KR101142458B1 - Mobile communication base station network system - Google Patents

Abstract

The present invention relates to a mobile communication base station network system, which converts TDM data received through a TDM dedicated line connected to a base station controller into GPON data, converts the converted GPON data into an optical signal, and transmits the optical signal through an optical transmission network. Converts the optical signal transmitted through the Zippon OLT and the optical transmission network into GPON data, analyzes the header information of the converted GPON data, converts the TDM data into TDM data, and transmits it to the base station connected through the TDM dedicated line. It is provided with a chiffon Orient. According to such a mobile communication base station network system, it is possible to reduce facility construction costs by supporting TDM communication between a base station and a base station controller using an ultra-high speed GPON optical subscriber network, and also support Ethernet-based communication between the base station and the base station controller in the future. It provides the advantages.

Base Station, Base Station Controller, GPON, TDM, Ethernet

Description

Mobile communication base station network system

The present invention relates to a mobile communication base station network system, and more particularly, to a mobile communication base station network system capable of performing communication between a base station and a base station controller using a GPON subscriber network.

A mobile communication network is constructed of a base station that transmits and receives a signal wirelessly with a mobile communication terminal called a cellular phone, and a base station controller that manages and controls a plurality of base stations.

According to the development stage of the technology, the communication technology through the mobile communication network uses the first generation mobile communication, which transmits voice signals in an analog manner, and the second generation mobile communication, which transmits data as well as voice while using digital transmission, and data transmission speed. It is divided into 3rd generation mobile communication which improves video call and multimedia communication, and this technological development is continuously evolving into 4th generation mobile communication.

On the other hand, the basis of the mobile communication network from the first generation to the third generation in this technological development stage is a time division multiplexer (TDM).

The largest area of mobile communication service is voice communication service and is connected to PSTN (Public Switched Telephone Network) network. PSTN networks also use TDM as their primary connection. In the TDM scheme, the quality of service (QoS) of a transmission section is reliably guaranteed, and is always transmitted with a fixed band, and the transmission band is maintained even with or without data.

The TDM scheme mainly uses a transmission layer called E1 or T1. In the case of E1, TDM transmits at 2.048 Mbps and T1 at 1.544 Mbps. In general, in the second to third generation mobile communication networks, a transmission network between a base station and a base station controller uses E1 or T1. In addition, when the base station and the base station controller is far away, or when the control range of the base station controller is extended, through ultra-high speed optical transmission equipment based on SDH (Synchronous Digital Hierarchy) and SONET (Synchronous Optical Network) multiplexed with E1 or T1. One such device used for transmission is the Multi-Service Provisioning Platform (MSPP).

MSPP equipment is composed of EoS (Ethernet over SDH / SONET) that can be connected to the existing TDM while supporting the SONET / SDH network as a transmission equipment between communication companies. These MSPP equipments are mainly used for mobile communication network equipments that require TDM and Ethernet data at the same time, but in practical part, they are fixed as inter-company connection network equipments using optical transmission method with ring structure based on SDH. It is suitable for band service and does not support aggregation, which has a high cost of facilities.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a mobile communication base station network system that can increase communication efficiency between a base station and a base station controller using a gigabit passive optical subscriber network.

In order to achieve the above object, a mobile communication base station network system relaying communication between a base station of a mobile communication network and a base station controller converts TDM data received through a TDM dedicated line connected to the base station controller into GPON data. And a zippon OLT which converts the converted GPON data into an optical signal and transmits the optical signal through an optical transmission network; After converting the optical signal transmitted through the optical transmission network to GPON data, and analyzes the header information of the converted GPON data, if the TDM mode, converts to TDM data and transmits to the base station connected through the TDM dedicated line It includes;

Preferably, the chiffon OLT comprises an optical network matching unit for photoelectric conversion of the signal received from the optical transmission network; A GPON processing unit which converts Ethernet data to be transmitted through the optical transmission network into GEM packet data and outputs the converted data to the optical network matching unit; An Ethernet matching unit connected to an Ethernet communication line to transmit / receive Ethernet data and converting GEM packet data received from the GPON processing unit into Ethernet packet data, matching with a TDM dedicated line of the base station controller, transmitting and receiving TDM data, and receiving TDM data. And a TDM processing unit converting the Ethernet data into the Ethernet matching unit, converting the Ethernet packet data received from the Ethernet matching unit into a TDM frame, and transmitting the converted TDM frame to the TDM dedicated line.

The chiffon ENT may include an optical network matching unit configured to photoelectrically convert a signal received from the chiffon OLT through the optical transmission network; A GPON processing unit for converting Ethernet packet data to be transmitted through the optical network matching unit into GEM packet data; Ethernet matching unit converts the GEM packet data received from the GPON processing unit to Ethernet packet data, and transmits and receives Ethernet data through an Ethernet communication line, matches with the TDM dedicated line of the base station, transmits and receives TDM data, and receives the received TDM data. And converting the Ethernet data into the Ethernet matching unit, converting the Ethernet data received from the Ethernet matching unit into TDM data, and transmitting the TDM data through the TDM dedicated line of the base station.

According to the mobile communication base station network system according to the present invention, by supporting the TDM communication between the base station and the base station controller using an ultra-high speed GPON optical subscriber network, it is possible to reduce the cost of building facilities, Ethernet-based base station and base station controller of the future It also provides the advantage of supporting communication.

Hereinafter, a mobile communication base station network system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a mobile communication base station network system according to the present invention.

Referring to FIG. 1, a mobile communication base station network system includes a base station controller 200, a plurality of base stations 230, a GPON OLT 110, a GPON ONT 130, An optical splitter (ODN) 120 is provided.

The base station controller (200) (210) serves to deliver voice and communication data while controlling and managing the managed base station (230), and is connected to a mobile switching center (MSC) (not shown). Process the call of the mobile communication terminal.

Among the base station controllers 200 and 210, the base station controller 200 denoted by reference numeral 200 indicates communication through the existing TDM dedicated line 102, and the base station controller denoted by reference numeral 210 denotes an Ethernet communication line in an Ethernet manner. Through 104, it is shown to be built to perform communication.

The base station 230 processes a signal wirelessly received from the mobile communication terminal, and transmits and receives a signal with the base station controller 200 and 210 through an optical transmission network.

GPON OLT 110 is an optical fiber terminator, which is installed in a national company.

Zippon OLT 110 converts the TDM frame received through the TDM dedicated line 102 connected to the base station controller 200 into a GPON frame, and converts the converted GPON frame into an optical signal for transmission through an optical transmission network. do.

Here, the optical transmission network is a network for transmitting and receiving optical signals, the optical splitter 120, the optical splitter 120 and the optical fiber 121, the optical splitter 120 and the chiffon ENT 130 connected between the ) And an optical fiber 121 connected therebetween.

The zip OLT 110 will be described with reference to FIG. 2.

The chiffon OLT 110 includes a TDM processing unit 112, an Ethernet matching unit 114, a GPON processing unit 116, and an optical network matching unit 118.

The TDM processing unit 112 is connected to the base station controller 200 through the TDM dedicated line 102 to transmit and receive a TDM frame through the TDM dedicated line 102, and converts the TDM frame received from the base station controller 200 into an Ethernet frame to Ethernet. Output to matching unit 114.

In addition, the TDM processing unit 112 converts the Ethernet frame received from the Ethernet matching unit 114 into a TDM frame and transmits the TDM frame to the base station controller 200 through the TDM dedicated line 102.

That is, the TDM processing unit 112 is constructed to support CESoE (Circuit Emulation service over Ethernet).

3, the TDM processing unit 112 includes a TDM matching unit 112a and a data converter 112b.

The TDM matching unit 112a matches the TDM dedicated line 102 connected with the base station controller 200 to transmit and receive a TDM frame. That is, the TDM matching unit 112a transmits the TDM frame received from the base station controller 200 through the TDM dedicated line 102 to the data conversion unit 112b and clocks the TDM frame received from the data conversion unit 112b. To the TDM dedicated line 102 in synchronization with.

In this case, the clock information may be generated by extracting clock information embedded in the TDM frame or by using a clock synchronization packet periodically transmitted between the chiffon OENT 130 and the chiffon OLT 110.

The data converter 112b converts the TDM frame received from the TDM matcher 112a into an Ethernet frame and outputs the TDM frame to the Ethernet matcher 114. As an Ethernet frame structure for converting a TDM frame, a packet structure having an Ethernet MAC, an IP / UDP header, TDM data, and an FCS field may be applied. Here, the address of each terminal device of Ethernet is recorded in the Ethernet MAC field, the IP address is recorded in the IP / UDP header, and the TDM frame received from the TDM dedicated line is recorded in the TDM data field, and the FCS detects a data transmission error. Used for.

Ethernet matching unit 114 is a portion corresponding to Ethernet MAC (Media Access Control) converts GEM packet data received from GPON processing unit 116 into Ethernet data, and analyzes the header information of the converted Ethernet packet data in Ethernet mode If it is, the transmission and reception process through the Ethernet communication line 104.

In addition, the Ethernet matching unit 114 transmits to the TDM processing unit 112 when the Ethernet packet data converted for the GEM packet data received from the GPON processing unit 116 is in the TDM mode.

The GPON processing unit 116 processes the signal received from the optical network matching unit 118 and transmits the signal to the Ethernet matching unit 114, and receives the Ethernet data from the Ethernet matching unit 114 and transmits Ethernet data to be transmitted through the optical transmission network. The data is converted into data and output to the optical network matching unit 118.

Here, the data transfer method of the GPON processing unit 116 is transmitted in a synchronous manner of 8 KHz, and the synchronized data packet includes a header called PLOAM (Physical layer Operations, Administration) having system management related information, and a payload. In addition, the payload includes GEM header and network data for a GPON Encapsulation Method (GEM) port-ID having address information corresponding to each GPON ONT.

The GEM header is mapped to Ethernet Media Access Control (MAC) addresses and the GEM payload is used as an Ethernet packet.

GEM frame is generally composed of PLI (16 bit), Port-ID (12 bit), Frag (2 bit), FFS (2 bit), HEC (16 bit) Fragment payload (L byte), and double PLI (Payload) length Identifier), Port-ID, Frag, FFS, and HEC are GEM headers.

Here, PLI is a field for indicating the length of the payload, Port-ID is a field indicating an ID for identifying traffic in order to provide traffic multiplexing, and Frag is a field for indicating the split state of the payload. Finally, HEC is a field for header error detection and correction. FFS is an unknown field.

In such a GEM frame, the Frag field may be used to record the Ethernet mode or the TDM mode, or the FFS field may be used to record the mode information.

The optical network matching unit 118 photoelectrically converts a signal received from the optical transmission network to the GPON processing unit 116, and converts all the data to be transmitted from the GPON processing unit 116 to the base station 230 and transmits the data to the optical transmission network.

The optical network matching unit 118 converts transmission data in series, converts serially received data in parallel, extracts clock signals and data from the serially transmitted data, and transmits them to the GPON processing unit 114. do.

The GPON ONT 130 converts the optical signal transmitted from the optical splitter 120 through the optical fiber 122 into a GPON frame, and analyzes header information of the converted GPON frame. In the TDM mode, the signal is converted into a TDM frame and transmitted to the base station 230 through the TDM dedicated line 106 connected to the base station.

The Chiffon Entity 130 also includes an optical network matching unit 138, a GPON processing unit 136, an Ethernet matching unit 134, and a TDM processing unit 132.

 The optical network matching unit 138, the GPON processing unit 136, the Ethernet matching unit 134, and the TDM processing unit 132 of the chiffon ENT 130 have the same functions as the corresponding elements of the chiffon OLT 110 described above. Do this.

The optical network matching unit 138 demultiplexes a signal received through the optical transmission network from the Zippon OT 110 and photoelectrically converts the signal.

The GPON processing unit 136 processes the signal received from the optical network matching unit 138 and transmits the signal to the Ethernet matching unit 134, and converts the Ethernet data transmitted from the Ethernet matching unit 134 into GEM packet data to perform optical processing. Output to network matching unit 138.

The Ethernet matching unit 134 converts the GEM packet data received from the GPON processing unit 136 into Ethernet packet data, and transmits the converted Ethernet packet data through the Ethernet communication line 108 when the converted Ethernet packet data is the Ethernet mode. If is in the TDM mode, the output to the TDM processing unit 132.

The TDM processing unit 132 transmits and receives a TDM frame through the TDM dedicated line 106 of the base station 230 and converts the TDM frame received from the base station 230 into an Ethernet frame in the above-described manner to match the Ethernet matching unit 134. And converts the Ethernet frame received from the Ethernet matching unit 134 into a TDM frame and transmits the converted Ethernet frame to the base station 230 through the TDM dedicated line 106.

On the other hand, although not shown, in the case of the base station is configured to communicate by the Ethernet method of the base station may be connected through the Ethernet communication line 108 of the Ethernet matching unit 134 to perform communication.

1 is a block diagram showing a mobile communication base station network system according to the present invention,

FIG. 2 is a detailed block diagram of Zipon OT and Zipon ENT of FIG. 1;

3 is a detailed block diagram of the TDM processing unit of FIG. 2.

Claims (3)

delete A mobile communication base station network system for relaying communication between a base station of a mobile communication network and a base station controller, A zip-on-elty for converting TDM data received through a TDM dedicated line connected to the base station controller into GPON data, converting the converted GPON data into an optical signal, and transmitting the optical signal through an optical transmission network; After converting the optical signal transmitted through the optical transmission network to GPON data, and analyzes the header information of the converted GPON data, if the TDM mode, converts to TDM data and transmits to the base station connected through the TDM dedicated line With; The chiffon OLTI An optical network matching unit for photoelectrically converting a signal received from the optical transmission network; A GPON processing unit converting Ethernet data to be transmitted through the optical transmission network into GPEM Encapsulation Method (GEM) packet data and outputting the converted data to the optical network matching unit; An Ethernet matching unit connected to an Ethernet communication line for transmitting and receiving Ethernet data and converting GEM (GPON Encapsulation Method) packet data received from the GPON processing unit into Ethernet packet data; TDM data is transmitted and received according to the TDM dedicated line of the base station controller. The TDM data is converted into Ethernet data and output to the Ethernet matching unit, and the Ethernet packet data received from the Ethernet matching unit is converted into a TDM frame to convert the TDM data into the TDM dedicated line. TDM processing unit for transmitting to the mobile communication base station network system comprising a. A mobile communication base station network system for relaying communication between a base station of a mobile communication network and a base station controller, A zip-on-elty for converting TDM data received through a TDM dedicated line connected to the base station controller into GPON data, converting the converted GPON data into an optical signal, and transmitting the optical signal through an optical transmission network; After converting the optical signal transmitted through the optical transmission network to GPON data, and analyzes the header information of the converted GPON data, if the TDM mode, converts to TDM data and transmits to the base station connected through the TDM dedicated line With; The chiffon Oriente An optical network matching unit for photoelectrically converting a signal received from the Zippon OLT through the optical transmission network; A GPON processing unit for converting Ethernet packet data to be transmitted through the optical network matching unit into GPEM Encapsulation Method (GEM) packet data; An Ethernet matching unit for converting GEM (GPON Encapsulation Method) packet data received from the GPON processing unit into Ethernet packet data and transmitting and receiving Ethernet data through an Ethernet communication line; TDM data is transmitted and received by matching with the TDM dedicated line of the base station, and the received TDM data is converted into Ethernet data and output to the Ethernet matching unit, and the Ethernet data received from the Ethernet matching unit is converted into TDM data to convert the TDM dedicated line of the base station. And a TDM processing unit for transmitting and processing through the mobile communication base station network system.

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