KR102180844B1 - System and method for monitoring spurious - Google Patents

Abstract

A system for monitoring unwanted waves, comprising: an unwanted wave generation determining unit that receives a received signal strength value of a radio signal received from a base station and compares the received signal strength value with a received signal strength threshold to determine whether an unwanted wave has occurred; In addition, when the unwanted wave occurs, the base station includes an unnecessary wave control unit for changing a frequency band allocated to a random access channel used in the reverse link channel of the base station.

Description

Spurious surveillance system {SYSTEM AND METHOD FOR MONITORING SPURIOUS}

The present invention relates to a technique for monitoring and taking action against whether or not an unnecessary wave occurs.

The unwanted wave is a signal having a frequency that affects the frequency used by the mobile communication device, and not only causes communication obstacles, but also blocks nearby communication in severe cases. Recently, due to the rapid spread of repeaters, generation of unnecessary waves due to failure or oscillation of repeaters, or generation of unnecessary waves due to malfunction or malfunction of external electronic devices (for example, TV boosters, etc.) has become a problem.

The existing 3G network system has its own RSSI alarm function, so it is easy to detect unwanted waves, but since this function is not implemented in the LTE network system, there are many difficulties in monitoring the unwanted waves, and There was a problem that the time it took to process also increased.

The problem to be solved by the present invention is to provide a system and method for monitoring and taking action against the occurrence of unwanted waves that substantially affect a communication network.

The system for monitoring unwanted waves according to an embodiment of the present invention receives a received signal strength value of a radio signal received from a base station and compares the received signal strength value with a received signal strength threshold to determine whether an unwanted wave has occurred. And a spurious-wave generation determining unit configured to change the frequency band allocated to a random access channel used in a reverse link channel of the base station when the spurious wave is generated.

The unwanted wave generation determiner determines an average value of the received signal strength of the radio signal received from the base station for a certain period as the received signal strength threshold value, and when the received signal strength value is greater than the received signal strength threshold value, unnecessary It is determined that the wave has occurred.

When the base station is interlocked with at least one repeater, the unwanted wave generation determiner determines a value greater than the average value of the received signal strength as the received signal strength threshold.

The system for monitoring unwanted waves further includes an interference determining unit for receiving block error rate information for the radio signal and comparing the block error rate information with a block error rate threshold, and the unwanted wave control unit Is generated, and when the block error rate information is greater than the block error rate threshold value, the frequency band allocated to the random access channel is changed.

The block error rate threshold is an average value of the block error rate for the radio signal received from the base station during the predetermined period.

The unnecessary wave control unit is the frequency band allocated to the random access channel and? Other frequency bands that are not available are reallocated to the random access channel.

The method for detecting the unwanted wave by the unwanted wave monitoring system according to an embodiment of the present invention is unnecessary when the received signal strength value of the radio signal received from the base station is received, and the received signal strength value is greater than the received signal strength threshold. Determining that the wave has occurred, and when the unwanted wave has occurred, changing a frequency band allocated to a random access channel used in a reverse link channel of the base station.

The received signal strength threshold is an average value of the received signal strength of the radio signal received by the base station for a certain period, and when the base station is interlocked with a repeater, it is a value greater than the average value of the received signal strength.

The method of detecting the spurious wave by the spurious wave monitoring system further comprises receiving block error rate information for the radio signal and comparing the block error rate information with a block error rate threshold, wherein the step of changing the frequency band comprises: When an unnecessary wave is generated and the block error rate is greater than the block error rate threshold, the frequency band is changed.

The block error rate threshold is an average value of the block error rate for the radio signal received from the base station during the predetermined period.

The step of changing the frequency band includes the frequency band allocated to the random access channel and? Other frequency bands that are not available are reallocated to the random access channel.

According to the present invention, by monitoring whether or not an unwanted wave is generated in real time and taking measures to control the unwanted wave when the generated unwanted wave has a substantial influence on a communication network, it is possible to facilitate the use of terminal users.

1 is a diagram illustrating an environment in which an unwanted wave monitoring system according to an embodiment of the present invention is implemented.
2 is a structural diagram of an unwanted wave monitoring system according to an embodiment of the present invention.
3 is a diagram illustrating an exemplary method of changing a frequency band allocated to a random access channel used by a radio signal according to an embodiment of the present invention.
4 is a diagram illustrating a method of detecting and taking action by an unwanted wave monitoring system according to an embodiment of the present invention.
5 is a diagram illustrating another method of detecting and taking action by an unwanted wave monitoring system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the embodiments of the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated. In addition, terms such as "... unit", "... group", and "module" described in the specification mean units that process at least one function or operation, which can be implemented by hardware or software or a combination of hardware and software. have.

1 is a diagram illustrating an environment in which an unwanted wave monitoring system according to an embodiment of the present invention is implemented.

Referring to FIG. 1, the terminal 100 directly or indirectly through the repeater 200 performs wireless communication with the base station 300. That is, the first terminal 110 not interlocked with the repeater 200 performs wireless communication directly with the first base station 310, and the second terminal 120 interlocked with the repeater 200 communicates with the repeater 200. Through wireless communication with the second base station 320 is performed.

Here, the terminal 100 is a PDA (Personal Digital Assistant), a cellular phone, a PCS (Personal Communication Service) phone, a handheld PC (Hand-Held PC), a GSM (Global System for Mobile) phone, a WCDMA (Wideband CDMA) phone. , CDMA-2000 phone, MBS (Mobile Broadband System) phone, etc. may refer to a mobile communication terminal connected to the core network 400 through the base station 300.

The repeater 200 may be constructed to cover the shaded area and extend the cell coverage of the second base station 320, and is linked to the second base station 320 to control the radio signal received from the second terminal 120. 2 It transmits to the base station 320. Although FIG. 1 shows that one repeater 200 is linked to the second base station 320, a plurality of repeaters may be linked to one second base station 320. In this case, the outputs of the plurality of repeaters may all be the same or may be different from each other.

The base station 300 is arranged in a cell unit to receive a radio signal from the terminal 100 or the repeater 200 existing within the competent cell coverage so that the terminal 100 accesses the core network 400. In addition, the base station 300 performs location registration to determine the location of the terminal 100, and allocates a radio channel for voice communication and data communication to the terminal 100.

In addition, the base station 300 may establish a database for information on the received radio signal. For example, the base station 300 may build a database on the received signal strength value of the radio signal received for a certain period, and a database of block error rate information for the radio signal received for a certain period. Can build.

The core network 400 receives radio signals from the terminal 100 or the repeater 200 through the base station 300 and may refer to an LTE network capable of implementing Long Term Evoltion (LTE) communication.

In the present specification, a radio frequency (RF) signal that affects a radio signal transmitted from the terminal 100 to the base station 300 is defined as an unnecessary wave, and the unwanted wave generator 500 is an unspecified electronic device that generates an unnecessary wave, TV boosters, RFID blockers, etc. can be used as examples.

The unwanted wave monitoring system 600 receives information on a radio signal from the base station 300 and determines whether or not an unwanted wave has been generated based on the radio signal information. In addition, the spurious wave monitoring system 600 is unnecessary by changing the frequency band allocated to the random access channel of the reverse link channel of the base station 300 when a spurious wave that substantially affects the wireless communication of the terminal 100 is detected Actions can be taken on par.

In this specification, a channel used when transmitting from the terminal 100 or the repeater 200 to the base station 300 is referred to as a reverse link channel, and a channel used when transmitting from the base station 300 to the terminal 100 or the repeater 200 Is defined as a forward link channel.

Hereinafter, an unwanted wave monitoring system and a unwanted wave monitoring method according to an embodiment of the present invention will be described in detail with reference to the drawings.

2 is a structural diagram of an unwanted wave monitoring system according to an embodiment of the present invention.

Referring to FIG. 2, the unwanted wave monitoring system 600 includes an unwanted wave generation determining unit 610, an interference determining unit 620, and an unwanted wave control unit 630.

The unwanted wave generation determining unit 610 receives the received signal strength value of the radio signal received from the base station 300 and compares the received signal strength value with the received signal strength threshold to determine whether the unwanted wave is generated.

That is, when the unwanted wave is generated, the unwanted wave generation determining unit 610 determines whether the unwanted wave is generated by using a characteristic in which the strength of the signal measured in the reverse link channel of the base station 300 is greater than the average signal strength.

Specifically, the unwanted wave generation determining unit 610 sets a threshold value of the received signal strength to be compared with the measured received signal strength value.

In one embodiment, the unwanted wave generation determining unit 610 receives information on the received signal strength value of the radio signal received by the base station 300 for a certain period from the base station 300, and calculates an average value for the received information. The average value of the signal strength can be set as a threshold.

Specifically, the base station 300 builds a database of received signal strength values of a radio signal received from the base station 300 during different periods or times during which no unwanted waves are generated. In this case, the unwanted wave generation determination unit 610 requests the received signal strength values corresponding to the period or time period in which the received signal strength value of the radio signal is received from the base station 300, and calculates an average value of the received signal strengths through this. This can be set as a threshold value.

In another embodiment, the unwanted wave generation determiner 610 may set a value equal to or greater than the maximum signal strength of a signal that can be transmitted while the terminal 100 is operating normally as a threshold value. For example, when the terminal 100 can transmit a signal of a maximum of -90dBm, the unwanted wave generation determiner 610 may set a value of -90dBm or more as a threshold value.

In another embodiment, when the base station 300 is interlocked with at least one repeater 200, the unwanted wave generation determiner 610 may set a threshold value in consideration of the degree of interference caused by the interlocked repeater.

Specifically, in the case of the second base station 320 linked to the repeater 200, the cell coverage of the second base station 320 increases due to the repeater 200 and the number of acceptable terminals increases. As the number of terminals increases, interference between terminals in cell coverage increases, and a received signal strength value of the reverse link channel of the second base station 320 increases.

Therefore, in the case of the second base station 320 linked to the repeater 200, the received signal strength is greater than that of the first base station 310 that is not, and the received signal strength threshold is determined by compensating for the influence of the repeater 200. It should be, and this can be defined as Equation 1 below.

[Equation 1]

Threshold=average value of received signal strength+10*log(N+1)

In the above equation, N denotes the number of repeaters 200 linked to the second base station 320.

As a result, when the second base station 320 is interlocked with the repeater 200, the received signal strength threshold is greater than the average value of the received signal strengths of the radio signal.

The unwanted wave generation determining unit 610 determines that the unwanted wave has occurred when the received signal strength value of the wireless signal is greater than the set threshold value.

In this case, the unnecessary wave generation determining unit 610 may generate an audible alarm and notify the operator, and through a control system (not shown), the area where the unwanted wave has occurred can be specified and the range of influence of the unwanted wave can be analyzed, When an unwanted wave occurs, a change in the database built in the base station 300 may be detected to analyze which statistical range the unwanted wave affects.

If the received signal strength value is less than the threshold value, the spurious wave generation determining unit 610 ends the analysis of the radio signal.

The interference determination unit 620 receives block error rate information for a radio signal from the base station 300 when an unwanted wave occurs, and compares the block error rate with a preset block error rate threshold to determine the generated unwanted wave. It is determined whether it affects the radio signal transmitted from the terminal 100 to the base station 300.

Specifically, the interference determination unit 620 receives block error rate information for a radio signal received from the base station 300 from the base station 300. The block error rate refers to the number of error blocks for all received blocks.

In addition, the interference determination unit 620 sets a threshold to be compared with the block error rate.

Specifically, the interference determination unit 620 may receive a block error rate database for a radio signal received from the base station 300 for a predetermined period from the base station 300 and set an average value thereof as a threshold value.

When the block error rate for the radio signal is greater than the determined threshold, the interference determination unit 620 determines that the unwanted wave affects the radio signal transmitted from the terminal 100 to the base station 300.

The unwanted wave control unit 630 determines that the unwanted wave is generated by the unwanted wave generation determination unit 610, or the generated unwanted wave affects the radio signal transmitted from the terminal 100 to the base station 300 and determines interference. If determined by the unit 620, the frequency band set in the reverse link channel of the base station 300 is changed.

Specifically, if the frequency band allocated to the random access channel in the reverse link channel is not changed, when the terminal 100 accesses the base station 300, interference with a commercial terminal such as a wireless telephone or RFID may occur at a high frequency. . That is, since the band of the random access channel used by the existing reverse link channel overlaps the frequency used by the existing commercial terminal, the frequency characteristic is greatly affected by the commercial terminal, which causes the terminal 100 to be affected by the unwanted wave. It causes.

Therefore, the unnecessary wave control unit 630 is the frequency band allocated to the random access channel used by the radio signal in the reverse link channel and? Reassign the frequency band to the random access channel to another frequency band that does not.

For example, the unnecessary wave control unit 630 may change the frequency band allocated to the random access channel so that the frequency band allocated to the random access channel is located in a lower frequency band than the previously allocated frequency band. Alternatively, the unnecessary wave control unit 630 may change the frequency band allocated to the random access channel so that the frequency band allocated to the random access channel is located in a higher frequency band than the previously allocated frequency band.

A method of changing the frequency band allocated to the random access channel used by the radio signal by the spurious control unit 630 will be described in detail with reference to FIG. 3.

3 is a diagram illustrating an exemplary method of changing a frequency band allocated to a random access channel used by a radio signal according to an embodiment of the present invention.

Referring to FIG. 3, the reverse link channel of the base station 300 is configured in the order of PUCCH (Physical Uplink Shared Channel), PUSCH (Physical Uplink Shared Channel), and PRACH (Physical Random Access Channel).

PUCCH is a channel for transmitting reverse link control information, and specifically transmits ANK/NACK of HARQ and (CQI)Channel Quality Indicator information.

PUSCH is a channel for transmitting reverse link data, and is used for transmission of paging information as a main physical channel for unicast transmission.

PRACH is a channel for transmitting a random access signal, specifically, a channel used for the terminal 100 to initially access the base station 300, and for transmitting a short signaling message such as call origination, paging response, location registration, etc. to be. The PRACH consists of a preamble part and a message part, and the base station 300 acquires synchronization with the terminal 100 through the preamble, and after that, the terminal 100 sends the terminal 100 to the base station 300 through the message part. ) Information is transmitted.

When the PRACH is located in a relatively high frequency band like the initial reverse link channel, interference with a commercial terminal such as a wireless telephone or RFID occurs at a high frequency when the terminal 100 accesses the base station 300 as described above. I can.

To solve this, the PRACH Offset can be changed in a manner in which the band allocated to the PRACH is set to be lower than the previously allocated band. For example, referring to the changed reverse link channel, the band allocated to the PRACH may be lower than the conventional band by lowering the band allocated to the PRACH than the PUSCH. In this case, interference with the frequency band used by the commercial terminal can be avoided, and thus the influence of the terminal 100 on the unwanted wave can be minimized.

Thereafter, the terminal 100 communicates with the base station 300 through a reverse link channel having a changed frequency band.

4 is a diagram illustrating a method of detecting and taking action by an unwanted wave monitoring system according to an embodiment of the present invention.

Referring to FIG. 4, the unwanted wave monitoring system 600 receives a received signal strength value of a radio signal received from the base station 300 (S100).

The unwanted wave monitoring system 600 compares the received signal strength value and the threshold value of the wireless signal (S103), and if the received signal strength value does not exceed the threshold value, it is determined that no unwanted wave has occurred, and returns to the initial stage. Go (S103). In this case, the threshold value may be a value equal to or greater than the average value of the received signal strength received by the base station 300 for a predetermined period.

If the received signal strength value exceeds the threshold value, the unwanted wave monitoring system 600 receives block error rate information for the radio signal (S105).

The spurious wave monitoring system 600 determines whether the received block error rate information exceeds a threshold value (S107), and when the block error rate information does not exceed the threshold value, it is determined that the generated spurious wave does not affect the radio signal. It returns to the initial stage (S109). In this case, the threshold value may be an average value of the block error rate of the radio signal received by the base station 300 for a predetermined period.

If the received signal strength value exceeds the threshold value, the unwanted wave monitoring system 600 changes the frequency band allocated to the random access channel used in the reverse link channel of the base station 300 (S111).

5 is a diagram illustrating another method of detecting and taking action by an unwanted wave monitoring system according to an embodiment of the present invention.

Referring to FIG. 5, the unwanted wave monitoring system 600 receives a received signal strength value of a radio signal received from the base station 300 (S200).

The unwanted wave monitoring system 600 determines whether the base station 300 is interlocked with the repeater 200 (S201), and if it is not interlocked with the repeater 200, the received signal strengths of one or more radio signals received for a certain period of time are The average value is determined as the threshold value (S203). For example, the unwanted wave monitoring system 600 may receive a database on the received signal strengths of one or more radio signals received by the base station 300 from the base station 300, and through this, the average value is calculated and calculated. The average value can be determined as a threshold value.

If the base station 300 is interlocked with the repeater 200, the spurious monitoring system 600 determines a threshold value by Equation 1 described in FIG. 1 (S205). That is, the unwanted wave monitoring system 600 compensates for the influence of the repeater 200 to determine a threshold value.

Thereafter, the unwanted wave monitoring system 600 compares the received signal strength value of the radio signal and the determined threshold value (S207).

If the received signal strength value is less than the threshold value, the unwanted wave monitoring system 600 determines that the unwanted wave has not been generated and returns to the initial stage (S209).

If the received signal strength value is greater than the threshold value, the unwanted wave monitoring system 600 determines that the unwanted wave has occurred and counts the number of times the unwanted wave is generated (S211). For example, the unwanted wave monitoring system 600 may store information on whether or not the base station 300 generates unwanted waves for each identification information of the base station 300.

The spurious wave monitoring system 600 compares the number of occurrences of the spurious wave with a preset number (S213), generates a notification when it is greater than the preset number, and returns to the initial stage (S215). For example, the unwanted wave monitoring system 600 may generate an alarm notifying that the unwanted wave has been continuously generated within the cell coverage of the base station 300.

If the count does not exceed a preset number of times, the spurious wave monitoring system 600 receives block error rate information for a radio signal from the base station 300 (S217) and compares it with a preset threshold (S219).

Specifically, the unwanted wave monitoring system 600 may receive block error rate information for one or more radio signals received from the base station 300 for a certain period from the base station 300 and determine an average value thereof as a threshold value. .

If the block error rate for the radio signal is less than the threshold value, the spurious wave monitoring system 600 ends analysis of the generated spurious wave and returns to the initial stage (S221).

If the block error rate for the radio signal is less than the threshold value, the spurious monitoring system 600 changes the frequency band allocated to the random access channel of the reverse link channel of the base station 300 (S223), and returns to the initial stage. Go (S225).

Specifically, the spurious monitoring system 600 checks the frequency band allocated to the random access channel used by the radio signal in the reverse link channel of the base station 300, and the frequency band previously allocated to the random access channel and? ≠? The frequency band is changed so that other frequency bands that are not available are reassigned to the random access channel.

According to the present invention, by detecting the unwanted wave in real time and performing a measure for controlling the unwanted wave when the unwanted wave substantially affects the communication network, it is possible to facilitate the use of terminal users.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (11)

As a system to monitor unwanted waves,
An unwanted wave generation determining unit that receives a received signal strength value of a radio signal received from the base station, and determines whether an unwanted wave has occurred by comparing the received signal strength value and a received signal strength threshold value, and
When an unwanted wave occurs, an unwanted wave control unit for changing a first frequency band allocated to a random access channel to a second frequency band within the frequency band of the reverse link channel used by the base station
Including,
The second frequency band is a frequency band lower than the first frequency band, the unwanted wave monitoring system. In claim 1,
The spurious generation determination unit
The average value of the received signal strength of the radio signal received from the base station for a certain period is determined as the received signal strength threshold,
When the received signal strength value is greater than the received signal strength threshold, it is determined that the unwanted wave has occurred. In paragraph 2,
The spurious generation determination unit
When the base station is interlocked with at least one repeater, the spurious wave monitoring system determines a value greater than the average value of the received signal strength as the received signal strength threshold. In claim 1,
Further comprising an interference determination unit for receiving block error rate information for the radio signal and comparing the block error rate information and a block error rate threshold,
The unnecessary wave control unit
When a spurious wave is generated and the block error rate information is greater than the block error rate threshold, a frequency band allocated to the random access channel is changed. In claim 4,
The block error rate threshold is an average value of block error rates for radio signals received from the base station for a predetermined period of time. In claim 1,
The unnecessary wave control unit
Allocating the second frequency band that does not overlap with the first frequency band, spurious monitoring system. In the method for the spurious surveillance system to detect spurious waves,
Receiving a received signal strength value of a radio signal received at the base station, and determining that an unwanted wave has occurred when the received signal strength value is greater than a received signal strength threshold value, and
In the case of occurrence of an unnecessary wave, including the step of changing a first frequency band allocated to a random access channel to a second frequency band within a frequency band of a reverse link channel used by the base station,
The second frequency band is a frequency band lower than the first frequency band, the unwanted wave detection method. In clause 7,
The received signal strength threshold is
It is an average value of the received signal strength of the radio signal received from the base station for a certain period,
When the base station is interlocked with a repeater, the spurious wave detection method having a value greater than the average value of the received signal strength. In clause 7,
Receiving block error rate information for the radio signal, further comprising the step of comparing the block error rate information and a block error rate threshold value,
The step of changing to the second frequency band
When a spurious wave is generated and the block error rate is greater than the block error rate threshold, the frequency band allocated to the random access channel is changed. In claim 9,
The block error rate threshold is
A method of detecting spurious waves, which is an average value of a block error rate for a radio signal received from the base station for a certain period of time. In clause 7,
The step of changing to the second frequency band
Allocating the second frequency band that does not overlap the first frequency band, spurious detection method.

Images