KR100787295B1 - A method and apparatus of PABX capacity expansion using Fast Ethernet - Google Patents

Abstract

The present invention extends the capacity of a private exchange by using 100 Mbps Fast Ethernet. A capacity of one subscriber node by using M subscriber nodes processing N subscriber capacity and one central control node as 100 Mbps Fast Ethernet is provided. It is possible to use the limitation of the general 100M bps Fast Ethernet without additional lines, and the switching operation is simple because the switch handles all the switching in one switch of the central control node without installing the switch for each subscriber node. In addition, it is a capacity expansion device and method of a private exchange using Fast Ethernet, which can be easily implemented by using a general TDM switch. The present invention uses a universal Ethernet to limit the number of subscribers of one basic node and does not install additional lines, so all switching is handled at one central control board, so switching operation is simple, and the switch is a general TDM switch. It's available, so it's easy to implement.

Private Exchange, Subscriber Node, Central Control Node, Subscriber Board, Ethernet Converter.

Description

A method and apparatus of PABX capacity expansion using Fast Ethernet}

1 shows a schematic configuration of a conventional private exchange,

Figure 2 shows a schematic configuration when connecting the conventional private exchange M,

3 is a block diagram of a private exchange system of the present invention;

Figure 4 shows the structure of the NOE packet of the present invention.

<Description of Major Symbols in Drawing>

100: subscriber node 200: central control node

The present invention relates to the expansion of a private switch, and in particular, by connecting 100 M subscriber nodes having N subscriber capacity using 100 Mbps Fast Ethernet, and having a TDM large capacity switch at one central control node, it is easily expanded without a separate additional line. The present invention relates to a capacity expansion device and method for a private exchange using Fast Ethernet.

In general, Private Branch eXchange (PBX) refers to a general branch exchange that provides internal communication services such as telephones and faxes in an enterprise or premises. However, when automatic expression is separately classified as Private Automatic Branch eXchange (PABX), only manual expression is referred to.

The private exchange includes a subscriber circuit unit, a control circuit unit, a call circuit unit and a relay unit to enable a subscriber to use various services including a voice call service. Although a telephone network, a fax network, a data network, and the like of a conventional communication network are individually configured, due to the development of a high-speed general information communication network, telephone, fax, computer, and video data communication are being processed in an integrated network.

In addition, Ethernet is a widely installed local area network technology, a local network that can exchange information at a transmission rate of 10 Mbps between up to 1,024 data stations within a distance of about 2.5 km between data stations. One of the models that implement There are 10BASE 5, 10 BASE 2, and 10 BASE-T cables, but the most commonly used cables are 10BASE-T, which is easy to wire and excellent in management and safety. Recently, Fast Ethernet, which has a bandwidth of 100 Mbps, also appeared.

A conventional private exchange will be described in detail with reference to the drawings.

FIG. 1 shows a schematic configuration of a conventional private exchange, and FIG. 2 shows a schematic configuration when M conventional private exchanges are connected.

The private exchange can be divided into the subscriber board 20 and the control board 30, the subscriber board 20 is in charge of the connection with the subscriber terminal, the control board 30 is the voice switching and IPC ( It is in charge of Inter Processor Communication.

In the private exchange as shown in FIG. 1, the switching capacity is determined according to the number of subscriber boards 20 in the shelf connected to the switch 32 of the control board 30, and the CPU controlling the entire subscribers via the IPC 34. Since the performance of (36) is limited, the number of subscribers that can be processed is limited, thereby limiting capacity expansion.

In order to overcome this limitation, a private exchange having a structure as shown in FIG. 1 may be configured as a primary node to connect a plurality of private exchanges.

If the capacity of the primary node is N and the number of nodes connected is M, the capacity of the system is MxN. If the connection between the primary node is configured using the Ethernet control board 30 has an Ethernet conversion unit 38, as shown in Figure 2, an additional Ethernet switch 40 is further configured, M primary nodes An additional (MxN) X (MxN) switch is needed to switch the entire system to which it is connected. Voice exchange between basic nodes is done using VoIP.

In order to construct a non-blocking system, the speed of a physical link required for one primary node must be able to accommodate all N subscribers connected to the primary node, and the system switch has the capacity of (MxN) X (MxN). Should have

If N is 1024, 1024 x 64 kbps (64 Mbps) is required, and a separate data channel is needed for IPC between basic nodes.

In order to connect a node having 1024 subscribers with non-blocking, at least 64 Mbps and a separate bandwidth for data are required.

The conventional private exchange shown in FIGS. 1 and 2 has a problem in that a delay occurs when a packet is made using VoIP and a transmission delay in the network is not constant, causing an echo to occur at the receiving side. There is a problem that the Ethernet conversion switch is complicated because it is necessary to collect the data to generate a packet.

The present invention is to solve the above-mentioned problems, and to expand the capacity of the private exchange by using 100Mbps Fast Ethernet, by using M subscriber nodes and one central control node processing N subscriber capacity as 100Mbps Fast Ethernet Limiting the capacity of one subscriber node can be achieved without the need for additional lines by utilizing the universal 100M bps Fast Ethernet, and all switching on one switch in the central control node without installing switches for each subscriber node. It is an object of the present invention to provide a device and a method for expanding capacity of a private exchange using Fast Ethernet, which can be easily implemented since the switching operation is simple and the switch is also configured using a general TDM switch.

The apparatus for expanding capacity of a private exchange utilizing Fast Ethernet according to the present invention for achieving the above object includes a subscriber board connected to a subscriber terminal and processing a call and communication service, and a control board controlling the subscriber board. And M subscriber nodes processing N subscriber capacity, and a central control node connected to M subscriber nodes by Fast Ethernet, controlling the M subscriber nodes, and controlling and controlling all received voice and data. It features.

The control board converts the PCM data received from the subscriber board into a NOE packet and inversely converts the Ethernet converter to transmit and receive to the central control node via Fast Ethernet, and the switching information of the data converted by the Ethernet converter to the central controller. It provides a control node and comprises a CPU for controlling the subscriber board through the IPC.

The Ethernet converter converts the PCM data received from the subscriber board into the NOE packet at regular intervals and transmits the data to the central control node.

In addition, the central control node of the present invention is a TDM Ethernet converter for converting the NOE packets received from the M subscriber nodes to PCM data and inversely converted to provide Fast Ethernet, and the entire data received from the subscriber board CPU of the subscriber board Switch comprising a switch for switching according to the switching information provided by the subscriber, and the subscriber board is connected to the subscriber terminal for processing voice calls and data, PCM data transmitted from the subscriber board of the central control node is switched without converting into a NOE packet The PCM data switched to the central control node may also be provided to the subscriber board without packet conversion.

In addition, the present invention comprises the first step of connecting the M subscriber node processing the N subscriber capacity to the 100Mbps Fast Ethernet LAN, including the Ethernet converter, CPU and subscriber board, and the voice and data of the subscriber node NOE packet is the Ethernet Step 2 is transmitted and received from the converter, and switching data is transmitted and received to and from the CPU via the Fast Ethernet LAN, and the NOE packet and the switching information received from the M subscriber nodes via the Fast Ethernet LAN to receive the entire subscriber node. Switching from one central control node to providing the NOE packet to the subscriber node via the Fast Ethernet LAN.

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

3 is a diagram illustrating an extension of the private exchange system of the present invention, and FIG. 4 illustrates the structure of a NOE packet of the present invention.

The private switching system of FIG. 3 is configured by connecting the central control node 200 that handles the entire switching and the M subscriber nodes 100 that handle the N subscriber capacities.

3 illustrates an example in which M subscriber nodes 100 processing N subscriber capacities are connected to a central control node 200 by connecting 100 M Mbps Fast Ethernet LANs to expand the capacity of the private switch.

In order to connect between M subscriber nodes 100, a large-capacity switch was constructed by using a general-purpose 100 Mbps Fast Ethernet.

The central control node 200 is provided with a central control switch board 90 and a subscriber board 80, and the central control switch board 90 has a (MxM) X (MxN) switch 92, a CPU 96, and an IPC. 94, a TDM (Time Division Multiplexing) Ethernet converter 98. The (MxM) X (MxN) switch 92 switches the entire M subscriber nodes 100.

The present invention switches the call of the entire subscriber node 100 in the central control switch board 90 unlike the prior art.

The switch 92 in the central control switch board 90 should be able to switch the capacity of the entire system, exist only in the system, switch and process various services, including voice calls of the entire subscriber node 100, and switch ( 92 is very simple to implement using a general time division multiplexing (TDM) switch.

Therefore, the control board 60 of the subscriber node 100 does not need a conventional switch, and the CPU 66 in the control board 60 does not need to perform any processing related to switching, and handles diagnostic related and central control switches. The CPU 96 of the board 90 is connected to each other by an IP (Internet Protocol).

Subscriber node 100 of the present invention does not have its own switch, unlike the prior art, the subscriber board 50, the TDM Ethernet converter 62, and the CPU 66 for controlling the subscriber board 50 through the IPC (64) Equipped.

The subscriber node 100 is capable of processing N subscriber capacities, and includes a control board 60 and a subscriber board 50. The control board 60 includes a TDM Ethernet converter 62 for converting and restoring PCM data into NOE packets, an IPC 62 for controlling the subscriber board 50, and a CPU 66 for controlling the IPC 62. It includes.

As shown in FIG. 3, M subscriber nodes 100 are provided, and individual subscriber nodes 100 are connected to a CPU 96 of a central control node 200 and a TDM (Time Division Multiplexing) Ethernet converter 98. Voice data is transmitted and received, and the (MxN) x (MxN) switch 92 switches and processes subscriber stations connected to the entire subscriber node 100.

The present invention is to increase the capacity of the private exchange by using 100Mbps Fast Ethernet, having an Ethernet converter 62 to connect a plurality of subscriber nodes (100), a plurality of subscriber nodes (100) in the central control node (200) The processing capacity of the private exchange is expanded by switching the service request of the subscriber station via).

FIG. 3 illustrates an operation in which M subscriber nodes 100 processing N subscriber capacities are connected to a 100 Mbps Fast Ethernet LAN and an additional switching capacity of a private exchange controlled by one central control node 200 is described.

Pulse Coded Modulation (PCM) data received from the subscriber board 50 of the subscriber node 100, which accommodates N subscribers and M are connected to a 100 Mbps LAN, is stored in the Ethernet converter 62 as shown in FIG. The PCM data received from the entire subscriber board 50 is converted into one packet once every 125usec.

The NOE packet converted by the Ethernet converter 62 is immediately transmitted to the central control switch board 90 of the central control node 200, and the TDM Ethernet converter 98 provided in the central control switch board 90 is a subscriber node. The packet transmitted from the Ethernet converter 62 of 100 is converted into PCM data.

In addition, the CPU 66 of the subscriber node 100 transmits the switching information of the corresponding NOE packet to the CPU 86 of the central control switch board 90.

 The central control switch board 90 switches in the central control switch 92 according to the data converted from the TDM Ethernet converter 98 back to Pulse Coded Modulation (PCM) data and the received switching information. The switch 92 is configured using a general TDM switch.

The switched PCM data is NOE packetized for each subscriber node 100 to be received and transmitted to the corresponding subscriber node 100 via a 100M bps LAN.

The switched NOE packet transmitted to the subscriber node 100 is restored to the PCM data by the Ethernet converter 62 provided in the subscriber node 100 and written in the slot of each subscriber board 50.

On the other hand, unlike the subscriber node 100, PCM data raised from the subscriber board 80 of the central control switch board 90 of the central control node 200 is switched without converting into a NOE packet. In addition, the PCM data switched to the central control switch board 90 is also written in the slot of each subscriber board 80 without packet conversion.

4 shows the configuration of the NOE packet 210 of the present invention. The NOE packet of the present invention is constructed by adding a NOE header 212 to a conventional Ethernet frame.

The preamble 222 of the NOE packet 210 is used for synchronization establishment and is 7 octets, and the Start Frame Delimiter (SFD) 214 is 1 octet as a delimiter for initiating the preamble, and a destination address (DA) 216. ) Is 6 octets of address information of a destination, and a source address 218 is 6 octets of an address of a source.

The length / type 220 item designates a length and a type of a packet, which is 2 octets, the NOE header 222 of the present invention is 1 octet, and the payload 224 containing data consists of N octets.

In the NOE packet of the present invention, a node over Ethernet (NOE) header 222 is written immediately below the Ethernet header, and PCM data from slot 0 to slot N-1 is continuously written below the NOE header 222. In the header 222 of the NOE, a number of a source node may be written so as to be used for switching, and a flag related to diagnosis may be located. Slots are assigned a fixed size to transmit voice or data.

As described above, the present invention extends the capacity of a private exchange by using a 100 Mbps Fast Ethernet LAN. An additional line is connected by connecting M subscriber nodes that handle N subscriber capacity and one central control node to a 100 Mbps Fast Ethernet LAN. It does not have a switch for each subscriber node and handles all the switching in one switch provided in the central control node, so switching operation is simple. Fast Ethernet configured using a general TDM switch is used to expand the capacity of the private exchange. will be.

As described above, the present invention uses a universal Ethernet to limit the number of subscribers of one base node and does not install additional lines, so all switching is handled in one central control board, so the switching operation is simple, and the switch Is easy to implement since a common TDM switch is available.

Claims (8)

A subscriber board connected to the subscriber terminal to handle calls and communication services; M subscriber nodes including a control board for controlling the subscriber board and processing N subscriber capacities; And a central control node connected to the M subscriber nodes via Fast Ethernet, controlling the M subscriber nodes, and controlling and controlling all the received voice and data. The method of claim 1, The control board includes an Ethernet converter for converting the PCM data received from the subscriber board into a NOE packet and inversely converting the data to the central control node via Fast Ethernet; And a CPU for providing the switching information of the data converted by the Ethernet converter to the central control node and controlling the subscriber board through an IPC. The method according to claim 1 or 2, And the Ethernet converter converts the PCM data received from the subscriber board into the NOE packets in a predetermined time interval and transmits them to the central control node. The method according to claim 1 or 2, The NOE packet converted by the Ethernet converter includes a NOE header under the Ethernet header, and continuously writes PCM data under the NOE header, and writes the number of the source node in the NOE header for use in switching. Capacity expansion unit of private exchange using Ethernet. The method of claim 1, The central control node includes: a TDM Ethernet converter for converting NOE packets received from the M subscriber nodes into PCM data, inversely converting the same, and providing them to Fast Ethernet; A switch for switching all data received by the subscriber board according to switching information provided by the CPU of the subscriber board; A capacity expansion device for a private exchange utilizing Fast Ethernet, comprising a subscriber board to which subscriber terminals are connected to process voice calls and data. The method according to claim 1 or 5, The NOE packet processed by the TDM Ethernet converter includes a NOE header under the Ethernet header, and continuously writes PCM data under the NOE header, and uses Fast Ethernet to write down the number of source nodes for switching. Capacity expansion unit of a private exchange. The method according to claim 1 or 5, PCM data transmitted from the subscriber board of the central control node is switched without converting into NOE packets, and the PCM data switched to the central control node is also provided to the subscriber board without packet conversion. Expansion unit. Connecting M subscriber nodes including an Ethernet converter, a CPU, and a subscriber board to handle N subscriber capacities to a 100 Mbps Fast Ethernet LAN; A second step of transmitting / receiving NOE packets, which are voice and data of the subscriber node, to and from the Ethernet converter, and switching data to and from the CPU via the Fast Ethernet LAN; Receives NOE packets and switching information received at the M subscriber nodes via the Fast Ethernet LAN, switches the entire subscriber node at one central control node, and switches the NOE packets to the subscriber node via the Fast Ethernet LAN. Capacity expansion method of private exchange using Fast Ethernet, which includes 3 steps.

Images