JP2003087402A - Access network system and its control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an access network system and its control method that can prevent wasteful assignment and use so as to be able to efficiently utilize a communication band. SOLUTION: The access system network for interconnecting a terminal used by a subscriber with a line switch network being a relay system in a public network comprise; an access network device that assembles data received from the terminal into packets and transmits the packets, and disassembles received packetized data into data and transfers the data to the terminal; and a subscriber switch that disassembles the packetized data received from the access network into data, transfers the data to a prescribed transmission destination in the line switch network, assembles the data received from the line switch network into packets and transfers the packets to the access network.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an access network system for connecting a subscriber exchange and a terminal device such as a subscriber telephone and a control method thereof.

[0002]

2. Description of the Related Art A public network for providing a uniform communication service to an unspecified number of subscribers is divided into an access system and a relay system with a subscriber exchange as a boundary. The access system is the part that connects the terminal devices used by subscribers such as subscriber telephones and information processing devices to the subscriber exchange, and the relay system is the local network that provides communication services in the city area, long-distance communication service. It is a hierarchically constructed network that includes a long-distance network that provides Internet services and an international network that provides communication services with foreign countries. Hereinafter, the access system will be referred to as an access network system, and the relay system will be referred to as a circuit switching network.

FIG. 6 is a block diagram showing an example of the configuration of an access network system.

As shown in FIG. 6, the access network system includes a plurality of terminal devices 1 ₁ to 1 _n used by subscribers.
(N is a positive number) The access network device 4 that concentrates the line with the data, and the data received from the terminal device via the access network device 4 is transferred to a predetermined destination in the circuit switching network 6 and the circuit is switched The configuration includes a subscriber exchange 5 that transfers data received from the network 6 to the access network device 4. The terminal devices 1 ₁ to 1 _n are connected to the access network device 4 by electric wires such as analog metallic cables and CATV cables, or wireless communication means.

Data communication is performed between the access network device 4 and the subscriber exchange 5 in accordance with the layer 2 protocol. Between the access network device 4 and the subscriber exchange 5, for example, ITU-T (International Tele
When connected with a V5 interface specified by communication Union-Telecommunication Sector), LAPV5 (Link Access protocol V) is used as layer 2
5) is applicable.

Normally, in the V5 interface, the devices are connected by a PCM Link of 2 Mbps / 1 line,
By dividing the band of 2 Mbps into 32, a band of 64 kbps is allocated to each communication channel. It should be noted that a specific channel out of the 32 divisions is called, called,
It is used for transmitting and receiving control data such as fault notification, and other channels are used for transmitting and receiving user data such as voice and data.

In the conventional access network system, when a call is made from a terminal device or an incoming call is made to the terminal device, one communication channel is assigned to each terminal device, and the access network device 4 Between the subscriber switchboard 5 and the subscriber exchange 5, the data for those multiple channels is transmitted by TDM (Time Division Multiplexing).
It is multiplexed and transmitted / received by the method.

[0008]

As described above, in the conventional access network system, 6 units are provided for each terminal device.
Since the band can be allocated only in units of 4 kbps, there is a problem that the band cannot be efficiently allocated and the band is wasted when data is transferred at a speed other than 64 kbps.

Further, in the conventional access network system, when a call is made from a terminal device or an incoming call is made to the terminal device, a communication channel of a predetermined time slot is assigned to each terminal device and the terminal device makes a call or a call. Since the band is secured even when data is not transmitted / received, there is a problem that the band is wasted.

The present invention has been made in order to solve the problems of the above-mentioned conventional techniques, and it is possible to prevent wasteful allocation and wasteful use and efficiently use the communication band. Access network system and its control method.

[0011]

In order to achieve the above object, an access network system of the present invention is an access network for connecting a terminal device used by a subscriber and a circuit switching network which is a relay system in a public network. In the system, the data received from the terminal device is packetized and transmitted, the received packetized data is depacketized and transferred to the terminal device, and the access network device is transmitted.
And a subscriber exchange for depacketizing packetized data, transferring the packetized data to a predetermined destination in the circuit switching network, packetizing the data received from the circuit switching network, and transferring the packetized data to the access network device. Is.

[0012] At this time, the access network device has a voice encoding processing unit for encoding voice received from the terminal device and decoding encoded voice data received from the subscriber exchange. The private branch exchange may include a voice encoding processing unit that encodes voice received from the circuit switched network and decodes encoded voice data received from the access network device.

On the other hand, the control method of the access network system according to the present invention collects data from the terminal device received via the access network device and the access network device that concentrates the line with the terminal device used by the subscriber. A subscriber exchange that transfers data received from the circuit-switched network to the access network device while transferring to a predetermined destination in the circuit-switched network that is a relay system in the public network; and the terminal device, A control method of an access network system for connecting to the circuit switching network, wherein the access network device packetizes the data received from the terminal device, transfers the packetized data to the subscriber exchange, and receives from the subscriber exchange. The packetized data is depacketized and transferred to the terminal device, and the subscriber exchange Machine is depacketizes the received packetized data from said access network device is transferred to the circuit switched network, a method of transferring by packetizing the data received from the circuit switched network to the access network device.

At this time, the access network device encodes the voice received from the terminal device and decodes the encoded voice data received from the subscriber exchange, and the subscriber exchange exchanges the line exchange network. May be encoded and the encoded voice data received from the access network device may be decoded.

(Operation) In the above-described access network system and control method thereof, packetized data is transmitted and received between the access network device and the subscriber exchange to increase the data transfer rate to 6
It is possible to flexibly change not only in units of 4 kbps. Further, the packet is not transmitted and received when there is no data to be transmitted and received, so that the band is not wasted.

Further, the encoded voice data can be compressed by encoding / decoding the voice data in the access network device and the subscriber exchange, respectively.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings.

(First Embodiment) FIG. 1 is a block diagram showing a configuration of a first embodiment of an access network device of the present invention, and FIG. 2 is a first embodiment of a subscriber exchange of the present invention.
3 is a block diagram showing the configuration of the embodiment of FIG. Since the configuration of the access network system is the same as the conventional configuration shown in FIG. 6, description thereof will be omitted.

The access network system of the present invention proposes a method of packetizing user data and control data between the access network device and the subscriber exchange and transmitting and receiving them.

As shown in FIG. 1, the access network device of the present invention connects a plurality of subscriber circuits 10 ₁ to 10 _n (n is a positive number), which is an interface with the terminal device, and a line with the subscriber circuit. Concentrating circuit 12 for concentrating data and 64 k depending on the destination of the data from the terminal device or subscriber exchange.
a switch unit 13 for switching in units of bps, a layer 2 extraction / insertion unit 14 for exchanging control data with a subscriber exchange according to a layer 2 protocol, packetization of data to be transmitted to the subscriber exchange, and A packet termination processing unit 15 for depacketizing the data received from the subscriber exchange, a band required before the packet transfer is reserved for the subscriber exchange, and a switch unit 13,
A control unit 17 that controls the operations of the layer 2 extraction / insertion unit 14 and the bandwidth control unit 16 respectively, and a bandwidth control unit 1 that monitors whether or not the effective bandwidth is used after the bandwidth reservation.
6 and 6.

As shown in FIG. 2, the subscriber exchange of the present invention is a packet termination processing unit 2 for depacketizing a packet received from an access network device or packetizing data to be transmitted to the access network device.
0, a layer 2 extraction / insertion unit 22 for exchanging control data with the access network device according to the layer 2 protocol, and data from the terminal device or the circuit switching network in units of 64 kbps depending on the destination. The switch unit 23 that is switched by the switch, the trunk interface unit 24 that is an interface with the circuit switching network, the bandwidth required before packet transfer, and the bandwidth control unit 2
1, a layer 2 extraction / insertion unit 22, and a control unit 25 that controls the operations of the switch unit 23 respectively, and a band control unit 21 that monitors whether or not a valid band is used after band reservation. is there.

The subscriber circuit, the concentrator circuit 12, the switch unit 13, and the layer 2 extraction / insertion unit 14 included in the access network device are constituted by existing integrated circuit devices, for example. Further, the packet termination processing unit 15, the band control unit 16, and the control unit 17 are configured by an information processing device including a CPU and a recording medium in which a program for causing the CPU to execute a predetermined process is recorded. CPU
Executes the processing of the packet termination processing unit 15, the bandwidth control unit 16, and the control unit 17 described below according to the program recorded in the recording medium.

Similarly, the trunk interface section 24, the switch section 23, and the layer 2 extracting / inserting section 22 of the subscriber exchange are composed of existing integrated circuit devices. Also, the packet termination processing unit 20 and the bandwidth control unit 2
1 and the control unit 25 are configured by an information processing device including a CPU and a recording medium in which a program for causing the CPU to execute a predetermined process is recorded. The CPU executes the processes of the packet termination processing unit 20, the bandwidth control unit 21, and the control unit 25 described below according to the program recorded in the recording medium.

The packet is an IP (Internet Protocol).
col) packet, ATM (Asynchronous Transfer Mod)
e) Similar to cells or frame relays, it is generated by adding a header containing addresses of a transmission source and a destination (transmission destination) to a payload composed of user data or control data. In the case of the access network system of this embodiment, since packets are transmitted and received only between the access network device and the subscriber exchange, the header only needs to include at least the source address and the destination address, and the packet priority is given. Since it is unnecessary to provide information indicating the order, the header can be compressed.

Next, the operation of the access network system of the present invention having such a configuration will be described.

When data is transmitted / received between devices by packets, it is necessary to judge whether transmission / reception can be performed at a transfer rate requested in advance. In the following, a case where such a band reservation is made by the subscriber exchange will be described as an example.

First, when an arbitrary terminal device makes a call, the access network device receives the call message at the corresponding subscriber circuit, and the concentrator circuit 12 and the switch section 13 are received.
To the control unit 17 via. The control unit 17 generates a bandwidth reservation message for requesting bandwidth reservation and sends it to the layer 2 extraction / insertion unit 14. The layer 2 extraction / insertion unit 14 transfers the band reservation message received from the control unit 17 to the packet end processing unit 15, and the packet end processing unit 1
The packet is converted into a packet according to 5, and the generated control packet is transmitted to the subscriber exchange. The bandwidth of the control packet is assumed to be reserved in advance.

The subscriber exchange sends the control packet transmitted from the access network device to the packet termination processing unit 2
The layer 2 extraction / insertion unit 22 extracts a bandwidth reservation message from the control packet and transfers it to the control unit 25. The control unit 25 determines whether or not the requested bandwidth can be reserved from the generated call, and if the bandwidth can be reserved, the bandwidth control unit 21 informs the bandwidth control unit 21 of the minimum guaranteed rate (CIR) or peak rate of the call. Notify monitoring information such as (PIR). The bandwidth control unit 21 subsequently monitors the corresponding call according to the monitoring information received from the control unit 25.

The control unit 25 also generates a response message indicating that bandwidth reservation is possible, and extracts the layer 2 /
It is transmitted to the insertion unit 22. The layer 2 extraction / insertion unit 22
The response message received from the control unit 25 is transferred to the packet termination processing unit 20, packetized by the packet termination processing unit 20, and the generated control packet is transmitted to the access network device.

When the access network device receives the control packet including the response message indicating that the bandwidth reservation is completed at the subscriber exchange and the bandwidth reservation is possible, the packet termination processing unit 15 receives the control packet, and the layer 2 The extraction / insertion unit 14 extracts the response message from the control packet and notifies the control unit 17 of it.

The control unit 17 notifies the band control unit 16 of monitoring information such as the minimum guaranteed rate (CIR) and peak rate (PIR) of the call. The bandwidth control unit 16 subsequently monitors the corresponding call according to the monitoring information received from the control unit 17.

When the bandwidth reservation of the generated call is impossible, the subscriber exchange sends a control packet including a reservation impossible message to the access network device. In this case, the access network device returns a busy tone signal indicating, for example, that "the call is in progress" from the corresponding subscriber circuit to the calling terminal device.

When the link between the access network device and the subscriber exchange is established, the user data transmitted from the terminal device is received by the corresponding subscriber circuit of the access network device, concentrated by the concentrator circuit 12 and switched by the switch unit. 13 is transferred. The switch unit 13 switches the transferred user data in units of 64 kbps according to the transmission destination, and transmits it to the layer 2 extraction / insertion unit 14. The layer 2 extraction / insertion unit 14 transfers the user data to the packet termination processing unit 15, packetizes it for each destination, generates a user packet, and transmits the user packet to the subscriber exchange. At this time, the bandwidth for each call is determined by the bandwidth control unit 16 respectively.
Be monitored in.

The subscriber exchange has a packet end processing unit 20.
At, the user packet transmitted from the access network device 4 is received and depacketized. At this time, the bandwidth for each call is monitored by the bandwidth controller 21.

The depacketized user data is transmitted from the trunk interface unit 24 to the circuit switching network via the layer 2 extraction / insertion unit 22 and the switch unit 23 according to a predetermined protocol.

On the other hand, when a call to an arbitrary terminal device occurs, the subscriber exchange receives the control data from the circuit switching network at the trunk interface section 24, and the switch section 2
3 to the control unit 25. The control unit 25 determines whether or not the bandwidth of the generated call can be reserved. If the bandwidth can be reserved, the bandwidth control unit 21 informs the bandwidth control unit 21 of the minimum guaranteed rate (CIR) or peak rate (PIR) of the call. Notify monitoring information such as. The bandwidth control unit 21 subsequently monitors the corresponding call according to the monitoring information received from the control unit 25.

The control unit 25 also sends the control data received from the circuit switching network to the layer 2 extraction / insertion unit 22. The layer 2 extraction / insertion unit 22 transfers the control data received from the control unit 25 to the packet termination processing unit 20, packetizes the packet termination processing unit 20, and transmits the generated control packet to the access network device.

In the access network device, the packet termination processing unit 15 receives the control packet transmitted from the access network device, the layer 2 extracting / inserting unit 14 extracts the control data from the control packet, and the control unit 17 To notify.

The control unit 17 notifies the band control unit 16 of monitoring information such as the minimum guaranteed rate (CIR) and peak rate (PIR) of the call. The bandwidth control unit 16 subsequently monitors the corresponding call according to the monitoring information received from the control unit 17.

When the bandwidth reservation for the generated call is impossible, the subscriber exchange returns a control packet containing a reservation-disabled message to the circuit-switched network. In this case, the circuit switching network returns a busy tone signal indicating, for example, that the call is in progress, to the originator of the call.

When the link between the access network device and the subscriber exchange is established, the user data transmitted from the circuit switching network is received by the trunk interface section 24 and transferred to the switch section 23. The switch unit 23 sends the transferred user data according to the destination.
Switching is performed in units of 4 kbps and transmission is performed to the layer 2 extraction / insertion unit 22. The layer 2 extraction / insertion unit 22 transfers the user data to the packet termination processing unit 20, packetizes each transmission destination to generate a user packet, and transmits the generated user packet to the access network device.
At this time, the bandwidth for each call is monitored by the bandwidth controller 21.

The access network device receives the user packet transmitted from the subscriber exchange in the packet termination processing section 15 and depacketizes it. At this time, the bandwidth for each call is monitored by the bandwidth controller 16.

The depacketized user data is transmitted from the corresponding subscriber circuit to the terminal device via the layer 2 extraction / insertion unit 14, the switch unit 13, and the concentrator circuit 12.

FIG. 3 shows how packetized control data and user data are transferred between the access network device and the subscriber exchange described above.

In FIG. 3, the access network device (A
N) and the subscriber exchange (LE), user data (user data 1,
2) is transmitted and received, and control data is transmitted and received using a specific channel.

In the above description, the case where the bandwidth necessary for packet transfer is reserved in advance by the subscriber exchange has been described as an example, but the bandwidth may be reserved by the access network device.

Therefore, in the access network system of the present invention, since the TDM data is packetized and the bandwidth is reserved before the data transfer is performed between the access network device and the subscriber exchange, the transfer speed of the user data and the control data is reduced. Not only the unit of 64 kbps but also the unit can be flexibly changed and the band of the line can be effectively used. In particular, when the bandwidth of the control data is temporarily required, it is not necessary to increase it in units of 64 kbps, and it is sufficient to increase only the required bandwidth.

Further, since the packet is not transmitted / received when there is no data to be transmitted / received, the band is not wasted.

(Second Embodiment) Next, a second embodiment of the access network system of the present invention will be described with reference to the drawings.

FIG. 4 is a block diagram showing the configuration of the second embodiment of the access network device of the present invention, and FIG. 5 is a block diagram showing the configuration of the second embodiment of the subscriber exchange of the present invention. Is.

As shown in FIG. 4, the access network device of this embodiment encodes the voice from the terminal device into the access network device of the first embodiment shown in FIG. This is a configuration in which a voice encoding processing unit 18 that decodes encoded voice data is added.
The subscriber exchange of the present embodiment is the first one shown in FIG.
In the configuration of the subscriber exchange according to the embodiment of the present invention, a voice encoding processing unit 26 for encoding voice from the circuit switched network and decoding encoded voice data from the access network device is added. Since other configurations are similar to those of the first embodiment, the description thereof will be omitted.

By performing voice encoding / decoding in the access network device and the subscriber exchange as in the present embodiment, it is possible to compress the encoded voice data. Bandwidth can be saved more than a form of access network system. Therefore,
The number of subscribers that can be connected can be increased without changing the concentrating rate.

[0053]

Since the present invention is constructed as described above, it has the following effects.

By transmitting and receiving packetized data between the access network device and the subscriber exchange, the data transfer rate can be flexibly changed not only in units of 64 kbps, but also in effective bandwidth of the line. Can be used. In particular, when the bandwidth of the control data is temporarily required, it is not necessary to increase it in units of 64 kbps, and it is sufficient to increase only the required bandwidth. Further, the packet is not transmitted and received when there is no data to be transmitted and received, so that the band is not wasted.

Further, by encoding / decoding the voice data in the access network device and the subscriber exchange respectively, the encoded voice data can be compressed and the band can be further saved. become. Therefore, it is possible to increase the number of connectable subscribers without changing the concentrating rate.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment of an access network device of the present invention.

FIG. 2 is a block diagram showing a configuration of a first embodiment of a subscriber exchange of the present invention.

FIG. 3 is a schematic diagram showing how packetized control data and user data are transferred between an access network device and a subscriber exchange.

FIG. 4 is a block diagram showing a configuration of a second exemplary embodiment of an access network device of the present invention.

FIG. 5 is a block diagram showing a configuration of a second embodiment of a subscriber exchange according to the present invention.

FIG. 6 is a block diagram showing a configuration example of an access network system.

[Explanation of symbols]

1 ₁ to 1 _n Terminal device 4 Access network device 5 Subscriber switch 6 Circuit switching network 10 ₁ to 10 _n Subscriber circuit 12 Concentrator circuit 13, 23 Switch unit 14, 22 Layer 2 extraction / insertion unit 15, 20 Packet termination processing Units 16 and 21 Band control units 17 and 25 Control units 18 and 26 Voice coding processing unit 24 Trunk interface unit

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5K030 HA01 HB01 HC02 JA02 JA05                       KA19 LA07                 5K051 AA05 BB01 BB02 CC01 DD07                       DD13 HH01 HH27 JJ13

Claims (8)

[Claims] 1. An access network system for connecting a terminal device used by a subscriber and a circuit-switched network, which is a relay system in a public network, wherein the data received from the terminal device is packetized and transmitted. An access network device for depacketizing the received packetized data and transferring the packetized data to the terminal device, and a predetermined transmission in the circuit switching network for depacketizing the packetized data sent from the access network device An access network system, comprising: a subscriber exchange that transfers the data to the access network device, the data being transferred to the access network device. 2. The access network device includes a voice encoding processing unit that encodes voice received from the terminal device and decodes encoded voice data received from the subscriber exchange. The access network system according to claim 1, wherein the exchange has a voice encoding processing unit that encodes voice received from the circuit switching network and decodes encoded voice data received from the access network device. 3. An access network device for concentrating a line with a terminal device used by a subscriber, and a circuit switching network which is a relay system in a public network for data received from the terminal device via the access network device. An access network for connecting the terminal device and the circuit switching network, and a subscriber exchange for transferring the data received from the circuit switching network to the access network device, A method for controlling a system, wherein the access network device packetizes the data received from the terminal device and transfers the packetized data to the subscriber exchange, and depacketizes the packetized data received from the subscriber exchange to depacketize the data. Forwarded to the terminal device, and the subscriber exchange receives the packet received from the access network device. Control method for an access network system for transferring the door of data by depacketizing transferred to the circuit switched network, and packetizes the data received from the circuit switched network to the access network device. 4. The access network device encodes voice received from the terminal device and decodes encoded voice data received from the subscriber exchange, and the subscriber exchange transmits from the circuit switched network. 4. The method of controlling an access network system according to claim 3, wherein the received voice is encoded and the encoded voice data received from the access network device is decoded. 5. An access network device for concentrating a line with a terminal device for connecting a terminal device used by a subscriber and a circuit switching network, which is a relay system in a public network, through a subscriber exchange. A plurality of subscriber circuits that are interfaces with the terminal device, a concentrator circuit that concentrates lines with the subscriber circuit, a switch unit that switches received data according to the destination, and a layer 2 protocol A layer 2 extraction / insertion unit for exchanging control data with the subscriber exchange according to the above, and packet termination for packetizing data to be transmitted to the subscriber exchange and depacketizing data received from the subscriber exchange. A processing unit; a control unit for requesting the subscriber exchange to reserve a required bandwidth before transferring packetized data; A bandwidth control unit which line the subscriber exchange to monitor effectively whether it is bandwidth available, the access network device having a. 6. The access network device according to claim 5, further comprising a voice encoding processing unit that encodes voice received from the terminal device and decodes encoded voice data received from the subscriber exchange. 7. A terminal device used by a subscriber and a circuit switching network, which is a relay system in a public network, are connected via an access network device, and data received from the access network device is transferred to the circuit switching network. At the same time, it is a subscriber exchange that transfers the data received from the circuit switching network to the access network device, and depacketizes the packet received from the access network device and packetizes the data to be transmitted to the access network device. Layer 2 extraction for exchanging control data between the packet termination processing unit and the access network device according to the Layer 2 protocol
An insertion unit, a switch unit that switches data received from the terminal device or the circuit switching network according to the destination, a trunk interface unit that is an interface with the circuit switching network, and is necessary before packet transfer. A subscriber exchange having a control unit for reserving a band and a band control unit for monitoring whether or not the band is effectively used after the reservation of the band. 8. The subscriber exchange according to claim 7, further comprising a voice encoding processing unit that encodes voice received from the circuit switching network and decodes encoded voice data received from the access network device.