CN112950005A - Shared iron tower site selection method, system, site selection device and readable storage medium - Google Patents

Abstract

The invention discloses a shared iron tower site selection method, a shared iron tower site selection system, a site selection device and a readable storage medium, and belongs to the technical field of iron towers. The method comprises the following steps: identifying a shared iron tower in a first area indicated by a user, and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower; detecting an electromagnetic radiation parameter of the first area; establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, wherein the radiation model is used for describing the electromagnetic radiation distribution condition of the shared iron tower; establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located; and according to the site selection parameters input by the user, site selection is carried out in the second area on the basis of the site selection model, and at least one available address for establishing the shared iron tower is output and displayed. The shared iron tower site selection is carried out through the site selection model, the problems of poor accuracy and poor reliability caused by manual site selection are solved, and the labor cost is further saved.

Description

Shared iron tower site selection method, system, site selection device and readable storage medium

Technical Field

The invention relates to the technical field of iron towers, in particular to a shared iron tower site selection method, a shared iron tower site selection system, a site selection device and a readable storage medium.

Background

With the initial popularization of the feasibility of the iron tower sharing technology, more and more base stations are installed on the same shared iron tower to fully utilize the iron tower resources, and the site selection of the shared iron tower is more and more important;

in the prior art, site selection is performed manually based on experience and requirements on the basis of physical exploration, so that the site selection requirement of a shared iron tower is met.

However, due to the difference in experience of site selection personnel, when site selection of the shared iron tower is achieved through manual selection, not only is a large amount of manpower consumed, but also accuracy and reliability are poor.

Disclosure of Invention

In order to solve the problems in the prior art, the invention provides a shared iron tower site selection method, a shared iron tower site selection system, a site selection device and a readable storage medium. The technical scheme is as follows:

in a first aspect, a shared iron tower site selection method is provided, where the method includes:

identifying a shared iron tower in a first area indicated by a user, and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

detecting an electromagnetic radiation parameter of the first region;

establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, wherein the radiation model is used for describing the electromagnetic radiation distribution condition of the shared iron tower;

establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

and according to the address selection parameters input by the user, on the basis of the address selection model, address selection is carried out in the second area, and at least one available address for establishing the shared iron tower is output and displayed.

Optionally, the identifying the shared iron tower in the first area indicated by the user, and the obtaining the iron tower parameters of the shared iron tower includes:

identifying a first area selected by a user on a map interface;

acquiring and displaying all shared iron towers in the first area;

and obtaining iron tower parameters of all the shared iron towers, wherein the iron tower parameters comprise the voltage grade of the shared iron tower, and the installation height, the installation depression angle, the installation direction and the transmission power of a base station installed on the shared iron tower.

Optionally, the detecting the electromagnetic radiation parameter of the first area includes:

acquiring a plurality of electromagnetic measurement values respectively sent by a plurality of monitoring devices located in the first area;

acquiring the positions of the plurality of monitoring devices;

and calculating the electromagnetic radiation parameters of the first area according to the plurality of electromagnetic measurement values and the position of the corresponding monitoring device.

Optionally, the establishing a radiation model corresponding to the shared iron tower according to the environmental parameter and the iron tower parameter includes:

acquiring a plurality of voltage grades, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of emission powers, and a plurality of electromagnetic radiation parameters corresponding to the voltage grades, the installation heights, the installation depression angles, the installation directions and the emission powers respectively;

obtaining a corresponding relationship among the plurality of voltage levels, the plurality of electromagnetic radiation parameters, the plurality of mounting heights, the plurality of mounting depression angles, the plurality of mounting directions and the plurality of transmission powers;

and generating the radiation model according to the corresponding relation.

Optionally, the establishing, according to the radiation model and the geographic parameter of the second area where the user is located, an address selection model corresponding to the second area includes:

acquiring the geographic parameters according to the map data;

adjusting the corresponding relation according to the geographic parameter;

and establishing the address selection model according to the adjusted corresponding relation.

Optionally, the selecting the address in the second area based on the address model according to the address parameter input by the user, and outputting and displaying at least one available address for establishing the shared iron tower includes:

acquiring an address selection parameter input by a user, wherein the address selection parameter is used for describing a shared iron tower to be installed and a base station to be installed;

inputting the addressing parameters into the addressing model, addressing in the second area, outputting and displaying at least one available address for establishing a shared iron tower in the second area;

and outputting and displaying the installation suggestion of the base station to be installed.

Optionally, after the address selection is performed according to the address selection model, the method further includes:

after the user selects the available address from the at least one available address, acquiring the position of the user;

generating navigation information according to the position of the user and the available address;

and displaying the navigation information.

In a second aspect, a shared iron tower site selection device is provided, the device including:

the identification module is used for identifying a shared iron tower in a first area indicated by a user and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

the detection module is used for detecting the electromagnetic radiation parameters of the first area;

the processing module is used for establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, and the radiation model is used for describing the electromagnetic radiation quantity distribution condition of the shared iron tower;

the processing module is further used for establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

and the address selecting module is used for selecting an address in the second area on the basis of the address selecting model according to the address selecting parameters input by the user, and outputting and displaying at least one available address for establishing the shared iron tower.

In a third aspect, a shared iron tower site selection system is provided, where the system includes a shared iron tower located in a first area, a site selection device, a plurality of detection devices, and a handheld terminal of a user; wherein the content of the first and second substances,

the handheld terminal is used for acquiring a first area input by a user;

the addressing device is used for identifying a shared iron tower in a first area indicated by a user and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

the detection devices are respectively used for detecting a plurality of electromagnetic measurement values of the positions;

the addressing device is also used for detecting the electromagnetic radiation parameters of the first area by the plurality of electromagnetic measurement values;

the addressing equipment is also used for establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, and the radiation model is used for describing the electromagnetic radiation quantity distribution condition of the shared iron tower;

the addressing equipment is also used for establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

the handheld terminal is used for acquiring address selection parameters input by a user;

the addressing device is used for addressing in the second area on the basis of the addressing model according to the addressing parameters and outputting at least one available address for establishing a shared iron tower;

the handheld terminal is used for displaying the at least one available address used for establishing the shared iron tower.

In a fourth aspect, there is provided a readable storage medium storing a computer program executable by a processor and implementing the method of any of the first aspects.

The embodiment of the invention provides a shared iron tower site selection method, a system, a site selection device and a readable storage medium, wherein the method comprises the following steps: identifying a shared iron tower in a first area indicated by a user, and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower; detecting an electromagnetic radiation parameter of the first area; establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, wherein the radiation model is used for describing the electromagnetic radiation distribution condition of the shared iron tower; establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located; and according to the site selection parameters input by the user, site selection is carried out in the second area on the basis of the site selection model, and at least one available address for establishing the shared iron tower is output and displayed.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

the site selection is carried out through the site selection model, the problems of poor accuracy and poor reliability caused by manual site selection are solved, and the labor cost is further saved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a flowchart of a shared iron tower site selection method according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a shared iron tower site selection system according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a shared iron tower address selection device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

The embodiment of the invention provides a shared iron tower site selection method, which comprises the following steps of:

101. identifying a shared iron tower in a first area indicated by a user, and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower.

102. A parameter of the electromagnetic radiation of the first region is detected.

103. And establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, wherein the radiation model is used for describing the electromagnetic radiation distribution condition of the shared iron tower.

104. And establishing an addressing model corresponding to the second area according to the radiation model and the geographic parameters of the second area where the user is located.

105. And according to the site selection parameters input by the user, site selection is carried out in the second area on the basis of the site selection model, and at least one available address for establishing the shared iron tower is output and displayed.

Optionally, the process in step 101 may specifically be:

201. a first area selected by a user on a map interface is identified.

Specifically, a map interface is displayed on a handheld terminal of a user;

the method includes the steps that a first area input by a user through a gesture on a map interface is obtained, and the gesture is at least a closed area formed by the user through finger sliding on the map interface.

Optionally, in order to facilitate the use of the user, a first area input by the user through voice may be acquired; the voice input by the user at least comprises a position and a range; the first region is a region formed by the position and the range;

for example, the user may input at least three positions and indicate that the first position is a region formed by the three positions, and then the first region is a geometric region formed by the at least three positions; the user can input a position and a radius, and the first area is a circular area formed by taking the position as a center and taking the radius as a circle center.

Optionally, when the first area and the second area are similar, the address selection model formed according to the first area is more accurate when the address selection is performed in the second area, so as to further facilitate the user selection and improve the efficiency and accuracy of the address selection, the process in step 101 may further be:

obtaining description parameters of a second area, wherein the description parameters comprise the number of active devices connected with a base station in the second area and terrain parameters of the second area; the terrain parameters can be area, gradient, slope direction and surface curvature; the acquisition mode may be realized by a terrain parameter pre-stored in the system, and the specific acquisition mode of the pre-selected and stored terrain parameter in the system is not limited in the present invention.

Acquiring at least one available first area with the description parameters similar to those of the second area;

the handheld terminal of the user displays the at least one available first area on a map interface;

after the user selects one of the at least one available first area through the gesture, the available first area selected by the user is confirmed as the first area.

The above-mentioned parameter similar to the description parameter may specifically satisfy the following condition:

the area is the same as that of the second region;

the difference value between the number of the active devices connected with the base station and the number of the active devices in the second area is smaller than or equal to a preset value; the embodiment of the invention does not limit the preset value;

the terrain parameters are the same as the second area.

202. And acquiring and displaying all shared iron towers in the first area.

Specifically, all iron towers with positions in the first area are obtained; the process can be realized by identifying or searching the position of the shared iron tower stored in the system in advance, and the embodiment of the invention does not limit the specific identification mode or searching mode;

acquiring the identifiers of all the shared iron towers, wherein the identifiers can be numbers or names;

and displaying the identifications of all the sharing towers and all the sharing special towers on a map interface of the handheld terminal.

Optionally, in order to further facilitate the use of the user and improve the accuracy and efficiency of address selection, after step 202, the following steps may be further performed:

acquiring an operation instruction input by a user on a map interface, wherein the operation instruction is used for selecting at least one shared iron tower from all shared iron towers; the operation instruction can be a gesture input by a user;

and executing the operation corresponding to the operation instruction, and displaying at least one shared iron tower selected by the user on a map interface after the operation instruction is executed.

203. And obtaining iron tower parameters of all shared iron towers, wherein the iron tower parameters comprise the voltage grade of the shared iron tower, and the installation height, the installation depression angle, the installation direction and the transmitting power of a base station installed on the shared iron tower.

Specifically, the installation height may be a height of the base station relative to the shared iron tower base; the mounting depression angle is specifically a depression angle of the base station antenna; the mounting direction is specifically the direction of the base station antenna;

the acquiring process in step 203 may be:

according to the identifiers of all the shared iron towers obtained in step 202, iron tower parameters stored in advance are searched from the system, and the specific searching mode is not limited in the embodiment of the invention.

Optionally, in order to further improve the accuracy of the shared iron tower site selection, in addition to the iron tower parameters in step 203, operation and maintenance parameters of the shared iron tower may be obtained, where the operation and maintenance parameters are used to indicate an operation and maintenance mode of the iron tower; illustratively, the operation and maintenance parameters include equipment parameters collected in the operation and maintenance process, an operation and maintenance server, and a maintenance mode of equipment failure (such as online restart or offline maintenance).

Optionally, the process in step 102 may specifically be:

301. and acquiring a plurality of electromagnetic measurement values respectively transmitted by a plurality of monitoring devices positioned in the first area.

Specifically, the plurality of monitoring devices may be pre-installed, and after installation, establish communication connection with the site selection device, respectively, and after establishing communication connection, send the measured electromagnetic measurement value to the site selection device in real time; the monitoring device at least comprises an electromagnetic radiation measuring instrument, a GPS positioning module or a Beidou positioning module and an antenna assembly used for sending electromagnetic measurement values.

Optionally, in order to further improve the accuracy of the electromagnetic radiation parameters, the process of installing the plurality of monitoring devices may be:

acquiring an electromagnetic radiation range of a base station according to iron tower parameters, wherein the radiation range comprises an electromagnetic radiation direction and an electromagnetic radiation effective distance;

acquiring a plurality of mounting positions in the radiation range according to the topographic parameters; the mounting position at least satisfies the following condition: the slope is smaller than a preset slope value, and the surface curvature is smaller than a preset curvature value;

displaying the plurality of mounting locations on the handheld terminal;

and generating and displaying navigation information according to the position of the user and the plurality of installation positions.

302. The locations of a plurality of monitoring devices are obtained.

Specifically, the positions of the plurality of monitoring devices may be located by the GPS module or the beidou module after the installation is completed, and the positions are sent to the addressing device.

303. And calculating the electromagnetic radiation parameter of the first area according to the plurality of electromagnetic measurement values and the position of the corresponding monitoring device.

Specifically, the electromagnetic radiation intensity of the signal of the base station at different positions is obtained according to the distance between the monitoring device and the base station and the position corresponding to the monitoring device;

and calculating an electromagnetic radiation parameter of the first area according to the radiation intensity of the signal of the base station at different positions, wherein the electromagnetic radiation parameter is used for indicating the relation between the electromagnetic radiation intensity and the position in the first area.

Optionally, the process in step 103 may specifically be:

401. and acquiring a plurality of voltage grades, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of transmitting powers, and a plurality of electromagnetic radiation parameters corresponding to the installation heights, the installation depression angles, the installation directions and the transmitting powers respectively.

Specifically, the steps may be:

setting a plurality of groups of debugging parameters, wherein the debugging parameters comprise voltage level, installation height, installation depression angle, installation direction and transmitting power; for any one group, the process described in step 102 is executed, the electromagnetic radiation parameters corresponding to the group of debugging parameters are obtained, and the process described in step 102 is continuously executed for the next group until the processes described in step 102 are all executed by the plurality of groups of debugging parameters, and the electromagnetic radiation parameters are obtained.

402. Obtaining corresponding relations among a plurality of voltage levels, a plurality of electromagnetic radiation parameters, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of transmitting powers.

Specifically, acquiring a corresponding relation between the voltage grade and the electromagnetic radiation parameter; the corresponding relation reflects the change of the electromagnetic radiation parameter along with the voltage grade, and the corresponding relation can be a first function of the voltage grade and the electromagnetic radiation parameter;

acquiring a corresponding relation between the installation height and electromagnetic radiation parameters; the corresponding relation reflects the change of electromagnetic radiation parameters along with the installation height; the correspondence may be a second function of the mounting height and the electromagnetic radiation parameter;

acquiring a corresponding relation between an installation depression angle and an electromagnetic radiation parameter; the corresponding relation reflects the change of the electromagnetic radiation parameters along with the installation depression angle; the correspondence may be a third function between the installation dip angle and the electromagnetic radiation parameter;

acquiring a corresponding relation between the installation direction and electromagnetic radiation parameters; the corresponding relation reflects the change of the electromagnetic radiation parameters along with the installation direction; the corresponding relationship may be a fourth function of the installation direction and the electromagnetic radiation parameter;

acquiring a corresponding relation between the emission power and the electromagnetic radiation parameters; the corresponding relation reflects the change of the electromagnetic radiation parameters along with the emission power; the correspondence may be a fifth function of the emitted power and the electromagnetic radiation parameter.

Optionally, in order to further reflect the influence of the voltage level, the installation height, the installation depression angle, the installation direction, and the transmission power on the addressing, after step 402, the following steps may be further performed:

obtaining a curve between the voltage grade and the electromagnetic radiation parameter and the slope of the curve according to a first function between the voltage grade and the electromagnetic radiation parameter;

obtaining a curve between the installation height and the electromagnetic radiation parameter and the slope of the curve according to a second function between the installation height and the electromagnetic radiation parameter;

obtaining a curve between the installation depression angle and the electromagnetic radiation parameter and the slope of the curve according to a third function between the installation depression angle and the electromagnetic radiation parameter;

obtaining a curve between the installation direction and the electromagnetic radiation parameters and the slope of the curve according to a fourth function between the installation direction and the electromagnetic radiation parameters;

obtaining a curve between the transmission power and the electromagnetic radiation parameter and the slope of the curve according to a fifth function between the transmission power and the electromagnetic radiation parameter;

the above-described slope is set as a duty factor.

403. And generating a radiation model according to the corresponding relation.

Specifically, the radiation model at least comprises a corresponding relation between a voltage level and an electromagnetic radiation parameter;

the corresponding relation between the installation height and the electromagnetic radiation parameters;

the corresponding relation between the installation depression angle and the electromagnetic radiation parameters;

the corresponding relation between the installation direction and the electromagnetic radiation parameters;

a correspondence between the emitted power and the electromagnetic radiation parameter.

Optionally, the radiation model further includes:

the resulting scaling factor of the optional step of step 402.

Optionally, the process in step 104 may specifically be:

501. and acquiring the geographic parameters according to the map data.

Specifically, the geographic parameter is a height of the shared iron tower relative to a plane of an area where the shared iron tower is located, and in practical application, for convenience of calculation, the geographic parameter may be a sum of the height of the shared iron tower and an altitude of a position where the shared iron tower is located;

wherein, the altitude of the position of the shared iron tower is obtained by map data.

502. And adjusting the corresponding relation according to the geographic parameters.

Specifically, a plurality of geographic parameters and a plurality of corresponding electromagnetic radiation parameters are obtained; the corresponding relation reflects the change of the electromagnetic radiation parameters along with the geographic parameters;

and acquiring a corresponding relation between the geographic parameter and the electromagnetic radiation parameter, wherein the corresponding relation can be a sixth function of the geographic parameter and the electromagnetic radiation parameter.

Optionally, in order to further reflect the influence of the geographic parameter on the site selection, the following steps may be further performed:

obtaining a curve between the geographic parameter and the electromagnetic radiation parameter and the slope of the curve according to a sixth function between the geographic parameter and the electromagnetic radiation parameter;

503. and establishing an address selection model according to the adjusted corresponding relation.

Specifically, the address model at least includes:

the input interface can input voltage level, installation height, installation depression angle, installation direction, transmitting power and geographic parameters;

the output interface can output the shared iron tower installation address;

the first function, the second function, the third function, the fourth function, the fifth function and the sixth function are included between the input and the output.

Setting a training sample, wherein the training sample comprises a voltage grade, an installation height, an installation depression angle, an installation direction, transmission power, geographic parameters and an expected installation address corresponding to the training sample;

and training the site selection model according to the training sample, wherein the training process can be realized by continuously adjusting coefficients contained in the first function, the second function, the third function, the fourth function, the fifth function and the sixth function.

Optionally, in addition to the first function, the second function, the third function, the fourth function, the fifth function, and the sixth function, the method may further include:

the resulting scaling factor of the optional step of step 402.

The above training process may be:

and training the address selection model according to the training sample, wherein the training process can be realized by continuously adjusting coefficients contained in the first function, the second function, the third function, the fourth function, the fifth function and the sixth function, and the ratio coefficient.

Optionally, the process in step 105 may specifically be:

601. and acquiring site selection parameters input by a user, wherein the site selection parameters are used for describing the shared iron tower to be installed and the base station to be installed.

Specifically, the address selection parameters at least comprise voltage grade, installation height, installation depression angle, installation direction, transmission power and geographic parameters;

the input process may be implemented on a handheld terminal, and the specific input mode is not limited in the embodiment of the present invention.

602. And inputting the site selection parameters into the site selection model, selecting the site in the second area, outputting and displaying at least one available address for establishing the shared iron tower in the second area.

603. And outputting and displaying the installation suggestion of the base station to be installed.

Optionally, the installation proposal is an optimal address, and the optimal address can be obtained by calculating the cost on different available addresses, wherein the cost comprises the material transportation cost and the distance from the operation and maintenance.

Optionally, after step 105, the method further includes:

106. and after the user selects the available address from the at least one available address, acquiring the position of the user.

Specifically, the location of the user may be implemented by a positioning module of the handheld terminal.

107. And generating navigation information according to the position of the user and the available address.

108. And displaying the navigation information.

Example two

An embodiment of the present invention provides a shared iron tower site selection device 2, and as shown in fig. 2, the device 2 includes:

the identification module 21 is configured to identify a shared iron tower in a first area indicated by a user, and acquire an iron tower parameter of the shared iron tower, where the iron tower parameter is used to describe the shared iron tower;

a detection module 22 for detecting an electromagnetic radiation parameter of the first area;

the processing module 23 is configured to establish a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, where the radiation model is used to describe the electromagnetic radiation distribution of the shared iron tower;

the processing module 24 is further configured to establish an addressing model corresponding to a second area according to the radiation model and the geographic parameter of the second area where the user is located;

and the address selecting module 25 is used for selecting an address in the second area on the basis of the address selecting model according to the address selecting parameters input by the user, and outputting and displaying at least one available address for establishing the shared iron tower.

Optionally, the identification module 21 is specifically configured to:

identifying a first area selected by a user on a map interface;

acquiring and displaying all shared iron towers in a first area;

and obtaining iron tower parameters of all shared iron towers, wherein the iron tower parameters comprise the voltage grade of the shared iron tower, and the installation height, the installation depression angle, the installation direction and the transmitting power of a base station installed on the shared iron tower.

Optionally, the detection module 22 is specifically configured to:

acquiring a plurality of electromagnetic measurement values respectively sent by a plurality of monitoring devices positioned in a first area;

acquiring the positions of a plurality of monitoring devices;

and calculating the electromagnetic radiation parameter of the first area according to the plurality of electromagnetic measurement values and the position of the corresponding monitoring device.

Optionally, the processing module 24 is specifically configured to:

acquiring a plurality of voltage grades, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of emission powers, and a plurality of electromagnetic radiation parameters corresponding to the voltage grades, the installation heights, the installation depression angles, the installation directions and the emission powers respectively;

acquiring corresponding relations among a plurality of voltage grades, a plurality of electromagnetic radiation parameters, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of transmitting powers;

and generating a radiation model according to the corresponding relation.

Optionally, the processing module 24 is specifically configured to:

acquiring geographic parameters according to the map data;

adjusting the corresponding relation according to the geographic parameters;

and establishing an address selection model according to the adjusted corresponding relation.

Optionally, the address selecting module 25 is specifically configured to:

acquiring an address selection parameter input by a user, wherein the address selection parameter is used for describing a shared iron tower to be installed and a base station to be installed;

inputting the site selection parameters into a site selection model, selecting a site in a second area, outputting and displaying at least one available address for establishing a shared iron tower in the second area;

and outputting and displaying the installation suggestion of the base station to be installed.

Optionally, the address selecting module 25 is further configured to:

after a user selects an available address from at least one available address, acquiring the position of the user;

generating navigation information according to the position of the user and the available address;

and displaying the navigation information.

EXAMPLE III

The embodiment of the invention provides a shared iron tower site selection system, which is shown in fig. 3 and comprises a shared iron tower 31, site selection equipment 32, a plurality of detection devices 33 and a handheld terminal 34 of a user, wherein the shared iron tower 31, the site selection equipment 32 and the handheld terminal are positioned in a first area; wherein the content of the first and second substances,

the handheld terminal 34 is used for acquiring a first area input by a user;

the addressing device 32 is configured to identify a shared iron tower in a first area indicated by a user, and obtain an iron tower parameter of the shared iron tower, where the iron tower parameter is used to describe the shared iron tower;

the detection devices 33 are respectively used for detecting a plurality of electromagnetic measurement values of the positions;

the addressing device 32 is also used for detecting a plurality of electromagnetic measurement values and detecting an electromagnetic radiation parameter of the first area;

the addressing device 32 is further configured to establish a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, where the radiation model is used to describe the electromagnetic radiation distribution of the shared iron tower;

the addressing device 32 is further configured to establish an addressing model corresponding to the second area according to the radiation model and the geographic parameter of the second area where the user is located;

the handheld terminal 34 is used for acquiring address selection parameters input by a user;

the addressing device 32 is configured to perform addressing in the second area based on the addressing model according to the addressing parameters, and output at least one available address for establishing the shared iron tower;

the handheld terminal 34 is configured to display at least one available address for establishing a shared iron tower.

Alternatively to this, the first and second parts may,

the handheld terminal 34 is specifically configured to identify a first area selected by the user on the map interface;

the handheld terminal 34 is specifically configured to acquire and display all shared iron towers in the first area;

the addressing device 32 is specifically configured to obtain tower parameters of all shared towers, where the tower parameters include voltage levels of the shared towers, and installation heights, installation depression angles, installation directions, and transmission powers of base stations installed on the shared towers.

Optionally, the addressing device 32 is specifically configured to:

acquiring a plurality of electromagnetic measurement values respectively sent by a plurality of monitoring devices positioned in a first area;

acquiring the positions of a plurality of monitoring devices;

and calculating the electromagnetic radiation parameter of the first area according to the plurality of electromagnetic measurement values and the position of the corresponding monitoring device.

Optionally, the addressing device 32 is specifically configured to:

acquiring a plurality of voltage grades, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of emission powers, and a plurality of electromagnetic radiation parameters corresponding to the voltage grades, the installation heights, the installation depression angles, the installation directions and the emission powers respectively;

acquiring corresponding relations among a plurality of voltage grades, a plurality of electromagnetic radiation parameters, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of transmitting powers;

and generating a radiation model according to the corresponding relation.

Optionally, the addressing device 32 is specifically configured to:

acquiring geographic parameters according to the map data;

adjusting the corresponding relation according to the geographic parameters;

and establishing an address selection model according to the adjusted corresponding relation.

Alternatively to this, the first and second parts may,

the handheld terminal 34 is specifically configured to obtain an address selection parameter input by a user, where the address selection parameter is used to describe a shared iron tower to be installed and a base station to be installed;

the addressing device 32 is specifically configured to input addressing parameters into the addressing model, perform addressing in the second area, output and display at least one available address for establishing the shared iron tower in the second area;

the handheld terminal 34 is specifically configured to output and display an installation recommendation of a base station to be installed.

Optionally, the handheld terminal 34 is specifically configured to:

after a user selects an available address from at least one available address, acquiring the position of the user;

generating navigation information according to the position of the user and the available address;

and displaying the navigation information.

Example four

The embodiment of the invention provides a readable storage medium which stores a computer program capable of being executed by a processor and realizing the method of any one of the embodiment.

All the above-mentioned optional technical solutions can be combined arbitrarily to form the optional embodiments of the present invention, and are not described herein again.

It should be noted that: when the shared iron tower site selection device and the shared iron tower site selection system provided by the above embodiments execute the shared iron tower site selection method, only the division of the above functional modules is taken as an example, in practical application, the above function distribution can be completed by different functional modules according to needs, that is, the internal structures of the device and the system are divided into different functional modules, so as to complete all or part of the above described functions. In addition, the embodiments of the method, the device and the system for shared iron tower site selection provided by the embodiments belong to the same concept, and specific implementation processes thereof are described in the embodiments of the method for site selection, and are not described herein again.

It will be understood by those skilled in the art that all or part of the steps for implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, where the program may be stored in a computer-readable storage medium, and the above-mentioned storage medium may be a read-only memory, a magnetic disk or an optical disk, etc.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. A shared iron tower site selection method is characterized by comprising the following steps:

identifying a shared iron tower in a first area indicated by a user, and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

detecting an electromagnetic radiation parameter of the first region;

establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, wherein the radiation model is used for describing the electromagnetic radiation distribution condition of the shared iron tower;

establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

and according to the address selection parameters input by the user, on the basis of the address selection model, address selection is carried out in the second area, and at least one available address for establishing the shared iron tower is output and displayed.

2. The method of claim 1, wherein the identifying the shared iron tower of the first area indicated by the user and obtaining the iron tower parameters of the shared iron tower comprises:

identifying a first area selected by a user on a map interface;

acquiring and displaying all shared iron towers in the first area;

and obtaining iron tower parameters of all the shared iron towers, wherein the iron tower parameters comprise the voltage grade of the shared iron tower, and the installation height, the installation depression angle, the installation direction and the transmission power of a base station installed on the shared iron tower.

3. The method of claim 2, wherein said detecting an electromagnetic radiation parameter of said first region comprises:

acquiring a plurality of electromagnetic measurement values respectively sent by a plurality of monitoring devices located in the first area;

acquiring the positions of the plurality of monitoring devices;

and calculating the electromagnetic radiation parameters of the first area according to the plurality of electromagnetic measurement values and the position of the corresponding monitoring device.

4. The method according to claim 3, wherein the establishing a radiation model corresponding to the shared iron tower according to the environmental parameters and the iron tower parameters comprises:

acquiring a plurality of voltage grades, a plurality of installation heights, a plurality of installation depression angles, a plurality of installation directions and a plurality of emission powers, and a plurality of electromagnetic radiation parameters corresponding to the voltage grades, the installation heights, the installation depression angles, the installation directions and the emission powers respectively;

obtaining a corresponding relationship among the plurality of voltage levels, the plurality of electromagnetic radiation parameters, the plurality of mounting heights, the plurality of mounting depression angles, the plurality of mounting directions and the plurality of transmission powers;

and generating the radiation model according to the corresponding relation.

5. The method of claim 4, wherein the establishing an addressing model corresponding to a second area in which the user is located according to the radiation model and geographic parameters of the second area comprises:

acquiring the geographic parameters according to the map data;

adjusting the corresponding relation according to the geographic parameter;

and establishing the address selection model according to the adjusted corresponding relation.

6. The method of claim 5, wherein the step of performing site selection in the second area based on the site selection model according to the site selection parameters input by the user, and outputting and displaying at least one available address for establishing a shared iron tower comprises:

acquiring an address selection parameter input by a user, wherein the address selection parameter is used for describing a shared iron tower to be installed and a base station to be installed;

inputting the addressing parameters into the addressing model, addressing in the second area, outputting and displaying at least one available address for establishing a shared iron tower in the second area;

and outputting and displaying the installation suggestion of the base station to be installed.

7. The method of claim 6, wherein after the addressing according to the addressing model, the method further comprises:

after the user selects the available address from the at least one available address, acquiring the position of the user;

generating navigation information according to the position of the user and the available address;

and displaying the navigation information.

8. A shared iron tower site selection apparatus, the apparatus comprising:

the identification module is used for identifying a shared iron tower in a first area indicated by a user and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

the detection module is used for detecting the electromagnetic radiation parameters of the first area;

the processing module is used for establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, and the radiation model is used for describing the electromagnetic radiation quantity distribution condition of the shared iron tower;

the processing module is further used for establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

and the address selecting module is used for selecting an address in the second area on the basis of the address selecting model according to the address selecting parameters input by the user, and outputting and displaying at least one available address for establishing the shared iron tower.

9. A shared iron tower site selection system is characterized by comprising a shared iron tower, site selection equipment, a plurality of detection devices and a handheld terminal of a user, wherein the shared iron tower is positioned in a first area; wherein the content of the first and second substances,

the handheld terminal is used for acquiring a first area input by a user;

the addressing device is used for identifying a shared iron tower in a first area indicated by a user and acquiring iron tower parameters of the shared iron tower, wherein the iron tower parameters are used for describing the shared iron tower;

the detection devices are respectively used for detecting a plurality of electromagnetic measurement values of the positions;

the addressing device is also used for detecting the electromagnetic radiation parameters of the first area by the plurality of electromagnetic measurement values;

the addressing equipment is also used for establishing a radiation model corresponding to the shared iron tower according to the electromagnetic radiation parameters and the iron tower parameters, and the radiation model is used for describing the electromagnetic radiation quantity distribution condition of the shared iron tower;

the addressing equipment is also used for establishing an addressing model corresponding to a second area according to the radiation model and the geographic parameters of the second area where the user is located;

the handheld terminal is used for acquiring address selection parameters input by a user;

the addressing device is used for addressing in the second area on the basis of the addressing model according to the addressing parameters and outputting at least one available address for establishing a shared iron tower;

the handheld terminal is used for displaying the at least one available address used for establishing the shared iron tower.

10. A storage medium, characterized in that the readable storage medium stores a computer program which can be executed by a processor and implements the method of any of claims 1 to 7.

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