CN110932803A - Interference intensity acquisition method, device, terminal and storage medium - Google Patents

Abstract

The application discloses an interference intensity obtaining method, an interference intensity obtaining device, a terminal and a storage medium, and belongs to the technical field of communication. The method is executed by a terminal, and comprises the following steps: acquiring test parameters, wherein the test parameters comprise a network type of the antenna to be tested when the interference strength of a test interference source to the antenna to be tested is indicated; under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameters; acquiring first interference strength received by an antenna to be tested; when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of a test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode; and acquiring the second interference strength received by the antenna to be tested. According to the method and the device, an additional comprehensive tester is not needed, the operation process of establishing signaling connection is avoided, and the efficiency and the automation rate of the interference intensity acquisition process are improved.

Description

Interference intensity acquisition method, device, terminal and storage medium

Technical Field

The embodiment of the application relates to the technical field of communication, in particular to an interference strength acquisition method, an interference strength acquisition device, a terminal and a storage medium.

Background

The receiving sensitivity is a key index for measuring the cellular communication performance, certain interference can be caused to the receiving sensitivity in certain application scenes of the terminal, and how to effectively test the interference strength has great significance for improving the communication experience of users.

In the related art, the interference strength is tested by a manual test mode based on signaling: the method comprises the steps that under the condition that an interference source is opened, test parameters of an integrated tester are manually configured, after the integrated tester establishes signaling connection with a terminal, the integrated tester sends signals to the terminal, the terminal receives the signals and tests the strength of the received signals, and the interference strength of the interference source is determined by comparing the strength of the received signals of the terminal under the condition that the interference source is opened and closed.

However, in the related art, the terminal and the integrated tester need to establish signaling connection to test the strength of the signal received by the terminal, and the test process is complicated.

Disclosure of Invention

The embodiment of the application provides an interference intensity obtaining method, an interference intensity obtaining device, a terminal and a storage medium, and can improve the efficiency and the automation rate of an interference intensity obtaining process. The technical scheme is as follows:

in one aspect, an embodiment of the present application provides an interference strength obtaining method, where the method is executed by a terminal, and the method includes:

acquiring test parameters, wherein the test parameters comprise a network standard of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is indicated to be tested;

under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameter;

acquiring a first interference strength received by the antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by the terminal to the antenna to be tested;

when the test parameter indicates that the network standard of the antenna to be tested comprises a second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested as the second network standard in the non-signaling mode;

and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system.

On the other hand, an embodiment of the present application provides an interference strength obtaining apparatus, where the apparatus is used in a terminal, and the apparatus includes:

the parameter acquisition module is used for acquiring test parameters, and the test parameters comprise a network standard of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is indicated;

a first configuration module, configured to configure the network standard of the antenna to be tested as the network standard indicated by the test parameter in a non-signaling mode;

a first obtaining module, configured to obtain a first interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested;

the second configuration module is used for automatically configuring the network standard of the antenna to be tested to a second network standard in the non-signaling mode when the test parameters indicate that the network standard of the antenna to be tested contains the second network standard when the test parameters indicate that the interference strength of the interference source to the antenna to be tested is tested;

a second obtaining module, configured to obtain a second interference strength received by the antenna to be tested, where the second interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested configured in the second network type.

In another aspect, an embodiment of the present application provides a terminal, where the terminal includes a processor and a memory, where the memory stores at least one instruction, at least one program, a code set, or a set of instructions, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by the processor to implement the interference strength obtaining method according to the above aspect.

In another aspect, the present application provides a computer-readable storage medium, in which at least one instruction, at least one program, a code set, or a set of instructions is stored, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by a processor to implement the interference strength obtaining method according to the above aspect.

The technical scheme provided by the embodiment of the application can at least comprise the following beneficial effects:

by obtaining a test parameter, the test parameter comprises a network type of the antenna to be tested when the interference strength of a test interference source to the antenna to be tested is indicated; under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameters; acquiring a first interference strength received by an antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by a terminal to the antenna to be tested; when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of a test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode; and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system. According to the method and the device, an additional comprehensive tester is not needed, the interference intensity can be acquired through the terminal, the operation process of establishing signaling connection is avoided, the wireless network system can be automatically switched, manual operation is avoided, and the efficiency and the automation rate of the interference intensity acquisition process can be improved.

Drawings

Fig. 1 is a flow chart of a method of interference testing according to an exemplary embodiment of the present application;

fig. 2 is a flowchart of a method for obtaining interference strength according to an exemplary embodiment of the present application;

fig. 3 is a flowchart of a method for obtaining interference strength according to an exemplary embodiment of the present application;

FIG. 4 is an interface diagram of a configuration interface according to an exemplary embodiment of the present application;

FIG. 5 is an interface schematic of another configuration interface to which an exemplary embodiment of the present application relates;

FIG. 6 is an interface schematic of yet another configuration interface to which an exemplary embodiment of the present application relates;

FIG. 7 is an interface diagram of another configuration interface contemplated by an exemplary embodiment of the present application;

fig. 8 is a block diagram of an interference strength obtaining apparatus according to an exemplary embodiment of the present application;

fig. 9 is a schematic structural diagram of a terminal according to an exemplary embodiment of the present application.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

Reference herein to "a plurality" means two or more. "and/or" describes the association relationship of the associated objects, meaning that there may be three relationships, e.g., a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

The signal receiving sensitivity is a key index for measuring the performance of cellular communication, and for some reasons, the use of other modes by the terminal may bring certain interference to the cellular communication, so that the receiving sensitivity of the cellular communication is deteriorated, and the terminal may drop the call or the network under the weak signal condition.

In common application scenes of a terminal user, such as opening a camera, connecting the terminal with a computer for data copying, charging the terminal, turning on and off a screen of the terminal or starting a large-scale game, theoretical analysis and experiments show that the application scenes can cause certain deterioration on the receiving sensitivity of cellular communication, the reduction of the interference of the application scenes on the cellular communication has great significance on improving the communication experience of the user, and how to find the interference through an effective test method is the premise of optimizing all performances.

Currently, for the test procedure of such interference signals, a comprehensive tester needs to establish a signaling connection with a test device to perform interference test. Referring to fig. 1, a flow chart of an interference testing method according to an exemplary embodiment of the present application is shown. As shown in fig. 1, the interference test method may include the following steps.

Step 101, a tester manually opens an interference source.

For example, the tester may manually turn on any of the interference sources, for example, the interference source may be turning on a camera, turning on a terminal screen, charging the terminal, and the like.

Optionally, the terminal may be a mobile phone, a tablet computer, an e-book reader, smart glasses, a smart watch, an MP3 player (Moving Picture Experts Group Audio Layer III, motion Picture Experts compression standard Audio Layer 3), an MP4 player (Moving Picture Experts Group Audio Layer IV, motion Picture Experts compression standard Audio Layer 4), a notebook computer, a laptop computer, a desktop computer, and the like.

Step 102, the tester puts the terminal into a shielding box.

And 103, manually configuring the comprehensive tester by a tester through a computer.

Optionally, the tester configures the integrated tester according to the relevant information of the test, and the relevant configuration information of the test may include the network type of the test, the frequency band corresponding to the network type, the channel range, and the like. The tester configures the comprehensive tester to enable the terminal to establish signaling connection with the comprehensive tester.

And step 104, establishing signaling connection between the terminal and the comprehensive tester.

The terminal is connected with the comprehensive tester through a radio frequency line.

And 105, the terminal acquires and records the first signal receiving strength.

The comprehensive tester sends a signal to the testing equipment, and the terminal receives the signal and determines the currently acquired first signal receiving strength.

And step 106, judging whether the interference test is finished or not by the tester under the interference source opening state. If the tester judges that the interference test in the interference source opening state is completed, the flow enters step 107; if the tester determines that the interference test is not completed in the interference source on state, the process starts to be executed again from step 103.

Step 107, the tester manually turns off the interference source.

Step 108, the tester places the terminal in a shielded box.

Step 109, the tester manually configures the comprehensive tester.

And step 110, the terminal establishes signaling connection with the comprehensive tester.

And step 111, the terminal acquires and records the second signal receiving strength.

In step 112, the tester determines whether the interference test is completed in the interference source off state. If the tester judges that the interference test is finished in the interference source closed state, the flow enters the step 113; if the tester determines that the interference test is not completed in the interference source off state, the process starts to be executed again from step 109.

And step 113, determining the interference strength corresponding to the interference source according to the first signal receiving strength and the second signal receiving strength.

The steps 101 to 113 are an interference test unit, the test process of other interference sources is consistent with the interference test unit, and the steps 101 to 113 are repeatedly executed to realize the purpose of detecting the interference of other interference sources to the terminal communication at one time.

In the above scheme, in the process of acquiring the first signal reception intensity and the second signal reception intensity, if the first signal reception intensity and the second signal reception intensity under different parameters (different network systems, different test frequency bands, and the like) need to be acquired, a professional tester needs to manually control the comprehensive tester to complete the acquisition and the recording. That is, each time the test is performed, the terminal not only needs to establish signaling connection with the integrated tester for many times, but also needs to manually adjust the parameters of the integrated tester by a professional tester in the process. When the content to be tested is more, professional testers need to repeatedly adjust the parameters of the comprehensive tester again and again, and the like, so that the process of acquiring the first signal receiving intensity and the second signal receiving intensity is complicated, and the problems of low automation rate and efficiency of the whole testing process are caused.

In order to optimize the test process, the efficiency and the automation rate of the interference intensity acquisition process are improved. The application provides an interference strength acquisition method, which can actively acquire the first signal receiving strength or the second signal receiving strength without a tester, and is beneficial to improving the execution efficiency of interference testing.

Referring to fig. 2, a flowchart of an interference strength obtaining method according to an exemplary embodiment of the present application is shown. The method may be used in the terminal that needs to be tested and executed by the terminal, as shown in fig. 2, and the interference strength obtaining method may include the following steps.

Step 201, obtaining a test parameter, where the test parameter includes a network standard of the antenna to be tested when the test interference source indicates the interference strength of the antenna to be tested.

Optionally, the interference source refers to an interference source installed in the terminal itself, that is, the terminal to be tested may be installed with the interference source in advance, and illustratively, the interference source may be a shooting component (for example, an open camera), a charging component (for example, charging the terminal), a speaker (an open speaker), a microphone (for example, an open microphone), a display screen (for example, a display screen in a bright screen state), and the like.

Optionally, the antenna to be tested refers to an antenna installed on the terminal itself. That is, the terminal to be tested also needs to have its own antenna. For example, the terminal may include a GPS (Global Positioning System) antenna, a WiFi (Wireless Fidelity) antenna, and the like. The method and the device for testing the antenna selection can select any one or more antennas in the terminal as the antennas to be tested.

Optionally, the network standard may be any one of network standards supported by the antenna to be tested. In general, one antenna may support multiple network systems, for example, a first antenna in a terminal may support a Global System for Mobile Communication (GSM) System, a Code Division Multiple Access (CDMA) System, a Wideband Code Division Multiple Access (WCDMA) System, a Long Term Evolution (Long Term Evolution) System, a New Radio (NR) System, and the like.

Step 202, under the non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameter.

The non-signaling mode refers to that the terminal does not establish a wireless signaling connection with any other device. Optionally, when the test parameters are obtained, the terminal may also be in a non-signaling mode.

Optionally, after obtaining the test parameters, the terminal may obtain a network system included in the test parameters according to the test parameters, and configure its own antenna to be tested to the network system to operate.

Step 203, obtaining a first interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a ground noise generated by the terminal on the antenna to be tested.

That is, when the interference source is in the off state, the strength of the noise signal received by the antenna to be tested is obtained, because no other working device exists in the terminal at this time, the obtained noise signal is the bottom noise signal generated by the terminal to the antenna to be tested.

And 204, when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of the test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode.

Each antenna in the terminal may support a plurality of different network systems, and the antennas to be tested under each network system need to be measured in the test process, and the network systems of the antennas to be tested may be various when the test parameters indicate the interference strength of the test interference source to the antennas to be tested.

For example, when the network standard of the antenna to be tested includes LTE and GSM standards when the terminal indicates the interference strength of the test interference source to the antenna to be tested in the test parameters acquired by the terminal, the terminal may configure the network standard of the antenna to be tested as the LTE standard in step 202, and after acquiring the first interference strength received by the antenna to be tested in the LTE standard, automatically configure the network standard of the antenna to be tested as the GSM standard from the LTE standard.

Step 205, obtaining a second interference strength received by the antenna to be tested, where the second interference strength is a signal strength of a background noise generated by the terminal to the antenna to be tested configured in the second network system.

That is, after configuring the network standard of the antenna to be tested as another network standard indicated by the test parameter, acquiring the signal strength of the noise generated by the terminal on the antenna to be tested in the network standard.

In a possible implementation manner, when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, and the network standard of the antenna to be tested includes three or more network standards, after the terminal acquires the second interference strength, the terminal may continue to automatically configure the network standard of the antenna to be tested as the network standard which is not configured, and continue to acquire the signal strength of the ground noise generated by the terminal to the antenna to be tested in the corresponding network standard, until the network standards of the antenna to be tested are configured when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, the step of acquiring the interference strength may be ended.

In summary, by acquiring the test parameters, the test parameters include a network standard of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated; under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameters; acquiring a first interference strength received by an antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by a terminal to the antenna to be tested; when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of a test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode; and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system. According to the method and the device, an additional comprehensive tester is not needed, the interference intensity can be acquired through the terminal, the operation process of establishing signaling connection is avoided, the wireless network system can be automatically switched, manual operation is avoided, and the efficiency and the automation rate of the interference intensity acquisition process can be improved.

In a possible implementation manner, in order to complete the test of the antenna to be tested and obtain the noise interference strength of the antenna to be tested from the interference source in the terminal, in this embodiment of the application, after obtaining each interference strength, the interference source may be automatically turned on to obtain the noise interference strength received by the antenna to be tested in each network system when the interference source is turned on and the antenna to be tested is in each network system, and according to the obtained noise interference strength, the signal strength of the bottom noise obtained by the antenna to be tested in the corresponding network system when the interference source is turned off is subtracted, so as to obtain the noise interference strength generated by the interference source to the antenna to be tested in the corresponding network system, and finally complete the test of the antenna to be tested from the interference source in the terminal.

Please refer to fig. 3, which illustrates a flowchart of an interference strength obtaining method according to an exemplary embodiment of the present application. The method may be used in the terminal that needs to be tested and executed by the terminal, as shown in fig. 3, and the interference strength obtaining method may include the following steps.

Step 301, obtaining configuration information input in a configuration interface, where the configuration information includes a network type to be tested.

In the embodiment of the present application, the configuration information includes a network type to be tested. The network standard to be tested can be any network standard, such as NR, GSM, CDMA, WCDMA, LTE, etc.

In a possible implementation manner, the terminal may be provided with a configuration interface, and the terminal displays, in the configuration interface, system identifiers of candidate network systems, where the candidate network systems include all network systems supported by each antenna of the terminal; when receiving the selection operation of the system identification, acquiring the network system corresponding to the selected system identification as a network system to be tested; and acquiring the network system to be tested as input configuration information. Each candidate network type identifier corresponds to one candidate network type.

Referring to fig. 4, an interface diagram of a configuration interface according to an exemplary embodiment of the present application is shown. As shown in fig. 4, the configuration interface 400 includes a network format control 401, a network format sub-interface 402, a format identifier 403, and a selection control 404. A tester can click the network system control 401 to display or close the network system sub-interface 402 in the configuration interface 400, the tester can also click the system identifier 403 or the selection control 404 to select or deselect the corresponding system identifier 403, when the terminal receives the click operation of the tester on the system identifier 403 or the selection control 404, the terminal is considered to receive the selection operation on the system identifier 403, and the terminal can acquire the network system corresponding to the selected system identifier 403 as the network system to be tested and acquire the network system to be tested as the input configuration information.

For example, a tester may click on the "LTE" system identifier and the "GSM" system identifier shown in fig. 4, so as to select the "LTE" system identifier and the "GSM" system identifier, and when the terminal receives a click operation on the "LTE" system identifier and the "GSM" system identifier, the terminal may acquire the LTE system and the GSM system corresponding to the "LTE" system identifier and the "GSM" system identifier as a network system to be tested, and acquire the LTE system and the GSM system as input configuration information.

Optionally, the candidate network standard may be a network standard that is preset in a software installation package by a software developer or an operation and maintenance person, and when the terminal runs the software, the software may provide all network standards supported by each antenna of the terminal.

Optionally, the configuration information may further include an identifier of the antenna to be tested, or a working power of the antenna to be tested, or a frequency band to be tested of the network system to be tested. That is, the configuration information may include any two or more kinds of information between the network standard to be tested and the identifier of the antenna to be tested, the working power of the antenna to be tested, and the frequency band to be tested of the network standard to be tested.

In a possible implementation manner, the terminal may further display frequency band identifiers of candidate frequency bands in the configuration interface, where the candidate frequency bands are all frequency bands included in the network system to be tested; when receiving a selection operation of the frequency band identifier, acquiring the frequency band corresponding to the selected frequency band identifier as a frequency band to be tested; at this time, the terminal may acquire the network standard to be tested and the frequency band to be tested as input configuration information.

Referring to fig. 5, an interface diagram of another configuration interface according to an exemplary embodiment of the present application is shown. As shown in fig. 5, the configuration interface 500 includes a network system control 501, a network system sub-interface 502, a system identifier 503, a selection control 505, a candidate frequency band control 506, a frequency band sub-interface 507, and a frequency band identifier 508.

The mode shown in fig. 4 may be referred to for the selection of the network system by the tester, and details are not described here. After the tester finishes selecting the network system, the tester may click the candidate frequency band control 506 to display or close the frequency band sub-interface 507 in the configuration interface 500, the tester may also click the frequency band identifier 508 or the selection control 505 to select or deselect the corresponding frequency band identifier 508, when the terminal receives the click operation of the tester on the frequency band identifier 508 or the selection control 505, the terminal is considered to receive the selection operation on the frequency band identifier 508, and the terminal may acquire the frequency band corresponding to the selected frequency band identifier 508 as the frequency band to be tested, and acquire the network system to be tested and the frequency band to be tested as the input configuration information.

Taking the example shown in fig. 4, the network system to be tested selected by the tester in the configuration interface is the LTE system and the GSM system, the terminal may obtain all frequency bands included in the LTE system and the GSM system, and when receiving the operation of displaying the frequency band sub-interface 507, display frequency band identifiers corresponding to all frequency bands included in the LTE system and the GSM system in the frequency band sub-interface 507. These frequency bands are candidate frequency bands. For example, all frequency bands of the GSM system include 800MHz frequency bands, 900MHz frequency bands, 1800MHz frequency bands, and 1900MHz frequency bands, and the terminal can acquire these frequency bands as candidate frequency bands and display them in the frequency band sub-interface.

Optionally, when the network system to be tested selected by the tester in the configuration interface is a CDMA system, an NR system, or the like, the frequency band identifier 508 displayed in the frequency band sub-interface 507 is a frequency band identifier corresponding to all frequency bands included in the corresponding CDMA system, NR system, or the like, which is not illustrated here. Optionally, the candidate frequency bands corresponding to the various network systems may also be preset in a software installation package by a software developer or an operation and maintenance person, and when the terminal runs the software, the software may provide the candidate frequency bands corresponding to the various network systems of the terminal.

In a possible implementation manner, the terminal may further display antenna identifiers of candidate antennas in the configuration interface, where the candidate antennas are all antennas supporting the network standard to be tested in the terminal; when receiving the selection operation of the antenna identification, acquiring the antenna corresponding to the selected antenna identification as an antenna to be tested; at this time, the terminal may acquire the network standard to be tested and the antenna to be tested as input configuration information.

Referring to fig. 6, an interface diagram of yet another configuration interface according to an exemplary embodiment of the present application is shown. As shown in fig. 6, the configuration interface 600 includes a network format control 601, a network format sub-interface 602, a format identifier 603, a selection control 604, a candidate antenna control 605, an antenna sub-interface 606, and an antenna identifier 607.

The mode shown in fig. 4 may be referred to for the selection of the network system by the tester, and details are not described here. After the tester finishes selecting the network system, the tester may click the candidate antenna control 605 to display or close the antenna sub-interface 606 in the configuration interface 600, the tester may also click the antenna identifier 607 or the selection control 604 to select or deselect the corresponding antenna identifier 607, when the terminal receives the click operation of the tester on the antenna identifier 607 or the selection control 604, the terminal regards as receiving the selection operation on the antenna identifier 607, and the terminal may acquire the antenna corresponding to the selected antenna identifier 607 as the antenna to be tested, and acquire the network system to be tested and the antenna to be tested as the input configuration information.

Taking the above fig. 4 as an example, the network system to be tested selected in the configuration interface by the tester is the LTE system and the GSM system, the terminal may obtain all frequency bands included in the LTE system and the GSM system, and when receiving the operation of displaying the antenna sub-interface 606, the antenna identifiers corresponding to all antennas supporting the LTE system and the GSM system in the terminal are displayed in the antenna sub-interface 606. These antennas are the candidate antennas.

Optionally, when the network system to be tested selected by the tester in the configuration interface is a CDMA system, an NR system, or the like, the antenna identifier 607 displayed in the antenna sub-interface 606 is an antenna identifier corresponding to all antennas supporting the CDMA system, the NR system, or the like, which is not illustrated here.

Optionally, the method for the terminal to obtain all antennas of the to-be-tested network standard supported in the terminal according to the to-be-tested network standard may be as follows. The terminal can generate a corresponding relation table of the antenna identifier and the network standard, and the terminal obtains all the antennas of the supported network standard to be tested from the corresponding relation table. Optionally, one or more antennas may be included in the terminal. In one possible implementation, the terminal includes antenna one, antenna two, and antenna three. After the terminal is installed with the software, the software can number each antenna in the terminal, and the number of each antenna is used as the antenna identifier of each antenna. Please refer to table 1, which shows a correspondence table between antenna identifiers and network types according to an exemplary embodiment of the present application.

TABLE 1

As shown in table 1, each antenna may have its own supported network format. Optionally, after obtaining the network standard to be tested, the terminal may query all antennas supporting the network standard to be tested according to table 1. For example, the network system to be tested is LTE, and the antennas that the terminal can acquire include antenna one and antenna two. When the selected format identifier 603 is an LTE format in the configuration interface shown in fig. 6, the terminal may include a first antenna and a second antenna in each antenna identifier 607 displayed in the antenna sub-interface 606.

In a possible implementation manner, the terminal can also display a power identifier of a candidate power in the configuration interface, wherein the candidate power is the working power of the antenna to be tested after the terminal configures the antenna to be tested to the network standard to be tested; when receiving the selection operation of the power identifier, acquiring the working power corresponding to the selected power identifier as the power of the antenna to be tested; the terminal can obtain the network system to be tested and the power of the antenna to be tested as input configuration information.

Referring to fig. 7, an interface diagram of another configuration interface according to an exemplary embodiment of the present application is shown. As shown in fig. 7, the configuration interface 700 includes a network format control 701, a network format sub-interface 702, a format identifier 703, a selection control 704, a candidate power control 705, a power sub-interface 706, and a power identifier 707.

The mode shown in fig. 4 may be referred to for the selection of the network system by the tester, and details are not described here. After the tester finishes selecting the network system, the tester may click the candidate power control 705 to display or close the power sub-interface 706 in the configuration interface 700, the tester may also click the power identifier 707 or select the control 704 to select or deselect the corresponding power identifier 607, when the terminal receives the click operation of the tester on the power identifier 707 or select the control 704, the terminal regards as receiving the selection operation on the power identifier 707, and may acquire the working power corresponding to the selected power identifier 707 as the power of the antenna to be tested, and acquire the network system to be tested and the power of the antenna to be tested as the input configuration information.

Taking the example shown in fig. 4, where the network system to be tested selected by the tester in the configuration interface is the LTE system and the GSM system, the terminal may further obtain the working power of the antenna to be tested, and adjust the working power of the antenna to be tested to the obtained working power when the network system of the antenna to be tested is configured to the LTE system or the GSM system subsequently. Optionally, a correspondence table between the antenna identifier and the working power may be generated in the terminal, and the terminal obtains the working power of the antenna to be tested from the correspondence table. Optionally, the generation of the table of correspondence between the antenna identifier and the working power may refer to the generation manner in table 1, which is not described herein again.

Please refer to table 2, which shows a correspondence table between antenna identifiers and operating powers according to an exemplary embodiment of the present application.

Antenna identification	Operating power
		Antenna 1	Power one, power two, power three
Antenna two	Power one, power three
		Antenna three	Power one, power four
……	……

TABLE 2

As shown in table 2, where each antenna may have its own operating power. Optionally, the terminal may query the working power at which each antenna may operate according to table 2, and each power identifier 707 displayed in the power sub-interface 706 by the terminal may include power one, power two, power three, and power four.

Optionally, the input of the configuration information shown in fig. 4 to fig. 7 may be combined at will, that is, multiple pieces of configuration information are set and input in the same configuration interface, optionally, a control for starting detection may also be set in fig. 4 to fig. 7, and when a tester starts a test, the terminal may use the input configuration information as the configuration information finally obtained, which is not limited in the embodiment of the present application.

Step 302, obtaining test parameters according to the configuration information.

The test parameters comprise a network system of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is indicated.

Optionally, when the configuration information includes a network type to be tested, the test parameter obtained by the terminal according to the configuration information may be the network type to be tested, that is, the test parameter includes a network type of the antenna to be tested when the test parameter indicates the interference strength of the test interference source to the antenna to be tested.

When the configuration information includes a network system to be tested and a frequency band to be tested, the test parameters acquired by the terminal according to the configuration information may be the network system to be tested and the frequency band to be tested, the test parameters may include a network system of an antenna to be tested when the interference strength of a test interference source to the antenna to be tested is indicated, and may also include the frequency band to be tested in the network system to be tested.

When the configuration information includes a network standard to be tested and an antenna identifier of an antenna to be tested, the test parameters acquired by the terminal according to the configuration information may be the network standard to be tested and the antenna identifier of the antenna to be tested, the test parameters may include a network standard of the antenna to be tested when the interference strength of a test interference source to the antenna to be tested is indicated, and may further include an antenna identifier of each antenna to be tested supporting the network standard to be tested.

When the configuration information includes a network system to be tested and working power of an antenna to be tested, the test parameters acquired by the terminal according to the configuration information may be the network system to be tested and the working power of the antenna to be tested, the test parameters may include a network system of the antenna to be tested when the interference strength of a test interference source to the antenna to be tested is indicated, and may also include the working power of the antenna to be tested when the antenna to be tested is tested.

Optionally, when the configuration information includes any two or more information between the network standard to be tested and the identifier of the antenna to be tested, the working power of the antenna to be tested, and the frequency band to be tested of the network standard to be tested, the test parameter acquired by the terminal according to the configuration information may also include the any two or more information. This is not limited by the examples of the present application.

Step 303, configuring the network type of the antenna to be tested as the network type indicated by the test parameter in the non-signaling mode.

Optionally, the terminal may configure the network type of its own antenna to be tested as the network type indicated in the test parameter in a non-signaling mode. For example, the network type indicated in the test parameter is an LTE type, and the terminal may configure the network type of the antenna to be tested as the LTE type.

In a possible implementation manner, one or more antennas exist in the terminal, and when the test parameter does not indicate which antenna in the terminal is the antenna to be tested, the terminal may obtain all antennas as the antennas to be tested, and sequentially configure each antenna to the network standard indicated in the test parameter. For example, there are a first antenna and a second antenna in the terminal, in this step, the terminal may configure the first antenna as the network type indicated in the test parameter, and perform step 304 on the first antenna, and after performing step 304, automatically configure the second antenna as the network type indicated in the test parameter, and perform step 304 on the second antenna.

Optionally, the test parameter further includes a test frequency band supported by the network system when the interference strength of the test interference source to the antenna to be tested is indicated. That is, corresponding to one implementation manner in the step 302, the test parameter includes a test frequency band supported by the network system when the test interference source indicates the interference strength of the test interference source to the antenna to be tested, and this step 303 may be replaced with: and under a non-signaling mode, configuring the antenna to be tested to a network system and a test frequency band. For example, the network standard indicated in the test parameter is a GSM standard and an 800MHz frequency band, and the terminal may configure the network standard of the antenna to be tested as the GSM standard and configure the test frequency band of the antenna to be tested as the 800MHz frequency band.

Optionally, the test parameter further includes a working power of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated. That is, corresponding to one implementation manner in step 302, the test parameter includes a working power of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated, and this step 303 may be replaced with: and under a non-signaling mode, configuring the antenna to be tested to a network system and the power to be operated. For example, the network standard indicated in the test parameters is a GSM standard and the operating power is 1w (watt), and the terminal may configure the network standard of the antenna to be tested as the GSM standard and configure the operating frequency of the antenna to be tested as 1 w.

Optionally, the test parameters further include an antenna identifier indicating an antenna to be tested. That is, corresponding to an implementation manner in the step 302, the test parameters include antenna identifiers of each antenna to be tested that supports the network type to be tested, and this step 303 may be replaced with: and under a non-signaling mode, configuring the network standard of the first antenna to be tested as the network standard indicated by the test parameter, wherein the first antenna to be tested is any one of the antennas to be tested. For example, the network system indicated in the test parameter is a GSM system and the first antenna, and the terminal may configure the network system of the first antenna as the GSM system.

Optionally, in this embodiment of the application, when multiple kinds of indication information in the test parameters are tested, the terminal may also be configured at the same time. For example, the test parameter includes that the network standard is a GSM standard, the test frequency band is an 800MHz frequency band, the antenna is identified as antenna one, the working power is power one, the terminal can configure the network standard of the antenna one as the GSM standard, the test frequency band of the antenna one is configured as the 800MHz frequency band, and the working power of the antenna one is configured as the power one.

Step 304, obtaining a first interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a background noise generated by the terminal on the antenna to be tested.

Optionally, after the network system configuration of the antenna to be tested is completed, the first interference strength of the antenna to be tested may be obtained. Optionally, when the test parameter includes other indication information, the terminal may obtain the first interference strength of the antenna to be tested after the configuration of each antenna is completed.

In a possible implementation manner, when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, the test frequency band supported by the network system includes a second test frequency band; the terminal can also automatically configure the test frequency band of the antenna to be tested to be the second test frequency band in a non-signaling mode.

Corresponding to one implementation manner in the step 303, the test parameters further include a second test frequency band that indicates the test frequency band supported by the network system when the interference strength of the interference source to the antenna to be tested is tested. For example, when the network standard indicated in the test parameters is a GSM standard and a 800MHz frequency band, 900MHz frequency band, the terminal configures the network standard of the antenna to be tested as the GSM standard, and configures the test frequency band of the antenna to be tested as the 800MHz frequency band, after the first interference strength received by the antenna to be tested is obtained in this step, the terminal may also automatically configure the test frequency band of the antenna to be tested as the 900MHz frequency band, and obtain the first interference strength received by the antenna to be tested again, where the first interference strength at this time is that the network standard of the antenna to be tested is configured as the GSM standard, and the terminal generates the signal strength of the bottom noise to the antenna to be tested when the test frequency band of the antenna to be tested is the 900 MHz.

Optionally, when the test parameters further include a test frequency band supported by the network standard when the test interference strength of the interference source to the antenna to be tested is indicated, and the test frequency band includes three or more test frequency bands, reference may also be made to the description herein, and details are not described here again. In a possible implementation manner, if the test parameter does not include a test frequency band supported by the network system when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, the terminal may sequentially configure the antenna to be tested according to all the test frequency bands supported by the network system, which is not limited in the embodiment of the present application.

In a possible implementation manner, when the test parameter indicates that the working power of the antenna to be tested includes the second working power when the test parameter indicates the strength of the test interference source to the interference of the antenna to be tested, the terminal may further automatically configure the working power of the antenna to be tested as the second working power in a non-signaling mode.

Corresponding to one implementation manner in the step 303, the test parameter further includes an operating power of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated, and the operating power includes a second operating power. For example, when the network system indicated in the test parameters is a GSM system and the working power is 1w and 2w, the terminal configures the network system of the antenna to be tested as the GSM system, and configures the working frequency of the antenna to be tested as 1w, after the first interference strength received by the antenna to be tested is obtained in this step, the terminal may also automatically configure the working frequency of the antenna to be tested as 2w, and obtain the first interference strength received by the antenna to be tested again, where the first interference strength is that the network system of the antenna to be tested is configured as the GSM system, and the working frequency of the antenna to be tested is 2w, the terminal generates the signal strength of the noise cancellation for the antenna to be tested.

Optionally, when the test parameter indicates that the working power of the antenna to be tested includes three or more working powers when the test parameter indicates the strength of the interference from the interference source to the antenna to be tested, the description herein may also be referred to, and details are not described here again. In a possible implementation manner, if the test parameter does not include the working power of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated, the terminal may sequentially configure the antenna to be tested according to all the working powers at which the antenna to be tested may work, which is not limited in the embodiment of the present application.

When the number of the antennas to be tested is greater than or equal to 2, the terminal may configure the network type of the first antenna to be tested as the network type indicated by the test parameter in the non-signaling mode in step 303, and the terminal may obtain the first interference strength received by the first antenna to be tested corresponding to the first antenna to be tested configured in step 303, where the first antenna to be tested is any one of the antennas to be tested.

Optionally, the terminal may further automatically switch from the first antenna to be tested to a second antenna to be tested in a non-signaling mode, and configure the network standard of the second antenna to be tested as the network standard indicated by the test parameter, where the second antenna to be tested is another antenna in the antennas to be tested.

Corresponding to an implementation manner in the step 303, the test parameters further include an antenna identifier indicating an antenna to be tested, and the antenna identifier includes at least two antennas. For example, when the network system indicated in the test parameter is a GSM system and the antenna identifier of each antenna to be tested is antenna one and antenna two, the terminal configures the network system of antenna one as the GSM system, and after the first interference strength received by antenna one is obtained in this step, the terminal may also automatically switch the antenna to antenna two, configure the network system of antenna two as the GSM system, and obtain the first interference strength received by antenna two again, where the first interference strength at this time is the signal strength of the bottom noise generated by the terminal to antenna two when the network system of antenna two is configured as the GSM system.

Optionally, when the antenna identifier indicating the antenna to be tested in the test parameter includes three or more antenna identifiers, reference may also be made to the description herein, and details are not described here again. In a possible implementation manner, if the test parameter does not include an antenna identifier of each antenna to be tested that supports the network system to be tested, the terminal may sequentially configure each antenna in the terminal, which is not limited in the embodiment of the present application.

Step 305, when the test parameter indicates that the network standard of the antenna to be tested includes the second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested as the second network standard in the non-signaling mode.

That is, when the network standard of the antenna to be tested includes the second network standard when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, the terminal may also automatically configure the network standard of the antenna to be tested as the second network standard in the non-signaling mode.

For example, when the network system indicated in the test parameter is a GSM system and an LTE system, after the terminal configures the network system of the antenna to be tested as the GSM system, the terminal may further automatically configure the network system of the antenna to be tested as the LTE system after obtaining the received first interference strength of the antenna to be tested in step 304. Optionally, when the network system indicated in the test parameter includes three or more network systems, the terminal may also configure the network system of the antenna to be tested to a network system different from the previously configured network system in sequence, which is not described herein again.

Step 306, obtaining a second interference strength received by the antenna to be tested, where the second interference strength is a signal strength of a background noise generated by the terminal to the antenna to be tested configured in the second network system.

Optionally, the terminal may obtain a second interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested when the network system of the antenna to be tested is configured as another network system.

Optionally, the terminal may further detect the test parameter after obtaining the first interference strength or the second interference strength, and check whether the test of the network type or other information indicated by the test parameter is completed, thereby determining the subsequent execution step.

Step 307, automatically turning on an interference source in the terminal.

That is, the above steps 301 to 306 can be regarded as that the terminal obtains the noise interference strength received by the antenna to be tested under the condition that the interference source is not turned on, and in order to obtain the interference strength caused by the interference source to the antenna to be tested, the terminal can also automatically turn on the interference source and execute the subsequent steps after the above steps are completed, so as to complete the test of the interference source to the antenna to be tested.

In one possible implementation, the interference source consumes power of the terminal when turned on. A complete test process may require 2 to 4 hours on average, wherein the time that the interference source is in the on state reaches at least 1 to 2 hours, and the interference source is always in the on state, which undoubtedly consumes the power of the terminal, so as to avoid that the previous test data does not have a corresponding reference value due to the sudden interruption of the test caused by insufficient power in the process of turning on the interference source, thereby causing unnecessary time waste. Therefore, in a possible implementation manner, after the terminal obtains the first interference strength and the second interference strength corresponding to the test parameters in the interference source closed state, the power consumption required for executing the subsequent steps after the interference source is started can be estimated, so that the power consumption can be compared with the residual power of the current terminal, and if the subsequent test requirements cannot be met, a charging prompt can be performed, so that a tester can timely know the power state of the current terminal and adjust the subsequent test scheme.

That is, before this step, the terminal may further obtain first test power consumption and first test consumed time, where the first test power consumption is power consumed for obtaining the first interference strength and the second interference strength, and the first test consumed time is total consumed time for obtaining the first interference strength and the second interference strength; determining second test power consumption according to the first test power consumption, the first test consumed time and the power consumption of the interference source in unit time, wherein the second test power consumption is the power consumption consumed for obtaining the third interference intensity and the fourth interference intensity; and when the residual electric quantity of the terminal is lower than the second test electric consumption quantity, carrying out charging prompt.

Optionally, when the interference source is in a closed state and the terminal starts to perform a signal reception strength test, a first electric quantity and a first time of the current terminal are obtained, and after the terminal obtains the first interference strength and the second interference strength indicated by the test parameter, a second electric quantity and a second time of the terminal at this time are obtained. And the terminal obtains first test power consumption according to the difference value of the first electric quantity and the second electric quantity. And the terminal obtains the first test time according to the difference value of the first time and the second time.

For example, if the first amount of power is 98% and the second amount of power is 54%, the first test power consumption amount is 44%; the first time was 11:28 and the second time was 13:30, the first test took 2 hours and 2 minutes.

Optionally, the power consumption of the interference source in unit time duration may be preset in the terminal by a tester, or may be calculated by the terminal according to historical data, for example, the terminal obtains the starting time period of the front camera in a certain period of time and the total power consumption corresponding to the starting time period, so as to obtain the power consumption in unit time duration according to the starting time period and the total power consumption. The terminal can determine the second test power consumption according to the first test time consumption and the unit time consumption of the interference source. Such as: and the terminal multiplies the power consumption of the interference source in unit time length by the first test time consumption and adds the first test power consumption to obtain a second test power consumption.

Exemplarily, the terminal compares the obtained second test power consumption with the current remaining power consumption of the terminal, and if the current remaining power consumption is lower than the second test power consumption, it indicates that the current power consumption of the terminal may not meet the test of the signal reception intensity when the interference source is in the on state, and at this time, a charging prompt may be performed, so as to remind a tester that the test may be suspended to charge the terminal. Optionally, the charging prompt mode may be a voice prompt or a text prompt, and the charging prompt mode in the embodiment of the present application is not limited.

And 308, under the non-signaling mode, reconfiguring the network standard of the antenna to be tested into the network standard indicated by the test parameters according to the test parameters.

Step 309, obtaining a third interference strength received by the antenna to be tested, where the third interference strength is a noise signal strength received by the antenna to be tested when the interference source works.

Step 310, when the test parameter indicates the interference strength of the test interference source to the antenna to be tested, and the network standard of the antenna to be tested includes a second network standard, automatically configuring the network standard of the antenna to be tested as the second network standard in a non-signaling mode.

Step 311, obtaining a fourth interference strength received by the antenna to be tested, where the fourth interference strength is a noise signal strength received by the antenna to be tested configured in the second network system when the interference source works.

Optionally, the manner in which the terminal performs steps 308 to 311 is performed when the interference source is turned on, and the description of each step may refer to the content of the interference source turned off (steps 303 to 306), which is not described herein again.

Step 312, obtaining a first noise intensity generated by the interference source to the antenna to be tested according to the first interference intensity and the third interference intensity.

And 313, acquiring a second noise intensity generated by the interference source to the antenna to be tested according to the second interference intensity and the fourth interference intensity.

Optionally, in step 312 and step 313, the terminal may obtain, according to the obtained first interference strength and third interference strength, the second interference strength and the fourth interference strength, a first noise strength generated by the interference source to the antenna to be tested, and a second noise strength generated by the interference source to the antenna to be tested.

In a possible mode, the terminal may store the configuration information used in the first interference strength in association with the configuration information, the terminal may store the configuration information used in association with the configuration information used in the second interference strength in association with the configuration information used in association with the configuration information, the terminal may store the configuration information used in association with the configuration information when the terminal obtains the fourth interference strength.

For example, please refer to tables 3 to 6, which show a corresponding relationship table between the interference strength and the configuration information according to the embodiment of the present application.

First interference intensity	Configuration information
		First interference intensity of	Antenna one, network system one and frequency band one
First interference intensity two	Antenna one, network system one and frequency band two
		……	……

TABLE 3

Second interference intensity	Configuration information
		Second interference intensity one	Antenna one, network type two, frequency band one
Second interference intensity two	Antenna one, network type two and frequency band two
		……	……

TABLE 4

Intensity of third interference	Configuration information
		Third interference intensity one	Antenna one, network system one and frequency band one
Third interference intensity two	Antenna one, network system one and frequency band two
		……	……

TABLE 5

Fourth intensity of interference	Configuration information
		Fourth interference intensity one	Antenna one, network type two, frequency band one
Fourth interference intensity two	Antenna one, network type two and frequency band two
		……	……

TABLE 6

The terminal may obtain a first noise strength generated by the interference source to the antenna in the configuration information according to the first interference strength and the third interference strength which are the same as the configuration information. And acquiring a second noise intensity generated by the interference source to the antenna in the configuration information according to the second interference intensity and the fourth interference intensity which are the same with the configuration information.

Optionally, in this embodiment of the present application, before step 301, a processor platform corresponding to the terminal processor may also be determined; and executing the interference intensity acquisition method by calling the instruction corresponding to the processor platform. That is, when the methods of steps 301 to 313 are executed, the method is executed by calling an instruction corresponding to the processor platform. For example, when the processor platform is a high-pass platform, the instruction is a Diag (diagnosis) instruction, and when the processor platform is a concurrency platform, the instruction is an AT (Attention) instruction. The embodiments of the present application are not limited thereto.

In summary, by acquiring the test parameters, the test parameters include a network standard of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated; under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameters; acquiring a first interference strength received by an antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by a terminal to the antenna to be tested; when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of a test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode; and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system. According to the method and the device, an additional comprehensive tester is not needed, the interference intensity can be acquired through the terminal, the operation process of establishing signaling connection is avoided, the wireless network system can be automatically switched, manual operation is avoided, and the efficiency and the automation rate of the interference intensity acquisition process can be improved.

The following are embodiments of the apparatus of the present application that may be used to perform embodiments of the method of the present application. For details which are not disclosed in the embodiments of the apparatus of the present application, reference is made to the embodiments of the method of the present application.

Referring to fig. 8, a block diagram of an interference strength obtaining apparatus according to an exemplary embodiment of the present application is shown. The interference strength obtaining apparatus may be used in a terminal to perform all or part of the steps performed by the terminal in the method provided by the embodiment shown in fig. 2 or fig. 3. The interference strength acquisition device may include:

a parameter obtaining module 801, configured to obtain a test parameter, where the test parameter includes a network standard of an antenna to be tested when the interference strength of the interference source to the antenna to be tested is tested;

a first configuration module 802, configured to configure the network standard of the antenna to be tested as the network standard indicated by the test parameter in a non-signaling mode;

a first obtaining module 803, configured to obtain a first interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested;

a second configuration module 804, configured to, when the test parameter indicates that the network standard of the antenna to be tested includes a second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configure the network standard of the antenna to be tested as the second network standard in the non-signaling mode;

a second obtaining module 805, configured to obtain a second interference strength received by the antenna to be tested, where the second interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested configured in the second network system.

In summary, by acquiring the test parameters, the test parameters include a network standard of the antenna to be tested when the interference strength of the test interference source to the antenna to be tested is indicated; under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameters; acquiring a first interference strength received by an antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by a terminal to the antenna to be tested; when the test parameters indicate that the network standard of the antenna to be tested comprises a second network standard when the test parameters indicate the interference strength of a test interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested into the second network standard in a non-signaling mode; and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system. According to the method and the device, an additional comprehensive tester is not needed, the interference intensity can be acquired through the terminal, the operation process of establishing signaling connection is avoided, the wireless network system can be automatically switched, manual operation is avoided, and the efficiency and the automation rate of the interference intensity acquisition process can be improved.

Optionally, the apparatus further comprises:

the starting module is used for automatically starting an interference source in the terminal;

a third configuration module, configured to reconfigure, in the non-signaling mode, the network standard of the antenna to be tested to the network standard indicated by the test parameter according to the test parameter;

a third obtaining module, configured to obtain a third interference strength received by the antenna to be tested, where the third interference strength is a noise signal strength received by the antenna to be tested when the interference source operates;

a fourth configuration module, configured to, when the test parameter indicates that the network standard of the antenna to be tested includes the second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configure the network standard of the antenna to be tested as the second network standard in the non-signaling mode;

a fourth obtaining module, configured to obtain a fourth interference strength received by the antenna to be tested, where the fourth interference strength is a noise signal strength received by the antenna to be tested in the second network system configured when the interference source operates;

a fifth obtaining module, configured to obtain, according to the first interference strength and the third interference strength, a first noise strength generated by the interference source to the antenna to be tested;

and the sixth obtaining module is configured to obtain, according to the second interference strength and the fourth interference strength, a second noise strength generated by the interference source to the antenna to be tested.

Optionally, the test parameter further includes a test frequency band supported by the network standard when the interference strength of the interference source to the antenna to be tested is indicated;

the first configuring module 802 is configured to configure the antenna to be tested to the network system and the test frequency band in the non-signaling mode.

Optionally, the apparatus further comprises:

a fifth configuration module, configured to, when the test parameter indicates that the test frequency band supported by the network standard includes a second test frequency band when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configure the test frequency band of the antenna to be tested as the second test frequency band in the non-signaling mode after the first obtaining module 803 obtains the first interference strength received by the antenna to be tested.

Optionally, the test parameter further includes an instruction indicating the working power of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is tested;

the first configuring module 802 is configured to configure the antenna to be tested to the network standard and the power to be operated in the non-signaling mode.

Optionally, the apparatus further comprises:

a sixth configuring module, configured to, when the test parameter indicates that the working power of the antenna to be tested includes a second working power when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configure the working power of the antenna to be tested as the second working power in the non-signaling mode after the first obtaining module 803 obtains the first interference strength received by the antenna to be tested.

Optionally, the first configuring module 802 is configured to, when the number of the antennas to be tested is greater than or equal to 2, configure the network standard of a first antenna to be tested as the network standard indicated by the test parameter in the non-signaling mode, where the first antenna to be tested is any one of the antennas to be tested;

the first obtaining module 803 is configured to obtain a first interference strength received by the first antenna to be tested;

the device further comprises:

and the seventh configuration module is configured to, in the non-signaling mode, automatically switch from the first antenna to be tested to a second antenna to be tested, and configure the network standard of the second antenna to be tested as the network standard indicated by the test parameter.

Optionally, the parameter obtaining module 801 includes: an information acquisition unit and a parameter acquisition unit;

the information acquisition unit is used for acquiring configuration information input in a configuration interface, wherein the configuration information comprises a network type to be tested;

and the parameter acquisition unit is used for acquiring the test parameters according to the configuration information.

Optionally, the information obtaining unit includes: the display sub-unit comprises a display sub-unit, a first acquisition sub-unit and a second acquisition sub-unit;

the display subunit is configured to display, in the configuration interface, a system identifier of a candidate network system, where the candidate network system includes all network systems supported by each antenna of the terminal;

the first obtaining subunit is configured to, when receiving a selection operation on the system identifier, obtain a network system corresponding to the selected system identifier as the network system to be tested;

the second obtaining subunit is configured to obtain the network standard to be tested as the input configuration information.

Optionally, the configuration information further includes an identifier of the antenna to be tested, or a working power of the antenna to be tested, or a frequency band to be tested of the network standard to be tested, and the information obtaining unit is configured to show a frequency band identifier of a candidate frequency band in the configuration interface, where the candidate frequency band is all frequency bands included in the network standard to be tested; when receiving the selection operation of the frequency band identifier, acquiring the frequency band corresponding to the selected frequency band identifier as the frequency band to be tested;

the second obtaining subunit is configured to obtain the network standard to be tested and the frequency band to be tested as the input configuration information;

alternatively, the first and second electrodes may be,

the information acquisition unit is used for displaying antenna identifications of candidate antennas in the configuration interface, wherein the candidate antennas are all antennas supporting the network standard to be tested in the terminal; when receiving the selection operation of the antenna identification, acquiring the antenna corresponding to the selected antenna identification as the antenna to be tested;

the second obtaining subunit is configured to obtain, as input, the configuration information from the network standard to be tested and the antenna to be tested;

alternatively, the first and second electrodes may be,

the information acquisition unit is used for displaying a power identifier of a candidate power in the configuration interface, wherein the candidate power is the working power of the antenna to be tested after the terminal configures the antenna to be tested to the network standard to be tested; when the selection operation of the power identifier is received, acquiring the working power corresponding to the selected power identifier as the power of the antenna to be tested;

the second obtaining subunit is configured to obtain the network standard to be tested and the power of the antenna to be tested as the input configuration information.

Optionally, the apparatus further comprises:

a seventh obtaining module, configured to obtain a first test power consumption and a first test consumed time before the interference source in the terminal is automatically turned on, where the first test power consumption is a power consumption consumed for obtaining the first interference strength and the second interference strength, and the first test consumed time is a total consumed time for obtaining the first interference strength and the second interference strength;

an eighth obtaining module, configured to determine a second test power consumption according to the first test power consumption, the first test time consumption, and a unit time length power consumption of the interference source, where the second test power consumption is a power consumption consumed by obtaining the third interference strength and the fourth interference strength;

and the prompting module is used for carrying out charging prompt when the residual electric quantity of the terminal is lower than the second test electric consumption.

Optionally, the apparatus further comprises:

the platform determining module is used for determining a processor platform corresponding to the terminal processor;

the execution module is used for executing the interference intensity acquisition method by calling the instruction corresponding to the processor platform;

when the processor platform is a high-pass platform, the instruction is a judgment Diag instruction, and when the processor platform is a joint platform, the instruction is an attention AT instruction.

Referring to fig. 9, which shows a schematic structural diagram of a terminal provided in an exemplary embodiment of the present application, as shown in fig. 9, the terminal includes a processor 910, a memory 920, a display component 930, and a sensor component 940, where the display component 930 is used to display an interface of a program running in a foreground in the terminal, and the sensor component 940 is used to collect data of each sensor. The memory 920 stores at least one instruction, and the instruction is loaded and executed by the processor 910 to implement some or all of the steps performed by the terminal in the interference strength obtaining method according to the above embodiments.

The present embodiments also provide a computer-readable storage medium, where at least one instruction, at least one program, a code set, or a set of instructions is stored in the storage medium, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by a processor to implement the interference strength obtaining method according to the above embodiments.

The embodiment of the present application further provides a computer program product, where at least one instruction is stored, and the at least one instruction is loaded and executed by the processor to implement the interference strength obtaining method according to the above various embodiments.

Those skilled in the art will recognize that, in one or more of the examples described above, the functions described in the embodiments of the present application may be implemented in hardware, software, firmware, or any combination thereof. When implemented in software, the functions may be stored on or transmitted over as one or more instructions or code on a computer-readable storage medium. Computer-readable storage media includes both computer storage media and communication media including any medium that facilitates transfer of a computer program from one place to another. A storage media may be any available media that can be accessed by a general purpose or special purpose computer.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (15)

1. An interference strength acquisition method, wherein the method is executed by a terminal, and the method comprises:

acquiring test parameters, wherein the test parameters comprise a network standard of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is indicated to be tested;

under a non-signaling mode, configuring the network standard of the antenna to be tested as the network standard indicated by the test parameter;

acquiring a first interference strength received by the antenna to be tested, wherein the first interference strength is the signal strength of a background noise generated by the terminal to the antenna to be tested;

when the test parameter indicates that the network standard of the antenna to be tested comprises a second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested as the second network standard in the non-signaling mode;

and acquiring a second interference strength received by the antenna to be tested, wherein the second interference strength is the signal strength of the background noise generated by the terminal to the antenna to be tested configured in the second network system.

2. The method of claim 1, further comprising:

automatically starting an interference source in the terminal;

under the non-signaling mode, reconfiguring the network standard of the antenna to be tested into the network standard indicated by the test parameter according to the test parameter;

acquiring a third interference strength received by the antenna to be tested, wherein the third interference strength is the noise signal strength received by the antenna to be tested when the interference source works;

when the test parameter indicates that the network standard of the antenna to be tested contains the second network standard when the test parameter tests the interference strength of the interference source to the antenna to be tested, automatically configuring the network standard of the antenna to be tested as the second network standard in the non-signaling mode;

acquiring fourth interference strength received by the antenna to be tested, wherein the fourth interference strength is the noise signal strength received by the antenna to be tested, which is configured to be under the second network system when the interference source works;

acquiring a first noise intensity generated by the interference source to the antenna to be tested according to the first interference intensity and the third interference intensity;

and acquiring a second noise intensity generated by the interference source to the antenna to be tested according to the second interference intensity and the fourth interference intensity.

3. The method according to claim 1, wherein the test parameters further include a test frequency band supported by the network standard when the interference strength of the interference source to the antenna to be tested is tested;

the configuring, in the non-signaling mode, the network standard of the antenna to be tested to the network standard indicated by the test parameter includes:

and under the non-signaling mode, configuring the antenna to be tested to the network standard and the test frequency band.

4. The method according to claim 3, wherein when the test parameter indicates that the test frequency band supported by the network standard when testing the interference strength of the interference source to the antenna to be tested includes a second test frequency band; after the obtaining of the first interference strength received by the antenna to be tested, the method further includes:

and under the non-signaling mode, automatically configuring the test frequency band of the antenna to be tested to the second test frequency band.

5. The method of claim 1, wherein the test parameters further include an operating power indicating the antenna to be tested when testing the interference strength of the interference source to the antenna to be tested;

the configuring, in the non-signaling mode, the network standard of the antenna to be tested to the network standard indicated by the test parameter includes:

and under the non-signaling mode, configuring the antenna to be tested to the network standard and the power to be operated.

6. The method of claim 5, wherein when the test parameter indicates that the operating power of the antenna to be tested includes a second operating power when the test parameter tests the interference strength of the interference source to the antenna to be tested, after the obtaining the first interference strength received by the antenna to be tested, further comprising:

and in the non-signaling mode, automatically configuring the working power of the antenna to be tested to the second working power.

7. The method according to claim 1, wherein when the number of the antennas to be tested is greater than or equal to 2, the configuring, in the non-signaling mode, the network standard of the antennas to be tested to the network standard indicated by the test parameter includes:

under the non-signaling mode, configuring a network standard of a first antenna to be tested as the network standard indicated by the test parameter, wherein the first antenna to be tested is any one of the antennas to be tested;

the obtaining of the first interference strength received by the antenna to be tested includes:

acquiring first interference strength received by the first antenna to be tested;

the method further comprises the following steps:

and under the non-signaling mode, automatically switching from the first antenna to be tested to a second antenna to be tested, and configuring the network standard of the second antenna to be tested as the network standard indicated by the test parameter.

8. The method of any one of claims 1 to 7, wherein the obtaining test parameters comprises:

acquiring configuration information input in a configuration interface, wherein the configuration information comprises a network system to be tested;

and acquiring the test parameters according to the configuration information.

9. The method of claim 8, wherein the obtaining configuration information entered in the configuration interface comprises:

displaying a system identifier of a candidate network system in the configuration interface, wherein the candidate network system comprises all network systems supported by each antenna of the terminal;

when receiving the selection operation of the system identification, acquiring the network system corresponding to the selected system identification as the network system to be tested;

and acquiring the network standard to be tested as the input configuration information.

10. The method according to claim 9, wherein the configuration information further includes a frequency band to be tested of the network standard to be tested, an antenna identifier of the antenna to be tested, or a working power of the antenna to be tested, and the obtaining of the configuration information input in the configuration interface includes:

displaying a frequency band identifier of a candidate frequency band in the configuration interface, wherein the candidate frequency band is all frequency bands contained in the network standard to be tested; when receiving the selection operation of the frequency band identifier, acquiring the frequency band corresponding to the selected frequency band identifier as the frequency band to be tested;

the acquiring the network standard to be tested as the input configuration information includes:

acquiring the network standard to be tested and the frequency band to be tested as input configuration information;

alternatively, the first and second electrodes may be,

displaying antenna identifications of candidate antennas in the configuration interface, wherein the candidate antennas are all antennas supporting the network standard to be tested in the terminal; when receiving the selection operation of the antenna identification, acquiring the antenna corresponding to the selected antenna identification as the antenna to be tested;

the acquiring the network standard to be tested as the input configuration information includes:

acquiring the network standard to be tested and the antenna to be tested as input configuration information;

alternatively, the first and second electrodes may be,

displaying a power identifier of candidate power in the configuration interface, wherein the candidate power is the working power of the antenna to be tested after the terminal configures the antenna to be tested to the network standard to be tested; when the selection operation of the power identifier is received, acquiring the working power corresponding to the selected power identifier as the power of the antenna to be tested;

the acquiring the network standard to be tested as the input configuration information includes:

and acquiring the network standard to be tested and the power of the antenna to be tested as the input configuration information.

11. The method of claim 2, further comprising, before the automatically turning on the interference source in the terminal:

acquiring a first test power consumption and a first test time consumption, wherein the first test power consumption is the power consumed by acquiring the first interference strength and the second interference strength, and the first test time consumption is the total time consumption for acquiring the first interference strength and the second interference strength;

determining second test power consumption according to the first test power consumption, the first test consumed time and the power consumption of the interference source in unit time, wherein the second test power consumption is the power consumption for acquiring the third interference intensity and the fourth interference intensity;

and when the residual electric quantity of the terminal is lower than the second test electric consumption quantity, carrying out charging prompt.

12. The method of claim 1, further comprising:

determining a processor platform corresponding to a terminal processor;

executing the interference intensity obtaining method by calling an instruction corresponding to the processor platform;

when the processor platform is a high-pass platform, the instruction is a judgment Diag instruction, and when the processor platform is a joint platform, the instruction is an attention AT instruction.

13. An interference strength acquisition apparatus, wherein the apparatus is used in a terminal, and the apparatus comprises:

the parameter acquisition module is used for acquiring test parameters, and the test parameters comprise a network standard of the antenna to be tested when the interference strength of the interference source to the antenna to be tested is indicated;

a first configuration module, configured to configure the network standard of the antenna to be tested as the network standard indicated by the test parameter in a non-signaling mode;

a first obtaining module, configured to obtain a first interference strength received by the antenna to be tested, where the first interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested;

the second configuration module is used for automatically configuring the network standard of the antenna to be tested to a second network standard in the non-signaling mode when the test parameters indicate that the network standard of the antenna to be tested contains the second network standard when the test parameters indicate that the interference strength of the interference source to the antenna to be tested is tested;

a second obtaining module, configured to obtain a second interference strength received by the antenna to be tested, where the second interference strength is a signal strength of a noise floor generated by the terminal to the antenna to be tested configured in the second network type.

14. A terminal comprising a processor and a memory, wherein the memory has stored therein at least one instruction, at least one program, a set of codes, or a set of instructions, which are loaded and executed by the processor to implement the interference strength acquisition method according to any one of claims 1 to 12.

15. A computer-readable storage medium, having stored therein at least one instruction, at least one program, a set of codes, or a set of instructions, which is loaded and executed by a processor to implement the interference strength acquisition method according to any one of claims 1 to 12.

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