KR101115521B1 - Full?autonomous remote-dm apparatus - Google Patents

Abstract

The present invention relates to a fully automatic remote DM measurement device and a method thereof, and more particularly, to receive a measurement scenario for a wireless communication environment through a wireless communication from a relay device, and according to the priority of the received measurement scenario. The present invention relates to a fully automatic remote DM measurement device and a method for automatically transmitting a measurement result data to a neighboring relay device by performing a measurement.

The present invention transmits the measurement scenario and priority information of the measurement scenarios to the DM measuring apparatus using the relay apparatus installed in various places, and when the DM measuring apparatus approaches the communication radius of the repeating apparatus, the relay apparatus transmits the measurement result data to the DM measuring apparatus. It is intended to enable automatic transmission and reception of measurement scenarios, measurement result data, etc. by receiving the data from the measurement device and transmitting the data to the analysis server.

The remote DM measurement apparatus of the present invention for achieving the above object is a first wireless communication module for receiving a measurement scenario from the relay device, and transmitting and receiving data with the relay device, and the target of the wireless communication environment measurement according to the measurement scenario A measurement result data calculation module for receiving a communication signal to calculate measurement result data, a memory for storing various data including measurement result data, and storing the calculated measurement result data in a memory and transmitting the result to a relay device It can be made including a control module to control to.

Remote DM, diagnostic monitoring, wireless communication environment measurement, automatic transmission, measurement scenario

Description

Fully-automatic remote DMM measuring apparatus and method thereof

The present invention relates to a fully automatic remote DM measurement device and a method thereof, and more particularly, to receive a measurement scenario for a wireless communication environment through a wireless communication from a relay device, and according to the priority of the received measurement scenario. The present invention relates to a fully automatic remote DM measurement device and a method for automatically transmitting a measurement result data to a neighboring relay device by performing a measurement.

With the development of wireless communication technology, wireless communication environment such as urban center becomes more complicated and problems such as interference between radio waves have appeared. In addition, the need for accurate understanding and analysis of the characteristics of the wireless communication environment is increasing due to the demand for improvement of the wireless communication environment and other requirements, and thus, the measurement of the wireless communication environment is an important field in the wireless communication technology. It was priced.

Conventionally, the communication quality between the base station and the mobile communication terminal, the wireless Internet quality, the quality of upload and download data, Various measuring devices have been used to measure the quality of SMS (Short Message Service) services.

1 is a configuration diagram of a system implementing a video phone monitoring method through a DM port of a conventional mobile communication terminal. As shown in FIG. 1, a system in which a video phone monitoring method is implemented through a DM port of a conventional mobile communication terminal is measured to be connected to the monitoring equipment 110 and the monitoring equipment 110 to measure a wireless environment. It comprises a mobile communication terminal 120 for. In general, the monitoring equipment 110 is implemented as a monitoring program mounted on a notebook computer, and the measurement mobile communication terminal 120 transmits and receives radio signals, wireless channel encoding, and the like with a mobile station, that is, the mobile communication terminal 120 for measurement. Node B 130, which performs decoding, baseband signal processing, and the like, controls a plurality of Node Bs 130, and performs a function such as matching with Node B, inter-cell handover processing, and call control. A mobile switch 132 that provides voice / video calls and various additional functions, establishes a call path, and provides connection with various other devices and external networks between the circuit switching network 134 and the wireless network controller 131. ), And communicates with other mobile communication terminals through a circuit switched network 134 to which a wired video telephone 142 or another mobile communication terminal 141 is connected.

On the other hand, the monitoring equipment 110 is connected to the standard connection terminal of the measurement mobile communication terminal 120 through a USB terminal, such as the identification number of the counterpart equipment, for example of the video telephone 141, (142) Input of a phone number or URL of the VOD server 140, setting various log commands to be transmitted to the measurement mobile communication terminal 120 through the DM port (Diagnostic Monitoring Port) and various monitoring results for the video call The user interface (UI) module 111 for displaying and collecting various log commands set by the user through the DM port, for example, collecting data, for example, data of the H.324M setup process or received audio / video data. Data collection module 113, the audio / video codec module 114 to decode the received audio / video data, and compares the received audio / video with a preset reference audio / video to measure the quality It comprises a driver module 116 for the measurement mobile communication terminal 120 in charge of the function such as opening the above-described DM port between the MOD analysis module 115 and the measurement mobile communication terminal 120. .

In this case, the 'DM port' is a logical terminal used to analyze or monitor the operation of the terminal or the wireless communication environment among data transmitted / received through a transmission / reception terminal provided in a standard access terminal, for example. It refers to the port.

However, the conventional mobile communication terminal DM (Diagnostic Monitoring) measuring device has a problem that can only store a limited amount of measurement result data in the built-in memory, and perform an integrated analysis of the measurement result data measured in various regions There is a problem in that the data must be transferred directly to the analysis server through a separate manual operation.

In addition, in order to measure various wireless communication environment parameters, there is a problem in that a user of a mobile communication terminal (DM) measuring apparatus directly inputs a measurement scenario to be measured directly into a DM (Diagnostic Monitoring) measuring apparatus.

In addition, there is a problem in that the capacity of the measurement result data is huge, so that every time a certain period passes, the analysis server is repeatedly moved to the place where the analysis server is located, and the measurement result data is repeatedly transmitted to measure the wireless environment again.

The present invention has been made to solve the above problems, using a relay device installed in various places to transfer the measurement scenario and priority information of the measurement scenario to the DM measuring device, the DM measuring device within the communication radius of the relay device; In the case of approaching, the relay device receives the measurement result data from the DM measurement device and transmits the measurement result data to the analysis server, thereby enabling automatic transmission and reception of measurement scenarios and measurement result data. Through this process, the present invention enables the DM measuring device to automatically receive the radio environment measurement scenario and priority and transmit the measured measurement result data to the relay device as long as the DM measuring device approaches the communication radius of the neighboring device.

The remote DM measurement apparatus of the present invention for achieving the above object is a first wireless communication module for receiving a measurement scenario from the relay device, and transmitting and receiving data with the relay device, and the target of the wireless communication environment measurement according to the measurement scenario A measurement result data generation module for receiving measurement signals and generating measurement result data, a memory for storing various data including measurement result data, and storing the calculated measurement result data in a memory and transmitting the result to a relay device It can be made including a control module to control to.

Further, in the above-described configuration, when the first wireless communication module enters a wireless communication area with the relay device and receives a unique identification number transmission command from the relay device, the first wireless communication module transmits the unique identification number of the DM measuring device to the relay device in response thereto. Can be.

In addition, in the above-described configuration, the first wireless communication module may receive a priority for each measurement parameter included in the measurement scenario from the relay device.

In addition, in the above-described configuration, when there is no free space for storing the measurement result data in the memory, the control module may instruct to delete the measurement result data stored in the memory in order of low priority of the measurement parameter.

In addition, in the above-described configuration, when the transmission of the measurement result data is completed, the control module may instruct to delete the measurement result data that has been transmitted from the memory and to cut off the battery power to prevent battery power consumption.

In addition, in the above-described configuration, the control module requests the reception of the measurement result data to the nearest relay device when the empty area where the measurement result data can be stored in the memory is below a certain capacity or when all parameters are measured according to the measurement scenario. It can be controlled to transmit a signal.

In addition, in the above-described configuration, when the remote DM measurement device is transmitting the measurement result data to the relay device or receiving the measurement scenario from the relay device, the size of the wireless communication signal received from the relay device becomes smaller than a predetermined size. It may further include an alarm module for generating an alarm signal.

In addition, the relay device of the present invention for achieving the above object is a measurement scenario generation module for generating a measurement scenario for wireless communication environment measurement, and transmits the measurement scenario to the remote DM measurement device, the measurement result data from the remote DM measurement device And a second wireless communication module for receiving the measurement result, a measurement result data transmission module for transmitting the measurement result data received to the analysis server, and a storage for storing the generated measurement scenario and the received measurement result data.

In addition, in the above configuration, it may further include a priority setting module for setting the priority for each measurement parameter included in the measurement scenario.

In addition, in the above-described configuration, the second wireless communication module may transmit the measurement result data received to another relay device within a wireless communication range.

In addition, in the above-described configuration, the relay device may monitor in real time whether the remote DM measurement device enters a wireless communication area with the relay device by periodically transmitting a unique number transmission command.

In addition, the remote DM measurement system of the present invention for achieving the above object, receiving a measurement scenario for measuring the wireless communication environment from the relay device, and measuring the various parameters according to the received measurement scenarios for the measurement result for the wireless communication environment A remote DM measuring device for generating data and transmitting the measurement result data to the relay device;

A relay device for generating measurement scenarios and transmitting them to a remote DM measurement device, receiving measurement result data from the remote DM measurement device, and transmitting the measurement result data received to the analysis server;

It may include an analysis server for receiving and storing the measurement result data for the wireless communication environment of various regions from at least one or more relay devices, and analyzes the received measurement result data to analyze the wireless communication environment.

In addition, the automatic wireless communication environment measurement result data collection method of the present invention for achieving the above object, the measurement scenario generation step for generating a measurement scenario for wireless communication environment measurement, and wireless LAN (WirelessLAN) as a remote DM measurement device A measurement scenario transmission step of transmitting a measurement scenario for measurement of a wireless communication environment by using a signal, a measurement result data reception step of receiving measurement result data using a wireless LAN from a remote DM measurement device, and reception to an analysis server And a measurement result data transmission step of transmitting the measured result data.

According to the present invention, the remote DM measuring device is installed in a vehicle or the like to perform a measurement for a wireless communication environment and automatically enters a measurement result data by wireless communication when entering a wireless communication area of a neighboring relay device, thereby measuring the measurement result data one by one. There is no inconvenience to move to the analysis server.

In addition, since the measurement result data is automatically transferred and the measurement result data is deleted, the measurement result data accumulates and there is an advantage that it is not necessary to stop the measurement and move to transmit the measurement result data in order to secure memory space. .

In addition, after automatically transmitting the measurement result data, it is possible to check whether or not the normal transmission is performed, thereby deleting the completed measurement result data to secure memory space and turn off the battery to efficiently manage power.

In addition, the measurement result data of various regions are collected in the analysis server in real time, there is an effect that can be integrated analysis.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter, the embodiments of the present invention will be described in detail so that those skilled in the art can easily understand and reproduce the present invention.

2 is a block diagram showing a remote DM measurement system capable of automatic data collection according to an embodiment of the present invention.

As shown in Figures 2a and 2b, the remote DM measurement system 200 capable of automatic data collection according to an embodiment of the present invention receives a measurement scenario for wireless communication environment measurement from the relay device to the received measurement scenario According to the measurement of various parameters to generate the measurement result data for the wireless communication environment and the remote DM measurement device 210 for transmitting the measurement result data to the relay device, and generates a measurement scenario and transmits to the remote DM measurement device 210 Receives the measurement result data from the remote DM measurement device, and receives the measurement result data for the wireless communication environment of various regions from the relay device 220 and the relay device 220 for transmitting the measurement result data received to the analysis server And storing and analyzing the received measurement result data to analyze the wireless communication environment.

The remote DM measuring device 210 is a device for measuring a wireless communication environment while moving in various regions, and measures various parameters according to a measurement scenario received from the relay device 220 to generate measurement result data for the wireless communication environment. . As shown in FIG. 2, the remote DM measuring device 210 is preferably installed in a vehicle, and may collect data on wireless communication environments of various regions within a short time by using a moving means.

The remote DM measurement apparatus 210 may measure wireless communication environment or parameters of a region not included in the measurement scenario when there is a user input.

When the remote DM measuring device enters a wireless communication enabled area of the plurality of relay devices 220, the remote DM measuring device receives a unique identification number transmission command of the relay device 220. The unique identification number transmission command is a signal transmitted by the relay device to identify the remote DM measurement device, and when receiving the unique identification number transmission command, the remote DM measurement device transmits its own identification number to the relay device. When the repeater 220 identifies the unique identification number of the remote DM measurement device 210 through this process, the relay device transmits the measurement scenario to the remote DM measurement device 210 and the remote DM measurement device 210 is You will receive a measurement scenario. When the relay device transmits the measurement scenario including the unique identification number of the remote DM measurement device 210, only the remote DM measurement device 210 having the corresponding unique identification number may receive and store the measurement scenario. In addition, the remote DM measurement device 210 transmits the stored measurement result data to the relay device 220.

The relay device 220 generates a measurement scenario to be transmitted to each remote DM measurement device 210 that has entered within its communication radius. Measurement scenarios include parameters such as signal-to-noise ratio, received signal code power, RSSI (Received Signal Strength Indicator), DATA Throughput (Uplink, Downlink), Voice Quality (QoS), Call Success, Service Area, Wireless Internet Quality, and SMS Quality. Include specific instructions for the measurement.

If the analysis server 230 has a measurement scenario of the entire service area, some measurement scenarios may be distributed to the relay device 220 according to the measurement scenario of the entire service area, and the relay device 220 may be distributed. According to the measured measurement scenarios can be transmitted after distributing the measurement scenario to be transmitted to each remote DM measuring device 210 entered within its communication radius.

On the other hand, the measurement scenario includes a command for measuring the various parameters may be prioritized for each parameter. For example, the priority of measuring RSSI may be set to 1, and the priority of voice QoS measurement may be set to 3, for example. This setting is made by the analysis server 230 or the relay device 220. Priority information is transmitted to the remote DM measurement unit 210 together with the measurement scenario, the remote DM measurement unit 210 performs the measurement in the order of priority, and if the memory space is insufficient, the measurement for the low priority parameters You can free up memory space by deleting the resulting data.

Figure 3 is a block diagram showing a remote DM measurement system capable of automatic data collection according to an embodiment of the present invention.

As shown in FIG. 3, a remote DM measurement system capable of automatic data collection according to an embodiment of the present invention includes a remote DM measurement device 310, a relay device 320, and an analysis server 330.

The remote DM measurement device 310 may include a measurement result data generation module 311, a memory 312, a first wireless communication module 313, a control module 314, and an alarm module 315.

The measurement result data generation module 311 measures the wireless communication environment parameters according to the measurement scenario under the control of the control module 314 and generates the measurement result data. The measurement result data refers to data generated in a predetermined format for analysis by the analysis server 330 as a result of measuring wireless communication environment parameters as described above, for example, RSSI, signal-to-noise ratio, voice quality, and the like.

The memory 312 stores the measurement scenario received from the relay device 320 and the measurement result data generated by the measurement result data generation module 311 under the control of the control module 314. In addition, the memory 312 may store priority information for each measurement parameter included in the measurement scenario.

The first wireless communication module 313 performs wireless communication with the second wireless communication module 322 of the relay device 320. The wireless communication method between the first wireless communication module 313 and the second wireless communication module 322 may be implemented by a communication method using a wireless LAN method such as Wi-Fi. The first wireless communication module 313 may receive a unique number transmission command or a measurement scenario transmitted from the second wireless communication module 322 and transmit the measurement result data to the relay device 320.

The control module 314 controls various functions of the remote DM measurement device 310.

In particular, the control module 314 may determine whether there is no free space in which the measurement result data is stored in the memory 312, and instruct the memory module 312 to delete the measurement result data stored in the memory 312 in order of low priority of the measurement parameter. have. That is, when there is no free space for storing all the measurement result data in the memory 312, the measurement result data measured in the order of high priority is generated and stored. If the lower priority measurement result data is stored in the memory 312, the measurement result data is deleted and the higher priority measurement result data is stored. For example, if the measurement result data for RSSI is stored in the memory 312, and there is no space for storing the measurement result data for Voice Quality, the measurement result data for RSSI is higher than the RSSI parameter. Delete and save the measurement result data for Voice Quality.

In addition, when the control module 314 transmits the measurement result data to the relay device 320 and receives a signal from the relay device that the reception is normally completed, the control module 314 deletes the measurement result data from the memory, and deletes the battery. Battery power can be controlled to cut off battery power to prevent power consumption.

Meanwhile, according to another exemplary embodiment of the present invention, the control module 314 may include the closest relay device when the empty area where the measurement result data may be stored is less than or equal to a certain capacity or when all parameters are measured according to the measurement scenario. It can be controlled to move to transmit the measurement result data reception request signal.

The alarm module 315 may generate an alarm signal under the control of the control module 314. The alarm signal may be generated by any one or more of an audio, a sound, a video signal, and a vibration signal. The control module 314 is a wireless communication signal received from the relay device 320 when the first wireless communication module is transmitting measurement result data to the relay device 320 or receiving a measurement scenario from the relay device 320. If the size is smaller than the predetermined size, the alarm module 315 is controlled to generate an alarm signal by determining that it will soon be out of the wireless communication possible area of the relay device 320. In this way, the user of the remote DM measurement apparatus may be warned so that the user stops moving so that the user does not have a problem of leaving the wireless communication available area before data transmission and reception is completed.

The relay device 320 may include a measurement scenario generation module 321, a second wireless communication module 322, a measurement result data transmission module 323, a storage unit 324, and a priority setting module 325. have.

The measurement scenario generation module 321 generates a measurement scenario transmitted to the remote DM measurement device 310. If the relay device 320 receives the measurement scenario from the analysis server 330, the received measurement scenario is divided into two or more measurement scenarios in order to distribute the received measurement scenario to one or more remote DM measurement devices 310. Can be generated. If the priority setting module 325 is included in the relay device 320, priority information for each parameter generated by the priority setting module 325 may be added to the measurement scenario.

The second wireless communication module 322 wirelessly communicates with the first wireless communication module 313 and receives data transmitted by the first wireless communication module and transmits data such as a unique number transmission command and a measurement scenario to the first wireless communication module. send.

The measurement result data transmission module 323 transmits the measurement result data to the analysis server 330. This transmission may be implemented in a communication method via a LAN connection.

The storage unit 324 stores the received measurement result data, the generated measurement scenario, the measurement scenario received from the analysis server 330, priority information, and the like.

The analysis server 330 analyzes the wireless communication environment by integrally analyzing the measurement result data collected from the one or more relays 320. In addition, it is possible to generate and store measurement scenarios of various regions, and transmit them to one or more relays 320. Of course, it is possible to transmit a different measurement scenario for each relay device (320).

4 is a flowchart illustrating an operation of a relay apparatus according to an embodiment of the present invention.

As shown in FIG. 6, the relay device 220 transmits a unique identification number transmission command through a wireless communication at a predetermined cycle (S410). When the remote DM measuring device 210 receives the unique identification number transmission command, it transmits a response signal including the unique identification number to the relay device 220. When the relay device 220 receives the unique identification number of the remote DM measurement device, the relay device 220 transmits a measurement result data transmission command to the remote DM measurement device (S420). When the remote DM measuring device 210 receives the measurement result data transmission command, it transmits the stored measurement result data to the relay device 220 only when the measurement result data is stored. Send it. The relay device 220 receives the measurement result data (S430), and transmits the received measurement result data to the analysis server 230 (S440). The relay device 220 transmits the measurement scenario to the remote DM measurement device 210 (S450).

The relay device may first transmit the measurement scenario to the remote DM measurement device 220 before transmitting the measurement result data transmission command or before transmitting the measurement result data received by the analysis server 230.

5 is a flowchart showing the operation of the relay apparatus according to another embodiment of the present invention.

Receiving a wireless communication signal from the remote DM measuring device 210 and the relay device transmits the response signal to the remote DM measuring device 210, the remote DM measuring device 210 transmits a signal containing a unique identification number to the relay device ( 220 and the relay 220 receives it (S510). The relay device 22 transmits a measurement scenario to the remote DM measurement device 210 having transmitted the unique identification number (S520), and when the transmission of the measurement scenario is terminated, transmits a measurement result data transmission command (S530). When the remote DM measuring device 210 receives the measurement result data transmission command, it transmits the stored measurement result data to the relay device 220 only when the measurement result data is stored. Send it. The relay device 220 receives the measurement result data (S540), and transmits the received measurement result data to the analysis server 230 (S550).

Of course, the relay device may perform the measurement scenario transmission after the reception of the measurement result data.

On the other hand, according to another embodiment of the present invention, the remote DM measurement device 210 may be provided with a location detection module, such as a location identification module (not shown) using a GPS module or mobile communication. The remote DM measuring device 210 may grasp its current location information and location information of a neighboring relay device 220 previously stored using a location identification module (not shown), and wireless communication of the relay device 220. When entering the available area, it is possible to perform a communication with the relay device 220 by transmitting a signal for securing a communication channel to the relay device and transmitting a signal including its own identification number to the relay device 220. . According to this embodiment, since the relay device 220 does not have to continuously transmit a unique identification number transmission command in order to find the remote DM measurement device 210, there is an advantage of reducing power consumption.

In addition, according to another embodiment of the present invention, the remote DM measuring device 210 is transmitting the measurement result data to the relay device 220, or while receiving the measurement scenarios from the relay device 220 and the relay device 220. An alarm module 315 for sending an alarm signal to a user of the remote DM device may be further included in the remote DM measurement device 210 in order to prevent the mobile communication from moving beyond the communication enabled area. The remote DM measuring device 210 may determine that the remote DM measurement device deviates from the communicable area when the intensity of the wireless signal received from the relay device 220 is smaller than a predetermined size, thereby operating the alarm module. The alarm module may be implemented to generate vibration, voice or video signals.

1 is a configuration diagram of a system implementing a video phone monitoring method through a DM port of a conventional mobile communication terminal.

2 is a block diagram showing a remote DM measurement system capable of automatic data collection according to an embodiment of the present invention.

Figure 3 is a block diagram showing a remote DM measurement system capable of automatic data collection according to an embodiment of the present invention.

4 is a flowchart illustrating an operation of a relay apparatus according to an embodiment of the present invention.

5 is a flowchart showing the operation of the relay apparatus according to another embodiment of the present invention.

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

210. Remote DM Measuring Device 220. Repeater

230. Analysis server 310. Remote DM measurement device

311.Measurement Data Generation Module 312.Memory

313. First Wireless Communication Module 314. Control Module

315.Alarm module 320. Repeater

321. Measurement scenario generation module 322. Second wireless communication module

323. Measurement result data transmission module 324. Storage unit

325. Priority setting module 330. Analysis server

Claims (13)

A first wireless communication module for receiving a measurement scenario from a relay device and transmitting and receiving data with the relay device; A measurement result data generation module configured to receive a communication signal targeted for wireless communication environment measurement and generate measurement result data according to the measurement scenario; A memory for storing various data including measurement result data; And And a control module which stores various data including the measurement result data in the memory and transmits the data to the relay device. When the first wireless communication module enters a wireless communication area with the relay device and receives a unique identification number transmission command from the relay device, the first wireless communication module transmits the unique identification number of the DM measurement device to the relay device in response thereto. Remote DM measuring device. delete The method of claim 1, The first wireless communication module, the remote DM measurement device, characterized in that for receiving the priority for each measurement parameter included in the measurement scenario from the relay device. The method of claim 3, wherein the control module, And when there is no free space for storing the measurement result data in the memory, instructing to delete the measurement result data stored in the memory in the order of low priority of the measurement parameters. The method of claim 4, wherein the control module, And when the transmission of the measurement result data is completed, deleting the measurement result data that has been transmitted from the memory and instructing to cut off the battery power to prevent battery power consumption. The method of claim 1, wherein the control module, If the empty area where the measurement result data can be stored in the memory is below a certain capacity, or if all parameters are measured according to the measurement scenario, the control unit transmits the measurement result data reception request signal to the nearest relay device. Remote DM measurement device. The method according to any one of claims 1 and 3 to 6, When the remote DM measurement device is transmitting the measurement result data to the relay device or while receiving the measurement scenario from the relay device, the size of the wireless communication signal received from the relay device becomes smaller than a predetermined size. Remote DM measuring device further comprising an alarm module for generating an alarm signal. A measurement scenario generation module for generating a measurement scenario for wireless communication environment measurement; A second wireless communication module for transmitting the measurement scenario to a remote DM measurement device and receiving measurement result data from the remote DM measurement device; A measurement result data transmission module for transmitting the received measurement result data to an analysis server; And It includes a storage for storing the generated measurement scenario and the received measurement result data. And transmitting in real time periodically a remote DM measuring apparatus to monitor whether the remote DM measuring apparatus enters an area capable of wireless communication with itself. The method of claim 8, And a priority setting module for setting priorities for each measurement parameter included in the measurement scenario. The method of claim 8, wherein the second wireless communication module, And transmitting the measurement result data received to another relay device within a wireless communication range. delete Receiving a measurement scenario for wireless communication environment measurement from a relay device, measuring various parameters according to the received measurement scenario to generate measurement result data for a wireless communication environment, and transmitting the measurement result data to the relay device Remote DM measuring device; A relay device for generating the measurement scenario and transmitting the measurement scenario to the remote DM measurement device, receiving the measurement result data from the remote DM measurement device, and transmitting the received measurement result data to an analysis server; And It includes an analysis server for receiving and storing the measurement result data for the wireless communication environment of various regions from at least one or more relay devices, and analyzing the received measurement result data to analyze the wireless communication environment, The relay device periodically transmits a unique number transmission command to monitor in real time whether the remote DM measurement device enters a wireless communication area with itself, The remote DM measuring device enters a wireless communication area with the relay device and transmits its own identification number to the relay device in response to receiving a unique identification number transmission command from the relay device. Remote DM measurement system with automatic data collection. delete

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