CN113091793B - Test equipment and test method thereof - Google Patents

Abstract

The present disclosure relates to a test apparatus comprising: a plurality of test sites arranged in parallel along a straight line in the horizontal direction; the transmission module is positioned on the test bit and used for transmitting the tested mobile terminal among a plurality of test bits; and the test module is positioned above the transmission module and used for testing at least one sensor corresponding to the test module in the tested mobile terminal positioned on the test position. The test bits are arranged in parallel along the straight line, and the test bits can be added, removed or replaced without mutual influence among the test bits. The adaptability, accessibility and flexibility of the detection equipment are enhanced, corresponding test bits can be added, removed or replaced according to different use requirements, and the difficulty in changing, adding or reducing the test bits caused by changing the test items is reduced. The mobile terminal to be tested is transmitted among a plurality of test bits through the transmission module, so that the transmission efficiency is improved, and the mobile terminal to be tested is conveniently tested.

Description

Test equipment and test method thereof

Technical Field

The disclosure relates to the technical field of equipment, and in particular relates to test equipment and a test method of the test equipment.

Background

With the gradual popularization of electronics and intelligence, mobile terminals are one representative of the mobile terminals, and more fields use the mobile terminals to different extents. The mobile terminal is provided with a plurality of sensors, and different information can be perceived through the sensors, so that more intelligent service can be provided.

Before the mobile terminal is shipped after assembly, retests are needed to ensure the realizability of the sensor function in the mobile terminal, and when the sensor device in the mobile terminal is tested, a special test device is needed to test so as to ensure the quality of the mobile terminal.

Disclosure of Invention

The present disclosure provides a test apparatus and a test method of the test apparatus.

In a first aspect of embodiments of the present disclosure, there is provided a test apparatus comprising: a plurality of test sites arranged in parallel along a straight line in the horizontal direction; the transmission module is positioned on the test bit and used for transmitting the tested mobile terminal among a plurality of test bits; and the test module is positioned above the transmission module and used for testing at least one sensor corresponding to the test module in the tested mobile terminal positioned on the test position.

In one embodiment, different test bits have test modules for testing different sensors in the tested mobile terminal.

In one embodiment, the test apparatus further comprises: and the scanning module is positioned above or in front of the test bit and is used for acquiring the identification information of the tested mobile terminal by scanning the identification code area of the tested mobile terminal.

In one embodiment, the test apparatus further comprises: the processing module is positioned on the test position and is used for receiving and processing the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal; the scanning module is electrically connected with the processing module and is also used for: and establishing wireless communication connection between the processing module and the tested mobile terminal by scanning wireless communication information displayed by the tested mobile terminal.

In one embodiment, the test apparatus further comprises: and the display module is positioned on the test position and used for displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal.

In one embodiment, the test apparatus further comprises: the charging tray is used for bearing the tested mobile terminal; the transmission module comprises: the first transmission module is positioned below the test module and is used for transmitting the tray among a plurality of test positions along a first horizontal direction; the second transmission module is positioned below the first transmission module and is used for transmitting the material tray among a plurality of test positions along a second horizontal direction, and the first horizontal direction is opposite to the second horizontal direction.

In one embodiment, the test apparatus further comprises: and the lifting module is positioned at one side of the test position and used for transmitting the material tray between the first transmission module and the second transmission module.

In one embodiment, the tray comprises: the mobile terminal bearing piece is used for fixing the tested mobile terminals with different sizes or different shapes; the charging tray body is used for fixing the mobile terminal bearing piece.

In a second aspect of embodiments of the present disclosure, there is provided a test method, including: the method comprises the steps that a mobile terminal to be tested is transmitted among a plurality of test positions which are arranged in parallel along a straight line in the horizontal direction through a transmission module; and testing at least one sensor corresponding to the testing module in the tested mobile terminal on the testing position through the testing module above the transmission module.

In one embodiment, the method further comprises: and scanning the identification code area of the tested mobile terminal through a scanning module positioned above or in front of the test bit to acquire the identification information of the tested mobile terminal.

In one embodiment, the method further comprises: the wireless communication information displayed by the tested mobile terminal is scanned through the scanning module, and wireless communication connection between the processing module located on the test position and the tested mobile terminal is established; and processing the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal through the processing module.

In one embodiment, the method further comprises: and displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal through the display module positioned on the test position.

In one embodiment, the method further comprises: transmitting a tray bearing the tested mobile terminal among a plurality of test positions along a first horizontal direction through a first transmission module in the transmission modules; and the material tray is transmitted among the plurality of test positions along a second horizontal direction through a second transmission module positioned below the first transmission module, and the first horizontal direction is opposite to the second horizontal direction.

In one embodiment, the method further comprises: the material tray is transferred between the first transmission module and the second transmission module through the lifting module positioned at one side of the test position.

In a third aspect of the disclosed embodiments, there is provided a non-transitory computer-readable storage medium having stored therein computer-executable instructions that, when executed by a processor, implement the method of any one of the above.

The technical scheme provided by the embodiment of the disclosure can comprise the following beneficial effects:

the test equipment comprises a plurality of test sites, a transmission module and a test module which are arranged in parallel along a straight line. The transmission module is positioned on the test bit and used for transmitting the tested mobile terminal among a plurality of test bits; the test module is positioned above the transmission module and used for testing at least one sensor in the tested mobile terminal positioned on the test position. The test bits are arranged in parallel along the straight line, and the test bits can be added, removed or replaced without mutual influence among the test bits. The adaptability, accessibility and flexibility of the detection equipment are enhanced, corresponding test bits can be added, removed or replaced according to different use requirements, and the difficulty in changing, adding or reducing the test bits caused by changing the test items is reduced. The mobile terminal to be tested is transmitted among a plurality of test bits through the transmission module, so that the transmission efficiency is improved, and the mobile terminal to be tested is conveniently tested. After the corresponding test bit is added, removed or replaced, the at least one sensor in the tested mobile terminal can be tested through the test module located on the test bit, so that the detection efficiency is further improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

FIG. 1 is a schematic diagram of a test apparatus of a general mobile terminal;

FIG. 2 is a schematic diagram of a test apparatus according to an exemplary embodiment;

FIG. 3 is a schematic diagram of a scanning module according to an exemplary embodiment;

FIG. 4 is a schematic diagram of a tray according to an exemplary embodiment;

FIG. 5 is a schematic diagram showing a display module structure according to an exemplary embodiment;

FIG. 6 is a schematic diagram illustrating the structure of a test bit according to an exemplary embodiment;

FIG. 7 is a schematic diagram of a camera calibration assembly according to an exemplary embodiment;

FIG. 8 is a schematic diagram illustrating a configuration of a ranging calibration assembly according to an exemplary embodiment;

FIG. 9 is a schematic diagram illustrating another test bit configuration according to an example embodiment;

Fig. 10 is a schematic diagram illustrating the structure of an NFC test component according to an example embodiment;

FIG. 11 is a schematic diagram illustrating a configuration of a light sensation calibration/test assembly according to an exemplary embodiment;

FIG. 12 is a schematic diagram of a fingerprint test assembly, according to an example embodiment;

FIG. 13 is a flow chart of a test method according to an exemplary embodiment;

FIG. 14 is a flow chart illustrating another test method according to an exemplary embodiment;

FIG. 15 is a flow chart illustrating another test method according to an exemplary embodiment;

FIG. 16 is a flow chart illustrating another test method according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples do not represent all implementations consistent with the invention. Rather, they are merely examples of apparatus and methods consistent with aspects of the invention as detailed in the accompanying claims.

Referring to fig. 1, a schematic structure of a conventional test apparatus is shown. The workbench of the test equipment comprises a workbench surface and a main panel, wherein a station turntable mechanism and a protection plate are arranged on the workbench surface, four stations are uniformly arranged around the station turntable mechanism, and test clamps corresponding to the four stations are also uniformly arranged in the station turntable mechanism and are used for placing test mobile phones. The test equipment needs to manually place products such as mobile phones on the test fixture, and after the test is finished, the products such as mobile phones are manually taken out of the test fixture.

The test equipment is a surrounding type test station, the number of the test stations is fixed and limited due to the influence of factors such as a main panel of a workbench surface, the layout of the test stations is limited, more test stations are difficult to increase, and when more test projects are needed, no redundant test stations exist, and only four existing test stations can be recycled. Therefore, the accessibility, flexibility and suitability of the test equipment are poor, the test efficiency is low, and the update of the test equipment and the improvement of the test efficiency are not facilitated.

Referring to fig. 2, a schematic structural diagram of a test apparatus according to an embodiment of the present disclosure is provided, where the test apparatus includes:

A plurality of test sites 1 arranged in parallel along a straight line in the horizontal direction.

And the transmission module 2 is positioned on the test bit 1 and is used for transmitting the tested mobile terminal among the plurality of test bits 1.

And the test module 3 is positioned above the transmission module and is used for testing at least one sensor corresponding to the test module in the tested mobile terminal positioned on the test position 1.

The test bits 1 in the embodiment are arranged in parallel along a straight line in the horizontal direction, each individual test bit 1 does not affect each other, and each test bit can test the tested mobile terminal individually. The test bit 1 may be an independent test cabinet for testing the tested mobile terminal. The mobile terminal may include a mobile terminal including at least one sensing device, such as a mobile phone, a tablet computer, a vehicle-mounted central control device, a wearable device, an intelligent device, and the intelligent device may include an intelligent office device, an intelligent home device, and the like.

The adjacent test sites 1 can be connected through a connecting piece or a fixing piece, and the gap between the adjacent test sites 1 after connection is smaller than a preset threshold value, so that the transmission module 2 can conveniently transmit the tested mobile terminal among different test sites 1.

Since the plurality of different test bits 1 are arranged in parallel along a straight line in the horizontal direction, the number of the test bits 1 is not limited, and the test bits 1 can be adjusted according to actual use requirements, such as adding, removing or replacing, and the adjusted test bits are still arranged in parallel along the straight line, so that the next adjustment is performed according to the use requirements. In this embodiment, shown in fig. 2 are 5 test bits, namely test bit 101, test bit 102, test bit 103, test bit 104, and test bit 105, arranged side-by-side along a straight line.

Through a plurality of test positions 1 that set up in parallel along the straight line in the horizontal direction, can increase, remove or replace corresponding test position 1 according to different user demands, strengthened check out test set's suitability, accessibility and flexibility, reduced the degree of difficulty that the test position that leads to because of the change of test item changes, increases or reduces, improved check out test set's detection efficiency.

For example, the test bit with different test modules 3 can be adjusted according to the test item and/or the test object actually required, and then at least one sensor in the tested mobile terminal is tested through different test modules 3 in different test bits 1.

The test bit 1 includes a transmission module 2, and the position of the transmission module 2 in the test bit 1 is not limited, in this embodiment, the transmission module 2 is located at the middle lower part of the test bit 1, so that the test module 3 can test the tested object. The transmission modules 2 in different test bits 1 have the same height, and the interval is smaller than a preset threshold value, so that the tested mobile terminal can be conveniently transmitted among a plurality of test bits 1 through the transmission modules 2. The preset threshold value can be set according to actual use requirements.

The transmission module 2 includes, but is not limited to: conveyor belts, roller conveyors, and the like. The specific structure of the transfer module 2 is not limited here, and for example, the specific structure of the conveyor belt and the roller conveyor is not limited as long as the mobile terminal under test can be transferred between the transfer modules 2 of the plurality of test sites 1.

In one embodiment, each transmission module 2 may individually perform driving of transmission, and the transmission module 2 may include a driver, for example, a motor, etc., for driving a conveyor belt or a transmission roller, etc., so as to transmit the tested mobile terminal.

And the test module 3 is positioned above the transmission module 2 and is used for testing at least one sensor in the tested mobile terminal positioned on the test position 1, wherein the sensor can be a sensor corresponding to the test module. The specific position of the test module 3 above the transmission module 2 in the test bit 1 is not limited.

Because the test bit 1 is arranged in parallel along a straight line, the test bit can be added, removed or replaced according to actual use requirements, and then the test module 3 can be added, removed or replaced, so that the test of the sensor in the tested mobile terminal according to service requirements is realized.

The test modules 3 in the same test bit 1 can be different, and different test modules 3 in the same test bit 1 are used for testing different sensors in the tested mobile terminal. Different test sites 1 can also be provided with test modules 3 for testing different sensors in the tested mobile terminal. The test modules 3 in the different test bits 1 are also different, and the different test modules 3 included in the different test bits 1 are used for carrying out different tests on different sensors in the tested mobile terminal.

Test module 3 includes, but is not limited to: camera bellows calibration test subassembly, apart from feel calibration subassembly, light sense calibration subassembly, NFC read test subassembly, spirit level, acceleration sensor, gyroscope, fingerprint test subassembly, light sense test subassembly and/or apart from feel test subassembly etc.. When a plurality of test modules 3 are included in a single test site, the positions among the plurality of test modules 3 are not limited herein, and may be adaptively set according to business requirements. When a plurality of test components are included in the single test bit 1, the positions between the plurality of test components are not limited.

The test modules 3 in each test bit 1 can be set according to actual service requirements, and the test components included in the test modules 3 can be determined according to the type of at least one sensor included in the tested mobile terminal. For example, the test module in the first test station includes a camera calibration test module and a fingerprint test module, and the test module in the second test station includes a distance sensing calibration module and a light sensing calibration module.

The position of at least one test component included in the test module 3 at the test site 1 is not limited, and can be set according to actual service requirements, so that the sensor in the tested mobile terminal transmitted by the transmission module 2 in the test site 1 can be tested, and a specific test sequence or a test process is not limited, and the test can be performed according to a preset sequence.

For example, the tested mobile terminal includes a light sensor, a distance sensor and a fingerprint sensor, and the tested mobile terminal is tested by a first test bit and then tested by a second test bit. When at least one sensor in the tested mobile terminal is tested in the first test position, the darkroom calibration test can be performed on the light sensor in the tested mobile terminal through the darkroom calibration test assembly, and then the fingerprint sensor is tested through the fingerprint test assembly. And then, performing calibration test on the distance sensor in the tested mobile terminal through the distance sensing calibration component in the second test position, and finally performing calibration test on the light sensor through the light sensing calibration component.

Through the plurality of test bits of the parallel equipment along the straight line in the embodiment, the adaptability, accessibility and flexibility of the detection equipment are enhanced, corresponding test bits can be added, removed or replaced according to different use requirements, and the difficulty in changing, adding or reducing the test bits caused by changing test items is reduced. The mobile terminal to be tested is transmitted among a plurality of test bits through the transmission module, so that the transmission efficiency is improved, and the mobile terminal to be tested is conveniently tested. After the corresponding test bit is added, removed or replaced, the at least one sensor in the tested mobile terminal can be tested through the test module located on the test bit, so that the detection efficiency is further improved.

Referring to fig. 2, in one embodiment, the test apparatus further comprises: and the scanning module 4 is positioned above or in front of the test bit 1 and is used for acquiring the identification information of the tested mobile terminal by scanning the identification code area of the tested mobile terminal.

The scanning module 4 may be a module such as a code scanning gun that can scan the identification code area of the tested mobile terminal, and the specific structure is not limited herein. The scanning module 4 can obtain the identification information of the tested mobile terminal by scanning the identification code area of the tested mobile terminal, and the identification information is used as the unique identification code of the tested mobile terminal and used for distinguishing different tested mobile terminals.

The identification information can comprise identification information in the forms of two-dimensional codes, bar codes and the like, and is displayed in the form of two-dimensional codes or bar codes. The identification information includes, but is not limited to: and the material number and serial number of the tested mobile terminal.

After the scanning module 4 scans the identification code region of the tested mobile terminal, the testing device can identify the tested mobile terminal, which means that the tested mobile terminal is scanned and identified by the testing device, and the testing device tests the tested mobile terminal. Each tested mobile terminal needs to be scanned by the scanning module 4 before being tested by the testing module 3 in the tested bit 1, and the testing equipment can identify each scanned tested mobile terminal, so that each tested mobile terminal can be matched with the testing information, and the testing information of each tested mobile terminal can be more conveniently determined.

Referring to fig. 3, a schematic structural diagram of a scan module according to an embodiment is provided. The scanning module 4 includes a scanning bracket 401, a cylinder 402, an angle adjusting member 403, and a scanning member 404. The scan holder 401 is used for fixing and supporting the air cylinder 402, the angle adjusting part 403 and the scan part 404, and the bottom of the scan holder 401 may be fixed in front of or above the first test site 1 for testing the tested mobile terminal. A cylinder 402 is located at the top of the scanning carriage 401 for moving the scanning unit 404 in the horizontal direction. An angle adjustment member 403 is coupled to the telescoping member of the cylinder 402 for adjusting the angle of the scanning assembly 404. The scanning unit 404 is connected to the angle adjusting unit 403, and is used for scanning identification information of the tested mobile terminal.

Through the cylinder 402 and the angle adjusting part 403 in the scanning module 4, the position of the scanning part 404 can be adjusted according to service requirements, and the feeding, the scanning and the like are facilitated.

Referring to fig. 2, in another embodiment, the test apparatus further comprises: an upper level 5 and a lower level 6.

The material loading level 5 includes the material loading cabinet body, and the top of this material loading cabinet body is provided with the feed inlet, and the feed inlet is linked together with the transmission module 2 of first test position 101, will be surveyed mobile terminal and transmit to the transmission module 2 of first test position 101 through this feed inlet. The blanking level 6 includes the unloading cabinet body, and the top of this unloading cabinet body is provided with the feed opening, and the feed opening is linked together with the transmission module 2 of fifth test position 105, can take off the mobile terminal that is surveyed through this feed opening.

And the loading level 5 is positioned in front of the test level 1 arranged in parallel along the straight line and is used for transmitting the tested mobile terminal to the test level 1, so that the test level 1 is convenient for testing the tested mobile terminal. And the discharging level 6 is positioned behind the test level 1 which is arranged in parallel along the straight line and is used for outputting the tested mobile terminal from the test equipment. The loading level 5 and the unloading level 6 may be separate cabinets.

The loading level 5 is located in front of one end of the test bits arranged in parallel along the straight line, and the tested mobile terminal can be conveniently transmitted to the test bit 1 for testing through the loading level 5. The blanking level 6 is positioned at the rear of the test bit positioned at the other end of the test bits arranged in parallel along the straight line, and the tested mobile terminal after the test can be output from the test equipment through the blanking level 6, so that the other tested mobile terminals can be tested conveniently.

Referring to fig. 2, in one embodiment, the scanning module 4 is located at the top of the feeding unit 5, and is configured to scan the mobile terminal to be tested before the mobile terminal to be tested is transmitted to the test station 1 through the feeding unit 5, so as to obtain identification information of the mobile terminal to be tested, so that the test information corresponds to the mobile terminal to be tested.

Referring to fig. 2, in another embodiment, the scanning module 4 may also be located at the top of the blanking level 6, and is configured to retest the tested mobile terminal tested by the module 3, and acquire the identification information of the tested mobile terminal again. The identification information of the tested mobile terminal scanned twice can determine that the tested mobile terminal has completed testing, thereby facilitating test statistics of the tested mobile terminal and the like.

In one embodiment, the test apparatus further comprises:

the processing module is positioned on the test position 1 and is used for receiving and processing the test information of the test module 3 for testing at least one sensor corresponding to the test module in the tested mobile terminal.

The scanning module 4 is electrically connected with the processing module and is also used for: and establishing wireless communication connection between the processing module and the tested mobile terminal by scanning the wireless communication information displayed by the tested mobile terminal.

The wireless communication information displayed by the tested mobile terminal can be wireless network connection information, and the wireless communication connection between the processing module and the tested mobile terminal can be established through the wireless network connection information. The wireless communication information can be displayed in the form of a two-dimensional code and the like, and after the scanning module 4 scans the wireless communication information, the processing module is in wireless connection with the mobile terminal to be tested, and the processing module and the mobile terminal to be tested can perform wireless communication, such as output transmission and the like.

The position of the processing module in the test bit 1 is not limited, the scanning module 4 establishes wireless communication connection between the processing module and the tested mobile terminal after scanning the wireless communication information displayed by the tested mobile terminal, and the tested mobile terminal sends the test information to the processing module in a wireless communication mode after the test module 3 tests the tested mobile terminal.

The scanning module 4 can also send the identification information of the tested mobile terminal to the processing module after scanning the identification information of the tested mobile terminal, so that the processing module can process the test information of the sensor in the tested mobile terminal according to the identification information of the tested mobile terminal and the test module 3.

In another embodiment, the processing module is further configured to: after receiving the test information sent by the tested mobile terminal and the identification information of the tested mobile terminal sent by the scanning module 4, matching the test information with the representation information, and uploading the test information, the identification information and the matching result to a background server connected with the processing module, so that the test information of the tested mobile terminal can be checked conveniently.

In another embodiment, the test apparatus further comprises: the display module is positioned on the test position 1 and used for displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal. The display module located on test site 1 in this embodiment is not shown.

The display module is electrically connected with the processing module, after the processing module matches the test information of the tested mobile terminal by the test module 3 with the identification information of the tested mobile terminal scanned by the scanning module 4, the test information, the identification information and the matching result are generated to the display module, and the display module displays the test information, the identification information and the matching result.

The position of the display module in the test position 1 can be set according to actual service requirements, and the specific position of the display module on the test position 1 is not limited, so that the display module is convenient to watch. After the display module displays the test information, the identification information and the matching result, relevant personnel can conveniently check the test conditions, and relevant test conditions can be conveniently checked.

Referring to fig. 2, in another embodiment, the display module 7 is further located on the loading level 5, and is used for displaying the identification information scanned by the scanning module 4, so as to facilitate the relevant personnel to check whether the scanning module 4 finishes scanning the tested mobile terminal, and so on.

The display module 7 may also be located on the discharging level 6, and is used for displaying the identification information scanned by the scanning module 4 located on the discharging level 6, the test information of the test module 3 on the tested mobile terminal, and the like.

The display modules 7 located on the loading level 5 and the unloading level 6 may be display modules having the same structure as the display modules located on the test level 1.

In another embodiment, the test apparatus further comprises:

and the charging tray 8 is used for bearing the tested mobile terminal. The tested mobile terminal is located on the material tray 8, and the transmission module 2 transmits the tested mobile terminal among different test positions 1 through the transmission material tray 8.

Referring to fig. 4, a schematic structural diagram of a tray is shown, the tray includes: mobile terminal carrier 801 and tray body 802, mobile terminal carrier 801 is located on tray body 802.

The mobile terminal carrier 801 is used for fixing the tested mobile terminals with different sizes or different shapes. The mobile terminal bearing part 801 can be determined according to the tested mobile terminal, and the mobile terminal bearing part 801 matched with the tested mobile terminal can better fix the tested mobile terminal, so that the tested mobile terminal can be conveniently transmitted and tested.

The tray body 802 is used for fixing the mobile terminal bearing part 801, the tray body 802 is a universal tray, is suitable for different test positions, and can bear and fix different mobile terminal bearing parts 801. The tray body 802 is located on the transmission module 2, and when the transmission module 2 transmits the tested mobile terminal, the tested mobile terminal is further transmitted through the transmission tray 8.

Since the mobile terminal bearing member 801 is located on the tray body 802, when testing different tested mobile terminals, different mobile terminal bearing members 801 can be selected, and only the mobile terminal bearing member 801 is required to be replaced, so that the tray body 802 does not need to be replaced, and the replacement cost of the tray can be reduced.

Referring to fig. 2, in another embodiment, the transmission module 2 includes:

the first transmission module 201 is located below the test module 3, and is configured to transmit the tray 8 between the plurality of test sites 1 along the first horizontal direction.

The second transmission module 202 is located below the first transmission module 201, and is configured to transmit the tray 8 between the plurality of test sites 1 along a second horizontal direction, where the first horizontal direction is opposite to the second horizontal direction.

When testing the tested mobile terminal, the first transmission module 201 transmits the tested mobile terminal between the adjacent test sites 1, and the transmission direction in the process is a first horizontal direction, namely, the transmission direction is from one end to the other end of a plurality of test sites which are arranged in parallel along a straight line. For example, the tray 8 carrying the mobile terminal under test may be transferred from the test site adjacent to the loading site 5 to the test site adjacent to the unloading site 6. The test station adjacent to the blanking level 6 is transferring the tray 8 to the blanking level 6.

After the tray 8 is transferred to the discharging position 6 by the first transfer module 201 and the tested mobile terminal is removed, the second transfer module 202 transfers the tray 8 between the plurality of test positions 1 in the second horizontal direction. For example from the blanking level 6 in the direction of the upper level 5. During this transfer process, the second transfer module 202 only transfers the tray 8, and the mobile terminal to be tested is no longer located on the tray 8.

The second transfer module 202 transfers the trays 8 from the discharge level 6 to the feed level 5 in the second horizontal direction, and transfers the trays 8 to the feed level 5 again, so that the trays 8 can be continuously recycled in the feed level 5. The mobile terminal carrier 801 can be continuously transmitted and tested for the same batch of tested mobile terminals with the same size or shape without replacing the mobile terminal carrier 801, so that the transmission efficiency and the testing efficiency are improved. If the size or shape of the mobile terminal to be tested is changed, the mobile terminal carrier 801 can be replaced, and then the same batch of mobile terminals to be tested after the size or shape is changed can be continuously transmitted and tested, so that the transmission efficiency and the testing efficiency can be improved.

In another embodiment, the test apparatus further comprises:

And the lifting module is positioned at one side of the test position and used for transmitting the material tray between the first transmission module and the second transmission module.

After the tray 8 is transferred to the discharging position 6 through the first transfer module 201 and the tested mobile terminal is removed, the lifting module transfers the tray 8 from the height of the first transfer module 201 to the height of the second transfer module 202, thereby completing the transfer of the tray 8 between the first transfer module 201 and the second transfer module 202. After the lifting module moves the tray 8 from the height of the first transmission module 201 to the height of the second transmission module 202, the second transmission module 202 can conveniently transmit the tray 8 from the discharging position 6 to the feeding position 5 along the second horizontal direction, and further the tray can be reused conveniently.

After the second transfer module 202 transfers the tray 8 to the upper level 5 in the second horizontal direction, since the second transfer module 202 is lower than the first transfer module 201, it is also necessary to move the tray from the height of the second transfer module 202 to the height of the first transfer module 201 by the lifting module. This may facilitate the first transfer module 201 to continue transferring the tray along the first horizontal direction.

The lifting module in this embodiment includes, but is not limited to: the specific structure of the lifting bracket, the lifting rod, etc. is not limited herein, and any lifting structure capable of transferring the tray 8 between the first transfer module 201 and the second transfer module 202 is within the scope of the present embodiment.

In one embodiment, the lifting module is located at the loading level and the unloading level. The lifting module can be located in the feeding level 5, and the feeding port is located above the lifting module, so that the feeding of the tested mobile terminal can be facilitated after the lifting module ascends the tray from the height of the second transmission module to the height of the first transmission module. The lifting module can also be positioned in the discharging position 6, and the discharging opening is positioned above the lifting module. Therefore, the mobile terminal to be tested can be conveniently taken down, and then the tray is downwards moved to the height of the second transmission module.

In another embodiment, a display module is further provided, and referring to fig. 5, a schematic diagram of the display module is provided.

The display module includes:

a display 701 for displaying the test information.

An input component 702 for inputting control instructions. The input components may include input components such as a mouse, keyboard, etc.

A control button 703 for controlling the switching of the test device. For example, an on button, an off button, a scram button, etc.

An alarm component 704 can also be included for prompting corresponding information based on a test status of the test equipment. The test states of the test device include a normal test state and an abnormal test state. The alarm assembly includes: a light alarm, a sound alarm and the like, wherein the light alarm comprises an alarm lamp and the like. When the test is in a normal test state, the alarm component prompts normal information, and when the test is in an abnormal test state, the alarm component prompts abnormal information, and the prompt information of the two states is different.

May further include: a gas source assembly 705 for controlling the pneumatic portion of the test equipment.

In another embodiment, a test bit is also provided, and referring to fig. 6, a schematic structural diagram of the test bit is provided.

The test bit includes: the camera module comprises a first transmission module 201, a second transmission module 202, a camera module 301 and a distance sensing calibration module 302.

The first transmission module 201 is higher than the second transmission module 202, the camera calibration assembly 301 is located above the first transmission module 201, and the distance sensing calibration assembly 302 is located above the camera calibration assembly 301.

Referring to fig. 7, a schematic diagram of a camera module is shown.

The camera calibration assembly includes an open-close window 3011, an open-close window control assembly 3012, and a securing assembly 3013. The window opening and closing control component 3012 controls the opening and closing of the window opening and closing 3011, and the window opening and closing control component 3012 can be a cylinder, a push rod and the like. The fixing component 3013 is used for fixing the camera calibration component, and may be a buckle fixing component or the like.

When the camera calibration assembly tests, the opening and closing window control assembly 3012 controls the opening and closing window 3011 to be in a closed state. After the camera bellows calibration assembly is tested, the opening and closing window control assembly 3012 pushes the opening and closing window 3011 to open, and the gray card on the distance sensing calibration assembly 302 is just located above the opening and closing window 3011, so that the distance sensor of the tested mobile terminal can be calibrated.

Referring to fig. 8, a schematic diagram of a distance sensing calibration assembly is shown.

The distance sensing calibration assembly comprises: support 3021, driving motor 3022, lead screw slide 3023, gray card 3024 and black card 3025. Lead screw sliding table 3023 and driving motor 3022 are located on support 3021, ash card 3024 and black card 3025 are located on lead screw sliding table 3023, driving motor 3022 is used for driving lead screw sliding table 3023 to move, and then driving ash card 3024 and black card 3025 to move, so that the tested mobile terminal can be tested conveniently.

In another embodiment, another test bit is provided, and referring to fig. 9, a schematic structural diagram of the test bit is provided.

The test bit includes: a light sense calibration component 303, an NFC test component 304, a level 305, a first transmission module 201, and a second transmission module 202. The first transmission module 201 is located above the second transmission module 202, the NFC testing device 304 is located above the first transmission module 201, the level meter 305 is located above the NFC testing device 304, and the light sensing calibration device 303 is located above the level meter 305. The level meter 305 is used for ensuring the levelness of the horizontal plane of the testing device so as to meet the testing of the gravitational acceleration sensor and the gyroscope of the tested mobile terminal.

Referring to fig. 10, a schematic structural diagram of an NFC testing component is shown.

The NFC test component includes an NFC reader 3041, a horizontal direction adjusting position 3042 and a vertical direction adjusting position 3043, and can be adjusted according to actual use requirements.

Referring to fig. 11, a schematic structural diagram of a light sensation calibration device/test device is shown.

The light sensation calibration/test assembly 303 includes: a light source panel 3031, a vertical direction regulator 3032, a horizontal direction regulator 3033, a movable guide post 3034 and a fixed plate 3035. One end of the movable guide post 3034 is fixedly connected with the light source panel 3031, and the other end is arranged on the fixed plate 3035 in a penetrating way. One end of the vertical direction adjusting member 3032 is connected with the light source panel 3031, and the other end is penetrated through the fixing plate 3035, and the distance between the light source panel 3031 and the fixing plate 3035 can be adjusted by the rotation of the vertical direction adjusting member 3032, so that the light sensor can be conveniently calibrated and tested. The horizontal direction adjusting member 3033 is connected to a support or the like in the test site, so that the position of the light sensation calibration device/test device 303 in the test site can be adjusted, and the horizontal direction movement of the light sensation calibration device/test device 303 in the test site can be adjusted by the horizontal direction adjusting member 3033.

In another embodiment, a fingerprint test assembly is also provided, and referring to fig. 12, a schematic structural diagram of the fingerprint test assembly is provided.

The fingerprint test assembly includes: fingerprint head 3061, elevator 3062, servo motor 3063, and fingerprint test assembly stand 3064. The lifter 3062 and the servo motor 3063 are fixed on the fingerprint test assembly bracket 3064, the lifter 3062 is connected with the servo motor 3063, and the servo motor 3063 is used for driving the lifter 3062 to lift. The fingerprint head 3061 is fixedly connected with the lifter 3062, and the servo motor 3063 drives the fingerprint head 3061 to move by driving the lifter 3062 to lift, so that fingerprint test is performed.

In another embodiment, a test method is also provided. Referring to fig. 13, a flow chart of the test method is shown. The method comprises the following steps:

step S100, the tested mobile terminal is transmitted among the test positions through a transmission module which is positioned on a plurality of test positions which are arranged in parallel along a straight line in the horizontal direction.

Step 200, testing at least one sensor corresponding to the testing module in the tested mobile terminal on the testing position through the testing module above the transmission module.

Since the plurality of test bits are arranged in parallel along the straight line in the horizontal direction, each test bit comprises the transmission module, the tested mobile terminal can be transmitted in the plurality of test bits arranged in parallel along the straight line through the transmission module. The number of the plurality of test bits arranged in parallel along the straight line is not limited, and the test bits do not affect each other, so that the test bits can be adjusted according to actual service requirements.

Through a plurality of test positions that set up in parallel along the straight line in the horizontal direction, can increase, remove or replace corresponding test position according to different user demands, strengthened check out test set's suitability, accessibility and flexibility, reduced the test position change, increase or reduce the degree of difficulty because of the change of test item, improved check out test set's detection efficiency.

In another embodiment, the method further comprises:

and scanning the identification code area of the tested mobile terminal through a scanning module positioned above or in front of the test bit to acquire the identification information of the tested mobile terminal.

After the scanning module scans the identification code area of the tested mobile terminal and acquires the identification information of the tested mobile terminal, the scanning module can send the identification information of the tested mobile terminal to the processing module, and the test equipment can identify the tested mobile terminal to indicate that the tested mobile terminal is tested by the test equipment. The identification information can also be used for matching test information with a corresponding mobile terminal under test, etc.

In another embodiment, another test method is provided, referring to fig. 14, the method further comprising:

And step S300, scanning the wireless communication information displayed by the tested mobile terminal through the scanning module, and establishing wireless communication connection between the processing module located on the test position and the tested mobile terminal.

Step 400, the processing module is used for processing the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal.

After the scanning component scans the wireless communication information displayed by the tested mobile terminal, the wireless communication connection between the processing module and the tested mobile terminal can be established, and the wireless communication can be performed between the tested mobile terminal and the processing module through the wireless communication connection. In this embodiment, the mobile terminal to be tested may send, to the processing module, test information for testing the mobile terminal to be tested by the test module through the wireless communication connection.

After the processing module receives the test information, the processing module may process the test information, for example, upload the test information to a background server or send the test information to other modules.

In another embodiment, the method further comprises: and displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal through the display module positioned on the test position.

The display module can receive the information sent by the processing module and then display the received information, so that related personnel can conveniently check the information in the testing process, and the testing efficiency is improved.

In another embodiment, another test method is provided, and referring to fig. 15, the method further includes:

and S500, transmitting the tray bearing the tested mobile terminal among a plurality of test positions along a first horizontal direction through a first transmission module in the transmission modules.

Step S600, transmitting the tray between the plurality of test sites along a second horizontal direction by a second transmission module located below the first transmission module, where the first horizontal direction is opposite to the second horizontal direction.

When the tested mobile terminal is tested, the tested mobile terminal is transmitted between the adjacent test positions through the first transmission module, and the transmission direction in the process is a first horizontal direction, namely, the transmission direction is from one end to the other end of a plurality of test positions which are arranged in parallel along a straight line. For example, the tray carrying the mobile terminal to be tested may be transferred from the test site adjacent to the loading site to the test site adjacent to the unloading site. The test bit adjacent to the blanking bit transfers the tray to the blanking bit.

After the tray is conveyed to the discharging position through the first conveying module and the tested mobile terminal is taken down, the second conveying module conveys the tray among the plurality of testing positions along the second horizontal direction. For example, from the blanking level to the upward level. In the transmission process, the second transmission module only transmits the material tray, and the tested mobile terminal is no longer positioned on the material tray.

The trays are transported from the discharge level to the upper level in the second horizontal direction by the second transport module, and the trays 8 are transported to the upper level again, so that the recycling of the trays in the upper level can be continued. The method can continuously transmit and test the tested mobile terminals of the same batch with the same size or shape under the condition of not replacing the mobile terminal bearing piece, thereby improving the transmission efficiency and the test efficiency. If the size or the shape of the tested mobile terminal is changed, the tested mobile terminal in the same batch after the size or the shape is changed can be continuously transmitted and tested after the mobile terminal bearing piece is changed, and the transmission efficiency and the testing efficiency can be improved as well.

In another embodiment, the method further comprises:

the material tray is transferred between the first transmission module and the second transmission module through the lifting module positioned at one side of the test position.

After the tray is conveyed to the discharging position through the first conveying module and the tested mobile terminal is taken down, the lifting module conveys the tray from the height of the first conveying module to the height of the second conveying module, and therefore the tray is conveyed between the first conveying module and the second conveying module. After the lifting module moves the material tray from the height of the first transmission module to the height of the second transmission module, the second transmission module can conveniently transmit the material tray from the discharging position to the feeding position along the second horizontal direction, and the repeated use of the material tray is facilitated.

After the second transmission module transmits the tray to the feeding level along the second horizontal direction, the second transmission module is lower than the first transmission module, so that the tray is required to be moved from the height of the second transmission module to the height of the first transmission module through the lifting module. Therefore, the first transmission module can conveniently continue to transmit the material tray along the first horizontal direction.

In another embodiment, a test method is also provided.

The test equipment in this embodiment includes 5 test stations arranged in parallel along a straight line, namely a first test station, a second test station, a third test station, a fourth test station, and a fifth test station. Besides 5 test stations, the device also comprises a feeding station and a discharging station. The test module in the first test station comprises a camera bellows calibration assembly and a distance sensing calibration assembly. The test module in the second test station comprises a light sensation calibration assembly, an NFC test assembly and a level meter. The test module in the third test station comprises a first fingerprint test assembly and a light sensation calibration assembly. The test module in the fourth test station comprises a second fingerprint test assembly and a light sensing test assembly. The test module in the fifth test station comprises a light sensing test assembly and a distance sensing test assembly. The feeding station and the discharging station comprise lifting modules. The mobile terminal to be tested in this embodiment is a mobile phone.

Referring to fig. 16, a flow chart of the method is shown, the method is as follows:

the lifting module in the feeding station is located at the height of the first transmission module, the charging tray is located on the lifting module in the feeding station, and the tested mobile terminal is located on the charging tray. The mobile terminal to be tested is positioned on the charging tray, the scanning module scans the identification information of the mobile terminal to be tested, the identification information comprises the material information of the mobile phone, and the identification information of the mobile terminal to be tested is uploaded to the processing module. And the scanning module is used for scanning the wireless communication information displayed by the tested mobile terminal and establishing wireless communication connection between the tested mobile terminal and the processing module. The wireless communication connection includes a WIFI connection, etc.

The lifting module comprises a third transmission module in the feeding station, and the third transmission module transmits the material tray to the first transmission module in the first test position. And the first transmission module in the first test station moves the tested mobile terminal to a preset position to start the test. And closing an opening and closing window in the camera calibration assembly to form a camera environment, and connecting the processing module to the tested mobile terminal through wireless communication to send a camera calibration instruction, and carrying out camera calibration by the tested mobile terminal. After the camera bellows calibration test is completed, a distance sensing calibration instruction is sent to the tested mobile terminal, a screw rod sliding table in the distance sensing calibration assembly is controlled to drive the ash card to a designated position, and distance sensing calibration is carried out on the tested mobile terminal. After the distance sensing calibration is completed, the tray is conveyed to the second testing station through the first conveying module in the first testing station.

The first transmission module in the second test station receives the tray transmitted by the first transmission module in the first test station, and the first transmission module in the second test station moves the tray to a preset position. And sending a light sensation calibration instruction and an NFC test instruction to the tested mobile terminal, performing front light sensation calibration on the tested mobile terminal through a fixed light source of the light sensation calibration assembly, and completing NFC test on the tested mobile terminal through an NFC white card, an NFC card reader and a test program in the NFC test assembly. And then, performing an acceleration sensor and gyroscope testing program on the tested mobile terminal. And finally, conveying the material tray to a third test station through a first conveying module in the second test station.

And the first transmission module in the third test station moves the tray to a preset position, a first fingerprint test instruction is sent to the tested mobile terminal, and the tested mobile terminal starts a first fingerprint test program. The lifter of the first fingerprint test assembly drives 3 common silica gel fingerprint heads to sequentially press down, and meanwhile the 3 common silica gel fingerprint heads are moved in the horizontal plane perpendicular to the streamline direction, so that the 3 fingerprint heads are sequentially pressed down in the fingerprint test area of the tested mobile terminal. And after the fingerprint test is completed, the light sensation calibration assembly is used for carrying out back light sensation calibration on the tested mobile terminal. After the tests are completed, the tray is conveyed to a fourth test station through the first conveying module of the third test station.

The first transmission module in the fourth test station moves the tray to a preset position, sends a second fingerprint test instruction to the tested mobile terminal, the mobile phone starts a second fingerprint test program, and the lifter of the second fingerprint test assembly drives the 3 strip-shaped silica gel fingerprint heads to be sequentially pressed down, and meanwhile, the horizontal plane moves in a direction perpendicular to the streamline direction, so that the 3 fingerprint heads are sequentially pressed down in a fingerprint test area of the tested mobile terminal. And after the fingerprint test is finished, the light sensing test of the back is carried out on the tested mobile terminal through the light sensing calibration assembly. After the tests are completed, the tray is conveyed to a fifth test station through the first conveying module of the fourth test station.

And the first transmission module in the fifth test station moves the material tray to a preset position, sends a light sensing test instruction to the tested mobile terminal, and the tested mobile terminal starts a light sensing test program to finish the light sensing test of the front surface of the tested mobile terminal through a light source provided by the light sensing test component. After the front light sensing test is finished, a distance sensing test instruction is sent to the tested mobile terminal, the tested mobile terminal starts a distance sensing test program, and the black card and the gray card are sequentially pushed to a designated position through a screw sliding table in the distance sensing test assembly to conduct distance sensing test. After the test is completed, the tested mobile terminal exits the test program and sends test information to the processing module. And the processing module sends the test information and the test state of the tested mobile terminal to the background server. The background server may include: an information management system.

After all the test stations complete the test of the tested mobile terminal, the first transmission module of the fifth test station transmits the material tray to the blanking station.

After the material tray reaches the appointed position of the blanking station, the scanning module positioned at the blanking station scans the identification information of the tested mobile terminal, and the display module displays the test information of the tested mobile terminal. And then the tested mobile terminal is taken down at the blanking station.

The tray is moved to the height of the second transmission module of the fifth test station through the lifting module positioned at the blanking station, and then is transmitted to the second transmission module of the fifth test station through the transmission module in the blanking station. And the material tray is sequentially transmitted to the second transmission modules of the fourth test station, the third test station, the second test station and the first test station through the second transmission modules of the fifth test station. The material tray is transmitted to the lifting module of the feeding station through the first transmission module, and then the material tray is lifted to the initial position by the lifting module in the feeding station.

In another embodiment, there is also provided a non-transitory computer readable storage medium having stored therein computer executable instructions that when executed by a processor implement the method of any of the above embodiments.

It should be noted that, the "first" and "second" in the embodiments of the present disclosure are merely for convenience of expression and distinction, and are not otherwise specifically meant.

Other embodiments of the application will be apparent to those skilled in the art from consideration of the specification and practice of the application disclosed herein. This application is intended to cover any variations, uses, or adaptations of the application following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the application pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It is to be understood that the application is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims (13)

1. A test apparatus, comprising:

a plurality of test sites arranged in parallel along a straight line in the horizontal direction; wherein the number of test bits is adjustable;

the transmission module is positioned on the test bit and used for transmitting the tested mobile terminal among a plurality of test bits;

The test module is positioned above the transmission module and used for testing at least one sensor corresponding to the test module in the tested mobile terminal positioned on the test position;

the loading level is positioned in front of the test bit at one end of the plurality of test bits arranged in parallel along a straight line and is used for the tested mobile terminal to transmit to the test bit for testing;

the discharging level is positioned behind the test bit at the other end of the plurality of test bits arranged in parallel along a straight line and is used for outputting the tested mobile terminal from the test bit;

the scanning module is positioned at the top of the loading level and is used for scanning the tested mobile terminal before the tested mobile terminal is transmitted to the test bit positioned at one end of the plurality of test bits which are arranged in parallel in a straight line, so as to acquire the identification information of the tested mobile terminal;

the scanning module is also positioned at the top of the discharging position and is used for acquiring the identification information of the tested mobile terminal again; the identification information of the tested mobile terminal scanned by the scanning module at the top of the loading level and the identification information of the tested mobile terminal scanned by the scanning module at the top of the unloading level are used for determining that the tested mobile terminal is tested;

The transmission module comprises: the first transmission module and the second transmission module; the first transmission module is positioned below the test module and is used for transmitting among a plurality of test positions along a first horizontal direction; the second transmission module is positioned below the first transmission module and is used for transmitting among a plurality of test positions along a second horizontal direction, and the first horizontal direction is opposite to the second horizontal direction;

the test module comprises:

the camera bellows calibration assembly is positioned above the first transmission module; the camera bellows calibration assembly comprises an opening and closing window, an opening and closing window control assembly and a fixing assembly; the opening and closing window control component controls the opening and closing of the opening and closing window; when the camera bellows calibration component tests, the opening and closing window control component controls the opening and closing window to be in a closed state; after the testing of the camera bellows calibration component is finished, the opening and closing window control component pushes the opening and closing window to be opened;

the distance sense calibration assembly is positioned above the camera bellows calibration assembly and comprises: the device comprises a bracket, a driving motor, a screw rod sliding table, a gray card and a black card; the screw sliding table and the driving motor are both positioned on the bracket, the ash card and the black card are positioned on the screw sliding table, and the driving motor is used for driving the screw sliding table to move so as to drive the ash card and the black card to move, so that the tested mobile terminal is tested; when the opening and closing window is in an opened state, the ash clamp is positioned above the opening and closing window so as to calibrate a distance sensor of the tested mobile terminal;

A light sensation calibration and testing assembly comprising: the device comprises a light source panel, a vertical direction adjusting piece, a horizontal direction adjusting piece, a movable guide pillar and a fixed plate; one end of the movable guide post is fixedly connected with the light source panel, and the other end of the movable guide post penetrates through the fixed plate; one end of the vertical direction adjusting piece is connected with the light source panel, and the other end of the vertical direction adjusting piece penetrates through the fixing plate and is used for adjusting the distance between the light source panel and the fixing plate through rotation of the vertical direction adjusting piece; the horizontal direction adjusting piece is connected with the support in the test position and used for adjusting the position of the light sensation calibration assembly in the test position in the horizontal direction so as to calibrate and test the light sensor.

2. The test apparatus of claim 1, wherein different ones of said test stations have test modules for testing different sensors within said mobile terminal under test.

3. The test apparatus of claim 1, wherein the test apparatus further comprises:

the processing module is positioned on the test position and is used for receiving and processing the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal;

The scanning module is electrically connected with the processing module and is also used for: and establishing wireless communication connection between the processing module and the tested mobile terminal by scanning wireless communication information displayed by the tested mobile terminal.

4. The test apparatus of claim 1, wherein the test apparatus further comprises:

and the display module is positioned on the test position and used for displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal.

5. The test apparatus of claim 1, wherein the test apparatus further comprises:

the charging tray is used for bearing the tested mobile terminal;

the first transmission module is used for transmitting the material tray among a plurality of test positions along a first horizontal direction;

the second transmission module is used for transmitting the material tray among a plurality of test positions along a second horizontal direction.

6. The test apparatus of claim 5, wherein the test apparatus further comprises:

and the lifting module is positioned at one side of the test position and used for transmitting the material tray between the first transmission module and the second transmission module.

7. The test apparatus of claim 5, wherein the tray comprises:

the mobile terminal bearing piece is used for fixing the tested mobile terminals with different sizes or different shapes;

the charging tray body is used for fixing the mobile terminal bearing piece.

8. A test method employing the test apparatus of any one of claims 1 to 7, comprising:

the method comprises the steps that a mobile terminal to be tested is transmitted among a plurality of test positions which are arranged in parallel along a straight line in the horizontal direction through a transmission module; wherein the number of test bits is adjustable;

testing at least one sensor corresponding to the testing module in the tested mobile terminal on the testing position through the testing module above the transmission module;

the method comprises the steps that through a scanning module positioned at the top of the loading level, a tested mobile terminal is scanned before being transmitted to the test bit positioned at one end of a plurality of test bits which are arranged in parallel in a straight line, and identification information of the tested mobile terminal is obtained;

acquiring the identification information of the tested mobile terminal again through the scanning module positioned at the top of the discharging position;

The scanning module at the top of the loading level scans the identification information of the tested mobile terminal, and the scanning module at the top of the unloading level scans the identification information of the tested mobile terminal, so as to determine that the tested mobile terminal completes the test;

the transmission module comprises: the first transmission module and the second transmission module; the first transmission module is positioned below the test module and is used for transmitting among a plurality of test positions along a first horizontal direction; the second transmission module is positioned below the first transmission module and is used for transmitting among a plurality of test positions along a second horizontal direction, and the first horizontal direction is opposite to the second horizontal direction;

the test module comprises:

the camera bellows calibration assembly is positioned above the first transmission module; the camera bellows calibration assembly comprises an opening and closing window, an opening and closing window control assembly and a fixing assembly; the opening and closing window control component controls the opening and closing of the opening and closing window; when the camera bellows calibration component tests, the opening and closing window control component controls the opening and closing window to be in a closed state; after the testing of the camera bellows calibration component is finished, the opening and closing window control component pushes the opening and closing window to be opened;

The distance sense calibration assembly is positioned above the camera bellows calibration assembly and comprises: the device comprises a bracket, a driving motor, a screw rod sliding table, a gray card and a black card; the screw sliding table and the driving motor are both positioned on the bracket, the ash card and the black card are positioned on the screw sliding table, and the driving motor is used for driving the screw sliding table to move so as to drive the ash card and the black card to move, so that the tested mobile terminal is tested; when the opening and closing window is in an opened state, the ash clamp is positioned above the opening and closing window so as to calibrate a distance sensor of the tested mobile terminal;

a light sensation calibration and testing assembly comprising: the device comprises a light source panel, a vertical direction adjusting piece, a horizontal direction adjusting piece, a movable guide pillar and a fixed plate; one end of the movable guide post is fixedly connected with the light source panel, and the other end of the movable guide post penetrates through the fixed plate; one end of the vertical direction adjusting piece is connected with the light source panel, and the other end of the vertical direction adjusting piece penetrates through the fixing plate and is used for adjusting the distance between the light source panel and the fixing plate through rotation of the vertical direction adjusting piece; the horizontal direction adjusting piece is connected with the support in the test position and used for adjusting the position of the light sensation calibration assembly in the test position in the horizontal direction so as to calibrate and test the light sensor.

9. The method of testing of claim 8, further comprising:

the wireless communication information displayed by the tested mobile terminal is scanned through the scanning module, and wireless communication connection between the processing module located on the test position and the tested mobile terminal is established;

and processing the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal through the processing module.

10. The method of testing of claim 8, further comprising:

and displaying the test information of the test module for testing at least one sensor corresponding to the test module in the tested mobile terminal through the display module positioned on the test position.

11. The method of testing of claim 8, further comprising:

transmitting a tray bearing the tested mobile terminal among a plurality of test positions along a first horizontal direction through a first transmission module in the transmission modules;

and the material tray is transmitted among the plurality of test positions along a second horizontal direction through a second transmission module positioned below the first transmission module, and the first horizontal direction is opposite to the second horizontal direction.

12. The method of testing according to claim 11, further comprising:

the material tray is transferred between the first transmission module and the second transmission module through the lifting module positioned at one side of the test position.

13. A non-transitory computer readable storage medium having stored therein computer executable instructions that when executed by a processor implement the method of any one of claims 8 to 12.