KR101520395B1 - Signal repeater equipment and control method thereof - Google Patents

Abstract

A signal relay equipment and a control method thereof are disclosed. When a signal is relayed between a digital unit (DU) and a remote unit (RU) of a separable base transceiver station equipment, problems of being unable to use a maximum relay power and lowering RU efficiency from a signal strength attenuation function of auto gain control (AGC) designed for RU overpower prevention can be effectively prevented in advance.

Description

Technical Field [0001] The present invention relates to a signal relay apparatus and a signal relay apparatus,

The present invention relates to a signal relay apparatus and an operation method of a signal relay apparatus, and more particularly, to a relay apparatus for relaying signals between a base station module (DU) and a wireless communication module (RU) A signal relay device and a signal relay device which can effectively prevent problems such as degradation of the efficiency of the RU due to the failure to properly use the relay maximum output due to the signal intensity reduction function of AGC (Auto Gain Control) And to a method of operation.

In order to accommodate surging data usage, communication systems are evolving to a higher frequency efficiency system, and as a part of the existing base station device structure in which DU (Digital Unit) and RU (Remote Unit) A structure of a base station apparatus in which DU and RU are separated and installed at a remote location has emerged.

In a base station apparatus (hereinafter referred to as a separate base station apparatus) having a DU and RU separate structure, a backhaul for connecting DU to the core network and a front hole for connecting DU and RU are required. And a signal relay device that employs an optical line as an interface is located in the front hole for connection between the DU and the RU.

The signal relay device for relaying the signals between the DU and the RU outputs the signals input from the DU in the downlink to the RU after outputting to the RU and outputs the signals input from the RU in the case of the uplink to the DU And outputs the signal to the DU so that the signals between DU and RU are relayed.

On the other hand, when there is no data traffic due to the subscriber terminal and when the data traffic due to the subscriber terminal is full, the output change range of the power amplifier (Power Amplifier) of the downlink, that is, the RU is 13 dB or more I go. In order to protect the power amplifier of the RU from excessive output, the signal relay device is provided with an AGC (Auto Gain Control) at an input terminal to which a signal is input from the DU to continuously monitor the intensity of the signal input from the DU, If the expected intensity (level) is exceeded, the AGC operates the signal intensity attenuation function to attenuate the intensity of the signal.

However, due to the signal strength reduction function of the AGC, which is operated to prevent over-output of the RU as described above in the signal relay device, the signal intensity is attenuated in the unnecessary situation and the RU efficiency And the like are often caused.

Therefore, in the present invention, a method of effectively preventing a problem such that the relay maximum output is not properly used and the efficiency of the RU is lowered due to the AGC signal strength reduction function for preventing over-output of the RU .

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a method and apparatus for relaying a signal between a DU and an RU, And to effectively prevent the occurrence of problems such as degradation of the efficiency of the RU without using the signal relay apparatus and the operation method of the signal relay apparatus.

According to a first aspect of the present invention, there is provided a signal relay apparatus comprising: a monitoring unit for monitoring an intensity of a signal input from a base station module; A signal processing unit for attenuating the intensity of the signal according to a predetermined attenuation value before outputting the signal to the wireless communication module; And if the abnormal peak signal is detected in the signal, the attenuation value of the signal processing unit is increased to a maximum value, and if the abnormal peak signal is detected in the signal, the attenuation value of the signal processing unit is determined to be smaller than the maximum value And the attenuation value control unit restores the attenuation value of the signal processing unit to the maximum attenuation value.

Preferably, the specific attenuation value may be determined based on the strength of the full traffic signal input from the base station module and the maximum output of the wireless communication module when the base station module allocates full traffic to the subscriber terminal have.

Preferably, the attenuation value control unit may determine the specific attenuation value based on the strength of the virtual full traffic signal and the maximum output of the wireless communication module when a virtual full traffic signal is input from the base station module.

Preferably, the specific attenuation value is set such that, when the virtual full traffic signal is transmitted as a radio signal by the wireless communication module based on the strength of the virtual full traffic signal, Can be determined as the attenuation value so as to be the maximum output.

According to a second aspect of the present invention, there is provided a method of operating a signal relay apparatus including: monitoring a strength of a signal input from a base station module; A maximum attenuation step of attenuating the intensity of the signal in the signal processing unit according to the maximum value by increasing the attenuation value of the signal processing unit to a maximum value when an abnormal peak signal is detected in the signal based on the monitoring result; And restoring the attenuation value of the signal processing unit to a specific attenuation value smaller than the maximum value when the detected abnormal peak signal disappears from the signal based on the monitoring result so that the attenuation value of the signal processing unit is not maintained at the maximum value And an attenuation value restoring step.

The specific attenuation value may be determined based on the strength of the full traffic signal input from the base station module and the maximum output of the wireless communication module when the base station module allocates full traffic to the subscriber terminal.

Preferably, when the virtual full traffic signal is input from the base station module, the mobile terminal further includes an attenuation value determination step of determining the specific attenuation value based on the strength of the virtual full traffic signal and the maximum output of the wireless communication module .

Therefore, according to the operation of the signal relay apparatus and the signal relay apparatus according to the preferred embodiment of the present invention, in relaying signals between the base station module DU and the wireless communication module RU of the separate base station apparatus, The AGC (Auto Gain Control) signal intensity reduction function for the RU can not effectively use the relay maximum output, and the efficiency of the RU is lowered.

1 is a configuration diagram illustrating a communication system including a signal relay device according to a preferred embodiment of the present invention.
2 is a block diagram illustrating a configuration of a signal relay apparatus according to a preferred embodiment of the present invention.
3 is a flowchart illustrating an operation method of a signal relay apparatus according to a preferred embodiment of the present invention.
4 is an exemplary diagram illustrating an example in which the output of the RU is improved by controlling the attenuation value when detecting an ideal peak signal in the signal relay apparatus of the present invention.

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

1 is a diagram illustrating a communication system including a signal relay apparatus according to a preferred embodiment of the present invention.

1, the signal relay apparatus 100 according to the present invention includes a base station module 10 and a wireless communication module 20 or a plurality of wireless communication modules 20, 30, In relation to a separate base station apparatus having a structure in which both terminals are connected to each other.

Hereinafter, the base station module 10 and the single wireless communication module 20 as a separate base station device will be described as separate structures for convenience of explanation.

That is, the base station module 10 and the wireless communication module 20 of the separate base station apparatus are spaced apart from each other and installed at a remote location, and signals between the base station module 10 and the wireless communication module 20 are transmitted to the signal relay device 100, Lt; / RTI >

Here, the signal relay device 100 may be an optical repeater adopting an optical line as an interface for relaying signals between the base station module 10 and the wireless communication module 20. Of course, the signal relay device 100 may be various types of repeaters for relaying signals between the base station module 10 and the wireless communication module 20 in addition to the optical repeater.

Hereinafter, for convenience of explanation, it will be described that the signal relay device 100 is an optical repeater.

The signal relay device 100 processes the signal input from the base station module 10 to output to the wireless communication module 20 in the case of the downlink and outputs the signal to the wireless communication module 20, A signal input from the wireless communication module 20 is processed for output to the base station module 10 and is then output to the base station module 10 to relay signals between the base station module 10 and the wireless communication module 20 do.

To this end, the signal relay apparatus 100 may include an AGC (Auto Gain Control), a drive amplifier, an IF / optical signal converter, and an optical signal distributor.

In case of the downlink, the wireless communication module 20 processes a signal received through the signal relay device 100 from the base station module 10 connected to the wireless communication module 20 and transmits the processed signal as a wireless signal. In the case of the uplink, And transmits the signal to the base station module 10 connected thereto through the signal relay device 100. [

For this purpose, the wireless communication module 20 may include an optical / digital signal converter, a Crest Factor Reduction (CFR), an A / D converter, a power amplifier, and the like.

The wireless communication module 20 may correspond to an RU (Remote Unit).

The base station module 10 provides a communication service to a subscriber terminal connected through a wireless communication module 20 to be connected.

The base station module 10 is connected to an external device (e.g., a broadband router) through a backhaul and transmits voice and data (e.g., voice data) to a subscriber terminal connected in its cell area via a wireless communication module 20 connected thereto Can be provided.

The base station module 10 may correspond to a digital unit (DU).

Hereinafter, a process of relaying downlink signals through the signal relay apparatus 100 will be briefly described.

The base station module 10 generates a traffic signal (hereinafter, referred to as a signal) of the subscriber station and transmits the traffic signal to the signal relay apparatus 100. At this time, the signal transmitted to the signal relay apparatus 100 is in the form of an IF signal.

The signal transmitted from the base station module 10 is input to the input terminal of the signal relay device 100, that is, the AGC. At this time, the signal relay apparatus 100 always monitors the intensity (level) of a signal input from the base station module 10. [ At this time, an appropriate input range for the signal strength input to the signal relay apparatus 100 is predetermined, and may be set to, for example, a minimum of -30 dBm to a maximum of -9 dBm.

Therefore, the AGC of the signal relay apparatus 100 operates the signal intensity attenuation function applying an appropriately determined attenuation according to the monitored result, thereby attenuating the intensity of the input signal to an appropriate level.

A signal (IF signal) whose intensity is attenuated by the AGC of the signal repeater 100 is converted into an optical signal through a drive amplifier and IF / optical signal converter, and the optical signal is converted into an optical signal Up to a maximum of eight wireless communication modules.

The optical signal output from the signal relay device 100 and input to the wireless communication module 20 is converted into a digital signal through the optical / digital signal converter of the wireless communication module 20, Average Ratio) is adjusted to the appropriate ratio.

The digital signal passed through the CFR of the wireless communication module 20 is converted into an analog RF signal via an A / D converter and then transmitted to a power amplifier. A terminating power amplifier receives the input RF signal Amplified according to a predetermined gain, and transmits it as a radio signal through an antenna.

At this time, when the end of the downlink, that is, the power amplifier of the wireless communication module 20, exceeds its maximum output (for example, 40W class), damage due to the over-generation of the output may occur have.

The signal relay device 100 monitors the intensity of a signal input from the base station module 10 in order to protect a power amplifier in the wireless communication module 20 from excessive output. As a result, When the peak signal exceeding 9 dBm is detected, the attenuation value (Atten.) Is rapidly increased so that the intensity of the signal is greatly attenuated through the AGC signal intensity attenuation function. Thus, the power amplifier (Power Amp.) Output is low.

However, in the conventional signal relay apparatus, as described above, when the ideal peak signal is detected, the attenuation value (Atten.) Of the AGC is increased so as to prevent over-output of the wireless communication module 20, The attenuation value (Atten.) Of the increased AGC is maintained. This is because the AGC signal intensity reduction function is a function that focuses on protecting the over-output damage of the power amplifier in the wireless communication module 20.

Accordingly, in the case of the conventional signal relay device, the attenuation value (Atten.), Which has been increased so as to prevent over-output of the wireless communication module 20, continues to be inputted to the AGC signal even though the ideal peak signal has disappeared. The output of the power amplifier in the wireless communication module 20 is also lowered so that the service coverage is reduced and the quality of the communication service is reduced There is a problem that the efficiency of the wireless communication module 20 is lowered.

Accordingly, in the present invention, due to the AGC signal intensity reduction function for preventing over-output of the wireless communication module 20, the relay maximum output can not be used properly and the efficiency of the wireless communication module 20 is lowered In order to achieve the above object, the present invention proposes a signal relay apparatus 100 that achieves this.

Hereinafter, the configuration of the signal relay apparatus 100 according to the preferred embodiment of the present invention will be described in more detail with reference to FIG.

The signal relay apparatus 100 according to the present invention includes a monitoring unit 110 for monitoring the intensity of a signal input from the base station module 10 and a signal processing unit 120 for outputting the signal (120) for attenuating the intensity of the signal from the signal processor (120) according to a predetermined attenuation value, and a signal processor (120) for attenuating the attenuation value of the signal processor (120) to a maximum value when an ideal peak signal is detected in the signal, And a damping value control unit 130 for restoring the attenuation value of the signal processing unit 120 to a specific attenuation value smaller than the maximum value when the detected abnormal peak signal disappears to prevent the attenuation value of the signal processing unit 120 from being maintained at the maximum value do.

The monitoring unit 110 monitors the intensity of a signal input from the base station module 10.

More specifically, as described above, a signal (IF signal) transmitted from the base station module 10 will be input to the signal relay device 100.

At this time, the monitoring unit 110 monitors the intensity (level) of a signal input from the base station module 10 at all times.

The signal processing unit 120 attenuates the signal strength according to a predetermined attenuation value (Atten.) Before outputting the signal input from the base station module 10 to the wireless communication module 20. [

This signal processing unit 120 will correspond to the AGC that operates the above-described signal intensity attenuation function.

That is, the signal processing unit 120 operates the signal intensity attenuation function to which the attenuation value (Atten.) Appropriately determined according to the monitoring result of the monitoring unit 110 is applied to measure the intensity of the signal input from the base station module 10 Decrease to the appropriate level.

At this time, the main body that determines the attenuation value (Atten.) Of the signal processing unit 120 may be the attenuation value control unit 130, which will be described later.

Thereafter, the signal (IF signal) whose intensity is attenuated by the signal processing unit 120 of the signal repeater 100 passes through the drive amplifier of the signal repeater 100 and the IF / optical signal converter, Signal, and the converted optical signal will be output to the wireless communication module 20 through the optical signal distributor.

The attenuation value control unit 130 increases the attenuation value of the signal processing unit 120 to a maximum value when an abnormal peak signal is detected in the signal inputted from the base station module 10 based on the monitoring result of the monitoring unit 110, When the detected ideal peak signal disappears from a signal input from the module 10, the attenuation value of the signal processing unit 120 is restored to a specific attenuation value smaller than the maximum value so that the attenuation value of the signal processing unit 120 is not maintained at the maximum value do.

More specifically, the attenuation value control unit 130, based on the monitoring result of the monitoring unit 110, detects an ideal peak signal in a signal input from the base station module 10, So as to maximize the value.

For example, an appropriate input range for signal strength input to the signal relay apparatus 100 is predetermined, and may be set to, for example, a minimum of -30 dBm to a maximum of -9 dBm.

4, it is assumed that a result of monitoring the signal strength input from the base station module 10 by the monitoring unit 110 appears as shown in FIG. 4A.

4A, when there is no data traffic due to the subscriber station, that is, when the terminal is in the idle state, the signal input to the signal repeater 100 is used only for RS (Reference Signal), control and overhead channels And the signal strength thereof is small.

4, the output of the wireless communication module 20 is set (designed) so that 4W = 36 dBm, which is about 10% of the maximum output (for example, 40 W = 46 dBm) do.

4, the attenuation value (Atten.) Of the signal processing unit 120 when the terminal is in the idle state depends on the intensity of the signal input to the signal repeater 100 and the intensity of the signal input to the signal relay unit 100, (For example, 10 dB) determined based on the set output (4 W = 36 dBm) of the output signal (4W = 36 dBm).

As shown in FIG. 4A, when the data traffic increases gradually after time t1, the signal intensity input from the base station module 10 gradually increases. When the data traffic due to the subscriber terminal is full, that is, The signal strength input from the base station module 10 approaches a maximum value within an appropriate input range (minimum -30 dBm to maximum -9 dBm).

4B, when the intensity of the signal input from the base station module 10 increases gradually after time t1, the attenuation value (Atten.) Of the signal processing unit 120 also increases gradually. In the full traffic state, The attenuation value (Atten.) Of the antenna 120 is determined to be an attenuation value (Atten_Full) of about 18 dB.

4C, the output of the wireless communication module 20 after the time t1 becomes the maximum output of the wireless communication module 20, that is, 40W = 46 dBm when it is in the full traffic state while increasing gradually.

In the meantime, if an abnormal peak signal occurs at time t2, the signal intensity input from the base station module 10 exceeds the maximum value of the proper input range, that is, -9 dBm, and the appropriate input range (minimum -30 dBm to maximum -9 dBm) When the abnormal peak signal disappears, the signal intensity input to the signal relay device 100 returns to the proper input range again.

Based on the monitoring result of the monitoring unit 110, the attenuation value control unit 130 can confirm that an ideal peak signal is detected when a signal having an intensity exceeding the maximum value of the appropriate input range, i.e., -9 dBm is detected .

4A, the attenuation value control unit 130 will confirm that an abnormal peak signal is detected from the signal input from the base station module 10 at time t2.

When the abnormal peak signal is detected in the signal inputted from the base station module 10, the attenuation value control unit 130 outputs the overdrive end of the downlink, that is, the over output of the power amplifier in the wireless communication module 20 The attenuation value (Atten.) Of the signal processing unit 120 is increased to the maximum value (Atten_Max).

For example, as shown in FIG. 4B, the attenuation value control unit 130 may control the attenuation value Atten of the signal processing unit 120 at time t2 when an abnormal peak signal is detected in a signal input from the base station module 10, ) To the maximum value (Atten_Max, 25dB).

4C, the output of the wireless communication module 20 at the time t2 when the ideal peak signal occurs is the output of the wireless communication module 20, that is, 40W = 46 dBm, to some extent .

Thereafter, if it is an existing signal repeater, the attenuation value (Atten_Max) rapidly increased even after the ideal peak signal disappears as described above (B and b_1 in FIG. 4).

Therefore, in the case of the existing signal relay device, the output of the wireless communication module 20 is also reduced to the maximum value even when the ideal peak signal is lost, since the input signal is also attenuated by the attenuation value (Atten_Max) (For example, 40 dBm) (C, c_4 in FIG. 4).

However, in the signal relay apparatus 100 of the present invention, in particular, the attenuation value control unit 130 controls the attenuation value (Atten.) Of the signal processing unit 120 when the detected ideal peak signal disappears from the signal input from the base station module 10. Is restored to a specific attenuation value smaller than the maximum value Atten_Max so that the attenuation value Atten of the signal processing unit 120 is not maintained at the maximum value Atten_Max.

That is, based on the monitoring result of the monitoring unit 110, the attenuation value control unit 130 detects a signal having an intensity exceeding the maximum value of the appropriate input range, that is, -9 dBm, If it is not detected, it is confirmed that the abnormal peak signal which is detected in the signal inputted from the base station module 10 disappears.

In this way, when the ideal peak signal that has been sensed disappears from the signal input from the base station module 10, the attenuation value control unit 130 increases the attenuation value (Atten.) Of the signal processing unit 120 to the maximum value (Atten_Max) To a specific attenuation value smaller than the maximum value (Atten_Max).

At this time, when the base station module 10 allocates full traffic to the subscriber terminal, the specific attenuation value is determined based on the strength of the full traffic signal input from the base station module 10 and the maximum output of the wireless communication module 20 . ≪ / RTI >

In other words, when the base station module 10 is in the full traffic state allocating the full traffic to the subscriber terminal, the specific attenuation value is determined based on the intensity of a signal (hereinafter referred to as a full traffic signal) input from the base station module 10, For example, 40 W = 46 dBm.

Hereinafter, a process of determining (storing) a specific attenuation value by the attenuation value control unit 130 will be described.

For example, when a virtual full traffic signal is input from the base station module 10, the attenuation value control unit 130 determines a specific attenuation based on the strength of the virtual full traffic signal and the maximum output of the wireless communication module 20 Can be determined.

Here, the specific attenuation value may be set such that, when the wireless communication module 20 transmits the virtual full traffic signal as a wireless signal based on the strength of the virtual full traffic signal, Which is the maximum output of the module.

The base station module 10 transmits a virtual signal of the same pattern as the case of allocating the full traffic to the actual subscriber terminal in the base station module 10 when the base station module 10 periodically or at a time set by the operator or manually operated by the operator, A full traffic signal can be generated and transmitted to the signal relay apparatus 100.

Preferably, the base station module 10 is capable of delivering a virtual full traffic signal to the signal relay device 100 at the shortest time (for example, every day at 03:00) when the traffic of the subscriber terminal is the smallest.

When the virtual full traffic signal is input from the base station module 10, the attenuation value control unit 130 processes the virtual full traffic signal in the wireless communication module 20 based on the strength of the virtual full traffic signal And determines the attenuation value so that the intensity of the radio signal becomes the maximum output of the wireless communication module 20, for example, 40 W = 46 dBm, as a specific attenuation value.

As described above, the attenuation value control unit 130 can determine a specific attenuation value based on the intensity of the virtual full traffic signal and the maximum output of the wireless communication module 20, for example, 40 W = 46 dBm. The specific attenuation value at this time is about 18 dB Which is close to the attenuation value (Atten_Full).

4B, the attenuation value control unit 130 determines the attenuation value of the signal processing unit 120, that is, the attenuation value of the signal processing unit 120, as shown in FIG. 4B. (Atten_Max, 25dB) with the attenuation value (Atten_Full, 18dB) (b_2) with the peak value (Atten_Max) increased to the maximum value (Atten_Max).

As a result, as shown in FIG. 4C, the signal input from the base station module 10 after the ideal peak signal disappears is attenuated by a specified attenuation value (Atten_Full, 18 dB) The output of the module 20 can be maintained and the maximum output can be maintained without falling (c_3).

As described above, the signal relay apparatus 100 according to the preferred embodiment of the present invention restores and lowers the attenuation value of the signal intensity attenuation function, which has been rapidly increased after the ideal peak signal has disappeared. Therefore, Existing problems can be improved.

That is, in the signal relay apparatus 100 according to the preferred embodiment of the present invention, in relaying signals between the base station module DU and the wireless communication module RU of the separate base station apparatus, the AGC signal It is possible to effectively prevent the problems such as the failure to properly use the relay maximum output due to the intensity attenuation function and the decrease in the efficiency of the RU.

Hereinafter, the operation of the signal relay apparatus according to the preferred embodiment of the present invention will be described with reference to FIG. For convenience of description, the reference numerals of FIGS. 1, 2, and 4 will be described.

The operation of the signal relay apparatus 100 of the present invention monitors the intensity of a signal input from the base station module 10 (S100).

More specifically, as described above, a signal (IF signal) transmitted from the base station module 10 will be input to the signal relay device 100.

At this time, the operation method of the signal relay apparatus 100 of the present invention always monitors the intensity (level) of a signal input from the base station module 10.

The method of operation of the signal relay apparatus 100 of the present invention checks whether a virtual full traffic signal is input from the base station module 10 at step S110. If a virtual full traffic signal is input, And determines a specific attenuation value based on the maximum output of the wireless communication module 20 (S120).

That is, when the base station module 10 periodically or at a time set by the operator or manually operated by the operator, the base station module 10 generates a virtual signal of the same pattern as that in the case of allocating the full traffic to the actual subscriber terminal A virtual full traffic signal can be generated and transmitted to the signal relay device 100.

Preferably, the base station module 10 is capable of delivering a virtual full traffic signal to the signal relay device 100 at the shortest time (for example, every day at 03:00) when the traffic of the subscriber terminal is the smallest.

When the virtual full traffic signal is inputted from the base station module 10, the method of operation of the signal relay device 100 of the present invention is such that the intensity of the virtual full traffic signal and the maximum output of the wireless communication module 20, A specific attenuation value can be determined based on 46 dBm, and the specific attenuation value at this time may be a value close to the attenuation value (Atten_Full) of about 18 dB.

Meanwhile, the operation of the signal relay apparatus 100 of the present invention checks whether an abnormal peak signal is detected from a signal input from the base station module 10 based on the monitoring result of step S100 (S130).

For example, the operation method of the signal relay apparatus 100 of the present invention detects an abnormal peak signal when a signal having an intensity exceeding the maximum value of the appropriate input range, that is, -9 dBm is detected based on the monitoring result of step S100 Can be confirmed.

4A, the operation method of the signal relay apparatus 100 of the present invention confirms that an abnormal peak signal is detected from the signal input from the base station module 10 at time t2.

If the abnormal peak signal is detected in the signal input from the base station module 10 (Yes in S130), the operation of the signal relay device 100 of the present invention is performed by detecting the end of the downlink, The attenuation value Atten of the signal processing unit 120 is increased to the maximum value Atten_Max in order to prevent the overpower of the power amplifier at step S150.

For example, as shown in FIG. 4B, at the time t2 when an abnormal peak signal is detected in a signal input from the base station module 10, the signal relay apparatus 100 of the present invention operates the signal processing unit 120 (Atten_Max, 25dB) of the attenuation value (Atten.

4, the output of the wireless communication module 20 is reduced by a maximum value (Atten_Max, 25 dB) at time t2 when an ideal peak signal is generated, and the output of the wireless communication module 20 The maximum output, that is, 40 W = 46 dBm, is maintained to some extent.

The operation of the signal relay apparatus 100 of the present invention checks whether the ideal peak signal that has been detected from the signal input from the base station module 10 disappears (S160).

For example, according to the operation of the signal relay apparatus 100 of the present invention, based on the monitoring result of step S100, a signal having an intensity exceeding the maximum value of the appropriate input range, that is, -9 dBm is detected, It is determined that the abnormal peak signal detected in the signal input from the base station module 10 disappears.

The operation of the signal relay apparatus 100 according to the present invention is such that if the ideal peak signal that has been detected in the signal input from the base station module 10 disappears (S160 Yes), the attenuation value (Atten.) Of the signal processing unit 120 is set to (Atten_Full, 18 dB) determined (stored) in step S120 (S170) in a state in which the maximum attenuation value is increased to a maximum value (Atten_Max).

As a result, as shown in FIG. 4C, the signal input from the base station module 10 after the ideal peak signal disappears is attenuated by a specified attenuation value (Atten_Full, 18 dB) The output of the module 20 can be maintained at a level lower than the maximum output (for example, 40 dBm) and the maximum output can be maintained (c_3).

The method of operation of the signal relay apparatus 100 of the present invention will return to step S100 and repeat the following steps as long as the signal relay operation is not turned off (S180 No).

If the abnormal peak signal is not detected in the signal input from the base station module 10 in step S130 (No in step S130), the operation of the signal relay apparatus 100 of the present invention determines whether the currently inputted signal The attenuation value (Atten.) Is appropriately determined (adjusted) according to the intensity of the input signal, and the intensity of the input signal is attenuated to an appropriate level (S140).

The method of operating the signal relay device according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the operation of the signal relay apparatus and the signal relay apparatus according to the present invention, in relaying signals between the base station module (DU) and the wireless communication module (RU) of the separate base station apparatus, Because it can effectively prevent the problems such as the failure to properly use the relay maximum output and the decrease in the efficiency of the RU due to the AGC signal intensity attenuation function for the AGC, It is an invention that is industrially applicable because it is not only the use of the related technology, but also the possibility of commercialization or operation of the applied device is sufficient and practically possible.

10: base station module 20,30 ...: wireless communication module
100: Signal relay device
110: monitoring unit 120: signal processing unit
130: attenuation value control section

Claims (7)

A monitoring unit for monitoring an intensity of a signal input from the base station module;
A signal processing unit for attenuating the intensity of the signal according to a predetermined attenuation value before outputting the signal to the wireless communication module; And
Wherein if the abnormal peak signal is detected in the signal, the attenuation value of the signal processing unit is increased to a maximum value, and if the abnormal peak signal is detected in the signal, the attenuation value of the signal processing unit is reduced to a specific attenuation So that the attenuation value of the signal processing unit is not maintained at the maximum value after the ideal peak signal disappears from the signal. The method according to claim 1,
The specific attenuation value,
Wherein the base station module is determined based on the strength of the full traffic signal input from the base station module and the maximum output of the wireless communication module when full traffic is allocated to the subscriber station by the base station module. The method according to claim 1,
Wherein the damping-
And when the virtual full traffic signal is input from the base station module, the specific attenuation value is determined based on the strength of the virtual full traffic signal and the maximum output of the wireless communication module. The method of claim 3,
The specific attenuation value,
When the wireless communication module transmits the virtual full traffic signal as a wireless signal based on the intensity of the virtual full traffic signal, the wireless communication module determines the intensity of the wireless signal to be the maximum output of the wireless communication module And the signal repeater. A monitoring step of monitoring an intensity of a signal input from the base station module;
A maximum attenuation step of attenuating the intensity of the signal in the signal processing unit according to the maximum value by increasing the attenuation value of the signal processing unit to a maximum value when an abnormal peak signal is detected in the signal based on the monitoring result; And
And restoring the attenuation value of the signal processing unit to a specific attenuation value smaller than the maximum value when the detected ideal peak signal disappears from the signal based on the monitoring result, And a damping value restoring step of restoring the damping value of the signal to the maximum value. 6. The method of claim 5,
And outputting a signal attenuated by the signal processing unit to a wireless communication module;
The specific attenuation value,
Wherein the base station module is determined based on the strength of the full traffic signal input from the base station module and the maximum output of the wireless communication module when full traffic is allocated to the subscriber station by the base station module. The method according to claim 6,
And determining a specific attenuation value based on the strength of the virtual full traffic signal and the maximum output of the wireless communication module when a virtual full traffic signal is input from the base station module A method of operating a signal relay device.

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