CN211791530U - Automatic monitoring system for base station antenna coverage variation - Google Patents

Abstract

The utility model relates to a base station antenna covers abnormal change automatic monitoring system. The system comprises an antenna work parameter acquisition device, an operator network server and an antenna coverage variation monitoring device; the antenna engineering parameter acquisition device is arranged on the base station antenna and used for acquiring engineering parameters of the base station antenna; the operator network server is configured to provide signal strength data of base station antenna operation and distance data of the user from the base station antenna; the antenna coverage variation monitoring device is respectively in communication connection with the antenna working parameter acquisition device and the operator network server, and is used for receiving the engineering parameters returned by the antenna working parameter acquisition device and judging whether the base station antenna covers variation or not by combining the signal intensity data and the distance data extracted from the operator network server. According to the method and the device, on one hand, full-automatic monitoring and positioning of the antenna coverage variation of the base station can be realized, on the other hand, the problem can be accurately and timely found by the antenna coverage variation monitoring device, and the influence on a network and a user is reduced to the greatest extent.

Description

Automatic monitoring system for base station antenna coverage variation

Technical Field

The utility model relates to a communication equipment technical field especially relates to a base station antenna covers abnormal change automatic monitoring system.

Background

In the network planning, optimization and maintenance work of mobile communication, the working state of the base station antenna and the engineering parameters of the antenna have decisive influence on the electromagnetic radiation performance of the base station, and directly influence the coverage and interference of the network.

In actual work, for a serious explicit problem, because an alarm is generated and is easy to be found, if an antenna is in a problem, a maintenance system has a standing-wave ratio alarm, a base station master device has a problem, and a corresponding master device alarm (such as a synthesizer and the like) is also generated. However, some hidden problems do not generate alarm, but also bring serious problem of field intensity coverage mutation, which affects network quality. For example, the signal strength is abnormal due to the aging of the antenna, and the signal strength is abnormal due to the inclination, the overturn and even the displacement of the mast of the antenna feeder tower.

These non-explicit problems can be found only by field inspection of base station antenna or large-area network pulling test of network optimization testers, and these two works are periodic and untimely, the problems are difficult to find in time, therefore, most of the time, after receiving complaint report of mobile phone user, the problems are found and solved on the spot, but this has long time affected reputation and complaint check of operator and brought long time network performance deterioration.

Therefore, there is an urgent need for a device or apparatus capable of detecting the variation in coverage of the base station antenna in real time, detecting the problem and performing early warning in the first time, and reducing the influence on the network and the complaints of the user to the greatest extent.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is desirable to provide an automatic monitoring system for base station antenna coverage variation.

An automatic monitoring system for base station antenna coverage variation comprises an antenna work parameter acquisition device, an operator network server and an antenna coverage variation monitoring device;

the antenna engineering parameter acquisition device is arranged on a base station antenna and is configured to acquire engineering parameters of the base station antenna;

the operator network server is configured to provide signal strength data of the base station antenna operation and distance data of a user from the base station antenna;

the antenna coverage variation monitoring device is respectively in communication connection with the antenna work parameter acquisition device and the operator network server, and is used for receiving the engineering parameters returned by the antenna work parameter acquisition device and judging whether the base station antenna covers variation or not by combining the signal intensity data and the distance data extracted from the operator network server.

In one embodiment, the antenna parameter acquisition device comprises an antenna position acquisition module and an antenna attitude acquisition module;

the antenna position acquisition module is arranged on the base station antenna and used for acquiring longitude and latitude data of the base station antenna;

the antenna attitude acquisition module is arranged on the base station antenna and used for acquiring attitude data of the base station antenna.

In one embodiment, the antenna attitude acquisition module comprises an altitude acquisition module, an azimuth acquisition module and an inclination acquisition module;

the height acquisition module is used for acquiring hanging height data of the base station antenna;

the azimuth angle acquisition module is used for acquiring azimuth angle data of the base station antenna;

the inclination angle acquisition module is used for acquiring inclination angle data of the base station antenna.

In one embodiment, the azimuth angle acquisition module is an electronic compass.

In one embodiment, the tilt angle acquisition module is a three-axis gyroscope.

In one embodiment, the antenna parameter collecting device further includes:

and the data transmission module is in communication connection with the antenna coverage variation monitoring device and is used for transmitting the engineering parameters acquired by the antenna work parameter acquisition device back to the antenna coverage variation monitoring device.

In one embodiment, the method further comprises the following steps:

and the power supply module is electrically connected with the antenna work parameter acquisition device and used for providing electric energy required by work for the antenna work parameter acquisition device.

In one embodiment, the power supply module comprises a mains supply and/or a storage battery.

In one embodiment, the coverage variation includes an abnormal radiation performance of the base station antenna and/or the base station antenna is blocked.

In one embodiment, the granularity of the engineering parameter collection is once a day; the granularity of acquisition of the signal strength data and the distance data is once per hour.

According to the automatic monitoring system for the base station antenna coverage variation, the engineering parameters of the base station antenna are collected by setting the antenna work parameter collecting device, the operator network server is set to provide the signal intensity data of the base station antenna operation and the distance data between the user and the base station antenna, the antenna coverage variation monitoring device is set to judge whether the base station antenna has the coverage variation or not according to the returned engineering parameters and the signal intensity data and the distance data extracted from the operator network server are combined. On the one hand, the full-automatic monitoring and positioning of the base station antenna coverage variation can be realized, and on the other hand, because the antenna work parameter acquisition device and the antenna coverage variation monitoring device are in communication connection, and the antenna coverage variation monitoring device and an operator network server are in communication connection, the antenna coverage variation monitoring device can be ensured to accurately and timely find problems, an alarm is provided, and the influence on a network and a user is reduced to the maximum extent.

Drawings

Fig. 1 is a schematic view of an application scenario of an automatic monitoring system for base station antenna coverage variation in an embodiment;

fig. 2 is a schematic block diagram of an automatic monitoring system for base station antenna coverage variation according to an embodiment;

fig. 3 is a schematic block diagram of an automatic monitoring system for base station antenna coverage variation in another embodiment;

fig. 4 is a schematic flow chart illustrating an automatic monitoring method for base station antenna coverage variation in an embodiment;

FIG. 5 is a flowchart illustrating an implementation of step S430 in FIG. 4;

FIG. 6 is a flowchart illustrating another specific implementation step of step S430 in FIG. 4;

fig. 7 is a schematic flow chart of an automatic monitoring method for base station antenna coverage variation in another embodiment;

fig. 8 is a flowchart illustrating an automatic monitoring method for base station antenna coverage variation in another embodiment.

Wherein:

LID: latitude and longitude data AAD: attitude data

And SS: signal strength data DD: distance data

HD: hanging high data AD: azimuth data

ID: inclination data

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

In the network planning, optimization and maintenance work of mobile communication, the working state of the base station antenna and the engineering parameters of the antenna have decisive influence on the electromagnetic radiation performance of the base station, and directly influence the coverage and interference of the network.

In actual work, for a serious explicit problem, because an alarm is generated and is easy to be found, if an antenna is in a problem, a maintenance system has a standing-wave ratio alarm, a base station master device has a problem, and a corresponding master device alarm (such as a synthesizer and the like) is also generated. However, some hidden problems do not generate alarm, but also bring serious problem of field intensity coverage mutation, which affects network quality. For example, the signal strength is abnormal due to the aging of the antenna, and the signal strength is abnormal due to the inclination, the overturn and even the displacement of the mast of the antenna feeder tower.

These non-dominant problems can only be discovered through field inspection of the base station antenna or large-area network pulling test of network optimization testers.

The period of manual inspection and network pulling test needs at least one week, and the real-time performance is too low. In addition, the manual inspection mode has high cost and low efficiency, has the potential safety hazard of frequent ascending, and can also cause the situation that the house and the east are not matched and cannot go upstairs for measurement. Meanwhile, the level of skill of the patrol personnel is uneven, and even if the patrol personnel arrives at the site, the patrol personnel cannot find the problem, even if the patrol personnel arrives at the site, the patrol personnel can not distinguish the problem because each operator has an antenna on the tower mast.

Based on the above, the present application is intended to provide a solution to the above technical problem, which will be explained in detail in the following embodiments.

Please refer to fig. 1 and fig. 2. In fig. 1, 1 denotes a base station antenna coverage variation automatic monitoring system, 10 denotes an antenna parameter acquisition device, 20 denotes an operator network server, 30 denotes an antenna coverage variation monitoring device, LID denotes latitude and longitude data, AAD denotes attitude data, SS denotes signal intensity data, and DD denotes distance data. The automatic monitoring system 1 may include an antenna parameter collecting device 10, an operator network server 20 and an antenna coverage variation monitoring device. The antenna engineering parameter collecting device 10 may be a plurality of antenna engineering parameter collecting devices, and the antenna engineering parameter collecting devices are respectively and correspondingly arranged on one base station antenna (not shown) and are used for collecting engineering parameters of the corresponding base station antenna. In this embodiment, the collected engineering parameters of the base station antenna include, but are not limited to, pitch angle, azimuth angle, suspension height, and longitude and latitude data. These parameters have a decisive influence on the electromagnetic radiation performance of the base station antenna, directly affecting the coverage and interference of the network. Ensuring the normalization of these parameters can ensure the coverage and interference of the network, and at the same time, can reduce the complaints of the users.

Wherein the operator network server 20 is configured to provide signal strength data SS of the base station antenna operation and distance data DD of the user from the base station antenna.

The antenna coverage variation monitoring device 30 is respectively connected to the antenna parameter collecting device 10 and the operator network server 20 in a communication manner. Specifically, the communication connection between the antenna coverage variation monitoring device 30 and the antenna parameter collecting device 10 may be based on a mobile communication network, such as 2G and 4G. Correspondingly, referring to fig. 3, the antenna working parameter collecting device 10 is integrated with a data transmission module 130, the data transmission module 130 is integrated with a 2G and/or 4G module based on a mobile communication network, and the engineering parameters collected by the antenna working parameter collecting device 10 can be transmitted back to the antenna coverage variation monitoring device 30 through the module 130.

As mentioned above, the antenna coverage variation monitoring device 30 may be configured to receive the engineering parameters returned by the antenna engineering parameter collecting device 10, and determine whether the base station antenna is in coverage variation or not by combining the signal strength data SS and the distance data DD extracted from the operator network server 20. Specifically, the antenna coverage variation monitoring device 30 may receive the engineering parameters acquired by the plurality of antenna engineering parameter acquisition devices 10, and then process the engineering parameters respectively. Meanwhile, the base station antenna coverage variation type that the antenna coverage variation monitoring device 30 can determine according to the engineering parameters and by combining the signal strength data SS and the distance data DD extracted from the operator network server 20 includes: the base station antenna radiation performance is abnormal and the antenna is blocked. The specific steps for determining that the radiation performance of the base station antenna is abnormal and the antenna is blocked will be described in detail in the following embodiments of the method, which are not described herein again. In addition, the antenna coverage variation monitoring device 30 may further determine whether the base station antenna is displaced and whether the tilt angle value of the base station antenna is abnormal according to the longitude and latitude data and the tilt angle data in the engineering parameters, and the detailed determining method steps will be described in the following method embodiments. Further, when the antenna coverage variation monitoring device 30 judges that the base station antenna has the coverage variation, an alarm can be automatically given to prompt maintenance personnel to maintain the base station antenna in time, so that the emotion of the user is stabilized in time, and the use experience of the user is improved.

In this embodiment, the antenna coverage variation monitoring apparatus 30 may include a controller (not shown), various input/output (IO) circuits (not shown), a memory (not shown), various auxiliary circuits (not shown), an alarm module (not shown), and a display module (not shown). The controller may comprise, among other things, any type of Microcontroller or Microprocessor (MCU) known in the art, which is primarily used for the reception, processing of data and the generation of various signals, which may include control signals and alert signals. The warning signal may be a visual or audio based warning signal, which may be generated by means of a Light Emitting Diode (LED), a Liquid Crystal Display (LCD), an On-Screen Display (OSD), and other devices capable of Emitting a visual warning signal; the auditory warning signal can be preset voice information played through a voice output device. The warning module is used for receiving and responding the warning signal. The memory may be used to record and store the engineering parameters returned by the antenna parameter acquisition device 10 for the controller to query, and may include a random access memory, a read only memory, a cache memory, a magnetic read/write memory, or the like, or any combination of these memories. In addition, control instructions required by the controller may also be stored on the memory. The support circuits may include cache, power supplies, clock circuits, data registers, data transfers, and the like. The display module may include a graphical User Interface (UI) through which a user may interact with the antenna coverage variation monitoring apparatus 30.

Further, with continued reference to fig. 2, the antenna parameter acquisition apparatus 10 may include an antenna position acquisition module 110 and an antenna attitude acquisition module 120. The antenna position acquisition module 110 may be disposed on the base station antenna for acquiring latitude and longitude data LID of the base station antenna. Specifically, the antenna position acquisition module 110 may be a module with a GPS positioning function, which measures longitude and latitude data LID of the base station antenna by using a satellite positioning technology, and determines the position of the base station antenna according to the longitude and latitude data LID. It can be understood that the determination of the position of the base station antenna by the latitude data LID is not the focus of the present application, and the method may also refer to the prior art, which is not further described herein.

In one embodiment, referring to fig. 3, the antenna attitude acquisition module 120 of the present application may include an altitude acquisition module 122, an azimuth acquisition module 124, and an inclination acquisition module 126. The height acquisition module 122 is connected to the data transmission module 130, and is mainly used to acquire the hanging height data HD of the base station antenna. In particular, the hang height data HD may be computed in conjunction with a barometer and the aforementioned module with GPS positioning. Illustratively, the barometric pressure value of the reference position can be obtained through a barometer, the altitude information can be obtained through a module with GPS positioning, and finally the hanging height data HD of the base station antenna can be obtained through calculation according to the barometric pressure change. It can be understood that the calculation of the hitching height data HD by combining the barometer and the module with GPS positioning is not the focus of the present application, and the method may also refer to the prior art and will not be further described herein.

As mentioned above, the azimuth angle collecting module 124 is connected to the data transmission module 130, and is mainly used for collecting the azimuth angle data AD of the base station antenna. Specifically, the azimuth angle collecting module 124 may be an electronic compass, and the azimuth angle of the base station antenna is obtained through the electronic compass disposed on the base station antenna. The tilt angle acquisition module 126 is also connected to the data transmission module 130, and is mainly used for acquiring tilt angle data ID of the base station antenna. Specifically, the inclination angle collecting module 126 may be a three-axis gyroscope, and measures an inclination angle (pitch angle) of the base station antenna through the three-axis gyroscope disposed on the base station antenna. It can be understood that the method for obtaining the azimuth angle of the base station antenna through the electronic compass disposed on the base station antenna and measuring the inclination angle (pitch angle) of the base station antenna through the three-axis gyroscope disposed on the base station antenna is not the key point of the present application, and the method may also refer to the prior art, and is not further described herein. Based on the above, it can be determined that the data returned by the data transmission module 130 to the antenna coverage variation monitoring apparatus includes, but is not limited to: latitude and longitude data, pitch angle, azimuth angle and hanging height data.

In one embodiment, the automatic monitoring system 1 may further include a power supply module (not shown) electrically connected to the antenna parameter collecting device 10 for supplying power required by the antenna parameter collecting device 10. Specifically, the power supply module can supply power to the mains supply or the storage battery. The antenna parameter collecting device 10 includes an antenna position collecting module 110, an antenna attitude collecting module 120 and a data transmission module 130, and the antenna attitude collecting module 120 includes an altitude collecting module 122, an azimuth collecting module 124 and an inclination collecting module 126. Therefore, the power supply module can be set to provide the electric energy required by the operation of the modules.

Based on the same inventive concept, referring to fig. 4, the present application further provides an automatic monitoring method for base station antenna coverage variation, which is based on an automatic monitoring system for base station antenna coverage variation, and the monitoring system can assist understanding with reference to the automatic monitoring system 1 in fig. 1 to 3. The method may include steps S410-S430.

Step S410, acquiring engineering parameters of a base station antenna through the antenna engineering parameter acquisition device.

Step S420, extracting the signal strength data of the operation of the base station antenna and the distance data between the user and the base station antenna from the operator network server.

And step S430, the antenna coverage variation monitoring device judges whether the base station antenna covers variation or not according to the engineering parameters and by combining the signal intensity data and the distance data.

Specifically, the engineering parameters of the base station antenna include, but are not limited to, pitch angle, azimuth angle, elevation, and latitude and longitude data. These parameters have a decisive influence on the electromagnetic radiation performance of the base station, directly affecting the coverage and interference of the network.

In one embodiment, as an implementation, referring to fig. 5, the specific implementation of the step S430 may include the sub-steps of: S510-S540.

Step S510, calculating a signal intensity average value of the signal intensity data on the day of signal intensity data acquisition.

Step S520, obtaining a first deviation ratio of the signal strength average value according to the signal strength average value and a preset signal strength threshold.

In step S530, it is determined whether the first deviation ratio is greater than or equal to a first preset deviation ratio.

Step S540, in response to that the first deviation ratio is greater than or equal to the first preset deviation ratio and the engineering parameter is unchanged, determining that the radiation performance of the base station antenna is abnormal.

The radiation performance of the base station antenna is abnormal, and the reasons of the abnormal radiation performance may be gain, front-to-back ratio, standing wave ratio and the like of the antenna. In this specific embodiment, the signal strength average value is recorded as SSv, the preset signal strength threshold value is recorded as SSV, the preset signal strength threshold value may be set with reference to the signal strength average value of the previous week, the first preset deviation ratio may be set to 20%, and specifically, the formula for determining that the radiation performance of the base station antenna is abnormal may be represented as:

|(SSv—SSV)|/SSV>＝20％；

in addition, for the judgment that the engineering parameters are not changed, the following formula can be referred to:

l (EP-EPV) |/EPV ═ 1%; wherein, EP represents the engineering parameter value of the data acquisition day, and EPV represents the average value of the engineering parameter of the previous week.

In another embodiment, as an implementation, referring to fig. 6, the specific implementation of step S430 may further include the sub-steps of: S610-S640.

Step S610, calculating a distance data average value of the distance data on the current day of the distance data acquisition.

Step S620, obtaining a second deviation ratio of the distance data average value according to the distance data average value and a preset distance data threshold.

In step S630, it is determined whether the second deviation ratio is greater than or equal to a second preset deviation ratio.

Step S640, in response to that the second deviation ratio is greater than or equal to the second preset deviation ratio and the engineering parameter is unchanged, determining that the base station antenna is blocked.

The reason for the base station antenna being blocked is generally due to the blocking of the new building. In this specific embodiment, the average value of the distance data is recorded as DDv, the preset distance data threshold is recorded as DDV, the preset distance data threshold may be set with reference to the average value of the distance data of the previous week, the second preset deviation ratio is recorded as 30%, and specifically, the formula for determining that the base station antenna is blocked may be represented as:

|(DDv—DDV)|/DDV>＝30％；

in addition, for the judgment that the engineering parameters are unchanged, reference may be made to the description of the previous embodiment, which is not described herein again.

In one embodiment, referring to fig. 7, the automatic monitoring method of the present application may further include steps S710-S740.

Step S710, obtaining the position information of the base station antenna according to the longitude and latitude.

Step S720, obtaining an absolute value of a difference between the position information and a preset position information threshold.

Step S730, determine whether the absolute value is greater than or equal to a preset difference threshold.

Step S740, in response to the absolute value being greater than or equal to a preset difference threshold, determining that the base station antenna is shifted.

Specifically, the base station antenna displacement may be caused by typhoon, earthquake, or unstable displacement of tower members. In this application, can be said LM with positional information, preset positional information threshold can be said YLM, and preset difference threshold can be said YD, and the judgement formula that the base station antenna shifted can be:

l (LM-yl) | >, YD; wherein YD can be 1 m.

In one embodiment, referring to FIG. 8, the automatic monitoring method of the present application may further include steps S810-S840.

Step S810, judging whether the inclination angle value is more than or equal to a first preset inclination angle or less than or equal to a second preset inclination angle; wherein the first preset inclination angle is larger than the second preset inclination angle.

Step S820, in response to the tilt angle value being greater than or equal to the first preset tilt angle or less than or equal to the second preset tilt angle, determining that the tilt angle of the base station antenna is abnormal.

In this embodiment, the tilt angle of the base station antenna is defined as follows: the angle between the base station antenna and the plumb line. When the included angle is positive in the first quadrant, it is expressed as a downward inclination angle, and when the included angle is negative in the fourth quadrant, it is expressed as an upward elevation angle. The abnormal inclination angle of the base station antenna may be caused by typhoon, earthquake or unstable tower member, which may cause the antenna to fall off or overturn. In particular, the first preset inclination angle may be 20 ° and the second preset inclination angle may be-5 °.

In summary, according to the method and system for automatically monitoring the base station antenna coverage variation, the antenna engineering parameter acquisition device is arranged to acquire the engineering parameter of the base station antenna, the operator network server is arranged to provide the signal intensity data of the base station antenna operation and the distance data between the user and the base station antenna, and the antenna coverage variation monitoring device is arranged to judge whether the base station antenna has the coverage variation according to the returned engineering parameter and by combining the signal intensity data and the distance data extracted from the operator network server. On the one hand, the full-automatic monitoring and positioning of the base station antenna coverage variation can be realized, and on the other hand, because the antenna work parameter acquisition device and the antenna coverage variation monitoring device are in communication connection, and the antenna coverage variation monitoring device and an operator network server are in communication connection, the antenna coverage variation monitoring device can be ensured to accurately and timely find problems, an alarm is provided, and the influence on a network and a user is reduced to the maximum extent.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A kind of base station antenna covers the automatic monitoring system of the variation, characterized by, including the antenna worker's parameter gathering unit, operator's network server and antenna covers the variation monitoring device;

the antenna engineering parameter acquisition device is arranged on a base station antenna and is configured to acquire engineering parameters of the base station antenna;

the operator network server is configured to provide signal strength data of the base station antenna operation and distance data of a user from the base station antenna;

the antenna coverage variation monitoring device is respectively in communication connection with the antenna work parameter acquisition device and the operator network server, and is used for receiving the engineering parameters returned by the antenna work parameter acquisition device and judging whether the base station antenna is in coverage variation or not by combining the signal intensity data and the distance data extracted from the operator network server;

the antenna coverage variation monitoring device comprises a controller and a memory;

the memory is used for recording and storing the engineering parameters returned by the antenna engineering parameter acquisition device;

the controller is connected with the memory and used for inquiring the engineering parameters in the memory, and the controller is also used for receiving and processing data and generating various signals.

2. The automatic monitoring system of claim 1, wherein the antenna parameter acquisition device comprises an antenna position acquisition module and an antenna attitude acquisition module;

the antenna position acquisition module is arranged on the base station antenna and used for acquiring longitude and latitude data of the base station antenna;

the antenna attitude acquisition module is arranged on the base station antenna and used for acquiring attitude data of the base station antenna.

3. The automatic monitoring system of claim 2, wherein the antenna attitude acquisition module comprises an altitude acquisition module, an azimuth acquisition module, and an inclination acquisition module;

the height acquisition module is used for acquiring hanging height data of the base station antenna;

the azimuth angle acquisition module is used for acquiring azimuth angle data of the base station antenna;

the inclination angle acquisition module is used for acquiring inclination angle data of the base station antenna.

4. The automated monitoring system of claim 3, wherein the azimuth angle acquisition module is an electronic compass.

5. The automated monitoring system of claim 3, wherein the tilt angle acquisition module is a three-axis gyroscope.

6. The automated monitoring system of claim 1, wherein the antenna parameter acquisition device further comprises:

and the data transmission module is in communication connection with the antenna coverage variation monitoring device and is used for transmitting the engineering parameters acquired by the antenna work parameter acquisition device back to the antenna coverage variation monitoring device.

7. The automated monitoring system of claim 1, further comprising:

and the power supply module is electrically connected with the antenna work parameter acquisition device and used for providing electric energy required by work for the antenna work parameter acquisition device.

8. The automated monitoring system of claim 7, wherein the power module comprises a utility and/or a battery.

9. The automatic monitoring system according to any one of claims 1-8, wherein the coverage variation comprises an abnormal base station antenna radiation performance and/or a blocked base station antenna.

10. The automated monitoring system of any of claims 1-8, wherein the engineering parameters are collected at a granularity of once a day; the granularity of acquisition of the signal strength data and the distance data is once per hour.

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