lines, and the terminal device and the digital subscriber line access device (DSLAM). ) Is increased, and the terminal device can access the Internet at high speed.

  Embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing the configuration of an access system according to the first embodiment of the present invention.

  Referring to FIG. 1, in the access system according to the first embodiment of the present invention, access from one terminal device 80 to a digital subscriber line access device (hereinafter referred to as DSLAM) 20 is multiplexed with a plurality of ADSL lines. It is configured to be performed by a multiple ADSL line configured as described above.

  The access system according to the first embodiment of the present invention includes a telephone exchange 10 for exchanging voice line telephone line signals and a digital subscriber line access apparatus (hereinafter referred to as DSLAM) for transmitting and receiving ADSL (asymmetric digital subscriber line) line signals. ) 20, a plurality of station-side band separation devices (hereinafter referred to as station-side POTS) 30-1, 30-2, 30-3, a telephone exchange 10 and a plurality of station-side POTS 30-1, 30-2, Station side telephone line 201 which connects 30-3 and carries a telephone line signal, and station side which connects DSLAM 20 and a plurality of station side POTS 30-1, 30-2 and 30-3 and carries an ADSL line signal A modem line 202 is provided in the office building, and a plurality of terminal side band separation devices (hereinafter referred to as terminal side POTS) 40-1, 40-2, 40-3, a demultiplexing device 50, and a plurality of terminal devices 80- 1, 0-2, 80-3, a plurality of telephones 90-1, 90-2, 90-3, a plurality of terminal side POTSs 40-1, 40-2, 40-3 and a plurality of telephones 90-1, A terminal side telephone line 204 that connects each of 90-2 and 90-3 and carries a telephone line signal, and a plurality of terminal side POTSs 40-1, 40-2, and 40-3 are connected to the demultiplexing device 50 to connect ADSL. A terminal-side modem line 205 that carries a line signal, an ETHER (registered trademark) that carries an Ethernet (registered trademark) line signal by connecting the multiplexer / demultiplexer 50 and a plurality of terminal devices 80-1, 80-2, 80-3. ) The line 206 is provided in the subscriber premises, each of the plurality of station side POTSs 30-1, 30-2, 30-3 provided in the station and the plurality of terminal side POTSs 40-1 provided in the subscriber premises, Each of 40-2 and 40-3 Configured to have each of the plurality of ADSL line 203-1,203-2,203-3 connecting.

  Each of the plurality of terminal devices 80-1, 80-2, 80-3 and each of the plurality of telephones 90-1, 90-2, 90-3 are provided in each room of the subscriber premises.

  Each of the plurality of ADSL lines 203-1, 203-2, and 203-3 includes a telephone line signal having a frequency band of 0 to 4 kHz, an ITU-TG. 992.1G. This is a line that carries a line signal composed of an ADSL line signal according to the dmt rule.

  The ADSL line signal is a line signal for the layer 1 ADSL interface as shown in FIG. 7, and as shown in FIG. 6, a maximum of 32 subcarriers in the frequency band 25k to 138 kHz. Is composed of an upstream ADSL line (terminal device 80 to DSLAM 20 direction) signal and a downstream ADSL line (DSLAM 20 to terminal device 80 direction) signal having a maximum frequency of 256 subcarriers in a frequency band of 138k to 1104 kHz.

  The station side POTS 30 receives a line signal transmitted from the terminal side POTS 40 via the ADSL line 203, separates the line signal into a telephone line signal and an upstream ADSL line signal, and separates the separated telephone line signal. It has a function of sending the separated upstream ADSL line signal to the DSLAM 20 via the station side modem line 202 as well as sending it to the telephone exchange 10 via the station side telephone line 201. Further, the station side POTS 30 receives a telephone line signal from the telephone exchange 10 via the station side telephone line 201, and receives a downlink ADSL line signal from the DSLAM 20 via the station side modem line 202. The line signal and the downstream ADSL line signal are combined to generate a line signal, and this line signal is transmitted to the terminal side POTS 40 via the ADSL line 203.

  The terminal-side POTS 40 receives a line signal transmitted from the station-side POTS 30 via the ADSL line 203, separates the line signal into a telephone line signal and a downlink ADSL line signal, and separates the separated telephone line signal. It has a function of sending to the telephone 90 via the terminal-side telephone line 204 and sending the separated downlink ADSL line signal to the demultiplexing device 50 via the terminal-side modem line 205. The terminal-side POTS 40 receives a telephone line signal from the telephone 90 via the terminal-side telephone line 204, and receives an upstream ADSL line signal from the multiplexer / demultiplexer 50 via the terminal-side modem line 205. The signal and the upstream ADSL line signal are combined to generate a line signal, and the line signal is transmitted to the station building side POTS 30 via the ADSL line 203.

  The terminal device 80 generates a plurality of IP packets, which are variable-length packets, for layer 3 IP (Internet Protocol) communication, which is a network layer as shown in FIG. 7, and sends the plurality of IP packets to the ETHER. A function of sending to the demultiplexing device 50 via the (registered trademark) line 206, and a function of receiving IP packets from the demultiplexing device 50 via the ETHER (registered trademark) line 206.

  The DSLAM 20 includes a packet generation unit 21, a packet reception unit 22, a packet demultiplexing unit 23, a plurality of ADSL line interface units 24-1, 24-2, and 24-3, and a program storage unit 25 that stores a control program. And a control unit 26 that controls the entire DSLAM 20 based on the control program.

  The packet generation unit 21 has a function of generating a plurality of variable-length packets to be transmitted to any one of the plurality of terminal devices 80, that is, a plurality of IP packets.

  The packet demultiplexing unit 23 distributes a plurality of IP packets from the packet generation unit 21 into a plurality of routes for each packet, that is, a plurality of ADSL line interface units 24-1, 24-2, 24 for each packet. -3 and a function of multiplexing IP packets from a plurality of ADSL line interface units 24-1, 24-2 and 24-3.

  Each of the ADSL line interface units 24-1, 24-2, and 24-3 transmits each of the IP packets distributed by the packet demultiplexing unit 23 for data link layer communication in the ADSL layer shown in FIG. 8 is converted into ATM (asynchronous transfer mode) cells, and the ATM cells are converted into downlink ADSL line signals, and each of the downlink ADSL line signals is converted into a plurality of station side POTS 30-1, A function of sending to each of 30-2 and 30-3, and converting each of a plurality of upstream ADSL line signals from each of the plurality of POTS 30-1, 30-2 and 30-3 to each of IP packets, A function of sending each of the IP packets to the packet demultiplexing unit 23.

  The packet receiving unit 22 has a function of receiving the IP packet multiplexed by the packet demultiplexing unit 23.

  The demultiplexing device 50 includes a demultiplexing unit 51, a plurality of ADSL line interface units 60-1, 60-2, 60-3, and a plurality of ETHER (registered trademark) line interfaces 70-1, 70-2, 70-. 3, a program storage unit 52 that stores a control program, and a control unit 53 that controls the entire multiplexer / demultiplexer 50 based on the control program.

  Each of the plurality of ADSL line interface units 60-1, 60-2, 60-3 converts each of the plurality of downlink ADSL line signals from each of the plurality of terminal-side POTSs 40 into each of IP packets. Each of the IP packets distributed to the demultiplexing unit 51 for each route are converted into ATM cells, and further converted into uplink ADSL line signals, Each of the ADSL line signals has a function of sending each of the plurality of terminal side POTSs 40-1, 40-2, 40-3.

  Any one of the ETHER (registered trademark) line interface 70 has a function of receiving an ETHER (registered trademark) line signal from the terminal device 80, extracting an IP packet from the line signal, and sending the IP packet to the demultiplexing unit 51. And a function of converting the IP packet from the demultiplexing unit 51 into an ETHER (registered trademark) line signal and sending the line signal to the terminal device 80.

The demultiplexing unit 51 multiplexes IP packets from each of the plurality of ADSL line interface units 60-1, 60-2, and 60-3 and sends them to the ETHER (registered trademark) line interface 70, and the ETHER ( A function of distributing a plurality of IP packets from a registered line interface 70 into a plurality of routes for each packet, that is, for each of a plurality of ADSL line interface units 60-1, 60-2, 60-3 for each packet. And a function of sorting.
Next, the operation of the embodiment of the present invention will be described in detail with reference to the drawings.

  2 is a diagram illustrating the flow of the downlink ADSL line signal, FIG. 3 is a diagram illustrating the flow of the uplink ADSL line signal, and FIG. 4 is a diagram illustrating multiplexing and demultiplexing of the line.

  The operation will be described mainly with reference to FIGS. 2, 3 and 4 with reference to FIG.

  First, an operation of sending an IP packet addressed to the terminal device 80-1 from the DSLAM 20 using a plurality of lines will be described.

  2 and 4, the packet generator 21 of the DSLAM 20 generates a plurality of IP packets P (1), P (2),..., P (n) addressed to the terminal device 80-1. IP packets P (1), P (2),..., P (n) are sent to the packet demultiplexing unit 23.

  The packet demultiplexing unit 23 distributes the plurality of IP packets P (1), P (2),..., P (n) from the packet generation unit 21 to a plurality of routes for each packet. (1) is assigned to the ADSL line interface unit 24-1, IP packet P (2) is assigned to the ADSL line interface unit 24-2, and IP packet P (3) is assigned to the ADSL line interface unit 24-3. Further, the packet demultiplexing unit 23 similarly distributes subsequent IP packets P (4) to P (n) to the ADSL line interface unit 24 in order for each packet. In the following description, only the IP packets P (1), P (2), and P (3) will be described.

  The ADSL line interface unit 24-1 converts the IP packet P (1) from the packet demultiplexing unit 23 into an ATM cell, further converts it into a downlink ADSL line signal DS1, and converts the downlink ADSL line signal DS1 to the station building. To the side POTS 30-1. Similarly, the ADSL line interface unit 24-2 converts the IP packet P (2) from the packet demultiplexing unit 23 into an ATM cell, further converts it into a downlink ADSL line signal DS2, and converts the downlink ADSL line signal DS2 into the ATM cell. To the station side POTS 30-2. Similarly, the ADSL line interface unit 24-3 converts the IP packet P (3) from the packet demultiplexing unit 23 into an ATM cell, further converts it into a downlink ADSL line signal DS3, and the downlink ADSL line signal. DS3 is sent to the station side POTS 30-3.

  The station-side POTS 30-1 sends the downlink ADSL line signal DS1 from the ADSL line interface unit 24-1 to the ADSL line 203-1, and the station-side POTS 30-2 transmits the downlink ADSL line signal DS1 from the ADSL line interface unit 24-2. The ADSL line signal DS2 is sent to the ADSL line 203-2, and the station side POTS 30-3 sends the downlink ADSL line signal DS3 from the ADSL line interface unit 24-3 to the ADSL line 203-3.

  The terminal-side POTS 40-1 receives the downlink ADSL line signal DS1 from the ADSL line 203-1, sends the downlink ADSL line signal DS1 to the ADSL line interface unit 60-1 of the demultiplexer 50, and the terminal-side POTS 40-2 The downlink ADSL line signal DS2 is received from the ADSL line 203-2, the downlink ADSL line signal DS2 is sent to the ADSL line interface unit 60-2, and the terminal side POTS 40-3 receives the downlink ADSL line signal DS3 from the ADSL line 203-3. The downstream ADSL line signal DS3 is received and sent to the ADSL line interface unit 60-3.

  The ADSL line interface unit 60-1 takes out the IP packet P (1) from the downlink ADSL line signal DS1 from the terminal side POTS 40-1, and sends the IP packet P (1) to the demultiplexing unit 51, so that the ADSL line interface The unit 60-2 takes out the IP packet P (2) from the downlink ADSL line signal DS2 from the terminal side POTS 40-2, and sends the IP packet P (2) to the demultiplexing unit 51, so that the ADSL line interface unit 60- 3 extracts the IP packet P (3) from the downlink ADSL line signal DS3 from the terminal side POTS 40-3, and sends the IP packet P (3) to the demultiplexing unit 51.

  The demultiplexing unit 51 includes an IP packet P (1) from the ADSL line interface unit 60-1, an IP packet P (2) from the ADSL line interface unit 60-2, and an IP packet P from the ADSL line interface unit 60-3. (3) is multiplexed, and the multiplexed IP packet is sent to the ETHER (registered trademark) line interface 70-1.

  The ETHER (registered trademark) line interface 70-1 converts the multiplexed IP packet from the demultiplexing unit 51 into an ETHER (registered trademark) line signal, and transmits this line signal to the terminal device 80-1.

  Next, an operation of sending an IP packet from the terminal device 80-1 to the DSLAM 20 using a plurality of lines will be described.

  3 and 4, the terminal device 80-1 generates a plurality of IP packets P (1), P (2), ..., P (n), and these IP packets P (1), P (2) to P (n) are converted into ETHER (registered trademark) line signals, and the line signals are sent to the ETHER (registered trademark) line interface 70-1 of the demultiplexer 50.

  The ETHER (registered trademark) line interface 70-1 extracts a plurality of IP packets P (1), P (2),..., P (n) from the ETHER (registered trademark) line signal from the terminal device 80-1. These IP packets P (1), P (2),..., P (n) are sent to the demultiplexing unit 51.

  The demultiplexing unit 51 distributes a plurality of IP packets P (1), P (2),..., P (n) from the ETHER (registered trademark) line interface 70-1 to a plurality of routes for each packet. That is, the IP packet P (1) is sent to the ADSL line interface unit 60-1, the IP packet P (2) is sent to the ADSL line interface unit 60-2, and the IP packet P (3) is sent to the ADSL line interface unit 60-3. Distribute. Further, the demultiplexing unit 51 similarly distributes the subsequent IP packets P (4) to P (n) to the ADSL line interface unit 60 in order for each packet. In the following description, only the IP packets P (1), P (2), and P (3) will be described.

  The ADSL line interface unit 60-1 converts the IP packet P (1) from the demultiplexing unit 51 into an ATM cell, further converts it into an upstream ADSL line signal US1, and converts the upstream ADSL line signal US1 to the terminal side POTS 40- Send to 1. Similarly, the ADSL line interface unit 60-2 converts the IP packet P (2) from the demultiplexing unit 51 into an ATM cell, further converts it into an upstream ADSL line signal US2, and converts the upstream ADSL line signal US2 to Send to terminal side POTS 40-2. Similarly, the ADSL line interface unit 60-3 converts the IP packet P (3) from the demultiplexing unit 51 into an ATM cell, further converts it into an upstream ADSL line signal US3, and the upstream ADSL line signal US3. Is sent to the terminal-side POTS 40-3.

  The terminal side POTS 40-1 sends the upstream ADSL line signal US1 from the ADSL line interface unit 60-1 to the ADSL line 203-1, and the terminal side POTS 40-2 sends the upstream ADSL line from the ADSL line interface unit 60-2. The signal US2 is sent to the ADSL line 203-2, and the terminal side POTS 40-3 sends the upstream ADSL line signal US3 from the ADSL line interface unit 60-3 to the ADSL line 203-3.

  The station side POTS 30-1 receives the upstream ADSL line signal US1 from the ADSL line 203-1, and sends the upstream ADSL line signal US1 to the ADSL line interface unit 24-1 of the DSLAM 20, and the station side POTS 30-2 receives the ADSL line signal US1. The upstream ADSL line signal US2 is received from the line 203-2, the upstream ADSL line signal US2 is sent to the ADSL line interface unit 24-2, and the station side POTS 30-3 receives the upstream ADSL line signal US3 from the ADSL line 203-3. Then, the upstream ADSL line signal US3 is sent to the ADSL line interface unit 24-3.

  The ADSL line interface unit 24-1 takes out the IP packet P (1) from the upstream ADSL line signal US1 from the station side POTS 30-1, and sends this IP packet P (1) to the packet demultiplexing unit 23. The line interface unit 24-2 takes out the IP packet P (2) from the upstream ADSL line signal US2 from the station side POTS 30-2, and sends the IP packet P (2) to the packet demultiplexing unit 23, so that the ADSL line interface The unit 24-3 extracts the IP packet P (3) from the upstream ADSL line signal US3 from the station side POTS 30-3, and sends the IP packet P (3) to the packet demultiplexing unit 23.

  The packet demultiplexing unit 23 includes an IP packet P (1) from the ADSL line interface unit 24-1, an IP packet P (2) from the ADSL line interface unit 24-2, and an IP packet from the ADSL line interface unit 24-3. P (3) is multiplexed and the multiplexed IP packet is sent to the packet receiver 22.

  As described above, the present invention distributes a plurality of IP packets from the terminal device 80 to each of a plurality of routes for each IP packet, converts each of the distributed IP packets into an ATM cell, Each of the ADSL line signals is converted to each of the ADSL line signals, and each of the ADSL line signals is carried to the DSLAM 20 by each of the plurality of ADSL lines 203, and each of the IP packets is transmitted from each of the ADSL line signals carried by each of the plurality of ADSL lines 203. Since the terminal device 80 and the DSLAM 20 are connected by a broadband line, the terminal device 80 can be accessed by high-speed data.

  In the present invention, a plurality of IP packets from the terminal device 80 are distributed for each IP packet and sent through each of the plurality of ADSL lines 203, and the DSLAM 20 is configured to multiplex these IP packets. Even if there is a difference in the arrival time of each IP packet to the DSLAM 20 due to the delay time difference between each of the ADSL lines 203, the DSLAM 20 receives the signals from the terminal device 80 in the correct order by the sequence number of each IP packet. it can.

  Next, a second embodiment of the present invention will be described.

  In the second embodiment, the interface with the terminal device 80 is replaced with an ITU-TG. It is configured to include a VDSL (Very High Bit Rate Subscriber Subscriber Line) interface defined in 993.1.

  FIG. 5 is a configuration block diagram of an access system according to the second embodiment of the present invention.

  Referring to FIG. 5, the access system according to the second embodiment of the present invention includes a telephone switch 10, a DSLAM 20a, a plurality of POTS 30-1, 30-2, 30-3, and a telephone switch 10. A station side telephone line 201 that connects a plurality of station side POTSs 30-1, 30-2, 30-3 and carries telephone line signals, a DSLAM 20a, and a plurality of station side POTSs 30-1, 30-2, 30- 3 and a station side modem line 202 for carrying an ADSL line signal in the station building, a plurality of terminal side POTSs 40-1, 40-2, 40-3, a demultiplexing device 50a, Two home-side POTSs 110-1, 110-2, 110-3, a plurality of first home-side POTSs 130-1, 130-2, 130-3, and a plurality of VDSL (Very High Bit Rate Digits) al Subscriber Line; high-speed digital subscriber line) modems 120-1, 120-2, 120-3, a plurality of terminal devices 80-1, 80-2, 80-3, and a plurality of telephones 90-1, 90- 2, 90-3, a plurality of terminal side POTSs 40-1, 40-2, 40-3 and a plurality of second in-house POTSs 110-1, 110-2, 110-3 are connected to each other and telephone line signals A terminal-side telephone line 204 that carries the ADSL line signal, a terminal-side modem line 205 that connects the demultiplexer 50a to each of the terminal POTSs 40-1, 40-2, and 40-3, and a demultiplexer 50a. And a plurality of second in-house POTSs 110-1, 110-2, 110-3 to carry a VDSL line signal and a plurality of second in-home POTSs 110-1. 110-2, 110-3 and a plurality of first in-home POTSs 130-1, 130-2, 130-3, a VDSL line 207 for carrying a VDSL line signal, a first in-home POTS 130 and a telephone 90, a room side telephone line 209 that carries a telephone line signal, a room side VDSL line 210 that connects the first in-house POTS 130 and the VDSL modem 120 and carries a VDSL line signal, a VDSL modem 120, and a terminal device 80 And a terminal-side VDSL line 211 that carries a VDSL line signal are provided in the subscriber premises, and each of the plurality of station-side POTSs 30-1, 30-2, 30-3 provided in the station premises and the subscriber premises A plurality of ADSL lines 203-1, 203-2, 203-connecting each of a plurality of terminal-side POTSs 40-1, 40-2, 40-3 provided Each of the three.

  Each of the plurality of terminal devices 80-1, 80-2, 80-3, each of the plurality of telephones 90-1, 90-2, 90-3, and the plurality of first in-house POTSs 130-1, 130-2 , 130-3 and each of the plurality of VDSL modems 120-1, 120-2, 120-3 are provided in each room on the subscriber premises.

  Components having the same functions as the components constituting the first embodiment are assigned the same reference numerals as the components constituting the second embodiment. Therefore, only components that are different from the components constituting the first embodiment will be described.

  The DSLAM 20a includes a packet generation unit 21a, a packet reception unit 22a, a packet demultiplexing unit 23a, a plurality of ADSL line interface units 24a-1, 24a-2, and 24a-3, and a program storage unit 25a that stores a control program. And a control unit 26a that controls the entire DSLAM 20a based on the control program.

  The packet generation unit 21a has a function of generating a plurality of fixed-length packets to be transmitted to any one of the plurality of terminal devices 80, that is, a plurality of ATM cells.

  The packet demultiplexing unit 23a distributes a plurality of ATM cells from the packet generation unit 21a to a plurality of routes for each ATM cell, that is, a plurality of ADSL line interface units 24a-1 and 24a-2 for each ATM cell. 24a-3, and a function of multiplexing ATM cells from a plurality of ADSL line interface units 24a-1, 24a-2, 24a-3.

  Each of the ADSL line interface units 24a-1, 24a-2, 24a-3 converts each of the ATM cells distributed by the packet demultiplexing unit 23a into each of the downlink ADSL line signals, and the downlink ADSL line signal A function of sending each to a plurality of station side POTSs 30-1, 30-2, 30-3 and a plurality of upstream ADSL lines from each of the plurality of station side POTSs 30-1, 30-2, 30-3 Each of the signals is converted into each ATM cell, and each ATM cell is sent to the packet demultiplexing unit 23.

  The packet receiving unit 22a has a function of receiving ATM cells multiplexed by the packet demultiplexing unit 23.

  The demultiplexer 50a includes a demultiplexer 51a, a plurality of ADSL line interface units 60a-1, 60a-2, and 60a-3, a plurality of VDSL line interfaces 71-1, 71-2, and 71-3, and a control. A program storage unit 52a for storing the program and a control unit 53a for controlling the entire demultiplexing device 50a based on the control program are configured.

  Each of the plurality of ADSL line interface units 60a-1, 60a-2, 60a-3 converts each of the plurality of downlink ADSL line signals from each of the plurality of terminal side POTSs 40 into each of the ATM cells. A function of sending each of the ADSL line signals to the demultiplexing unit 51a, and converting each of the ATM cells distributed for each route by the demultiplexing unit 51a into each of the upstream ADSL line signals. And a function of sending to each of the terminal side POTS 40-1, 40-2, 40-3.

  Each of the plurality of VDSL line interfaces 71-1, 71-2, 71-3 transmits the multiplexed ATM cell from the demultiplexing unit 51a to the ITU-TG. 993.1 stipulated VDSL line signal, a function of sending this line signal to the second in-house POTS 110 and a plurality of ATM cells are extracted from the VDSL line signal from the second in-house POTS 110, and the plurality of ATM cells are multiplexed. And a function of sending to the separation unit 51a.

  The demultiplexing unit 51 a has a function of multiplexing ATM cells from each of the plurality of ADSL line interface units 60 a-1, 60 a-2, and 60 a-3 and sending the multiplexed ATM cells to the VDSL line interface 71, and from the VDSL line interface 71 It has a function of distributing a plurality of ATM cells to a plurality of routes for each ATM cell, that is, a function of distributing each of the plurality of ADSL line interface units 60a-1, 60a-2, 60a-3 for each ATM cell.

  The second premises POTS 110 synthesizes the VDSL line signal from the VDSL line interface 71 and the telephone line signal from the terminal side POTS 40 to obtain a synthesized signal, and sends the synthesized signal to the first premises POTS 130; Upon receipt of a synthesized signal obtained by synthesizing the VDSL line signal and the telephone line signal from the in-house POTS 130, the telephone line signal and the VDSL line signal are separated from the synthesized signal, and the separated telephone line signal is transmitted to the terminal side. It has a function of sending the separated VDSL line signal to the demultiplexer 50a while sending it to the POTS 40.

  The first premises POTS 130 combines the VDSL line signal from the VDSL modem 120 and the telephone line signal from the telephone 90 to obtain a combined signal, and combines this combined signal with the telephone line signal from the terminal side POTS 40. Then, a function of sending the synthesized signal to the second in-house POTS 110 and a synthesized signal in which the VDSL line signal and the telephone line signal are synthesized from the second in-house POTS 110 are received, and the telephone line is obtained from the synthesized signal. It has a function of separating the signal and the VDSL line signal, sending the separated telephone line signal to the telephone set 90, and sending the separated VDSL line signal to the VDSL modem 120.

  The VDSL modem 120 transmits the ATM cell from the terminal device 80 to the ITU-TG. A VDSL line signal of 993.1 standard, a function of sending this VDSL line signal to the first in-house POTS 130, a VDSL line signal from the first in-house POTS 130, taking out an ATM cell from the VDSL line signal, The ATM cell is converted to a terminal interface signal and sent to the terminal device 80.

  The operation will be described.

  First, an operation of sending a plurality of ATM cells addressed to the terminal device 80-1 from the DSLAM 20a using a plurality of ADSL lines will be described.

  5 and 4, the packet generator 21a of the DSLAM 20a generates a plurality of ATM cells P (1), P (2),..., P (n) addressed to the terminal device 80-1. ATM cells P (1), P (2),..., P (n) are sent to the packet demultiplexing unit 23a.

  The packet demultiplexing unit 23a distributes the plurality of ATM cells P (1), P (2),..., P (n) from the packet generation unit 21 to a plurality of routes for each ATM cell. P (1) is assigned to the ADSL line interface unit 24a-1, ATM cell P (2) is assigned to the ADSL line interface unit 24a-2, and ATM cell P (3) is assigned to the ADSL line interface unit 24a-3. Further, the packet demultiplexing unit 23a similarly distributes the subsequent ATM cells P (4) to P (n) to the ADSL line interface unit 24a in order for each packet. In the following description, only the ATM cells P (1), P (2), and P (3) will be described.

  The ADSL line interface unit 24a-1 converts the ATM cell P (1) from the packet demultiplexing unit 23a into the downlink ADSL line signal DS1, and sends the downlink ADSL line signal DS1 to the station side POTS 30-1. Similarly, the ADSL line interface unit 24a-2 converts the ATM cell P (2) from the packet demultiplexing unit 23 into a downlink ADSL line signal DS2, and sends the downlink ADSL line signal DS2 to the station side POTS 30-2. send. Similarly, the ADSL line interface unit 24a-3 converts the ATM cell P (3) from the packet demultiplexing unit 23 into the downlink ADSL line signal DS3, and converts the downlink ADSL line signal DS3 to the station side POTS 30- Send to 3.

  The station side POTS 30-1 sends the downstream ADSL line signal DS1 from the ADSL line interface unit 24a-1 to the ADSL line 203-1, and the station side POTS 30-2 transmits the downstream ADSL line signal unit 24a-2 from the ADSL line interface unit 24a-2. The ADSL line signal DS2 is sent to the ADSL line 203-2, and the station side POTS 30-3 sends the downlink ADSL line signal DS3 from the ADSL line interface unit 24a-3 to the ADSL line 203-3.

  The terminal-side POTS 40-1 receives the downlink ADSL line signal DS1 from the ADSL line 203-1, sends the downlink ADSL line signal DS1 to the ADSL line interface unit 60a-1 of the demultiplexer 50a, and the terminal-side POTS 40-2 The downstream ADSL line signal DS2 is received from the ADSL line 203-2, the downstream ADSL line signal DS2 is sent to the ADSL line interface unit 60a-2, and the terminal side POTS 40-3 receives the downstream ADSL line signal DS3 from the ADSL line 203-3. The downstream ADSL line signal DS3 is received and sent to the ADSL line interface unit 60a-3.

  The ADSL line interface unit 60a-1 takes out the ATM cell P (1) from the downlink ADSL line signal DS1 from the terminal side POTS 40-1, and sends this ATM cell to the demultiplexing unit 51a, and the ADSL line interface unit 60a-2. The ATM cell is extracted from the downstream ADSL line signal DS2 from the terminal side POTS 40-2, and this ATM cell P (2) is sent to the demultiplexing unit 51a. The ADSL line interface unit 60a-3 is connected to the terminal side POTS 40-3. The ATM cell P (3) is taken out from the downstream ADSL line signal DS3 from the mobile phone, and this ATM cell P (3) is sent to the demultiplexing unit 51a.

  The demultiplexing unit 51a includes an ATM cell P (1) from the ADSL line interface unit 60a-1, an ATM cell P (2) from the ADSL line interface unit 60a-2, and an ATM cell P from the ADSL line interface unit 60a-3. (3) is multiplexed and the multiplexed ATM cell is sent to the VDSL line interface 71-1.

  The VDSL line interface 71-1 converts the multiplexed ATM cell from the demultiplexing unit 51a into a VDSL line signal, and transmits this VDSL line signal to the second premises POTS 110-1.

  The second in-home POTS 110-1 further sends the VDSL line signal from the VDSL line interface 71-1 to the first in-home POTS 130-1.

  The first premises POTS 130-1 sends the VDSL line signal from the second premises POTS 110-1 to the VDSL modem 120-1.

  The VDSL modem 120-1 extracts the ATM cell from the VDSL line signal, converts this ATM cell into a terminal interface signal, and sends it to the terminal device 80-1.

  Next, an operation of sending ATM cells from the terminal device 80-1 to the DSLAM 20a using a plurality of ADSL lines will be described.

  5 and 4, the terminal device 80-1 generates a plurality of ATM cells P (1), P (2), ..., P (n), and these ATM cells P (1), P (2),..., P (n) are converted into terminal interface signals, and the terminal interface signals are sent to the VDSL modem 120-1.

  The VDSL modem 120-1 converts the ATM cells P (1), P (2),..., P (n) from the terminal device 80-1 into VDSL line signals, and converts the VDSL line signals into the first in-home POTS 130. -1.

  The first in-home POTS 130-1 further sends the VDSL line signal from the VDSL modem 120-1 to the second in-home POTS 110-1.

  The second home POTS 110-1 sends the VDSL line signal from the first home POTS 130-1 to the VDSL line interface 71-1 of the demultiplexer 50a.

  The VDSL line interface 71-1 takes out a plurality of VDSL line interfaces 71-1 P (1), P (2), P (n) from the VDSL line signal from the second in-house POTS 110-1, The ATM cells P (1), P (2),..., P (n) are sent to the demultiplexing unit 51a.

  The demultiplexing unit 51a distributes the plurality of ATM cells P (1), P (2),..., P (n) from the VDSL line interface 71-1 to a plurality of routes for each ATM cell. The cell P (1) is distributed to the ADSL line interface unit 60a-1, the ATM cell P (2) is distributed to the ADSL line interface unit 60a-2, and the ATM cell P (3) is distributed to the ADSL line interface unit 60a-3. Furthermore, the demultiplexing unit 51a similarly distributes the subsequent ATM cells P (4) to P (n) to the ADSL line interface unit 60a in order for each ATM cell. In the following description, only the ATM cells P (1), P (2), and P (3) will be described.

  The ADSL line interface unit 60a-1 converts the ATM cell P (1) from the demultiplexing unit 51a into an upstream ADSL line signal US1, and sends the upstream ADSL line signal US1 to the terminal side POTS 40-1. Similarly, the ADSL line interface unit 60a-2 converts the ATM cell P (2) from the demultiplexing unit 51a into the upstream ADSL line signal US2, and sends the upstream ADSL line signal US2 to the terminal side POTS 40-2. Similarly, the ADSL line interface unit 60a-3 converts the ATM cell P (3) from the demultiplexing unit 51a into an upstream ADSL line signal US3, and sends the upstream ADSL line signal US3 to the terminal side POTS 40-3. .

  The terminal side POTS 40-1 sends the upstream ADSL line signal US1 from the ADSL line interface unit 60-1 to the ADSL line 203-1, and the terminal side POTS 40-2 sends the upstream ADSL line from the ADSL line interface unit 60-2. The signal US2 is sent to the ADSL line 203-2, and the terminal side POTS 40-3 sends the upstream ADSL line signal US3 from the ADSL line interface unit 60-3 to the ADSL line 203-3.

  The station side POTS 30-1 receives the upstream ADSL line signal US1 from the ADSL line 203-1 and sends the upstream ADSL line signal US1 to the ADSL line interface unit 24a-1 of the DSLAM 20a. The station side POTS 30-2 receives the ADSL line signal US1. The upstream ADSL line signal US2 is received from the line 203-2, the upstream ADSL line signal US2 is sent to the ADSL line interface unit 24a-2, and the station side POTS 30-3 receives the upstream ADSL line signal US3 from the ADSL line 203-3. The upstream ADSL line signal US3 is received and sent to the ADSL line interface unit 24a-3.

  The ADSL line interface unit 24a-1 takes out the ATM cell P (1) from the upstream ADSL line signal US1 from the station side POTS 30-1, and sends this ATM cell P (1) to the packet demultiplexing unit 23a. The line interface unit 24a-2 takes out the ATM cell P (2) from the upstream ADSL line signal US2 from the station side POTS 30-2, and sends this ATM cell P (2) to the packet demultiplexing unit 23a to send the ADSL line interface. The unit 24a-3 extracts the ATM cell P (3) from the upstream ADSL line signal US3 from the station side POTS 30-3, and sends this ATM cell P (3) to the packet demultiplexing unit 23a.

  The packet demultiplexing unit 23a includes an ATM cell P (1) from the ADSL line interface unit 24a-1, an ATM cell P (2) from the ADSL line interface unit 24a-2, and an ATM cell from the ADSL line interface unit 24a-3. P (3) is multiplexed and the multiplexed ATM cell is sent to the packet receiver 22a.

  As described above, the present invention is configured such that communication between a single terminal device and a digital subscriber line access device (DSLAM) is performed by a multiple ADSL line configured by multiplexing a plurality of ADSL lines. Therefore, the line bandwidth between the terminal device and the digital subscriber line access device (DSLAM) is increased, and high-speed data access from the terminal device can be realized.

1 is a configuration block diagram of an access system according to a first embodiment of the present invention. It is a figure which shows the flow of a downstream ADSL line signal. It is a figure which shows the flow of an upstream ADSL line signal. It is a figure explaining multiplexing and separation of a line. It is a block diagram of the configuration of the access system according to the second embodiment of the present invention. It is a figure which shows the power spectrum of an ADSL line. It is a figure which shows the hierarchy of ADSL. It is a figure which shows the structure of an ATM cell.

Explanation of symbols

10 telephone exchange 20 DSLAM
30 POTS side POTS
40 Terminal side POTS
DESCRIPTION OF SYMBOLS 50 Demultiplexing device 51 Demultiplexing part 52 Program memory | storage part 53 Control part 60 ADSL line interface part 70 ETHER (trademark) line interface 71 VDSL line interface 80 Terminal device 90 Telephone 110 Second in-house POTS
120 VDSL modem 130 1st premises POTS
201 Station side telephone line 202 Station side modem line 203-1, 203-2, 203-3 ADSL line 204 Terminal side telephone line 205 Terminal side modem line 206 ETHER (registered trademark) line 207 VDSL line 208 VDSL modem line 209 Room side telephone line 210 Room side VDSL line 211 Terminal side VDSL line

Claims (10)

A plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, the subscriber terminal device and the digital subscriber line access device are connected, and the digital subscriber line access is performed. A plurality of asymmetric digital subscriber lines (ADSL lines) carrying a downstream ADSL line signal flowing from a device to the subscriber terminal device and an upstream ADSL line signal flowing from the subscriber terminal device to the digital subscriber line access device; An asymmetric digital subscriber line access system comprising:
Multiplexing means for multiplexing downstream ADSL line signals flowing through each of the plurality of ADSL lines from the digital subscriber line access apparatus, and signals from the subscriber terminal apparatus are distributed to a plurality of upstream ADSL line signals. An asymmetric digital subscriber line access system comprising: a demultiplexer having a demultiplexing unit for transmitting each upstream ADSL line signal to each of a plurality of ADSL lines. The asymmetric digital subscriber line access system according to claim 1,
The subscriber terminal device has a means for generating a plurality of packets for communication, converting these packets into a terminal line signal, and sending it to the demultiplexing device,
The multiplexer / demultiplexer receives a terminal line signal from the subscriber terminal device, extracts a plurality of packets from the terminal line signal, and distributes the extracted packets to a plurality of routes for each packet. Each of the received packets is converted into each of the upstream ADSL line signals, and each of the upstream ADSL line signals is sent to each of the plurality of ADSL lines,
The digital subscriber line access device receives each of the upstream ADSL line signals carried via each of the plurality of ADSL lines from the demultiplexing device, extracts packets from each of the upstream ADSL line signals, and these packets And a plurality of packets to be sent to the subscriber terminal device, the plurality of packets are distributed to a plurality of routes for each packet, and each of the distributed packets is assigned to the downlink ADSL line signal. Means for converting each of the downstream ADSL line signals to each of a plurality of ADSL lines,
The demultiplexer further comprises:
Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the digital subscriber line access device, a packet is extracted from each of the downlink ADSL line signals, and the plurality of extracted packets are multiplexed. And means for converting the multiplexed packet into a terminal line signal and sending the terminal line signal to the subscriber terminal device,
2. The asymmetric digital subscriber line access system according to claim 1, wherein the subscriber terminal apparatus further comprises means for receiving a terminal line signal from the demultiplexing apparatus and extracting and receiving a packet from the terminal line signal. 3. The asymmetric digital subscriber line access system according to claim 2, wherein the packet is an IP (Internet Protocol) packet. 3. The asymmetric digital subscriber line access system according to claim 2, wherein the packet is an ATM (Asynchronous Transfer Mode) cell. The asymmetric digital subscriber line access system according to claim 1,
The subscriber terminal device has means for generating a plurality of IP packets for IP (Internet Protocol) communication, converting the IP packets into a terminal line signal, and sending it to the demultiplexing device;
The demultiplexing device receives a terminal line signal from the subscriber terminal device, extracts a plurality of IP packets from the terminal line signal, distributes the extracted plurality of IP packets into a plurality of routes for each packet, Each of the distributed IP packets is divided into ATM (asynchronous transfer mode) cells, further converted into each of upstream ADSL line signals, and each of the upstream ADSL line signals is transmitted to each of a plurality of ADSL lines. Having means,
The digital subscriber line access device receives each of the upstream ADSL line signals carried via each of the plurality of ADSL lines from the demultiplexing device, extracts an IP packet from each of the upstream ADSL line signals, and A means for multiplexing IP packets and a plurality of IP packets to be sent to the subscriber terminal device are generated, the plurality of IP packets are distributed to a plurality of routes for each packet, and each of the distributed IP packets is , Dividing into ATM (Asynchronous Transfer Mode) cells, further converting each of the downlink ADSL line signals into each of the plurality of ADSL lines,
The demultiplexer further comprises:
Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the digital subscriber line access device, an IP packet is extracted from each of the downlink ADSL line signals, and the extracted plurality of IP packets are Multiplexing, converting the multiplexed IP packet into a terminal line signal, and sending the terminal line signal to the subscriber terminal device;
2. The asymmetric digital subscriber line access system according to claim 1, wherein the subscriber terminal apparatus further comprises means for receiving a terminal line signal from the demultiplexing apparatus and extracting and receiving an IP packet from the terminal line signal. 6. The asymmetric digital subscriber line access system according to claim 2, wherein the terminal line signal is a signal for an ETHER line interface defined by IEEE 802.3. Subscriber line access system. 3. The asymmetric digital subscriber line access system according to claim 2, wherein the terminal line signal is ITU-TG. An asymmetric digital subscriber line access system characterized by being a signal for a VDSL (Very High Bit Rate Digital Subscriber Line) interface defined in 993.1. A plurality of subscriber terminal devices provided in a subscriber premises, a digital subscriber line access device provided in a station, the subscriber terminal device and the digital subscriber line access device are connected, and the digital subscriber line access is performed. A plurality of asymmetric digital subscriber lines (ADSL lines) carrying a downstream ADSL line signal flowing from a device to the subscriber terminal device and an upstream ADSL line signal flowing from the subscriber terminal device to the digital subscriber line access device; An access method for an asymmetric digital subscriber line access system, comprising:
Multiplexing step for multiplexing downlink ADSL line signals flowing from the digital subscriber line access device through each of a plurality of ADSL lines, and a signal from the subscriber terminal device are divided into a plurality of uplink ADSL line signals. And a separation step of sending each of the upstream ADSL line signals to each of a plurality of asymmetric digital subscriber lines. A plurality of subscriber terminal devices provided in the subscriber premises, a digital subscriber line access device provided in the station, a plurality of asymmetric digital subscriber lines (ADSL lines) connecting the subscriber and the station, and the subscriber premises An access method for an asymmetric digital subscriber line access system, comprising: a demultiplexer for demultiplexing a plurality of ADSL lines,
In the subscriber terminal device, generating a plurality of packets for communication, converting these packets into a terminal line signal and sending to the demultiplexing device,
The multiplexer / demultiplexer receives a terminal line signal from the subscriber terminal apparatus, extracts a plurality of packets from the terminal line signal, and distributes the extracted packets to a plurality of routes for each packet. Converting each of the received packets into each of the upstream ADSL line signals, and sending each of the upstream ADSL line signals to each of the plurality of ADSL lines,
In the digital subscriber line access apparatus, each of the upstream ADSL line signals carried via each of the plurality of ADSL lines is received from the demultiplexing apparatus, a packet is extracted from each of the upstream ADSL line signals, and these packets are received. And generating a plurality of packets to be sent to the subscriber terminal device, distributing the plurality of packets to a plurality of routes for each packet, and distributing each of the distributed packets to a downlink ADSL line signal Converting each of the downstream ADSL line signals to each of a plurality of ADSL lines,
In the demultiplexer, further,
Each of the downlink ADSL line signals carried via each of the plurality of ADSL lines is received from the digital subscriber line access device, a packet is extracted from each of the downlink ADSL line signals, and the plurality of extracted packets are multiplexed. Converting the multiplexed packet into a terminal line signal and sending the terminal line signal to the subscriber terminal device;
The subscriber terminal apparatus further comprises a step of receiving a terminal line signal from the multiplexer / demultiplexer and extracting and receiving a packet from the terminal line signal. A plurality of subscriber terminal devices provided in the subscriber premises, a digital subscriber line access device provided in the station, a plurality of asymmetric digital subscriber lines (ADSL lines) connecting the subscriber and the station, and the subscriber premises An access program for controlling an asymmetric digital subscriber line access system, comprising: a demultiplexer configured to demultiplex a plurality of ADSL lines;
In the subscriber terminal device, a process of generating a plurality of packets for communication, converting these packets into a terminal line signal, and sending it to the demultiplexing device;
In the demultiplexing device, a terminal line signal is received from the subscriber terminal device, a plurality of packets are extracted from the terminal line signal, and the extracted packets are distributed to a plurality of routes for each packet. Converting each of the received packets into each of the upstream ADSL line signals, and sending each of the upstream ADSL line signals to each of the plurality of ADSL lines;
In the digital subscriber line access apparatus, each of the upstream ADSL line signals carried via each of the plurality of ADSL lines is received from the demultiplexing apparatus, a packet is extracted from each of the upstream ADSL line signals, and these packets are received. And a plurality of packets to be sent to the subscriber terminal device, and the plurality of packets are distributed to a plurality of routes for each packet, and each of the distributed packets is assigned to the downlink ADSL line signal. A process of converting each of the downstream ADSL line signals to each of a plurality of ADSL lines;
The multiplexer / demultiplexer further receives, from the digital subscriber line access device, each downlink ADSL line signal carried via each of the plurality of ADSL lines, and extracts and extracts a packet from each of the downlink ADSL line signals. A plurality of received packets, converting the multiplexed packets into terminal line signals, and sending the terminal line signals to the subscriber terminal device;
In the subscriber terminal device, further, a process of receiving a terminal line signal from the demultiplexing device, extracting and receiving a packet from the terminal line signal,
An access program that is executed by a computer.

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