KR102387559B1 - Variable bandwidth TD-LTE ICS repeating device and its method - Google Patents

Abstract

The present invention relates to a variable bandwidth TD-LTE ICS repeating device and a method for the same. According to the present invention, in the case of a change in frequency bandwidth at a TD-LTE base station, the repeating bandwidth of a repeater is changed in real time and the repeating bandwidth is changed in real time so as to be identical to the TD-LTE base station so that the repeater is used without separate configuration. The variable bandwidth TD-LTE ICS repeating device of the present invention includes: a wireless transceiver matching a base station signal from a donor antenna and repeating the base station signal to a terminal through a service antenna; a sync signal detector detecting a sync signal from the wireless transceiver; a bandwidth information detector detecting frequency bandwidth information of the base station signal from the wireless transceiver; and a controller controlling the wireless transceiver based on the sync signal and the frequency bandwidth information.

Description

Variable bandwidth TD-LTE ICS repeating device and its method

The present invention relates to a bandwidth variable TD-LTE ICS repeater apparatus and method, and more particularly, to a variable bandwidth TD-LTE ICS repeater by changing the bandwidth of the repeater with the frequency bandwidth of a TD-LTE signal. That is, the present invention relates to a bandwidth variable TD-LTE ICS relay apparatus and method capable of automatically setting a bandwidth of a repeater for various bandwidths of a TD-LTE base station.

In a Long Term Evolution (LTE) system, downlink transmission and uplink transmission can be divided into two duplex modes, namely, Frequency Division Duplex (FDD) and Time Division Duplex (TDD) mode. The FDD mode uses a paired spectrum to distinguish between uplink and downlink transmission.

Also, in the TDD system, an unpaired spectrum in which both the uplink and the downlink are transmitted on the same carrier frequency may be used. Here, the uplink and the downlink are separated in the time domain. In the TD-LTE (Time Division-LTE) service, which is an LTE method to which the TDD method is applied, the switching timing between the downlink and the uplink must be precisely synchronized to operate stably.

On the other hand, a repeater refers to a device that is located in a place where radio waves are weak or cannot reach between the base station and the terminal, and provides a good signal to the area to enable the corresponding service. This repeater is located between the base station and the terminal and converts the weak signal generated from the base station into a good signal and transmits it to the terminal (downlink), or converts the weak signal generated from the terminal into a good signal and transmits it to the base station (up) link) can be

However, in the case of a TD-LTE signal, there is a difficulty in relaying because a synchronization signal, which is a time reference for uplink and downlink, is not provided to a repeater that relays the TD-LTE signal.

As an example, in Korean Patent Laid-Open Publication No. 10-2016-0075160, a signal frame of a downlink signal received from a base station is analyzed to detect a synchronization signal for switching between a downlink section and an uplink section, and the downlink section and the uplink section are detected. A synchronization control device for a TD-LTE based wireless repeater that generates a switching signal for link section switching is presented.

However, even in this case, if the transmission frequency bandwidth of the base station is changed, there is a disadvantage that it cannot be used continuously.

Korean Patent Publication No. 10-2016-0075160 (2016.06.29.)

It is an object of the present invention to provide a bandwidth-variable TD-LTE ICS relay apparatus and method for changing the relay bandwidth of a repeater in real time when the frequency bandwidth of a TD-LTE base station is changed.

Another object of the present invention is to provide a bandwidth-variable TD-LTE ICS relay apparatus and method in which the relay bandwidth is changed in real time in the same manner as that of the TD-LTE base station and the repeater is used without a separate setting.

The variable bandwidth TD-LTE ICS relay device according to the present invention includes a wireless transceiver that matches a base station signal from a donor antenna and relays a base station signal to a terminal through a service antenna, a sync signal detector that detects a sync signal from the wireless transceiver, and a radio It may include a bandwidth information detector for detecting frequency bandwidth information of the base station signal from the transceiver, and a controller for controlling the wireless transceiver based on the synchronization signal and frequency bandwidth information.

Here, the synchronization signal detection unit may include a first synchronization signal detection module for detecting a first synchronization signal among the synchronization signals of the base station signal and a second synchronization signal detection module for detecting a second synchronization signal among the synchronization signals of the base station signal. .

Also, the bandwidth information detector may detect frequency bandwidth information by demodulating a master information block (MIB) signal of the base station signal.

Here, the control unit may include a bandwidth control module for controlling the bandwidth of the wireless transceiver, and a synchronization signal providing module for generating a synchronization signal to provide the synchronization signal to the wireless transceiver.

In addition, the radio transceiver unit is a donor antenna switch module that switches the base station signal received from the donor antenna to the forward input amplifier and the reverse output amplifier, and the service antenna switch for switching the signal of the terminal matched from the service antenna to the forward output amplifier and the reverse input amplifier It may include a module, a forward feedback signal cancellation module for canceling a forward feedback signal between the forward input amplifier and the forward output amplifier, and a backward feedback signal cancellation module for canceling a backward feedback signal between the reverse input amplifier and the reverse output amplifier.

Here, the donor antenna switch module may receive a synchronization signal from the synchronization signal providing module of the control unit to switch the donor antenna to the forward input amplifier in the downlink time and switch the donor antenna to the reverse output amplifier in the uplink time.

In addition, the service antenna switch module may receive a synchronization signal from the synchronization signal providing module of the control unit to switch the service antenna to the forward output amplifier in the downlink time and switch the service antenna to the reverse input amplifier in the uplink time.

Here, the donor antenna switch module may receive frequency bandwidth information from the bandwidth control module of the controller to control the bandwidth of a filter through which the base station signal included in the donor antenna switch module passes.

In addition, the service antenna switch module may receive frequency bandwidth information from the bandwidth control module of the control unit to control the bandwidth of a filter through which the base station signal included in the donor antenna switch module passes.

Here, the forward feedback signal removal module receives frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of the digital circuit included in the forward feedback signal removal module to control the bandwidth of the filter that passes the base station signal. .

In addition, the reverse feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of the digital circuit included in the reverse feedback signal removal module to control the bandwidth of the filter through which the signal of the terminal passes. there is.

Here, the forward feedback signal removal module receives frequency bandwidth information from the bandwidth control module of the control unit and controls the frequency bandwidth by varying the coefficient of a filter that passes the base station signal of the digital circuit included in the forward feedback signal removal module. .

In addition, the reverse feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of the digital circuit included in the reverse feedback signal removal module to vary the coefficient of the filter that passes the signal of the terminal. You can control the bandwidth.

A bandwidth variable TD-LTE ICS relay method according to another embodiment of the present invention includes a synchronization signal detection step of detecting a synchronization signal from a synchronization signal detection unit, a bandwidth information detection step of detecting frequency bandwidth information of a base station signal from the bandwidth information detection unit, a control unit It may include a radio transceiver control step of controlling the radio transceiver based on the synchronization signal and frequency bandwidth information, and a base station signal relay step of matching the base station signal from the donor antenna and relaying the base station signal to the terminal through the service antenna.

The bandwidth variable TD-LTE ICS relay apparatus and method according to the present invention has the advantage of changing the relay bandwidth of the repeater in real time when the frequency bandwidth of the TD-LTE base station is changed.

In addition, the bandwidth variable TD-LTE ICS relay apparatus and method according to the present invention has the advantage that the relay bandwidth can be changed in real time in the same manner as that of the TD-LTE base station, so that the relay can be used without a separate setting.

1 is a block diagram illustrating a bandwidth variable TD-LTE ICS relay device according to an embodiment of the present invention.
FIG. 2 is a configuration diagram illustrating the synchronization signal detection unit of FIG. 1 in detail.
FIG. 3 is a configuration diagram illustrating the control unit of FIG. 1 in detail.
FIG. 4 is a detailed configuration diagram of the wireless transceiver of FIG. 1 .
5 is a flowchart illustrating a bandwidth variable TD-LTE ICS relay method according to another embodiment of the present invention.

Detailed embodiments for carrying out the present invention will be described with reference to the accompanying drawings.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. This is not intended to limit the present invention to specific embodiments, it can be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

Hereinafter, a variable bandwidth TD-LTE ICS relay apparatus and method according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a variable bandwidth TD-LTE ICS relay device according to an embodiment of the present invention, and FIGS. 2 to 4 are detailed block diagrams for explaining FIG. 1 in detail.

Hereinafter, a variable bandwidth TD-LTE ICS relay device according to an embodiment of the present invention may be described with reference to FIGS. 1 to 4 .

First, referring to FIG. 1 , the bandwidth variable TD-LTE ICS relay device according to an embodiment of the present invention matches the base station signal from the donor antenna 100 and relays the base station signal to the terminal through the service antenna 300 . A wireless transceiver 200, a sync signal detector 400 for detecting a sync signal from the radio transceiver 200, a bandwidth information detector 600 for detecting frequency bandwidth information of a base station signal from the radio transceiver 200, and It may include a control unit 500 for controlling the wireless transceiver 200 based on the synchronization signal and frequency bandwidth information.

Also, the bandwidth information detector 600 may detect frequency bandwidth information by demodulating a master information block (MIB) signal of the base station signal.

That is, the TD-LTE repeater must perform TDD synchronization and set the frequency bandwidth used in TD-LTE. In this case, in the case of a synchronization signal, a synchronization signal transmitted for cell search in TD-LTE may be detected and provided as a synchronization signal.

On the other hand, in the case of the frequency bandwidth, the existing repeater sets the frequency bandwidth before service, and in this case, there is a disadvantage that it cannot be used when the frequency bandwidth of the base station is changed. However, the present invention has the advantage of performing TD-LTE relay suitable for the frequency bandwidth in real time by demodulating the frequency bandwidth information included in the MIB information and applying the correct frequency bandwidth in real time.

Here, the information included in the MIB provides information such as 16 types of frequency bandwidth, shared channel information, and a system frame number (SFN).

16 types of frequency bandwidth can include channel bandwidths of 1.4, 3, 5, 10, 15, and 20 MHz and transmission bandwidths of 6, 15, 25, 50, 75, 100 MHz. At least one of the transmission bandwidths may be used, and when all the transmission bandwidths are provided, at least one of the transmission bandwidths may be used.

FIG. 2 is a detailed configuration diagram illustrating the synchronization signal detection unit 400 of FIG. 1 .

As can be seen in FIG. 2 , the synchronization signal detection unit 400 detects a first synchronization signal detection module 410 that detects a first synchronization signal among synchronization signals of a base station signal and a second synchronization signal among synchronization signals of a base station signal. It may be characterized by including a second synchronization signal detection module 420 to detect.

A total of 504 Cell_IDs of the LTE system is composed of 168 Cell_ID groups by bundling 3 Cell_IDs per group. The downlink of the LTE system transmits a Primary Synchronization Signal (PSS) for discriminating 3 Cell_IDs in a Cell_ID group and a Secondary Synchronization Signal (SSS) for discriminating 168 Cell_ID groups.

In the case of TD-LTE, the PSS signal is located in the third symbol of the first slot of subframes 1 and 6, and the SSS is located in the last symbol of the second slot of subframes 0 and 5. By demodulating this repetitive sync signal, the repeater There is an advantage in that the synchronization signal can be accurately obtained.

Here, the first synchronization signal detection module 410 detects the PSS and the second synchronization signal detection module 420 detects the SSS, so that the synchronization signal of the TD-LTE can be accurately demodulated.

FIG. 3 is a configuration diagram illustrating the control unit 500 of FIG. 1 in detail.

As can be seen in FIG. 3 , the controller 500 generates a bandwidth control module 510 for controlling the bandwidth of the wireless transceiver 200 and a synchronization signal to provide a synchronization signal to the wireless transceiver 200 . It may be characterized in that it includes a signal providing module (520).

That is, the bandwidth control module 510 may control a filter included in the wireless transceiver 200 , and the synchronization signal providing module 520 may control a switch included in the wireless transceiver 200 , FIG. 4 has been described in detail by way of example.

FIG. 4 is a detailed configuration diagram of the wireless transceiver 200 of FIG. 1 .

As can be seen in FIG. 4 , the wireless transceiver 200 switches the base station signal received from the donor antenna 100 to a forward input amplifier 220 and a reverse output amplifier 280, a donor antenna switch module 210 . , the service antenna switch module 250, the forward input amplifier 220 and the forward output amplifier 240 for switching the signal of the matching terminal from the service antenna 300 to the forward output amplifier 240 and the reverse input amplifier 260. A forward feedback signal removal module 230 for removing a forward feedback signal between can be characterized as

Here, the donor antenna switch module 210 receives a synchronization signal from the synchronization signal providing module 520 of the control unit 500 and switches the donor antenna 100 to the forward input amplifier 220 in the downlink time and uplink time In this case, the donor antenna 100 may be switched to the reverse output amplifier 280 .

In addition, the service antenna switch module 250 receives the synchronization signal from the synchronization signal providing module 520 of the control unit 500, in the downlink time, switches the service antenna 300 to the forward output amplifier 240, and uplink time In this case, the service antenna 300 may be switched to the reverse input amplifier 260 .

Here, the donor antenna switch module 210 receives the frequency bandwidth information from the bandwidth control module 510 of the control unit 500 to control the bandwidth of the filter through which the base station signal included in the donor antenna switch module 210 passes. can

In addition, the service antenna switch module 250 receives the frequency bandwidth information from the bandwidth control module 510 of the control unit 500 to control the bandwidth of the filter through which the base station signal included in the donor antenna switch module 210 passes. can

Here, the forward feedback signal removal module 230 receives frequency bandwidth information from the bandwidth control module 510 of the control unit 500 and varies the processing speed of the digital circuit included in the forward feedback signal removal module 230 to the base station You can control the bandwidth of the filter through which the signal passes.

In addition, the reverse feedback signal removal module 270 receives the frequency bandwidth information from the bandwidth control module 510 of the control unit 500 and changes the processing speed of the digital circuit included in the reverse feedback signal removal module 270 to change the processing speed of the terminal. You can control the bandwidth of the filter that passes the signal of.

Here, the forward feedback signal removal module 230 receives the frequency bandwidth information from the bandwidth control module 510 of the control unit 500 and passes the base station signal of the digital circuit included in the forward feedback signal removal module 230 as a filter The frequency bandwidth can be controlled by varying the coefficient of .

In addition, the reverse feedback signal removal module 270 receives the frequency bandwidth information from the bandwidth control module 510 of the control unit 500 and changes the processing speed of the digital circuit included in the reverse feedback signal removal module 270 to change the processing speed of the terminal. The frequency bandwidth can be controlled by varying the coefficient of the filter that passes the signal of.

That is, the donor antenna switch module 210 and the service antenna switch module 250 may include, in addition to the switch, a transmission/reception filter through which a base station signal and a terminal signal can pass. It can also be an analog device that can change the shape of

On the other hand, the transmission/reception filter in the forward feedback signal removal module 230 and the backward feedback signal removal module 270 can be changed digitally, and the frequency bandwidth can be easily varied by changing the digital processing speed to vary the relative bandwidth. There are advantages to doing. Also, the frequency bandwidth of the transmission/reception filter may be changed by changing only the coefficient values of the transmission/reception filters inside the forward feedback signal removal module 230 and the backward feedback signal removal module 270 .

5 is a flowchart illustrating a bandwidth variable TD-LTE ICS relay method according to another embodiment of the present invention.

As can be seen from FIG. 5 , the bandwidth variable TD-LTE ICS relay method detects a synchronization signal from the synchronization signal detection unit 400 ( S100 ), and detects the frequency bandwidth information of the base station signal from the bandwidth information detection unit 600 . step (S200), controlling the wireless transceiver 200 based on the synchronization signal and frequency bandwidth information in the controller 500 (S300), and matching the base station signal from the donor antenna 100 to the service antenna 300 It may include the step of relaying the base station signal to the terminal through (S400).

That is, the TD-LTE repeater must perform TDD synchronization and set the frequency bandwidth used in TD-LTE. In this case, in the case of a synchronization signal, a synchronization signal transmitted for cell search in TD-LTE may be detected in the synchronization signal detection step S100 and provided as a synchronization signal.

Meanwhile, by demodulating the frequency bandwidth information included in the MIB information in the bandwidth information detecting step ( S200 ) and applying the correct frequency bandwidth in real time, there is an advantage in that TD-LTE relay suitable for the frequency bandwidth can be performed in real time.

Here, the information included in the MIB provides information such as 16 types of frequency bandwidth, shared channel information, and a system frame number (SFN).

16 types of frequency bandwidth can include channel bandwidths of 1.4, 3, 5, 10, 15, and 20 MHz and transmission bandwidths of 6, 15, 25, 50, 75, 100 MHz. At least one of the transmission bandwidths may be used, and when all the transmission bandwidths are provided, at least one of the transmission bandwidths may be used.

On the other hand, in the radio transceiver control step (S300), the controller 500 controls the synchronization signal to the donor antenna switch module 210 and the service antenna switch module 250 or the donor antenna switch module 210, the service antenna switch module ( 250), a TD-LTE relay that provides frequency bandwidth information to the forward feedback signal removal module 230, and the backward feedback signal removal module 270 to easily control the frequency bandwidth of analog and digital filters to change the frequency bandwidth in real time There are advantages to being able to perform services.

As described above, the bandwidth variable TD-LTE ICS relay apparatus and method according to the present invention has the advantage of changing the relay bandwidth of the repeater in real time when the frequency bandwidth of the TD-LTE base station is changed, and the relay bandwidth is shared with the TD-LTE base station. In the same way, it has the advantage of being able to use a repeater without additional setting by changing it in real time.

What has been described above includes examples of one or more embodiments. Of course, it is not possible to describe every possible combination of components or methods for purposes of describing the above-described embodiments, and those skilled in the art will recognize that many further combinations and permutations of various embodiments are possible. Accordingly, the described embodiments are intended to cover all alternatives, modifications and adaptations falling within the spirit and scope of the appended claims.

Claims (14)

a wireless transceiver that matches the base station signal from the donor antenna and relays the base station signal to the terminal through the service antenna;
a synchronization signal detection unit for detecting a synchronization signal from the wireless transceiver;
a bandwidth information detector for detecting frequency bandwidth information of the base station signal from the radio transceiver; and
a control unit for controlling the wireless transceiver based on the synchronization signal and the frequency bandwidth information;
The wireless transceiver,
a donor antenna switch module for switching the base station signal received from the donor antenna to a forward input amplifier and a reverse output amplifier;
a service antenna switch module for switching a signal of a matched terminal from the service antenna to a forward output amplifier and a reverse input amplifier;
a forward feedback signal cancellation module for canceling a forward feedback signal between the forward input amplifier and the forward output amplifier; and
a reverse feedback signal removal module configured to remove a reverse feedback signal between the reverse input amplifier and the reverse output amplifier;
The donor antenna switch module receives the frequency bandwidth information from the bandwidth control module of the control unit and changes the bandwidth of the filter through which the base station signal included in the donor antenna switch module passes through an analog element that changes the shape of the filter. control and change
The service antenna switch module receives the frequency bandwidth information from the bandwidth control module of the control unit and changes a bandwidth of a filter through which the base station signal included in the donor antenna switch module passes through an analog element for changing the shape of the filter control and change
The forward feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of a digital circuit included in the forward feedback signal removal module to pass the base station signal. relatively controlled,
The reverse feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of a digital circuit included in the backward feedback signal removal module to pass the signal of the terminal. Variable bandwidth TD-LTE ICS relay device, characterized in that relatively controlling the. The method of claim 1,
The synchronization signal detection unit,
a first synchronization signal detection module for detecting a first synchronization signal among synchronization signals of the base station signal; and
and a second synchronization signal detection module for detecting a second synchronization signal among synchronization signals of the base station signal. The method of claim 1,
The bandwidth variable TD-LTE ICS repeater, wherein the bandwidth information detector detects the frequency bandwidth information by demodulating a master information block (MIB) signal of the base station signal. The method of claim 1,
The control unit is
a bandwidth control module for controlling a bandwidth of the wireless transceiver; and
Variable bandwidth TD-LTE ICS relay device comprising a; a synchronization signal providing module that generates a synchronization signal and provides the synchronization signal to the wireless transceiver. delete The method of claim 1,
The donor antenna switch module receives the synchronization signal from the synchronization signal providing module of the control unit and switches the donor antenna to the forward input amplifier in a downlink time and switches the donor antenna to the reverse output amplifier in an uplink time Variable bandwidth TD-LTE ICS relay device, characterized in that. The method of claim 1,
The service antenna switch module receives the synchronization signal from the synchronization signal providing module of the control unit, switches the service antenna to the forward output amplifier in a downlink time, and switches the service antenna to the reverse input amplifier in an uplink time Variable bandwidth TD-LTE ICS relay device, characterized in that. delete delete delete delete The method of claim 1,
The forward feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the coefficient of a filter that passes the base station signal of the digital circuit included in the forward feedback signal removal module to increase the frequency bandwidth Variable bandwidth TD-LTE ICS repeater, characterized in that the control. The method of claim 1,
The backward feedback signal removal module receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of a digital circuit included in the backward feedback signal removal module to pass the signal of the terminal. Filter coefficients Variable bandwidth TD-LTE ICS repeater, characterized in that by varying the frequency bandwidth. a synchronization signal detection step of detecting a synchronization signal from the synchronization signal detection unit;
a bandwidth information detection step of detecting frequency bandwidth information of a base station signal from a bandwidth information detection unit;
a radio transceiver control step of controlling the radio transceiver based on the synchronization signal and the frequency bandwidth information in the controller; and
A base station signal relay step of matching the base station signal from the donor antenna and relaying the base station signal to the terminal through the service antenna;
In the wireless transceiver,
Switching the base station signal received from the donor antenna in a donor antenna switch module to a forward input amplifier and a reverse output amplifier,
In the service antenna switch module, the signal of the matching terminal from the service antenna is switched to a forward output amplifier and a reverse input amplifier,
in a forward feedback signal cancellation module, removing a forward feedback signal between the forward input amplifier and the forward output amplifier;
In the reverse feedback signal cancellation module, the reverse feedback signal is removed between the reverse input amplifier and the reverse output amplifier;
In the donor antenna switch module, receiving the frequency bandwidth information from the bandwidth control module of the control unit, the bandwidth of the filter through which the base station signal included in the donor antenna switch module passes through an analog element for changing the shape of the filter control and change
In the service antenna switch module, an analog element for changing the shape of the filter by receiving the frequency bandwidth information from the bandwidth control module of the control unit and changing the bandwidth of the filter through which the base station signal included in the donor antenna switch module passes control and change
In the forward feedback signal removal module, the bandwidth of the filter through which the base station signal passes by receiving the frequency bandwidth information from the bandwidth control module of the control unit and varying the processing speed of the digital circuit included in the forward feedback signal removal module relatively controlled,
In the reverse feedback signal removal module, the bandwidth of a filter that receives the frequency bandwidth information from the bandwidth control module of the control unit and varies the processing speed of a digital circuit included in the reverse feedback signal removal module to pass the signal of the terminal A bandwidth variable TD-LTE ICS relay method that relatively controls the

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