KR20010065935A - apparatus and method for matching radio port and radio port controller in coireless local loop system - Google Patents

Abstract

PURPOSE: A radio optical interface device between an RP(Radio Port) and an RPC(Radio Port Controller) in a WLL(Wireless Local Loop) system and a method thereby are provided to connect an RP and an RPC by wireless light, instead of an E1 interface device. CONSTITUTION: An E1 signal transmitted through an E1 interface unit(31) in an RP(30) is firstly demultiplexed at a multiplexing/demultiplexing unit(32) and then supplied to an optical-to-electrical conversion unit(33). The optical-to-electrical conversion unit(33) converts the demultiplexed signal into an optical signal of 155M and transmits it to an optical transceiver unit(210) in an RPC(40). The optical transceiver unit(210) receives the 150M optical signal and outputs it to an optical-to-electrical conversion unit(43). The optical-to-electrical conversion unit(33) executes optical-to-electrical conversion for the optical signal and supplies it to a multiplexing/demultiplexing unit(42). The multiplexing/demultiplexing unit(42) converts the signal into an E1 signal so as to be interfaced with an E1 interface unit(41) in the RPC(40).

Description

Wireless optical matching device between base station and base station control in wireless subscriber network system and its method {apparatus and method for matching radio port and radio port controller in coireless local loop system}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless local loop (hereinafter referred to as a WLL), and more particularly, to wirelessly connect between a base station and a base station control in a WLL system to enable a wireless optical connection between a base station and a base station controller instead of an E1 matching device. An optical matching device and a method thereof.

In general, the WLL system has a merit that it is much better than the radio wave environment of the mobile communication network in terms of use as a communication medium through a wireless channel.

In addition, the line-of-sight environment is secured, and the propagation path loss is about 20 dB / decade, so that it can serve a wider area with the same transmission power. Fading due to multipath is much less than that of point-to-point mobile communication network.

Due to these advantages, the development and research of the WLL system is actively underway, and the accompanying drawings of FIG. 1 show a schematic configuration of a general WLL network having the above advantages.

As shown in Fig. 1, network components include network subscriber station 10, 10 ', subscriber access devices 20, 20', base station 30, 30 ', base station controller 40, WLL switching station ( 50), a base station operating device 60, and the like, and additionally, a data communication matching device 70 (IWF: inter-working function) for data service, a home location register (HLR: Home Location Resister / Authentication Center) ( 80).

In addition, the billing center 100 connected to the network management sensor 90, the WLL switch 50 and the data communication matching device 70 is connected to the base station operating device 60 and the WLL switch 50 is further provided.

Let us explain the interface between the network components in the WLL system network configured as described above.

The subscriber access devices 20 and 20 'and the base stations 30 and 30' use the standard WLL radio access standard as the access standard, and the channel bandwidth is 10 MHz. The connection standard between the base stations 30 and 30 'and the base station controller 40 selects and uses E1 or HDSL, and the signaling method uses LAPD (Link Access Protocol D).

The base station controller 40 and the WLL switch 50 use E1 as a connection standard and use ITU-T.G965 as a signaling method.

In addition, the connection standard between the base station controller 40 and the base station operating device 60 uses Ethernet, and as a signaling method, Simple Network Management Protocol (SNMP), File Transfer Protocol (FTP), and Telecommunication Network (TELNET). Etc.

On the other hand, the base station controller 40 and the data communication matching device 70 uses E1 as the connection standard, and uses LAPD as the signaling method. In addition, the connection between the WLL switch 50 and the data communication matching device 70 uses E1 as the connection standard and R2 is used as the signaling method.

The connection standard between the WLL switch 50 and the home position register 80 uses E1, and IS-41C is used as the signaling method.

Let's look at the operation of the WLL system network connected through the connection standard and the signaling method in more detail.

First, the base station (30, 30 ') is a base station control module (RCP) that performs the overall management function for one base station, a modem module performing a signal processing function related to the CDMA channel, high power / low noise amplification and transmission and reception frequency conversion function RF module for performing the step, and a line connection module for performing the relay line (E1) connection function for matching with the base station controller 40, amplification of the transmission signal in the RF module, low noise amplification of the received signal, frequency down / up It performs conversion, reception of diversity through two antennas, high power / low noise amplification, and transmission / reception frequency conversion.

In addition, the modem module provides CDMA channels (pilot channel, sync channel, paging channel, access channel, signaling channel, traffic channel, packet traffic channel, packet access channel), digital baseband function processing, CDMA channel coding and decoding related functions. Do this.

The line connection module performs data communication with the base station controller 40 with respect to traffic and control information, and performs a relay line (E1 / HDSL) function for matching the base station controller 40.

The base station controller 40, which controls the base stations 30 and 30 ', is composed of a transcoder module, a call processing module, a switching module, and a matching module. The transcoder module is a 64 Kbps Pulse Code Modulation (PCM) voice coding signal. It includes a transcoder that performs the conversion function, and echo cancellation is implemented. In addition, the call processing module performs various call processing functions such as incoming / outgoing call processing support and message processing of the base station, subsystem status management in the base station controller 40, and control signal format between the WLL switch 50 and the subscriber access device. It is a processor that has a redundant structure for system reliability. The switching module also provides a traffic path between the base station matching device and the transcoder in the base station controller 40.

In addition, the matching module is composed of a WLL switch matching module, a base station matching module and a base station operating device (60) matching module, dual WLL switch (50) matching module for installing the base station controller 40 remotely with the WLL switch (50) If so, perform the E1 / G.965 digital heavy accounting function. In addition, the base station matching module performs the E1 / LAPD, HDSL relay line matching function between the base station and the base station control, and the base station operating device matching module performs the Ethernet / SNMP, FTP, TELNET matching function during the base station operating device-base station control period.

Next, the base station operating device 60 operates the base station controller 40, the base stations 30 and 30 ', and the subscriber access devices 20 and 20', and is responsible for maintenance and repair of each device.

As described above, the connection medium between the base station and the base station controller in the WLL system is implemented as an E1 link, and the number of E1 links provided for the base station and the base station control period is defined as 2E1.

Currently, the base station provides subscriber capacity of 30 to 60 channels, and if the base station capacity is further increased to 2FA / 3 sectors, more E1 dedicated lines will be needed. However, it is difficult to rush to E1 leased line if subscriber capacity suddenly surges, as it maintains the possibility of generating 2FA / 3 sector capacity on initial cell plain and does not preempt E1 leased line first.

Conventional CDMA or PCS systems have adopted the E1 transmission scheme, but do not use the optical transmission scheme. The commercialized part of the wireless optical transmission system is the optical repeater of PCS / CDMA, which is installed in the shaded area where the base station radio waves are not transmitted well, and the base station RF frequency is directly loaded on the light and transmitted. After modulating with the RF frequency, it has never been used as a transmission method between the base station and the base station controller to cover the shadow area.

In addition, the E1 link is currently provided through the HDSL or FLC system without directly providing the E1 dedicated line. As the capacity of the E1 dedicated line increases, the size of the HDAL or FLC system to be installed in the telephone company increases.

FIG. 2 is a conceptual diagram of a base station and base station control period E1 link connection in a wireless subscriber network system according to the prior art. Referring to FIG. 2, the base station and base station control period matching device of the conventional WLL system will be described with reference to FIG. 2. As a method of connecting the base stations 30 and 30 'to the base station controllers 40 and 40', it is expensive to newly construct and provide a new E1 dedicated line to all regions requiring the base stations 30 and 30 '. It is provided using HDSL equipment or FLC system that can provide speed and transmission characteristics of 2.048M provided by E1 dedicated line. This is provided by using existing lines by using existing 2W analog lines and priority optical lines.

However, when they need more capacity, they need to be installed more, but it is difficult to provide a lot of E1 dedicated lines due to local characteristics.

In addition, since the wireline used as the transmission medium for the light currently used has to be laid underground, there is a huge problem of enormous investment cost and maintenance for the installation of the optical line.

Therefore, the present invention has been made to solve the above problems according to the prior art, an object of the present invention is to enable a wireless optical connection between the base station and the base station controller in the WLL system instead of the E1 matching device, the initial installation The present invention provides a wireless optical matching device between a base station and a base station control in a WLL system that can easily accommodate a rapidly increasing subscriber capacity with a simple operation and enable high-speed transmission (155M-622 Mbps).

In addition, another object of the present invention is to provide a base station and base station control period optical matching method in a WLL system corresponding to the operation of the apparatus.

In the WLL system according to the present invention for achieving the above object, the base station and the base station control period optical matching device is characterized in that the base station and the base station controller of the WLL system each having an E1 matching unit, a) in the E1 matching unit of the base station Converts the output E1 signal into high-speed digital data, converts the converted digital high-speed data into an optical signal having an arbitrary speed, and b) converts the optical signal received from the base station controller to digital high-speed data having an arbitrary speed. First signal converting means for converting and converting the converted digital high-speed data into an E1 signal for matching with an E1 matching portion of the base station; First optical transmission / reception means for transmitting the optical signal converted by the first signal conversion means to the base station controller in a time division manner, and receiving and providing the optical signal transmitted from the base station controller in the time division manner to the first signal conversion unit; a) converts the E1 signal output from the E1 matching unit of the base station controller into high-speed digital data, converts the converted digital high-speed data into an optical signal having an arbitrary speed, and b) converts the optical signal received from the base station side. Second signal conversion means for converting the digital high speed data having an arbitrary speed and converting the converted digital high speed data into an E1 signal for matching with the E1 matching portion of the base station controller; A first optical transmission / reception means for transmitting the optical signal converted by the second signal conversion means to the base station in a time division method, and receiving and providing the optical signal transmitted from the base station controller in the time division method to the second signal conversion means. Is in.

In addition, the characteristics of the base station and the base station control period optical matching method in the WLL system according to the present invention, in the base station and base station control period optical matching method having an optical transceiver, a photoelectric changer, a multiplexing / demultiplexer and an HDB3 matching unit in the WLL system, Receiving an optical signal transmitted from a base station or a base station controller through the optical transmitter; Converting the received optical signal into a high speed digital signal in the photoelectric converter, and then extracting a reference clock signal from the converted digital signal; Extracting a network synchronization clock signal from the extracted reference clock signal and distributing them to fit each block; Demultiplexing the electrical digital high-speed data converted by the photoelectric conversion unit at an arbitrary speed, and demultiplexing the demultiplexed signals of 45-155M into E1 signals having an arbitrary speed; HDB3 coding the converted E1 signal to E1 match with the base station or base station controller; Determining whether to receive the reassignment information according to the expansion of the E1 channel, analyzing the reassignment time slot when receiving the channel reassignment information, and transmitting the corresponding information to the multiplexer / demultiplexer to extract and insert the information. It is done.

1 is a block diagram illustrating a general broadband wireless subscriber network system;

2 is a conceptual diagram of a base station and base station control period E1 link connection in a wireless subscriber network system according to the prior art;

3 is a conceptual diagram of a wireless optical matching device between a base station and base station control in a wireless subscriber network system according to the present invention;

4 is a diagram illustrating a detailed configuration of a wireless optical matching device between a base station and a base station control in a wireless subscriber network system according to the present invention;

5 is a diagram illustrating a detailed configuration of a multiplexing / demultiplexing unit and a photoelectric conversion unit shown in FIG. 4;

6 is a flowchart illustrating an operation of a wireless optical matching method between a base station and base station control in a wireless subscriber network system according to the present invention.

<Explanation of symbols for main parts of drawing>

30: base station 40: base station controller

31, 41: E1 matching part 32, 42: multiplexing and demultiplexing part

33, 43: photoelectric conversion unit

a, b, c: first to third multiplexer / demultiplexer

d, e: 1st, 2 HDB3 matching unit

200, 210: Optical transmitting and receiving unit 220: CPU

230: alarm signal processing unit 240: clock extraction and distribution unit

250: oscillation unit

Hereinafter, a base station and a base station control period optical matching device and method thereof in a WLL system according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a conceptual diagram of a wireless optical matching device between a base station and base station control in a wireless subscriber network system according to the present invention, and FIG. 4 is a detailed view of a wireless optical matching device between base station and base station control in a wireless subscriber network system according to the present invention. As shown in FIG. 3, the present invention is equipped with optical transceivers 200 and 210 on base stations 30 and 30 'and base station controllers 40 and 40', respectively. 30 ') and the base station controller 40, 40' is to perform a wireless optical communication.

Referring to this in more detail with reference to Figure 4, in the plurality of base stations 30 is configured an E1 matching unit 31 for matching with the E1 link, the E1 signal transmitted through the E1 matching unit 30 is multiplexed / The demultiplexing unit 32 demultiplexes and provides the photoelectric conversion unit 33.

The photoelectric conversion unit 33 converts the demultiplexed signal output from the multiplexing / demultiplexing unit 32 into an optical signal of 155M to transmit and receive an optical transmission / reception unit of the base station controller 40 through the optical transmission / reception unit 200. 210).

The optical transceiver 210 on the side of the base station controller 40 receives a 150M optical signal transmitted from the optical transmitter / receiver 200 on the base station 30 side and outputs the optical signal to the photoelectric converter 43.

The photoelectric conversion unit 43 photoelectrically converts an input optical signal of 155M to the multiplexer / demultiplexer 42.

The multiplexer / demultiplexer 42 converts the signal multiplexed by the photoelectric converter 43 into an E1 signal and matches the E1 matcher 41 of the base station controller 40. At this time, the optical signal transmission method uses a time division method when transmitting an optical signal from the optical transmitter / receiver 200 on the base station 30 side to the optical transceiver 210 on the base station controller 40 side.

Meanwhile, the E1 signal transmitted through the E1 matching unit 41 in the base station controller 40 is demultiplexed by the multiplexing / demultiplexing unit 42 and provided to the photoelectric conversion unit 43.

The photoelectric conversion unit 43 converts the demultiplexed signal output from the multiplexing / demultiplexing unit 42 into an optical signal of 155M and transmits and receives the optical transmitting and receiving unit 200 of the base station 30 through the optical transmitting and receiving unit 210. To send.

The optical transceiver 200 on the side of the base station 30 receives the 150M optical signal transmitted from the optical transmitter / receiver 210 on the base station controller 40 side and outputs the optical signal to the photoelectric converter 33.

The photoelectric conversion unit 33 photoelectrically converts an input optical signal of 155M to the multiplexer / demultiplexer 32.

The multiplexer / demultiplexer 32 converts the signal multiplexed by the photoelectric converter 33 into an E1 signal and matches the E1 matcher 31 of the base station 30. At this time, when transmitting the optical signal from the optical transmitter and receiver 210 on the base station controller 40 side to the optical transceiver 200 on the base station 30 side, the optical signal transmission method uses a time division method. That is, in the present invention, as shown in FIG. 2, the photoelectric conversion units 33 and 43 and the multiplexing / demultiplexing unit 32 42 in front of each base station 30 and base station controller 40 E1 matching units 31 and 41. ), And converts the input optical signal into an E1 signal to transmit and receive. In the E1 frame allocation method, a time division multiplexing method is used to select a channel having a predetermined time zone to the base station 30 and load data at this time. If the allocation time is rearranged when the channel is increased, the capacity can be easily increased.

FIG. 5 is a diagram illustrating a detailed configuration of the multiplexing / demultiplexing unit and the photoelectric conversion unit shown in FIG. 4. Referring to FIG. 5, the multiplexing / demultiplexing units 32 and 42 and the photoelectric conversion unit ( The detailed operations of 33 and 43 will be described.

The photoelectric conversion units 33 and 43 photoelectrically convert 155M to 622M optical signals inputted through the optical transmission and reception units 200 and 210 and output them to the multiplexing / demultiplexing units 32 and 42. At this time, the clock extraction and distribution unit 240 extracts a reference clock from the signals converted by the photoelectric conversion units 33 and 43 and distributes them to the multiplexing / demultiplexing units 32 and 42, respectively.

The first multiplexer / demultiplexer (a) of the multiplexer / demultiplexer (32, 42) receives the 155M-622M signals output from the photoelectric converters (33, 43) from the clock extractor and divider (240). And demultiplexed into 45M to 155M signals to output to the second and third multiplexer / demultiplexers b and c, respectively.

The second and third multiplexer / demultiplexers (b, c) demultiplex 45-155M signals output from the first multiplexer / demultiplexer (a) into 2.01M E1 signals, and the HDB3 matcher (d, e) It will convert to the physical level HDB3 format that can be e1 matched. Here, the clock extraction and distribution unit 240 provides 155M-622M synchronous clock signals to the first multiplexer / demultiplexer (a) to synchronize the blocks, and the second and third multiplexers (b, c) provides synchronous clock signals of 45M to 155M, and 2M synchronous clock signals are distributed to the HDB3 matching units d and e, respectively.

In addition, the alarm signal processing unit 230 receives a signal error or an alarm signal generated in each block in the multiplexing / demultiplexing units 32 and 42 and reports the result to a higher level.

Meanwhile, the CPU 220 initializes the blocks and reassigns them when a new link is added to the E1 matching unit 31 of each base station 30.

In the wireless subscriber network system according to the present invention, a matching method corresponding to the operation of the wireless optical matching device between the base station and the base station control will be described step by step with reference to FIG. 6.

6 is a flowchart illustrating an operation of a wireless optical matching method between a base station and base station control in a wireless subscriber network system according to the present invention.

First, after the power of each block shown in Figure 5 is turned on (S101), each block is initialized according to the provided synchronous clock signal (S102).

After receiving the optical signal transmitted from the base station or the base station controller through the optical transmitter (200, 210) (S103), the received optical signal is converted into a high-speed digital signal of 155M-622M in the photoelectric conversion unit (33, 43) In operation S104, the clock signal is extracted from the converted electrical signal. At this time, the extracted reference clock signal is provided to the clock extraction and distribution unit 240. The clock extraction and distribution unit 240 extracts the reference clocks provided by the photoelectric conversion units 33 and 43, and then synchronizes each block. It is to provide a clock signal (S105).

Subsequently, the first multiplexing / demultiplexing unit (a) demultiplexes the electrical digital high-speed data converted by the photoelectric conversion units 33 and 43 at the corresponding speeds 45M to 155M (S106).

The demultiplexed signals of 45-155M are demultiplexed by the second and third multiplexing / demultiplexing units (b, c) and converted into 2M E1 signals that can be matched to the E1 matching unit 31 and outputted (S107). ), The HDB3 matcher (d, e) HDB3 coded 2M signals input from the second and third multiplexer / demultiplexer (b, c) and transmits them to the E1 matcher (31) (S108).

Subsequently, it is determined whether reassignment information is received according to the expansion of the E1 channel (S109), and when the channel reassignment information is received, the reassignment time slot is analyzed (S110), and then the multiplexing / demultiplexing units 32 and 42 are used. The information is transmitted to allow further extraction and insertion (S111).

In the wireless subscriber network system according to the present invention as described above, the wireless optical matching device and the method between the base station and the base station control in the matching method between the base station and the base station controller that is matched to the E1 dedicated line in the future capacity increase easy and easy maintenance In addition, by using the wireless section instead of the cable line currently used as the transmission medium of optical fiber, E1 dedicated line is reduced by the total loss method using the high speed of light while reducing the enormous investment cost and maintenance cost invested in the optical line to be installed. There is an advantage to solve the problems that can not be provided.

Claims (6)

In the base station and base station controller of the WLL system each having an E1 matching unit, a) converting the E1 signal output from the E1 matching unit of the base station into high-speed digital data, converting the converted digital high-speed data into an optical signal having an arbitrary speed, b) first signal conversion means for converting the optical signal received from the base station controller side into digital high speed data having an arbitrary speed, and converting the converted digital high speed data into an E1 signal for matching with the E1 matching unit of the base station; ; First optical transmission / reception means for transmitting the optical signal converted by the first signal conversion means to the base station controller in a time division manner, and receiving and providing the optical signal transmitted from the base station controller in the time division manner to the first signal conversion unit; a) converting the E1 signal output from the E1 matching unit of the base station controller to high speed digital data, converting the converted digital high speed data into an optical signal having an arbitrary speed, b) second signal converting means for converting the optical signal received from the base station to digital high speed data having an arbitrary speed, and converting the converted digital high speed data into an E1 signal for matching with an E1 matching unit of the base station controller; ; And a first optical transmission / reception means for transmitting the optical signal converted by the second signal conversion means to the base station in a time division method, and receiving the optical signal transmitted from the base station controller in a time division method and providing the optical signal to the second signal conversion means. The optical matching device of the base station and the base station control period in the WLL system, characterized in that. The method of claim 1, The first signal converting means demultiplexes the E1 signal output from the E1 matching section of the base station to convert it into digital high speed data, and converts the received high speed digital data into an E1 signal for matching with the E1 matching section of the base station. A multiplexing / demultiplexing unit; The digital high speed data demultiplexed and output by the multiplexer / demultiplexer is converted into an optical signal having an arbitrary speed, and the optical signal received from the first optical transmission / reception means is converted into digital high speed data to the multiplex / demultiplexer. An optical matching device for a base station and a base station control period in a WLL system, characterized by comprising a photoelectric conversion unit for outputting to a multiplexing unit. The method of claim 2, The multiplexer / demultiplexer comprises: a first multiplexer / demultiplexer for converting high-speed digital data converted by the photoelectric converter to 45-155M speed digital data and extracting and outputting a reference clock; A second and third multiplexer / demultiplexer for converting 45M-155M digital data output from the first multiplexer / demultiplexer into a 2M E1 signal according to a provided network synchronizer clock signal; An HDB3 matching unit for converting the 2M E1 signal output from the second and third multiplexing / demultiplexing units into an HDBS signal so as to match with the E1 matching unit of the base station or the base station controller; A clock extraction and distribution unit for extracting a network synchronization clock signal from the reference clock signal extracted by the first multiplexer / demultiplexer and providing the second and third multiplexer / demultiplexer and the HDB3 matcher; And a base station and base station control period optical matching device in a WLL system, characterized in that it comprises an alarm signal processing unit for receiving an alarm signal from each block and reporting it to a higher processor. The method of claim 1, The second signal converting means demultiplexes the E1 signal output from the E1 matching unit of the base station controller to convert the digital high speed data, and multiplexes the received high speed digital data into an E1 signal for matching with the E1 matching unit of the base station controller. A multiplexing / demultiplexing unit to convert; The digital high speed data demultiplexed by the multiplexing / demultiplexing unit is converted into an optical signal having an arbitrary speed, and the optical signal received from the second optical transmitting / receiving means is converted into digital high speed data to perform the multiplexing / demultiplexing. An optical matching device for a base station and a base station control period in a WLL system, characterized by comprising a photoelectric conversion unit for outputting to a multiplexing unit. The method of claim 4, wherein The multiplexer / demultiplexer comprises: a first multiplexer / demultiplexer for converting high-speed digital data converted by the photoelectric converter to 45-155M speed digital data and extracting and outputting a reference clock; A second and third multiplexer / demultiplexer for converting 45M-155M digital data output from the first multiplexer / demultiplexer into a 2M E1 signal according to a provided network synchronizer clock signal; An HDB3 matching unit for converting the 2M E1 signal output from the second and third multiplexing / demultiplexing units into an HDBS signal so as to match with the E1 matching unit of the base station or the base station controller; A clock extraction and distribution unit for extracting a network synchronization clock signal from the reference clock signal extracted by the first multiplexer / demultiplexer and providing the second and third multiplexer / demultiplexer and the HDB3 matcher; And a base station and base station control period optical matching device in a WLL system, characterized in that it comprises an alarm signal processing unit for receiving an alarm signal from each block and reporting it to a higher processor. In the base station and base station control period optical matching method having an optical transceiver, a photoelectric converter, a multiplexing / demultiplexing unit and an HDB3 matching unit in a WLL system, Receiving an optical signal transmitted from a base station or a base station controller through the optical transmitter; Converting the received optical signal into a high speed digital signal in the photoelectric converter, and then extracting a reference clock signal from the converted digital signal; Extracting a network synchronization clock signal from the extracted reference clock signal and distributing them to fit each block; Demultiplexing the electrical digital high-speed data converted by the photoelectric conversion unit at an arbitrary speed, and demultiplexing the demultiplexed signals of 45-155M into E1 signals having an arbitrary speed; HDB3 coding the converted E1 signal to E1 match with the base station or base station controller; Determining whether to receive the reassignment information according to the expansion of the E1 channel, analyzing the reassignment time slot when receiving the channel reassignment information, and transmitting the corresponding information to the multiplexer / demultiplexer to extract and insert the information. The optical matching method of the base station and the base station control period in the WLL system, characterized in that made.