KR20060036657A - Switching Time Determination Method for Time Delay Compensation of TDF Repeated RF Repeater in WiBro System and RF Repeater therefor - Google Patents

Abstract

The present invention relates to a switching time determining method for time delay compensation of a TDD type RF repeater in a WiBro system and an RF repeater therefor.

The present invention provides a switching time determining method for time delay compensation of a TDD type RF repeater in a WiBro system, the method comprising: (a) detecting a transmission signal transmitted from an RAS to an RF repeater and transmitting the signal to a switch controller of the RF repeater; (b) detecting a frame start point of the transmission signal by analyzing the transmission signal extracted in step (a); (c) calculating a downlink signal interval and an uplink signal interval included in the transmission signal based on a frame start point of the transmission signal, and determining a switching point by compensating for a time delay; (d) generating a switch control signal according to the switching point and transferring the switch control signal to a switch of the RF repeater; And (e) classifying and transmitting the downlink signal and the uplink signal according to a switch control signal, and a switching time determining method for time delay compensation of the RF repeater of the TDD method and the RF repeater therefor. to provide.

According to the present invention, an accurate switching control can be performed by generating a switch control signal to which time delay compensation is applied in a TDD type RF repeater.

WiBro, Mobile Internet, TDD, RF Repeater, Switching Control, Time Delay Compensation

Description

Method for Determining Switching Timing for Compensating Time Delay of TDD RF Repeater and RF Repeater Therefor for Use in WiBro System

1 is a schematic view showing a WiBro system;

2 is a diagram illustrating a frame structure of a transmission signal in transmitting data through WiBro;

3 is a block diagram showing the internal configuration of a TDD RF repeater according to a preferred embodiment of the present invention;

4 is a diagram illustrating a preamble time structure of a transmission signal frame when data is transmitted through WiBro;

5 is an exemplary screen showing a signal waveform output as a result of autocorrelation of a transmission signal in the case of transmitting data through WiBro;

6 is a block diagram showing the internal configuration of the switch control unit of the RF repeater according to a preferred embodiment of the present invention;

7 is a flowchart illustrating a switching time determination method for time delay compensation of a TDD type RF repeater according to an exemplary embodiment of the present invention.                 

<Description of the symbols for the main parts of the drawings>

100: PSS 110: RAS

120: ACR 130: PDSN

140: HA 150: AAA

160: IP network 170: the Internet

300: RF repeater 305: donor antenna

310, 345: band pass filter 315: coupler

320, 340: switches 325, 355: low noise amplifier

330, 360: Attenuator 335, 365: High power amplifier

350: remote antenna 370: switch control unit

600: frequency down converter 610: A / D converter

620: delay module 630: autocorrelation module

640: starting point detector 650: control signal generator

The present invention relates to a switching time determining method for time delay compensation of a TDD type RF repeater in a WiBro system and an RF repeater therefor. More specifically, when the transmission signal is transmitted to the RF repeater of the TDD method, the switch control unit of the RF repeater analyzes the transmission signal to determine a switching time compensated for the time delay, generates a switch control signal, and transmits the signal to the switch. The present invention relates to a switching time determining method for time delay compensation of a TDD type RF repeater in a WiBro system capable of distinguishing and relaying a downlink signal and an uplink signal by a switch control signal, and an RF repeater therefor.

As computer, electronic, and communication technologies have made rapid progress, various wireless communication services using wireless networks have been provided. Accordingly, a service provided by a mobile communication system using a wireless communication network is developing not only a voice service but also a multimedia communication service for transmitting data such as circuit data, packet data, and the like.

Recently, IMT-2000 (International Mobile Telecommunication 2000) (eg, CDMA (Code Division Multiple Access) 2000 1X, 3X, EV-DO), a third generation mobile communication system that has been standardized by ITU-R due to the development of information communication. And WCDMA (WideBand CDMA) are commercially available. IMT-2000 is a mobile communication system that aims to implement various application services by combining global direct roaming including personal mobility and service mobility, same call quality as wired telephone, high speed packet data service and wired / wireless network. As a result, as well as improving existing voice and WAP service quality, various multimedia services (AOD, VOD, etc.) may be provided at a higher speed.

However, the existing mobile communication system has a limitation in providing high-speed wireless Internet due to high base station construction cost and high usage rate of the wireless Internet, and a small screen size of the mobile communication terminal. . In addition, wireless local area network (WLAN) technology has limitations in providing public services due to problems such as radio wave interference and a narrow coverage area. Therefore, WiBro (Wireless Broadband Internet), a high-speed portable Internet service that guarantees portability and mobility and can use high-speed wireless Internet service at a low price, has emerged.

WiBro service uses various types of portable mobile terminals such as laptops, PDAs, and handheld PCs to access various information and contents through internet access in indoor and outdoor stationary environments and mobile environments with walking speeds and low to medium speeds. It is a service. WiBro system uses the 2.3 GHz frequency band and provides mobility of 60 km / h per hour. The downlink transmission rate is 24.8 Mbps, but the uplink transmission rate is 5.2 Mbps. System.

The WiBro system uses Time Division Duplex (TDD) as a duplex method and Orthogonal Frequency Division Multiple Access (OFDMA) / Time Division Multiple Access (TDMA) as a multiple access method to effectively use the allocated frequency spectrum. ).

Here, the TDD scheme is a bidirectional transmission scheme in which downlinks and uplinks are alternately assigned in time in the same frequency band. The TDD scheme has a high transmission efficiency and is suitable for asymmetric or bursty application transmission due to dynamic allocation of timeslots.                         

In addition, OFDMA / TDMA is a multiple access scheme similar to TDMA, in which all subcarriers spread over the entire bandwidth are allocated to one user for a certain time and to another user for the next predetermined time. (Multipath) has the property to prevent interference.

1 is a configuration diagram schematically showing a WiBro system.

As shown in FIG. 1, the WiBro system includes a personal subscriber station (PSS) 100, a radio access station (RAS) 110, an access control router (ACR) 120, and a packet data serving node (PDSN) 130. ), A Home Agent (HA) 140, an AAA (Authentication, Authorization, Accounting) 150, an IP network 160, the Internet 170, and the like.

The PSS 100 refers to a mobile communication terminal that uses a high-speed wireless Internet service by accessing a WiBro system, and has a low power RF (RF) / IF (Intermediate Frequency) module and controller function, service characteristics, and MAC (Media Access) according to a radio wave environment. Control) It has frame variable control function, handover function, authentication and encryption function.

The RAS 110 transmits data received from the ACR 120 to the PSS 100 wirelessly as a base station of the WiBro system, and provides a low power RF / IF module and controller function, OFDM / TDD packet scheduling and channel multiplexing function, and service. MAC frame variable control, 50 Mbps high-speed traffic real-time control, handover function, etc. according to characteristics and propagation environment.                         

In addition, the PSS 100 and the RAS 110 have a 50 Mbps packet transmission modulation and demodulation function, a high speed packet channel coding function, a real time modem control function, and the like for data transmission.

The ACR 120 is a packet access router accommodating a plurality of RAS 110, and has a handover control function between the RAS 110, a handover function between the ACR 120, a packet routing function, an Internet access function, and the like. Is connected to.

The PDSN 130 relays transmission and reception of packet data between an external packet data service server such as the Internet 170 and a base station through the IP network 160, and manages location information data of a mobile communication terminal including the PSS 100. do.

The HA 140 performs routing for tracking and connecting to a location of an external packet data service server such as the Internet 170, and the AAA 150 works with the PDSN 130 for the packet used by the PSS 100. Charge the data and authenticate the connection from the PSS 100.

The IP network 160 connects the PDSN 130, the HA 140, and the AAA 150, and receives packet data from an external packet data service such as the Internet 170 and transmits the packet data to the AP 110.

In the wireless communication system including the WiBro system, the wireless communication service area is divided into a plurality of cells by using a frequency reuse concept to expand coverage of the mobile communication network, and is located near the center of each cell. A base station (BS) is being installed to handle wireless communication services. Here, the radius of the cell is determined according to the signal strength of the region or the traffic amount of data. In other words, the cell radius is reduced in urban areas with high traffic volume, and the cell radius is increased in non-city areas with relatively low traffic, so that the traffic generated from each cell is handled by the wireless base station that is responsible for the corresponding mobile communication service. Do not exceed the.

Despite efforts to support better wireless communication services by appropriately adjusting the cell radius according to the frequency reuse concept and traffic volume, radio shadowing areas such as underground, interior, tunnel, etc. are difficult to reach in urban areas. This exists. Installing a number of new wireless base stations to address the radio shadows in these radio shadow areas is not only economically inefficient due to facility costs, installation costs, and maintenance costs, but can also be undesirable in cell design. There will be.

As a solution to this, it is possible to provide a wireless communication service using a repeater in such a radio shadow area. The repeater amplifies the base station signal and transmits it to the radio wave shadow area so that the signal of the base station can reach the radio wave shadow area, and amplifies and filters the terminal signal so that the signal of the terminal located in the radio wave shadow area can reach the base station. It transmits and solves the problem of radio wave shading.

In order to relay a radio signal between a base station and a terminal using a repeater, it is necessary to distinguish a downlink signal, which is a signal transmitted from a base station to a terminal, and an uplink signal, which is a signal transmitted from a terminal to a base station. Since the WiBro system uses the TDD scheme as described above, the downlink signal and the uplink signal are transmitted by dividing the time interval of the same frequency signal. Therefore, in order to relay a wireless signal in a WiBro system, a TDD repeater must be used, and a TDD repeater uses a switch to distinguish a downlink signal and an uplink signal and selectively provide a path for each signal. Done.

Therefore, the TDD repeater must be equipped with a function of analyzing a transmission signal frame of the WiBro system and generating a switch control signal for controlling the switch to perform a switching operation between the downlink signal section and the uplink signal section.

On the other hand, in the WiBro system, a repeater network including an optical repeater and a repeater may be used to extend the coverage of the WiBro network. The relay network connects the base station and the optical repeater, receives the signal transmitted from the optical repeater, and relays the signal to the terminal. Can be configured. Here, in the case of the RF repeater, a time delay of the signal hardly occurs, but in the case of the optical repeater, a signal delay may occur due to the optical communication cable because the signal is transmitted through the optical communication cable.

Therefore, since the RF repeater receives the transmission signal having a time delay from the optical repeater, if the time delay value is not corrected in the switch control signal, an incorrect switch control signal is generated and the downlink signal and the uplink signal are transmitted from the RF repeater. There is a problem that cannot be accurately distinguished.

Therefore, there is an urgent need for a method of accurately classifying a downlink signal and an uplink signal by compensating for a time delay of a transmission signal in a TDD type RF repeater.

In order to solve this problem, the present invention, when transmitting the transmission signal to the RF repeater of the TDD method, the switch control unit of the RF repeater analyzes the transmission signal to determine the switching time compensated for the time delay, and generates a switch control signal to switch In the WiBro system capable of distinguishing and relaying the downlink signal and the uplink signal by a switch control signal, a switching time determination method for time delay compensation of a TDD type RF repeater and an RF repeater for the same are provided. The purpose.

According to a first object of the present invention, an RF repeater using a time division duplex (TDD) scheme and an orthogonal frequency division multiplexing (OFDM) modulation scheme and using a personal subscriber station (PSS), a radio access station (RAS), and a TDD scheme In the WiBro system comprising a switching time determination method for the time delay compensation of the RF repeater, (a) detecting the transmission signal transmitted from the RAS to the RF repeater to transmit to the switch control unit of the RF repeater step; (b) detecting a frame start point of the transmission signal by analyzing the transmission signal extracted in step (a); (c) determining a switching point by calculating a downlink signal section and an uplink signal section included in the transmission signal based on a frame start point of the transmission signal and compensating for a time delay; (d) generating a switch control signal according to the switching point and transferring the switch control signal to a switch of the RF repeater; And (e) dividing and transmitting the downlink signal and the uplink signal by the switch control signal, and providing a switching time determination method for time delay compensation of an RF repeater of a TDD scheme. do.

According to a second object of the present invention, in a TDD type RF repeater for relaying a transmission signal between a PSS and a RAS in a WiBro system using a TDD method and an OFDM modulation method, the transmission signal received through the antenna of the RF repeater A band pass filter (310, 345) for passing the signal of the frequency band used to transmit the signal between the RAS and the PSS and removing signal components of other frequency bands; Low Noise Amplifiers 325 and 355 for reducing noise components of the transmitted signal and amplifying the signal components and delivering them to an attenuator; Attenuators (330, 360) for adjusting the signal level of the transmitted signal and transferring the signal to a high power amplifier (HPA); A switch (320, 340) for performing a switching operation to distinguish the transmission signal into a downlink signal and an uplink signal by a switch control signal; And receiving the transmission signal to detect a start point of the transmission signal frame, calculate a downlink signal interval and an uplink signal interval included in the transmission signal based on the start point of the transmission signal frame, and time delay the TDD optical repeater. TDD relaying a transmission signal between PSS and RAS, comprising: a switch control unit 370 for determining a switching point by compensating for the switching point and generating the switch control signal according to the switching point and transmitting the switch control signal to the remote switch. Provides an RF repeater.

According to a third object of the present invention, in a switch control unit of a TDD type RF repeater for relaying a transmission signal between a PSS and a RAS in a WiBro system using a TDD method and an OFDM modulation method, the transmission signal between the PSS and the RAS A frequency down converter for converting a frequency into a mid band or base band frequency; An A / D converter for converting the transmission signal from an analog signal to a digital signal; A delay module for delaying the transmission signal for a predetermined time; An auto-correlation module for auto-correlating the transmission signal and the delayed transmission signal received from the delay module; A start point detector for detecting a frame start point of the transmission signal by analyzing an autocorrelation result value output from the autocorrelation module; And calculating a frame structure of the transmission signal based on the frame start point of the transmission signal received from the starting point detector, determining a switching point by compensating for a time delay of the TDD optical repeater, and switching a switch control signal according to the switching point. It provides a switch control unit of the TDD-type RF repeater for relaying a transmission signal between the PSS and RAS, characterized in that it comprises a control signal generating unit for generating.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 is a diagram illustrating a frame structure of a transmission signal in the case of transmitting data through WiBro.

In the WiBro system, the entire frame is composed of downlink (DL) frames, uplink (UL) frames, TTG (Tx / Rx Transition Gap), and RTG (Rx / Tx Transition Gap).

Here, the downlink frame refers to a frame for the downlink signal transmitted from the base station to the terminal through the RF repeater, the uplink frame refers to a frame for the uplink signal transmitted from the terminal to the base station through the RF repeater. TTG and RTG are guard times for distinguishing the transmission time of the downlink signal and the uplink signal. During this interval, the base station and the terminal do not transmit valid signals including data.

The TTG refers to the interval between the downlink signal and the uplink signal transmitted subsequently. During this interval, the base station is changed to a mode for receiving the uplink signal and the terminal is changed to a mode for transmitting the uplink signal. The RTG refers to an interval between an uplink signal and a downlink signal transmitted subsequently. During this interval, the base station changes to a mode for transmitting a downlink signal and the terminal changes to a mode for receiving an uplink signal.

As shown in Fig. 2, the entire frame is composed of 5 msec in length, the downlink frame is defined as 3.1104 msec and the uplink frame is 1.728 msec in length. In addition, TTG is defined as 121.2 μs and RTG is 40.4 μs in length.

In order to separately transmit the downlink signal and the uplink signal in the frame structure of the WiBro system described above, the downlink frame and the uplink signal can be provided to provide respective movement paths for the downlink signal and the uplink signal transmitted to the repeater. Switching control should be performed such that the switch is switched in the TTG and RTG periods existing between the link frames.

Meanwhile, as described above, in the WiBro system, the base station and the optical repeater may be connected to extend the coverage of the WiBro network, and the signal transmitted from the optical repeater may be received from the RF repeater and relayed to the terminal. Therefore, since the downlink signal may be transmitted to the RF repeater via the optical communication cable of the optical repeater, the time delay value of the optical communication cable should be considered. The time delay by the optical communication cable is about 0 to 40 μs, and the switching timing considering the time delay should be determined in the TTG section.

Without considering the time delay caused by the optical communication cable and determining the front part of the TTG section or the rear part of the TTG section as the switching point, the downlink signal section or the uplink signal section overlaps the switching point, resulting in an incorrect switch control signal. The switching operation can be performed. Accordingly, as shown in FIG. 2, the switching point between the TTG section except for the section up to 55 μs from the start point of the TTG section and the section up to 55 μs before the end point of the TTG section in consideration of the time delay of the optical communication cable. Can be determined.

In this case, even if the relay network is configured so that the optical repeater is located between the base station and the RF repeater, the switching timing is determined in consideration of the time delay caused by the optical repeater, so that the downlink signal and the uplink are not affected by the optical repeater in the RF repeater. The signal can be distinguished accurately. In this case, the 55 μs time delay compensation interval is an appropriate length for compensating for the time delay caused by the optical communication cable, and is not limited thereto. The length may be adjusted according to the time delay value.

On the other hand, each time interval of the transmission signal frame is not limited to the above-described time length, it is also possible to change the time ratio of the downlink frame and uplink frame as necessary. In this case, the positions of the TTG section and the RTG section may be determined according to the changed time ratio, and the switching point may be determined in the remaining sections except for the time delay compensation section in the TTG section.

3 is a block diagram showing the internal configuration of a TDD RF repeater according to a preferred embodiment of the present invention.

As shown in FIG. 3, the TDD RF repeater 300 according to a preferred embodiment of the present invention includes a donor antenna 305 and a band pass filter (BPF) 310 and 345 as internal components. , Coupler (315), switches 320, 340, low noise amplifiers (LNA: 325, 355), attenuators (330, 360), high power amplifiers (HPA) 335, 365, a remote antenna 350, a switch controller 370, and the like.

The transmission of signals in the downlink and uplink channels using the above-described components of the TDD repeater 300 will be described in detail as follows.

In the case of the downlink channel, the downlink signal transmitted by the RAS 110 is transmitted to the band pass filter 310 through the donor antenna 305. The band pass filter 310 passes only signals of the frequency band of the transmission signal, removes signal components of other frequency bands, and transfers the signal components to the switch 320. Here, since the 2.3 GHz frequency band is used in the mobile communication network of the present invention, the band pass filter 310 passes only signals of the 2.3 GHz frequency band, and removes signal components of other frequency bands. Meanwhile, a coupler 315 is positioned between the band pass filter 310 and the switch 320, and the coupler 315 detects a transmission signal transmitted from the band pass filter 310 to the switch 320 to control the switch controller ( 370).

The switch 320 transmits the input downlink signal to the low noise amplifier 325 in the downlink direction during the time period of the downlink signal, and the low noise amplifier 325 reduces the noise component of the downlink signal and amplifies the signal component. Transfer to attenuator 330. The attenuator 330 adjusts the signal level of the downlink signal and transmits it to the high output amplifier 335, and the high output amplifier 335 amplifies the effective output for transmitting the downlink signal wirelessly and transmits it to the switch 340. . The switch 340 transmits the signal output from the high power amplifier 335 to the band pass filter 345 during the time period of the downlink signal, and the band pass filter 345 passes only the signal in the frequency band of the transmission signal to the remote. It transmits to the PSS 100 through the antenna 350.

In the uplink channel, the uplink signal transmitted from the PSS 100 is transmitted to the band pass filter 345 through the remote antenna 350, and the band pass filter 345 passes only signals in the frequency band of the transmission signal. To the switch 340. The switch 340 transmits the input uplink signal to the low noise amplifier 355 in the uplink direction during the time period of the uplink signal, and the low noise amplifier 355 reduces the noise component of the uplink signal and amplifies the signal component. Transfer to attenuator 360.

The attenuator 360 adjusts the signal level of the uplink signal and delivers it to the high output amplifier 365. The high output amplifier 365 amplifies the effective output for transmitting the uplink signal wirelessly and transmits it to the switch 320. . The switch 320 transmits the signal output from the high power amplifier 365 to the band pass filter 310 during the time period of the uplink signal, and the band pass filter 310 passes only the signal in the frequency band of the transmission signal. The antenna 305 is transmitted to the base station.

The switch controller 370 distinguishes the downlink signal and the uplink signal and generates a switch control signal that compensates for a time delay that may be generated by the optical repeater and transmits the generated switch control signal to the switches 320 and 340. The switch control signal controls the switches 320 and 340 such that a signal is transmitted in the downlink direction during the time period of the downlink signal, and a signal is transmitted in the uplink direction during the time period of the uplink signal.

Since the transmission signal frame structure of the WiBro system is previously defined in FIG. 2, the switch controller 370 analyzes the transmission signal detected by the coupler 315 to detect a starting point of the transmission signal frame and detects the detected starting point. As a reference, the frame structure of the transmission signal can be estimated. When the frame structure of the transmission signal is estimated, the switching point is determined in the TTG and RTG time intervals, but in the TTG interval, the switching point is determined in the remaining sections except for the time delay compensation interval, thereby generating a switch control signal that compensates for the time delay. . Here, the internal structure of the switch control unit 370 will be described later with reference to FIG. 6.                     

4 is a diagram illustrating a preamble time structure of a transmission signal frame in the case of transmitting data through WiBro.

In a WiBro system using an OFDM / TDD scheme, a downlink and an uplink constituting a frame may include a plurality of OFDM symbols, and the OFDM symbol may include a data symbol, a pilot symbol, and a preamble. have. Here, the data symbol is a time interval in which data is transmitted, and the pilot symbol is inserted in the middle of the data symbol and used to estimate whether the communication channel is downlink or uplink.

The preamble is used to indicate when data transmission begins and to synchronize transmission timing. Since the downlink period starts with the preamble and the downlink period of the frame of the transmission signal, the start time of the frame can be known using the preamble. Since the preamble consists of a sub-carrier set having an even frequency offset index, the preamble has a structure in which an NFFT / 2 (NFFT = 1024) sample pattern is repeated twice. Here, NFFT refers to the number of samples produced by the FFT transform. In addition, a CP time interval is inserted at the front of the preamble to collect signals of the multipath and to maintain orthogonality between subcarriers.

Thus, as shown in FIG. 4, the preamble consists of a CP time interval of 128 samples and a valid symbol time interval of two repeated Pc time intervals of 512 samples, so that the entire preamble consists of 1152 samples. .

5 is an exemplary screen showing a signal waveform output as a result of autocorrelation of a transmission signal in the case of transmitting data through WiBro.                     

As described above with reference to FIG. 4, since the transmission signal frame starts with a preamble, the first two OFDM symbols of the downlink are configured as a preamble, and the delayed signal and the original signal are auto-correlated after delaying the transmission signal for a predetermined time. Correlation outputs a signal waveform as shown in FIG. 5 to detect the starting point of the transmission signal frame.

More specifically, since the WiBro system using the OFDM method has a sampling frequency of 10 MHz, the transmission signal is sampled at a sampling interval of 100 nsec. Therefore, when the transmission signal between the RAS 110 and the PSS 100 is sampled in a sample unit of 100 nsec, the transmission signal is delayed by 512 sample time intervals, and the delayed signal and the original signal are autocorrelated, the output waveform is one. It has two peak peaks that maintain the maximum value for the length of the CP time interval in the frame.

Since the two maximum points are generated by the first preamble and the second preamble, respectively, the time point that precedes 1024 sample time intervals from the first maximum point becomes the start point of the transmission signal frame. On the other hand, in order to improve sampling accuracy, the sampling frequency may be increased to oversample.

Figure 6 is a block diagram showing the internal configuration of the switch control unit of the RF repeater according to a preferred embodiment of the present invention.

As shown in FIG. 6, the switch controller 370 according to the preferred embodiment of the present invention includes a frequency down converter 600, an A / D converter 610, and a delay module 620. , An auto-correlation module 630, a start point detector 640, a control signal generator 650, and the like.

The frequency down converter 600 lowers the frequency of the transmission signal received from the coupler 315 to the middle band or the baseband frequency and transfers it to the A / D converter 610, and the A / D converter 610 transmits the received transmission signal. Is converted into an analog signal to a digital signal and transmitted to the delay module 620 and the autocorrelation module 630.

The delay module 620 delays the transmission signal received from the A / D converter 610 for a predetermined time and transmits the delayed signal to the autocorrelation module 630. The autocorrelation module 630 auto-correlates the transmission signal received from the A / D converter 610 and the delayed transmission signal received from the delay module 620 to the start point detector 640. The starting point detector 640 detects the starting point of the transmission signal frame by analyzing the autocorrelation result value output from the autocorrelation module 630. Here, the starting point detector 640 may detect the starting point of the transmission signal frame by the method described in the description of FIG. 5.

The control signal generator 650 calculates the structure of the transmission signal frame using the start point of the transmission signal frame received from the start point detector 640, generates a switch control signal that compensates for the time delay, and delivers the switch control signal to the switch 375. do. Since the length of the frame of the transmission signal, the downlink frame, the TTG, the uplink frame, and the RTG time interval are previously defined in the WiBro standard, the control signal generator 650 may control the downlink frame, the TTG based on the starting point of the transmission signal frame. The uplink frame and the RTG time interval may be calculated. When the frame structure of the transmission signal is estimated, the switching point is generated in the remaining sections except the time delay compensation section and the RTG time section in the TTG time section to generate a switching control signal and transmits the switching control signals to the switches 320 and 340.

7 is a flowchart illustrating a switching time determination method for time delay compensation of a TDD type RF repeater according to an exemplary embodiment of the present invention.

As shown in FIG. 7, when the RF repeater 300 receives a transmission signal from the RAS 100 through the donor antenna 305, the coupler 315 detects the transmission signal and transmits the signal to the switch controller 370. (S700). The switch controller 370 detects the start point of the transmission signal frame by analyzing a waveform after auto-correlating the delayed signal with the original signal after delaying the transmission signal for a predetermined time (S702). As described above with reference to FIG. 6, since the frame structure of the transmission signal is previously defined in the WiBRO standard, the switch control unit 370 configures the downlink frame, TTG, and uplink constituting the transmission signal frame based on the start point of the transmission signal frame. The structure of the entire frame is calculated by calculating the link frame and the RTG time interval (S704).

When the frame structure of the transmission signal is calculated, the switching point that compensates for the time delay is determined so that the switching operation can be performed in the remaining sections except the time delay compensation section in the TTG time section and the RTG time section (S706). When the switching point is determined, a switch control signal for controlling to perform a switching operation at the corresponding point is generated and transmitted to the switches 320 and 340 (S708). The switches 320 and 340 distinguish the downlink signal and the uplink signal by the switch control signal, and selectively provide a path for each signal by adjusting a short circuit of the switches 320 and 340 (S710). .

Therefore, even if a time delay occurs due to the optical repeater connected to the RF repeater 200, the TDD RF repeater 200 accurately distinguishes the downlink signal and the uplink signal by using a switch control signal that compensates for the transmission signal. Will be relayed.

The above description is merely illustrative of the present invention, and those skilled in the art to which the present invention pertains may various modifications without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed herein are not intended to limit the present invention but to describe the present invention, and the spirit and scope of the present invention are not limited by these embodiments. It is intended that the scope of the invention be interpreted by the following claims, and that all descriptions within the scope equivalent thereto shall be construed as being included in the scope of the present invention.

As described above, the present invention generates a switch control signal that can distinguish the downlink signal and the uplink signal in the TDD RF repeater of the WiBro system, and selectively selects a path for each signal by a switching operation. There is an effect that can be provided.

In addition, even if a time delay caused by an optical repeater connected to the RF repeater can generate a switch control signal with time delay compensation to perform accurate switching control, a downlink signal and an uplink signal can be There is an advantage to relay effectively.

Claims (28)

In a WiBro system using a time division duplex (TDD) scheme and an orthogonal frequency division multiplexing (OFDM) modulation scheme, a personal subscriber station (PSS), a radio access station (RAS), and an RF repeater of a TDD scheme In the switching time determination method for the time delay compensation of the RF repeater, (a) detecting a transmission signal transmitted from the RAS to the RF repeater and transmitting the detected signal to a switch controller of the RF repeater; (b) detecting a frame start point of the transmission signal by analyzing the transmission signal detected in step (a); (c) determining a switching point by calculating a downlink signal section and an uplink signal section included in the transmission signal based on a frame start point of the transmission signal and compensating for a time delay; (d) generating a switch control signal according to the switching point and transferring the switch control signal to a switch of the RF repeater; And (e) classifying and transmitting the downlink signal and the uplink signal according to the switch control signal; Switching time determination method for the time delay compensation of the TDD RF repeater, characterized in that it comprises a. The method of claim 1, The switch controller delays the transmission signal for a predetermined time and then auto-correlates the delayed signal with the original signal to detect a frame start point of the transmission signal. How to determine switching time for The method of claim 1, The frame of the transmission signal includes a downlink (DL) frame, an uplink (UL) frame, a TTG (Tx / Rx Transition Gap) and an RTG (Rx / Tx Transition Gap) Switching time determination method for time delay compensation of TDD type RF repeater. The method of claim 3, wherein The TTG is a guard time for distinguishing a transmission time of the downlink signal and the uplink signal in a time interval between the downlink frame and the uplink frame transmitted after the downlink frame. The RAS is changed to a mode for receiving the uplink signal while the PSS is changed to a mode for transmitting the uplink signal. Switching time determination method for the time delay compensation of the TDD RF repeater. The method of claim 3, wherein The RTG is a guard time for distinguishing a transmission time of the uplink signal and the downlink signal as a time interval between the uplink frame and the downlink frame transmitted after the uplink frame. During the RAS is changed to a mode for transmitting the downlink signal and the PSS is changed to a mode for receiving the downlink signal switching time determination method for the time delay compensation of the TDD RF repeater. The method according to claim 4 or 5, The switch controller determines the switching point in the TTG and the RTG time interval, and generates the switch control signal that compensates for the time delay by determining the switching point in the remaining sections except for the time delay compensation interval in the TTG time interval. Switching time determination method for the time delay compensation of the RF repeater of the TDD scheme. The method of claim 6, The time delay compensation section is a switching for the time delay compensation of the TDD type RF repeater, characterized in that the section from the start point of the TTG time section up to 55 μs and the section up to 55 μs before the end point of the TTG time section How time is determined. The method of claim 6, When the time ratio of the downlink frame and the uplink frame is changed, the switch controller determines the position of the TTG and the RTG according to the changed time ratio based on the frame start point of the transmission signal, and determines the TTG and the RTG time. The switching point is determined in an interval, but in the TTG time interval, the switch control signal is compensated for the time delay by determining the switching point in the remaining intervals except the time delay compensation interval. Switching time determination method for time delay compensation of repeater. The method of claim 1, The frequency band of the transmission signal comprises a 2.3 GHz frequency band switching time determination method for the time delay compensation of the RF repeater of the TDD scheme. The TDD RF repeater relays a transmission signal between a Personal Subscriber Station (PSS) and a Radio Access Station (RAS) in a WiBro system using a Time Division Duplex (TDD) method and an Orthogonal Frequency Division Multiplexing (OFDM) modulation method. In Band pass filter for receiving the transmission signal received through the antenna of the RF repeater and passing the signal of the frequency band used for transmitting the signal between the RAS and the PSS and removing signal components of other frequency bands (Band Pass) Filters 310 and 345; Low Noise Amplifiers 325 and 355 for reducing noise components of the transmitted signal and amplifying the signal components and delivering them to an attenuator; Attenuators (330, 360) for adjusting the signal level of the transmitted signal and transferring the signal to a high power amplifier (HPA); A switch (320, 340) for performing a switching operation to distinguish the transmission signal into a downlink signal and an uplink signal by a switch control signal; And The start signal of the transmission signal frame is detected by receiving the transmission signal, the downlink signal section and the uplink signal section included in the transmission signal are calculated based on the start point of the transmission signal frame, and the time delay of the TDD optical repeater is calculated. A switch control unit 370 that determines a switching point by compensating and generates and transmits the switch control signal according to the switching point. RF repeater of the TDD method for relaying the transmission signal between the PSS and RAS, comprising a. The method of claim 10, A coupler 315 is positioned between the band pass filter 310 and the switch 320, and the coupler 315 transmits the transmission signal transmitted from the band pass filter 310 to the switch 320. The RF repeater of the TDD scheme for relaying the transmission signal between the PSS and RAS, characterized in that the sensing and transmitting to the switch control unit. The method of claim 10, The switch control unit repeats the transmission signal between the PSS and the RAS after detecting the start point of the transmission signal frame by auto-correlating the delayed signal with the original signal after delaying the transmission signal for a predetermined time. TDD RF Repeater. The method of claim 10, The transmission signal frame includes a downlink (DL) frame, an uplink (UL) frame, a TTG (Tx / Rx Transition Gap) and a RTG (Rx / Tx Transition Gap) RF repeater of TDD type to relay transmission signal between RAS. The method of claim 13, The TTG is a guard time for distinguishing a transmission time of the downlink signal and the uplink signal in a time interval between the downlink frame and the uplink frame transmitted after the downlink frame. While the RAS is changed to the mode for receiving the uplink signal and the PSS is changed to the mode for transmitting the uplink signal TDD RF repeater for relaying the transmission signal between the RAS. The method of claim 13, The RTG is a guard time for distinguishing a transmission time of the uplink signal and the downlink signal as a time interval between the uplink frame and the downlink frame transmitted after the uplink frame. While the RAS is changed to the mode for transmitting the downlink signal and the PSS is changed to the mode for receiving the downlink signal TDD RF repeater for relaying the transmission signal between the RAS. The method according to claim 14 or 15, The switch controller determines the switching point in the TTG and the RTG time interval, and generates the switch control signal that compensates for the time delay by determining the switching point in the remaining sections except for the time delay compensation interval in the TTG time interval. RF repeater of the TDD method for relaying the transmission signal between the PSS and RAS, characterized in that. The method of claim 16, The time delay compensation section is a TDD scheme for relaying a transmission signal between the PSS and RAS, characterized in that the section from the start point of the TTG time section up to 55 μs and the section up to 55 μs before the end point of the TTG time section RF repeater. The method of claim 16, When the time ratio of the downlink frame and the uplink frame is changed, the switch controller determines the position of the TTG and the RTG according to the changed time ratio based on the start point of the transmission signal frame, and determines the TTG and RTG time. Determining the switching point in the interval, but in the TTG time interval between the PSS and the RAS to generate the switch control signal to compensate for the time delay by determining the switching point in the remaining intervals other than the time delay compensation interval RF repeater of TDD type to relay transmission signal. The method of claim 10, The downlink signal received from the RAS to the RF repeater during the time period of the downlink signal by the switch control signal, the switches 320 and 340 is the band pass filter 310, the low noise amplifier 325 And a TDD type RF repeater for relaying a transmission signal between the PSS and the RAS through the attenuator (330), the high power amplifier (335), and the band pass filter (345). The method of claim 10, The switch 320, 340 is the uplink signal received from the PSS to the RF repeater during the time period of the uplink signal by the switch control signal is the band pass filter 345, the low noise amplifier 355 And a TDD type RF repeater for relaying a transmission signal between the PSS and the RAS through the attenuator (360), the high power amplifier (365), and the band pass filter (310). The method of claim 10, The frequency band passed by the band pass filter (310, 345) includes a frequency band of 2.3 GHz TDD RF repeater for relaying the transmission signal between the RAS. A TDD RF repeater that relays a transmission signal between a Personal Subscriber Station (PSS) and a Radio Access Station (RAS) in a WiBro system using a Time Division Duplex (TDD) scheme and an Orthogonal Frequency Division Multiplexing (OFDM) modulation scheme. In the switch control unit, A frequency down converter for converting a frequency of a transmission signal between the PSS and the RAS into an intermediate band or a baseband frequency; An A / D converter for converting the transmission signal from an analog signal to a digital signal; A delay module for delaying the transmission signal for a predetermined time; An auto-correlation module for auto-correlating the transmission signal and the delayed transmission signal received from the delay module; A start point detector for detecting a frame start point of the transmission signal by analyzing an autocorrelation result value output from the autocorrelation module; And The frame structure of the transmission signal is calculated based on the frame start point of the transmission signal received from the starting point detection unit, and the switching point is determined by compensating for the time delay of the TDD optical repeater, and generating a switch control signal according to the switching point. Control signal generator Switch control unit of the RF repeater of the TDD scheme for relaying the transmission signal between the PSS and RAS, comprising a. The method of claim 22, The frame of the transmission signal includes a downlink (DL) frame, an uplink (UL) frame, a TTG (Tx / Rx Transition Gap) and an RTG (Rx / Tx Transition Gap) Switch control unit of the TDD RF repeater for relaying the transmission signal between the PSS and RAS. The method of claim 23, The TTG is a guard time for distinguishing a transmission time of the downlink signal and the uplink signal as a time interval between the downlink frame and the uplink frame transmitted after the downlink frame. During the TTG, the RAS switches to a mode for receiving the uplink signal and the PSS changes to a mode for transmitting the uplink signal. The switch of the TDD type RF repeater relaying a transmission signal between the PSS and the RAS. Control unit. The method of claim 23, The RTG is a guard time for distinguishing a transmission time of the uplink signal and the downlink signal as a time interval between the uplink frame and the downlink frame transmitted after the uplink frame. While the RAS is changed to a mode for transmitting the downlink signal and the PSS is changed to a mode for receiving the downlink signal, the switch control unit of the TDD RF repeater relaying the transmission signal between the PSS and RAS . The method of claim 24 or 25, The control signal generator determines the switching point in the TTG and the RTG time interval, but determines the switching point in the remaining sections except for the time delay compensation interval in the TTG time interval to compensate for the switch control signal. Switch control unit of the RF repeater of the TDD method for relaying the transmission signal between the PSS and RAS, characterized in that for generating. The method of claim 26, The time delay compensation section is a TDD method of relaying the transmission signal between the PSS and RAS, characterized in that the interval from the start point of the TTG time interval up to 55 μs and the end point of the TTG time interval up to 55 μs before the end point Switch control unit of RF repeater. The method of claim 26, When the time ratio of the downlink frame and the uplink frame is changed, the control signal generator determines the positions of the TTG and the RTG according to the changed time ratio based on the frame start point of the transmission signal, and determines the TTG and the RTG. PSS and RAS to determine the switching point in the time interval, the TTG time interval to generate the switch control signal to compensate for the time delay by determining the switching point in the remaining intervals other than the time delay compensation interval Switch control unit of the RF repeater of the TDD system for relaying the transmission signal.

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