Disclosure of Invention
The embodiment of the invention provides a method and a device for presenting a network optimization scheme in multiple windows, which are used for solving the problems that in the prior art, a final analysis result cannot be obtained and the detection process is complex in the process of detecting the communication quality by using a network optimization tool.
The embodiment of the invention provides the following specific technical scheme:
in a first aspect, a method for a multi-window display network optimization scheme is provided, which includes:
calling the communication quality indexes of all the cells stored locally according to the communication quality index options input by a user on a GIS interface;
detecting a problem cell with communication quality problems from all the cells according to the communication quality index, and presenting the problem cell in a Geographic Information System (GIS) window of the GIS interface; and
and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and displaying the communication quality parameters and the network optimization scheme of the problem cell in the GIS chart area.
With reference to the first aspect, in a first possible implementation manner, a method for obtaining communication quality indicators of all cells includes: respectively acquiring communication quality indexes dynamically reported by each cell; or respectively sending a communication quality index acquisition instruction to each cell to acquire the communication quality index of each cell at the current moment.
With reference to the first possible implementation manner of the first aspect, in a second possible implementation manner, a communication quality parameter of at least one problem cell is obtained according to the communication quality index; sequencing the at least one problem cell according to the communication quality parameters, and presenting the sequenced at least one problem cell in a GIS window in a GIS interface of a geographic information system; acquiring a network optimization scheme of the at least one problem cell according to the communication quality parameters, and presenting the communication quality parameters of the at least one problem cell and the network optimization scheme in a GIS chart window in the GIS interface; the GIS interface at least comprises a GIS window and a GIS chart window.
With reference to the second possible implementation manner of the first aspect, in a third possible implementation manner, when it is detected that a user inputs at least two communication quality index options, each communication quality index corresponding to the at least two locally stored communication quality index options is respectively invoked; and in the GIS window, a sub-window is adopted to display corresponding to each communication quality index.
With reference to the first aspect, in a fourth possible implementation manner, when it is detected that a user selects a cell to be detected in a GIS window, acquiring a longitude and latitude of the cell to be detected; calling a communication quality index which is locally stored and corresponds to the longitude and latitude according to the longitude and latitude of the cell to be detected; and acquiring the communication quality parameters of the cell to be detected according to the communication quality index.
In a second aspect, an apparatus for a multi-window display network optimization scheme is provided, including:
the calling unit is used for calling the communication quality indexes of all the cells stored locally according to the communication quality index options input by a user on a Geographic Information System (GIS) interface;
the presentation unit is used for detecting a problem cell with a communication quality problem from all the cells according to the communication quality index and presenting the problem cell in a geographic information system window of the GIS interface; and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and displaying the communication quality parameters and the network optimization scheme of the problem cell in a graph area of the GIS.
With reference to the second aspect, in a first possible implementation manner, the method further includes a first obtaining unit, configured to: respectively acquiring communication quality indexes dynamically reported by each cell; or respectively sending a communication quality index acquisition instruction to each cell to acquire the communication quality index of each cell at the current moment.
With reference to the first possible implementation manner of the second aspect, in a second possible implementation manner, the presenting unit is specifically configured to: acquiring communication quality parameters of at least one problem cell according to the communication quality indexes; sequencing the at least one problem cell according to the communication quality parameters, and presenting the sequenced at least one problem cell in a GIS window in a GIS interface of a geographic information system; acquiring a network optimization scheme of the at least one problem cell according to the communication quality parameters, and presenting the communication quality parameters of the at least one problem cell and the network optimization scheme in a GIS chart window in the GIS interface; the GIS interface at least comprises a GIS window and a GIS chart window.
With reference to the second possible implementation manner of the second aspect, in a third possible implementation manner, the presenting unit is further configured to: when detecting that a user inputs at least two communication quality index options, respectively calling each communication quality index corresponding to the at least two communication quality index options stored locally; and in the GIS window, a sub-window is adopted to display corresponding to each communication quality index.
With reference to the second aspect, in a fourth possible implementation manner, the method further includes a second obtaining unit, configured to: when detecting that a user selects a cell to be detected in a GIS window, acquiring the longitude and latitude of the cell to be detected; calling a communication quality index which is locally stored and corresponds to the longitude and latitude according to the longitude and latitude of the cell to be detected; and acquiring the communication quality parameters of the cell to be detected according to the communication quality index.
In the embodiment of the invention, after a geographic information system tool detects a communication quality index option input by a user, the communication quality indexes of all local stored cells are called; and according to the communication quality index, acquiring a problem cell with a communication quality problem, and respectively presenting the problem cell and a network optimization scheme for the problem cell in corresponding windows of a GIS interface. By adopting the technical scheme of the invention, the geographic information system tool can perform whole network analysis according to the communication quality index input by the user, and the problem cells and the network optimization scheme obtained by analysis are respectively displayed in different windows, the detection process is convenient and quick, and the network optimization scheme does not need to be given by a worker according to related parameters, thereby avoiding misjudgment of manual operation and improving the accuracy of the network optimization scheme.
Detailed Description
The method and the device aim to solve the problems that in the prior art, the final analysis result cannot be obtained and the detection process is complex in the process of detecting the communication quality by using a network optimization tool. In the embodiment of the invention, after a geographic information system tool detects a communication quality index option input by a user, the communication quality indexes of all local stored cells are called; and according to the communication quality index, acquiring a problem cell with a communication quality problem, and respectively presenting the problem cell and a network optimization scheme for the problem cell in corresponding windows of a GIS interface. By adopting the technical scheme of the invention, the geographic information system tool can perform whole network analysis according to the communication quality index input by the user, and the problem cells and the network optimization scheme obtained by analysis are respectively displayed in different windows, the detection process is convenient and quick, and the network optimization scheme does not need to be given by a worker according to related parameters, thereby avoiding misjudgment of manual operation and improving the accuracy of the network optimization scheme.
Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
Referring to fig. 8, in the embodiment of the present invention, a detailed flow of a multi-window presentation network optimization scheme is as follows:
step 800: and calling the communication quality indexes of all the cells stored locally according to the communication quality index options input by the user on the GIS interface.
In the embodiment of the present invention, the communication quality indexes of all cells locally stored by the geographic information system may be obtained by dynamically reporting each cell, or may be obtained by obtaining in real time, that is, after the geographic information system detects a communication quality index option input by a user, a communication quality index obtaining instruction corresponding to the communication quality index option is sent to each cell, so as to obtain a real-time communication quality index of each cell at the current time. The communication quality index options include a pilot index option, a traffic index option, and the like.
Optionally, before the communication quality index option input by the user on the GIS interface, the geographic information system tool presents the window number option in the GIS interface, and prompts the user to select the number of sub-windows presented on the GIS window as required. For example, if the gis tool detects that the number of sub-windows input by the user is 1, the gis interface only presents one sub-window, as shown in fig. 9 a; if the geographic information system tool detects that the number of the sub-windows input by the user is 2, dividing the GIS window, and presenting two sub-windows, as shown in fig. 9 b; if the geographic information system tool detects that the number of the sub-windows input by the user is 3, dividing the GIS window, and presenting three sub-windows, as shown in fig. 9 c; if the GIS tool detects that the number of the sub-windows input by the user is 4, dividing the GIS window and presenting four sub-windows, as shown in FIG. 9 d. In a specific application scenario, the geographic information system tool presents 1 to 4 sub-windows in the GIS window according to the user instruction, as shown in fig. 10a to 10 d.
Step 810: and detecting the problem cell with the communication quality problem from all the cells according to the communication quality index, and displaying the problem cell in a GIS window of a GIS interface.
In the embodiment of the present invention, after the geographic information system tool obtains the communication quality index, the geographic information system tool obtains the communication quality parameter of each cell according to the communication quality index, and selects a problem cell having a problem of communication quality from all cells according to the communication quality parameter. Among them, there are communication quality problems including a call drop problem, a slow data transmission speed, and the like, which are related to the communication quality.
Further, the geographic information system tool presents the selected problem cell in a GIS window; when the number of the communication quality index options input by the user is at least two, each communication quality index is divided into a plurality of sub-windows in the GIS window, and each communication quality index corresponds to one sub-window. A GIS interface of the geographic information system tool at least includes a GIS window and a GIS chart window, the GIS window is used for presenting the position of the problem cell in a map including all cells, and the GIS chart window is used for presenting the communication quality parameter and the network optimization scheme of the selected problem cell, as shown in fig. 11. Wherein the communication quality parameter corresponds to the communication quality indicator.
Step 820: and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and displaying the acquired communication quality parameters and the network optimization scheme of the problem cell in a graph area of the GIS.
In the embodiment of the invention, the geographic information system tool acquires the communication quality parameters of one problem cell or at least two problem cells according to the communication quality index. The method comprises the steps that a geographic information system tool obtains communication quality parameters of a problem cell, namely, according to the communication quality parameters, a preset algorithm is adopted to obtain the reason of the problem cell with the communication quality problem, and a network optimization scheme is obtained and presented in a GIS icon window; when a geographic information system tool acquires communication quality parameters of at least two problem cells, sequencing the at least two problem cells according to the communication quality parameters, and displaying the sequenced at least two problem cells in a GIS window in a GIS interface of the geographic information system; and acquiring a network optimization scheme of at least one problem cell according to the communication quality parameters, presenting the communication quality parameters and the network optimization scheme of the at least two problem cells in a GIS graph window adjacent to the GIS window in a GIS interface, or locally storing the communication quality parameters and the network optimization scheme of the at least two problem cells, and presenting the communication quality parameters and the network optimization scheme of the problem cell selected by the user only in the GIS graph window when detecting that the user selects any problem cell.
Further, when the geographic information system detects that the user inputs at least two communication quality index options, each communication quality index corresponding to the at least two locally stored communication quality index options is respectively called; and presenting each communication quality index through a sub-window in the GIS window. For example, the communication quality indicator includes a pilot indicator and a traffic indicator.
Optionally, after the geographic information system tool detects that the user selects the problem cell, the notification quality parameter and the network optimization scheme of the problem cell are presented in the GIS window in the form of bubbles.
Specially, if the user specifies the cell to be detected in the GIS window, the geographic information system tool obtains the longitude and latitude of the cell to be detected after the user selects the cell to be detected in the GIS window; calling a communication quality index which is locally stored and corresponds to the longitude and the latitude according to the longitude and the latitude of the cell to be detected; acquiring communication quality parameters of the cell to be detected according to the communication quality indexes; and acquiring a network optimization scheme of the cell to be detected and presenting the network optimization scheme in the GIS icon area by adopting a preset algorithm according to the communication quality parameters of the cell to be detected. Optionally, the geographic information system tool obtains a communication quality index corresponding to the longitude and latitude through the longitude and latitude of the cell to be detected input by the user; or, the geographic information system selects a cell to be detected from all cell maps displayed on the GIS window, detects a selection indication of a user in the GIS window, acquires the longitude and latitude of the cell to be detected according to the grid position of the selection indication and the grid position, and determines a communication quality index corresponding to the longitude and latitude.
Optionally, the mapping relationship table of the longitude and latitude and the communication quality index is locally stored, and when the user selects the cell to be detected, the geographic information system tool obtains the communication quality index corresponding to the longitude and latitude of the cell to be detected from the geographic mapping relationship table.
Based on the technical scheme, the process of presenting the network optimization scheme in multiple windows is described in detail below in combination with a specific application scenario.
Application scenario one
In the embodiment of the present invention, taking the cell to be detected selected by the user as an example, referring to fig. 12, the process of presenting the network optimization scheme in multiple windows is as follows:
step 1200: and acquiring the longitude and latitude of the cell to be detected according to the cell to be detected input by a user on the GIS interface.
In the embodiment of the present invention, after the geographic information system tool presents the instruction according to the multi-window selected by the user in the GIS interface, the interface as shown in fig. 13 is presented. Optionally, a to-be-detected cell input box is presented in the GIS window, and a user can input the longitude and latitude of the to-be-detected cell in the to-be-detected cell input box, or the user inputs identification information of the to-be-detected cell in the to-be-detected cell input box, and the geographic information system tool obtains the locally-stored longitude and latitude of the to-be-detected cell through the identification information, wherein the identification information is name identification information or cell number identification information; or, all the cells are presented in a GIS window in a map form, a user can select a cell to be detected in the map, the map in the GIS window is presented in a grid form, and after the geographic information system tool detects a selection instruction of the user, the grid position of the selection instruction in the map is obtained, and the latitude and longitude corresponding to the grid position stored locally are obtained, wherein the latitude and longitude is the latitude and longitude of the cell to be detected.
Step 1210: and calling the locally stored communication quality index of the cell to be detected according to the communication quality index option input by the user.
In the embodiment of the invention, the geographic information system tool acquires the locally stored communication quality index of the cell to be detected according to the communication instruction index options input by the user and the longitude and latitude of the cell to be detected.
Step 1220: and acquiring the communication quality parameters of the cell to be detected and the network optimization scheme of the cell to be detected according to the communication quality index, and displaying the acquired communication quality parameters and the network optimization scheme of the cell to be detected in a graph area of a GIS.
In the embodiment of the invention, the geographic information system tool acquires the communication quality parameters of the cell to be detected and a network optimization scheme by adopting a preset algorithm according to the acquired communication quality index. And presenting the GIS chart in a GIS chart window process. Optionally, after the geographic information system tool detects that the cell to be detected is selected by the user, the communication quality parameter and the network optimization scheme of the cell to be detected are presented in the form of bubbles, as shown in fig. 14.
Application scenario two
In the embodiment of the present invention, taking the example that the user does not select the cell to be detected and the geographic information system tool performs the detection of all cells in the whole network, referring to fig. 15, the process of presenting the network optimization scheme in multiple windows is as follows:
step 1500: and receiving a full-network analysis instruction input by a user.
Referring to fig. 16, in the embodiment of the present invention, a region option may be included in the GIS interface, and a user inputs a region to be detected in the region option.
Step 1510: and acquiring the communication quality indexes of all the cells stored locally according to the whole network analysis instruction and the communication quality index options input by the user.
Step 1520: and respectively adopting a preset algorithm according to the communication quality index of each cell to obtain the communication quality parameter of each problem cell, sequencing the problem cells according to the communication quality parameter, and obtaining the network optimization scheme of each problem cell.
Referring to fig. 17, in the embodiment of the present invention, the problem cells are ranked according to each communication quality parameter of the problem cells according to the communication quality parameters. For example, if two communication quality parameters are included, which are communication quality parameter 1 and communication quality parameter 2, all problem cells are sorted according to communication quality parameter 1, and the sorting result is presented in sub-window 1 in the GIS window; and, all problem cells are sorted according to the communication quality parameters, and the sorting result is presented in a sub-window 2 in the GIS window.
Step 1530: and receiving a command of selecting the problem cell of the user, and presenting the communication quality parameter and the network optimization scheme of the selected problem cell in the GIS chart area.
In the embodiment of the present invention, after the geographic information system tool detects that the problem cell is selected by the user, the communication quality parameter and the network optimization scheme of the cell to be detected are presented in the form of bubbles, as shown in fig. 18.
Based on the above technical solution, referring to fig. 19, the present invention provides a device for presenting a network optimization scheme in multiple windows, including a calling unit 190 and a presenting unit 191, where:
the calling unit 190 is configured to call the locally stored communication quality indexes of all the cells according to the communication quality index options input by the user on the GIS interface, and send the communication quality indexes of all the cells to the presenting unit 191;
a presentation unit 191, configured to receive the communication quality indicator of the used cell sent by the calling unit 190, detect a problem cell with a problem in communication quality from all cells according to the communication quality indicator, and present the problem cell in a GIS window of the GIS interface; and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and presenting the communication quality parameters and the network optimization scheme of the problem cell in the GIS chart area.
The apparatus further comprises a first obtaining unit 192 configured to: respectively acquiring communication quality indexes dynamically reported by each cell; or respectively sending a communication quality index acquisition instruction to each cell to acquire the communication quality index of each cell at the current moment.
The apparatus further comprises a second obtaining unit 193 configured to: when detecting that a user selects a cell to be detected in a GIS window, acquiring the longitude and latitude of the cell to be detected; calling a communication quality index which is locally stored and corresponds to the longitude and latitude according to the longitude and latitude of the cell to be detected; and acquiring the communication quality parameters of the cell to be detected according to the communication quality index.
Based on the above technical solution, referring to fig. 20, the present invention provides a device for presenting a network optimization scheme in multiple windows, including a transceiver 200, a memory 201, and a processor 202, wherein:
a transceiver 200, configured to receive a communication quality indicator option input by a user in a GIS interface, and send the communication quality indicator option to a processor 202;
a memory 201, configured to store communication quality indicators of all cells, and send the communication quality indicators of all cells to a processor 202;
a processor 202, configured to receive the communication quality index options sent by the transceiver 200 and the communication quality indexes of all the cells sent by the memory 201, call the locally stored communication quality indexes of all the cells according to the communication quality index options input by the user on the GIS interface, detect a problem cell with a problem in communication quality from all the cells according to the communication quality indexes, and present the problem cell in the GIS window of the GIS interface; and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and presenting the communication quality parameters and the network optimization scheme of the problem cell in the GIS chart area.
Further, the transceiver 200 is further configured to send a communication quality indicator obtaining instruction to each cell, and receive a communication quality indicator dynamically reported by each cell.
The processor 202 is specifically configured to obtain a communication quality parameter of at least one problem cell according to the communication quality indicator; sequencing the at least one problem cell according to the communication quality parameters, and presenting the sequenced at least one problem cell in a GIS window in a GIS interface of a geographic information system; acquiring a network optimization scheme of the at least one problem cell according to the communication quality parameters, and presenting the communication quality parameters of the at least one problem cell and the network optimization scheme in a GIS chart window in the GIS interface; the GIS interface at least comprises a GIS window and a GIS chart window.
The processor 202 is further configured to, when a user inputs at least two communication quality indicator options, respectively invoke each communication quality indicator corresponding to the at least two locally stored communication quality indicator options; and in the GIS window, a sub-window is adopted to display corresponding to each communication quality index.
The processor 202 is further configured to, when the user selects the cell to be detected in the GIS window, obtain the longitude and latitude of the cell to be detected; calling a communication quality index which is locally stored and corresponds to the longitude and latitude according to the longitude and latitude of the cell to be detected; and acquiring the communication quality parameters of the cell to be detected according to the communication quality index.
In summary, in the embodiment of the present invention, according to the communication quality index option input by the user on the GIS interface, the communication quality indexes of all the cells stored locally are called; detecting a problem cell with communication quality problems from all cells according to the communication quality index, and presenting the problem cell in a GIS window of a GIS interface; and acquiring the communication quality parameters of the problem cell and the network optimization scheme of the problem cell according to the communication quality index, and displaying the acquired communication quality parameters and the network optimization scheme of the problem cell in a graph area of the GIS. By adopting the technical scheme of the invention, the geographic information system tool can carry out whole-network analysis according to the communication quality index input by the user, and the problem cells and the network optimization schemes obtained by analysis are respectively displayed in different windows, the detection process is convenient and quick, and the network optimization schemes do not need to be given by the staff according to the related parameters, thereby avoiding the misjudgment of manual operation and improving the accuracy of the network optimization schemes.
As will be appreciated by one skilled in the art, embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.
The present invention is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the invention.
It will be apparent to those skilled in the art that various modifications and variations can be made in the embodiments of the present invention without departing from the spirit or scope of the embodiments of the invention. Thus, if such modifications and variations of the embodiments of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to encompass such modifications and variations.