KR20060032934A - Optical repeater for tdd rf system - Google Patents

Abstract

The present invention is not only applicable to a wireless communication system using a time division duplexing method such as a portable Internet (for example, WiBro) capable of moving the Internet, but also a radio frequency of a base station and an optical relay period. The present invention relates to an optical repeater for a time division duplexing wireless communication system incorporating a technology for synchronizing transmission and reception times.

In the present invention, the bandpass filter 11 is connected to the antenna in the base station 10, the low noise amplifier (LNA) and high power amplifier (HPA) is connected through the circulator 12, the low noise amplifier (LNA) The radio frequency delayer 13 and the coupler 14, the high power amplifier (HPA) is connected to the radio frequency delayer 13 'and the coupler 14', respectively, down converter (DNC) and up-converter ( A TDD system module 15 is installed through the UPC; It is characterized by inserting a fixed delay module having a delay equal to the delay of the maximum optical section in which the optical repeater 20 can be installed at the front end of the high power amplifier (HPA) and the low noise amplifier (LNA) of the base station 10. .

TDD, Time Division Duplexing, Wireless Communication System, Optical Repeater, Portable Internet

Description

Optical division for time division duplexing wireless communication system {OPTICAL REPEATER FOR TDD RF SYSTEM}             

1 is a block diagram of an optical repeater for a time division duplexing wireless communication system according to an embodiment of the present invention;

2 is a timing diagram of a TDD synchronization in an optical repeater for a time division duplexing wireless communication system according to the present invention;

3 is a block diagram illustrating an optical repeater for a time division duplexing wireless communication system of the present invention.

Explanation of symbols on the main parts of the drawings

10: base station

20: optical repeater

30: donor unit

40: remote unit

The present invention is not only applicable to a wireless communication system using a time division duplexing method such as a portable Internet (for example, WiBro) capable of moving the Internet, but also to synchronize radio frequency transmission / reception time synchronization between a base station and an optical relay period. The present invention relates to an optical repeater for a time division duplexing wireless communication system having a built-in technology.

In wireless communication, a signal transmission medium of telecommunications uses electromagnetic waves in a space, where electromagnetic waves are interactions between an electric field and a magnetic field generated in a space by a strong current flow. Therefore, in wireless communication, electromagnetic waves are transmitted as a signal transmission medium, and a transmitting side radiates a signal into a radio wave of some form, and a receiving side detects an original signal from radio waves transmitted through the space.

The mobile communication network refers to a network for communication between moving objects such as trains, ships, and automobiles, or between a moving object, a moving object, and the outside, and various functions are required for a moving object such as tracking of a moving object, setting a base station, and setting a path. . By the way, the radio access network is mainly composed of a base station and a repeater, and among them, the base station equipment is largely divided into an RF (RADIO FREQUENCY) unit and a baseband unit. In this case, the baseband portion of several base stations are integrated in one place, and the RF unit is remotely located as a remote unit, and the connection between each remote unit and the central base station by an optical cable facilitates management and maintenance. .

Therefore, it is considered that installing an optical repeater in order to determine the coverage or increase the call quality in the shadow area in the wireless communication system can improve the economic efficiency than installing the base station. Among the mobile communication systems that have been recently discussed, the portable Internet system adopts a duplexing method as a time division duplexing method. When using an optical repeater for extending shadow area and base station coverage in a system using the time division duplexing method, In order to match the time division duplexing switching synchronization between a base station and an optical repeater remote (REMOTE), it is necessary to embed a technology for matching synchronization.

The present invention has been invented in consideration of the above circumstances, and can realize an optical repeater capable of matching a time division duplexing synchronization signal of a base station-optical relay period so that it can be used economically in terms of reliable operation and cost. An object of the present invention is to provide an optical repeater for a division duplexing wireless communication system.

In the present invention for achieving the above object, the bandpass filter 11 is connected to the antenna in the base station 10 is connected to a low noise amplifier (LNA) and a high power amplifier (HPA) through the circulator 12, the low noise An amplifier LNA is connected to a radio frequency delayer 13 and a coupler 14, and the high power amplifier HPA is connected to a radio frequency delayer 13 ′ and a coupler 14 ′, respectively, and a down converter (DNC). And a TDD system module 15 is installed through an up-converter (UPC); It is characterized by inserting a fixed delay module having a delay equal to the delay of the maximum optical section in which the optical repeater 20 can be installed at the front end of the high power amplifier (HPA) and the low noise amplifier (LNA) of the base station 10. .

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

1 is a block diagram illustrating an optical repeater for a time division duplexing wireless communication system according to an exemplary embodiment of the present invention. The present invention provides a technique for matching the radio frequency transmission / reception time synchronization between the base station 10 and the optical repeater 20. Built-in time division duplexing optical repeater for wireless communication system, it can be applied to wireless communication system using time division duplexing method such as portable internet which can move and internet.

The bandpass filter 11 of the base station 10 is connected through an antenna, and the bandpass filter 11 is connected to the circulator 12 by a low noise amplifier (LNA) of 30 dB and a high power amplifier (HPA) of 50 dB. Is connected. The low noise amplifier LNA is connected to a radio frequency delayer 13 and a coupler 14, and the high power amplifier HPA is connected to a radio frequency delayer 13 ′ and a coupler 14 ′, respectively. Since the TDD system module 15 is installed through the down-converter DCN and the up-converter UPC, it is divided into delay B (㎲) and delay A (A).

A fixed delay module having a delay equal to DELAY of the maximum optical section in which the optical repeater 20 can be installed is inserted in front of the high power amplifier HPA and the low noise amplifier LNA of the base station 10. In the optical repeater 20, a delay B (㎲), the optical fiber link 0-8Km between the donor unit 30 and the remote unit 40, the optical signal, radio frequency (RF) signal and switch signal It is supplied and has a built-in UL diversity function.

The optical repeater 20 measures the delay from the donor unit 30 of the signal to the remote unit 40 (antenna port), and from the portion combined with the repeater 20 in the base station 10 to the base station 10 antenna The delay of the repeater 20 can be adjusted to be equal to the fixed delay of.

In addition, by detecting the start and end power of the delayed burst signal (BURST), the high power amplifier (HPA) and the low noise amplifier (LNA) of the repeater 20 is turned on / off to distinguish the transmission / reception path (PATH) in time. At this time, the front end stage has a structure in which a band pass filter (BPF) 11 and an antenna are shared for a transmission / reception path using a circulator (CIRCULATOR) 12.

2 is a TDD synchronization timing diagram in an optical repeater for a time division duplexing wireless communication system according to the present invention, and the TDD transmission / reception timing at the antenna terminal of the base station (see FIG. 2C) and the TDD timing at the antenna terminal of the repeater (see FIG. 2D). ) Shows a match. 2A is a base station transmit / receive (modem reference), FIG. 2B is a base station transmit / receive (antenna basis: base station delay not inserted), and FIG. 2c is a base station transmit / receive (antenna basis: base station delay inserted). 2d is a repeater transmission / reception (antenna reference).

And, the on / off timing by TDD switching of the high power amplifier (LPA) and the low noise amplifier (LNA) of the repeater is shown.

3 is a block diagram illustrating an optical repeater for a time division duplexing wireless communication system according to the present invention, wherein the optical repeater is composed of a donor unit 30 and a remote unit 40. The donor unit 30 is composed of components basically required in a repeater of the FDD (FREQUENCY DIVISION DUPLEX) method and a module additionally required in the TDD repeater.

The donor unit 30 is largely composed of a master control unit 31 (MCU), a donor RF and an optical unit 32 (DROU), and a door power supply unit 33 (DPSU), and the master control unit 31 is Repeater state monitoring and control device, the donor RF and the optical unit 32 amplifies the radio frequency signal of RAS (RADIO ACCESS STATION) converts the optical signal and transmits remotely and the optical signal received from the remote to the radio frequency After the conversion is a device for amplifying and transmitting to the RAS, the door power supply unit 33 is a DC / DC converter for power supply of the donor unit (30).

The donor NMS FSK modem (DNFM) is a communication module between the donor unit 30 and the remote unit 40, and the system delay measuring module (SDM) measures the delay of the optical link section between the donor unit 30 and the remote unit 40. As a module, it is a module necessary for the TDD method.

The donor TX / RX driver module (DDM) is a driving module for transmitting and receiving radio frequency signals, the donor optical module (DOM) is a cross conversion module of radio frequency signals and optical signals, and the local generator and power detector (LGPD) are RX diversity. Power detection module for local signal generation and RX automatic gain setting of up-down converter, and variable optical link delay (VOLD) is a module for adjusting optical link delay.

The remote unit 40 is composed of a basic element necessary for the frequency division duplex repeater and a module additionally required for the TDD repeater. The optical module (ROM) is a mutual conversion module of radio frequency and optical signal, and the remote TX / RX driver module (RDM) is a driving module for transmitting / receiving radio frequency signal.

The remote NMS FSK modem (RNFM) is a communication module between the donor unit 30 and the remote unit 40, and the TDD synchronization module (TSM) transmits a TDD switching on / off signal by using a delayed radio frequency burst signal. As a module to control RDM, it is a module necessary for TDD method. WiBro linear power amplifier (WLPA) is a module that operates normal high output power amplifier in the LPA transmission mode according to the control signal of the TDD synchronization module (TSM) and does not affect the characteristics of the receiver in the reception mode. to be.

WiBro Low Noise Amplifier (WLNA) operates normal low noise amplifier in LPA reception mode according to the control signal of TDD synchronization module (TSM), and has built-in protection function for receiver high power input in transmission mode. This module is a low noise amplifier for TDD.

The WiBro band pass filter (WBPF) is a transmission / reception band pass field assembly of the WiBro antenna front end unit, and the remote power supply unit (RPSU) is a power supply unit of the remote unit 40. The remote detector module (RPDM) is a TX output power detection module, and the power monitor coupler (PMC) is an antenna power monitor coupler. The remote generator module (RGM) is a CW signal generation module for RX automatic gain setting, the remote system monitoring module (RSM) is a status monitoring and control device of the repeater, and the front end arrester (FEA) is a lightning strike between the equipment and the antenna. It is an arrester for protection.

The present invention configured as described above inserts a module having a fixed delay in the base station as shown in FIG. The repeater performs the following operations to match the transmission and reception times with the base station antennas.

In order to know the delay that occurs when the repeater is installed according to the optical link distance of the repeater, the delay between the donor unit and the remote unit of the repeater is measured by using the system delay measurement module (SDM) in the repeater donor unit. The repeater delay is set using a variable optical link delay (VOLD) so that the base station delay B (㎲) from the portion combined with the repeater to the antenna.

As shown in FIG. 2, the power amplifier (LPA) operation is turned on in the transmission mode of the power amplifier (LPA) and the low noise amplifier (LNA) of the front-end unit of the repeater using the TDD synchronization module (TSM) in the remote unit. The low noise amplifier (LNA) is turned off. In the receive mode, the operation of the power amplifier (LPA) is turned off and the low noise amplifier (LNA) is turned on. Both modules start on ahead of time for the rising time and the system margin (MARGIN) to start the power amplifier (LPA) and low noise amplifier (LNA).

As described above, according to the present invention, when a wireless mobile communication operator operating a deflector such as a portable Internet with time division duplexing uses an optical repeater to expand service coverage and improve shadow area service without installing an expensive base station. Repeaters with built-in technology should be used to match the time division duplexing switching synchronization of base stations and repeaters.                     

The present invention has sufficient advantages in terms of cost than adding a base station to a service provider using an optical repeater for service of time division duplexing wireless communication.

In addition, the present invention can be used by modifying or applying to all optical repeaters of a system that requires a variable delay of the relay system using an optical signal or a time division duplexing wireless communication.

Claims (6)

A band pass filter 11 having an antenna connected to the base station 10 is connected to a low noise amplifier (LNA) and a high power amplifier (HPA) through a circulator 12, and the low noise amplifier (LNA) is a radio frequency delay ( 13) and the coupler 14, the high power amplifier (HPA) is connected to the radio frequency delay 13 'and the coupler 14', respectively, TDD system through the down converter (DNC) and up converter (UPC) The module 15 is installed to be installed; A time delay characterized in that a fixed delay module having a delay equal to the delay of the maximum optical section in which the optical repeater 20 can be installed is inserted in front of the high power amplifier (HPA) and the low noise amplifier (LNA) of the base station 10. Optical repeater for division duplexing wireless communication system. The method of claim 1, The optical repeater 20 measures the delay from the donor unit 30 of the signal to the remote unit 40 (antenna port), and the base station 10 antenna at the portion coupled with the repeater 20 in the base station 10. An optical repeater for time division duplexing wireless communication system, characterized in that the delay of the repeater 20 is adjusted to be equal to the fixed delay. The method according to claim 1 or 2, In order to know the delay occurring when the repeater is installed according to the optical link distance of the repeater, the delay between the donor unit and the remote unit of the repeater is measured by using a system delay measurement module (SDM) in the repeater donor unit. An optical repeater for time division duplexing wireless communication systems. The method of claim 3, wherein And a variable optical link delay (VOLD) is inserted into the repeater to constantly adjust the delay between the donor unit and the remote unit of the optical repeater. The method of claim 3, wherein Time division duplexing wireless communication system, characterized in that the power amplifier (LPA) and low noise amplifier (LNA) of the front end unit of the repeater on / off using a TDD synchronization module (TSM) to the remote unit of the optical repeater. Optical repeater. The method of claim 3, wherein An optical repeater for a time division duplexing wireless communication system, characterized in that a circulator is inserted into the front end of the repeater to share an antenna with a band pass filter for TX / RX.

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