CN117376978A - Equipment testing method based on Bluetooth MESH - Google Patents

Abstract

The invention provides a device testing method based on Bluetooth MESH, which comprises the steps that testing equipment and equipment to be detected enter a first network and subscribe to a testing address; the test equipment sends an inquiry network access equipment instruction to a test address; the equipment to be detected sends equipment information of the equipment to be detected to a test address; the test equipment stores equipment information; the test equipment sets preset times and first preset time; the test equipment sends a first detection command to a test address; the test equipment sends a first reading command to a test address; the testing equipment judges whether first feedback information of the equipment to be detected is received in a first preset time; if yes, judging whether the feedback attribute value of the first function in the first feedback information is the same as the set attribute value of the first function of the first detection command, and if yes, testing the rest functions of the equipment to be detected. The testing equipment can test one function of a plurality of equipment to be tested only by sending two commands, so that the testing efficiency is improved.

Description

Equipment testing method based on Bluetooth MESH

Technical Field

The invention relates to the field of Bluetooth MESH testing, in particular to a device testing method based on Bluetooth MESH.

Background

Bluetooth MESH is often applied to intelligent household equipment, and intelligent household equipment can be interconnected through the Bluetooth MESH, so that many-to-many communication is realized. Before the intelligent household equipment with Bluetooth MESH leaves the factory, the intelligent household equipment needs to be tested, and whether the functions of the intelligent furniture equipment are problematic is tested. When a large number of intelligent household equipment with Bluetooth MESH are detected in a factory, the intelligent household equipment needs to be tested manually, and the testing mode is long in testing time and low in testing efficiency.

The existing wireless MESH network online measurement method is a closed measurement method formed by a measurement signal generation unit, a measurement signal acquisition unit and a measurement signal analysis unit which are embedded in a communication equipment entity of the wireless MESH network. However, the method cannot test a large number of devices and has low test efficiency.

The Chinese patent application CN115914025A discloses a testing method for automatic networking of products based on Bluetooth MESH, wherein target equipment and detection equipment of the method subscribe to a group address, and the target product detects whether the target product runs for the first time or not, if so, a Bluetooth protocol stack is initialized; the method comprises the steps of obtaining a model of the user, creating a network identification code according to the model of the user, generating a network key and an application key, creating a network according to the network key and the application key, and shielding a relay function of a target product; the detection equipment acquires the model of the target product, acquires the network identification code according to the model of the product, generates a network key and an application key, enters a network created by the target product according to the network key and the application key, and shields the relay function of the detection equipment; and after the detection equipment is connected with the target product, testing the target product. When the detection equipment tests the target product, the detection equipment independently tests one product through the established network, and tests the next product after the test of one product is completed. The test mode requires longer time and cannot meet the requirement that a large number of products in batches are detected on a production line.

Disclosure of Invention

The first object of the invention is to provide a device testing method based on Bluetooth MESH, which improves the testing efficiency.

In order to achieve the first object, the present invention provides a device testing method based on bluetooth MESH, including: the test equipment and the equipment to be detected enter a first network and subscribe to a test address; the test equipment sends an inquiry network access equipment instruction to a test address; after receiving the inquiry network access equipment instruction from the test address, the equipment to be detected sends equipment information of the equipment to be detected to the test address; after the test equipment receives the equipment information from the test address, the equipment information is stored in a memory of the test equipment; the test equipment sets preset times and first preset time; the test equipment sends a first detection command to the test address, wherein the first detection command comprises a set attribute value of a first function; the test equipment sends a first reading command to a test address; the testing equipment judges whether first feedback information of the equipment to be detected is received in a first preset time; if the testing equipment receives the first feedback information within the first preset time, judging whether the feedback attribute value of the first function in the first feedback information is the same as the first function setting attribute value of the first detection command, and if so, testing the residual functions of the equipment to be detected by the testing equipment.

According to the scheme, as the plurality of devices to be detected and the testing device enter the first network and subscribe to the testing address, when the testing device sends the instruction or the command to the testing address, the plurality of devices to be detected can simultaneously receive the instruction or the command sent by the testing device. The test equipment can send a command according to the function required to be detected by the equipment to be detected, the equipment to be detected subscribed to the same test address can receive the command of the detection function, the equipment to be detected feeds information back to the test address after the detection of the equipment to be detected is finished, and the test equipment can simultaneously receive feedback information of a plurality of pieces of equipment to be detected. The test equipment can compare the feedback attribute values of the functions of the feedback information of the multiple devices to be detected with the set attribute values of the first detection command at the same time, and judge whether the functions of the devices to be detected are normal. When testing one function of a plurality of devices to be tested in the batch, the testing device only needs to send one testing command and one reading command to the testing address, and the testing device waits for the devices to be tested to send feedback information and then performs testing. The test equipment only needs to send two commands to test one function of a plurality of equipment to be tested, and the test equipment sends the commands according to the number of the functions of the equipment to be tested when detecting, so that the test equipment does not need to test one equipment to be tested independently, and the next equipment to be tested is tested after the test is finished.

In a further scheme, if the feedback attribute value of the first function in the first feedback information is different from the set attribute value of the first function of the first detection command, the test equipment records that the test of the equipment to be detected fails.

Therefore, the testing device can compare the dimming duration in the first detection command with the actual dimming duration of the device to be detected, if the dimming duration is the same, the testing device can send the next testing command, and if the dimming duration is not the same, the failure of the device to be detected is recorded.

In a further aspect, if the test device does not receive the first feedback information within the first preset time, the test device further performs: the test equipment judges whether the sending times of the first detection command are larger than preset times or not; if the number of times of sending the first detection command is smaller than the preset number of times, the test equipment sends the first detection command to the test address again.

Therefore, during transmission, errors may occur to cause transmission failure, and the device to be detected or the test device cannot receive the command or the information, so that the preset times and the first preset time need to be set to enable the device to be detected to successfully perform the test.

In a further scheme, if the number of times of sending the first detection command is greater than a preset number of times, the test equipment records that the equipment to be detected fails in test.

Therefore, if the test equipment has sent the first detection command exceeding the preset times, the problem of the transmission between the equipment to be detected and the test equipment is proved, and the test equipment can record the test failure of the equipment to be detected.

In a further scheme, after the test equipment records that the equipment to be detected fails in test, the method further comprises the following steps: the test equipment generates a first test report, wherein the first test report comprises a node and a failure function point of equipment to be detected, a first test total duration and a first average signal strength of Bluetooth MESH of the equipment to be detected.

Therefore, after the test equipment records the record failure of the equipment to be detected, the test information of the equipment to be detected is generated into a first test report, and after the test of the batch of equipment to be detected is completed, a tester can screen out the equipment to be detected with the test failure through the first test report, so that the tester is not required to be individually prompted to test the equipment to be detected in the process of testing the batch of products to be detected, and the test efficiency of the whole test flow can be improved.

In a further aspect, the testing device performs testing on the remaining functions of the device to be tested, including: the test equipment sends a second detection command to the test address, and then sends a second reading command to the test address; after the test equipment sends the second reading command to the test address, if the feedback attribute value of the second function in the second feedback information is consistent with the set attribute value of the second function in the second detection command, judging whether the functions of the equipment to be detected are all detected, and if so, recording that the equipment to be detected is successfully tested by the test equipment.

Therefore, when all the functions of the equipment to be detected are tested, and no error occurs in the test process, the test equipment records that the equipment to be detected is tested successfully.

In a further scheme, after the test equipment records that the equipment to be detected is tested successfully, the method further comprises the following steps: generating a second test report of the equipment to be detected, wherein the test report comprises equipment information of the equipment to be detected, a second total detection duration and second average signal strength of Bluetooth MESH of the equipment to be detected.

Therefore, after the test equipment records that the equipment to be detected is successfully recorded, the test information of the equipment to be detected is generated into a second test report, and the detection personnel can screen the equipment to be detected which is successfully tested according to the second test report.

In a further aspect, after the test device sends the first detection command to the test address, the method further includes: the test device sends the first read command to the test address after a second preset time.

In a further aspect, the test device exits the first network after generating the first test report.

Therefore, after the test report is generated, the first network of the equipment to be detected in the batch can be exited to prepare the test of the equipment to be detected in the next batch.

In a further aspect, the test device exits the first network after generating the second test report.

Therefore, after the test report is generated, the first network of the equipment to be detected in the batch can be exited to prepare the test of the equipment to be detected in the next batch.

Drawings

FIG. 1 is a flow chart of an embodiment of a Bluetooth MESH-based device testing method of the present invention.

Fig. 2 is a flowchart of a test device for determining whether to resend a first detection command according to an embodiment of a device test method based on bluetooth MESH of the present invention.

FIG. 3 is a flow chart of a test device for determining whether to re-detect based on an embodiment of a device test method based on Bluetooth MESH.

The invention is further described below with reference to the drawings and examples.

Detailed Description

The to-be-detected device with the Bluetooth MESH needs to be tested by a detector before leaving the factory, for example, the signal intensity of a Bluetooth MESH module of the to-be-detected device and the function of the to-be-detected device. The equipment to be detected can be an intelligent lamp, an intelligent sound box and the like. For example, when the device to be detected is a smart lamp, the dimming time of the smart lamp is detected. When the equipment to be detected is tested, if the testing equipment is used for carrying out functional detection on the single equipment to be detected, the next equipment to be detected is tested, and the testing efficiency is low. The Bluetooth MESH-based equipment testing method provided by the embodiment can be used for detecting a large number of equipment to be tested, and when the testing is completed, a testing report is directly generated, and a tester only needs to screen products failing to be tested through the testing report, so that the testing efficiency on a production line is improved.

Referring to FIG. 1, FIG. 1 is a flow chart of an embodiment of a Bluetooth MESH-based device testing method of the present invention. First, step S100 is executed to test the device and the device to be tested and subscribe to the test address. During testing, the equipment to be detected entering the first network is the equipment to be detected of the same batch and the same model, and the functions of the equipment to be detected in the batch, which are required to be detected, are the same. Before testing, because the equipment to be tested is burned into the automatic network access firmware in batches before testing, the equipment to be tested in the batch can automatically configure the same network and subscribe to the same testing address. The test address is a network transit address or a group address. The test device may send information to the test address, which may send the information to the device to be tested subscribing to the test address. The device to be tested may send information to the test address, which may send the information to the test device subscribing to the test address. The test device may enter the first network according to the model of the device to be detected and subscribe to the test address.

And after the testing equipment and the equipment to be detected enter the first network. Step S101 is executed, where the test device sends a query access command to the test address. The device to be detected subscribing to the test address may receive the query networking instruction. The inquiry network access instruction comprises the step of enabling the equipment to be detected to send the MAC address of the equipment to be detected and the Bluetooth MESH address instruction of the equipment to be detected to the test equipment.

After receiving the inquiry network access instruction, the device to be detected executes step S102, and sends the device information of the device to be detected to the test address. The test information of the device to be detected comprises the MAC address of the device to be detected and the address of the Bluetooth MESH of the device to be detected. The test address can broadcast the equipment information of the equipment to be detected to the equipment subscribed to the address, when the test address receives the equipment information of the equipment to be detected, the equipment information of the equipment to be detected can be processed, and when the rest equipment to be detected receives the equipment information of the equipment to be detected, the equipment information of the equipment to be detected is disregarded.

After the test device receives the device information to be detected, step S103 is executed, and the test device stores the device information in the memory of the test device. The equipment information of the equipment to be detected can be used for recording the testing condition of the equipment to be detected.

After the test device saves the device information in the memory of the test device, step S104 is executed, where the test device sets a preset number of times and a first preset time, where the preset number of times is the maximum number of times that the test device tests a detection command sent by a function of the device to be detected, and the first preset time is the time for waiting for the device to be detected to reply to the feedback information after the test device of the device to be detected sends a read command.

After the test device sets the preset times and the first preset time, step S105 is executed, and the test device sends the first detection command to the test address. The first detection command includes a set attribute value of a first function, for example, the device to be detected is an intelligent lamp, the first function of the intelligent lamp is dimming duration, the test device needs to test the dimming duration of the intelligent lamp, and the first detection command is dimming test duration.

After the test device sends the first detection command, step S106 is executed, where the test device sends the first read command to the test address. The first reading command is to command the device to be detected to read the feedback attribute value and feed back the feedback attribute value to the test device. After the equipment to be detected receives the first detection command from the test address, the function of the equipment to be detected needs to be tested to obtain a feedback attribute value, for example, the equipment to be detected is an intelligent lamp, dimming is performed according to the received dimming test duration, the actual dimming duration is recorded, and the actual dimming duration is the feedback attribute value of the first function. After the test device sends the first detection command, the test device needs to send the first reading command to the test address after a second preset time. The test device needs to send the first read command after the second preset time, and the time of the test function is reserved for the device to be tested.

After the test device sends the first read command, step S107 is performed, where the test device determines whether first feedback information of the device to be detected is received at a first preset time. After the equipment to be detected receives the first reading command from the test address, the self test result is formed into first feedback information and sent to the test address. The test address broadcasts the first feedback information, which the test device may receive. And when the other devices to be detected receive the first feedback information, the other devices to be detected do not process the first feedback information. The first feedback information includes a feedback attribute value of the first function.

If the test device receives the first feedback information of the device to be detected at the first preset time, step S109 is executed, where the test device determines whether the feedback attribute value of the first feedback information is the same as the set attribute value of the first detection command. After the test device receives the first feedback information, the feedback attribute value of the first function in the first feedback information needs to be compared with the set attribute value of the first function in the first detection command, for example, if the device to be detected is an intelligent lamp, the dimming test duration can be compared with the actual dimming duration, and whether the dimming test duration is the same with the actual dimming duration or not is judged. The test equipment can simultaneously receive the first feedback information of the plurality of equipment to be detected, and simultaneously compare whether the feedback attribute value of the first feedback information of the plurality of equipment to be detected is the same as the set attribute value of the first detection command, detect whether the first function of the plurality of equipment to be detected is normal, and can reduce the test time of the test equipment.

If the feedback attribute value of the first feedback information is the same as the set attribute value of the first detection command, step S110 is executed, where the test device tests the remaining functions of the device to be detected. If the feedback attribute value of the first feedback information is different from the set attribute value of the first detection command, the function of the device to be detected is proved to be failed, step S111 is executed, and the test device records that the test of the device to be detected fails.

In step S107, if the test device receives the first feedback information of the device to be tested at the first preset time, step S108 is executed, and the test device sends the first test command to the test address again within the preset times. Wherein step S108 is detailed with reference to fig. 2. First, step S21 is executed, where the test apparatus determines whether the number of times of transmission of the first detection command is greater than a preset number of times. If the number of times of sending the first detection command is greater than the preset number of times, step S22 is executed, and the test equipment records the failure of the test of the equipment to be detected. During transmission, transmission failure may occur due to errors, and the device to be detected or the test device cannot receive the command or the information, so that the preset times and the first preset time need to be set to enable the device to be detected to successfully perform the test. If the test equipment has sent a first detection command exceeding the preset times, the test equipment proves that the transmission between the equipment to be detected and the test equipment is problematic, and the test equipment can record the test failure of the equipment to be detected. The test time of the batch of equipment to be detected can be saved by setting the preset times.

Referring to fig. 3, fig. 3 is a flowchart of a test device for determining whether to re-detect according to an embodiment of the bluetooth MESH-based device test method of the present invention. In step S110, the test device tests the remaining functions of the device to be tested, wherein the test device tests the second functions of the device to be tested. The test equipment sends a second detection command to the test address, and sends a second reading command to the test address after a third preset time interval. When the testing equipment tests the equipment to be detected, only two commands are required to be sent to detect one function of the equipment to be detected, so that the batch testing time of the equipment to be detected is reduced, and the testing efficiency of the production line is improved.

After the test device sends the second read command to the test address, if the second function feedback attribute value in the second feedback information is consistent with the second function setting attribute value summarized by the second detection command, step S31 is executed, and the test device determines whether all the functions of the device to be detected are detected. If the functions of the device to be detected are all detected, step S33 is executed to record that the test of the device to be detected is successful.

If the function of the device to be detected is not detected, step S32 is executed, and the test device continues to test the remaining functions of the device to be detected, and the test device may send a detection command and a read command to test the functions of the device to be detected.

After the test equipment records that the equipment to be detected is successfully tested, the test equipment generates a second test report of the equipment to be detected, wherein the second test report comprises equipment information of the equipment to be detected, second total detection duration and second average signal intensity of a Bluetooth MESH module of the equipment to be detected. Because the equipment to be detected sends information to the test equipment each time, the information comprises the signal intensity of the Bluetooth MESH module of the equipment to be detected and the MAC address of the equipment to be detected. When the test equipment receives the information of the equipment to be detected, the signal intensity of the Bluetooth MESH module of the equipment to be detected is recorded, and when a second test report is generated, the second average signal intensity is calculated through the recorded signal intensity of the equipment to be detected.

After the test equipment records the test failure of the equipment to be detected, the test equipment generates a first test report, wherein the first test report comprises the node and the failure function point of the equipment to be detected, the first test total duration and the first average signal strength of Bluetooth MESH of the equipment to be detected, and the first test report also comprises the equipment information of the equipment to be detected. If the device to be detected fails to be tested because the number of times of sending the test command is greater than the preset number of times, the number of times of sending the test command of the device to be detected is required to be recorded to be greater than the number of times of testing, and the current failure function point is required to be recorded. If the test of the device to be detected fails due to the fact that the feedback attribute value is inconsistent with the set attribute value, the feedback attribute value and the set attribute value are required to be recorded at what function point the device to be detected is inconsistent. Because the information comprises the signal intensity of the Bluetooth MESH module of the equipment to be detected and the MAC address of the equipment to be detected when the equipment to be detected sends information to the testing equipment each time, the testing equipment calculates the first average signal intensity through the recorded signal intensity of the equipment to be detected when generating a first test report.

After the test equipment generates a first test report or a second test report, the test equipment stores the report to a memory of the test equipment and sends the report to a designated mailbox, when the test of the batch of equipment to be detected is completed, a tester can analyze whether the equipment to be detected is successful or not through the first test report or the second test report, if the equipment to be detected is failed to be tested, the failed functional point and node are obtained from the test report, and the equipment to be detected is detected again. And the tester does not need more operations during testing, so that the testing efficiency is improved.

After the test equipment generates the first test report or the second test report, the test equipment proves that all the equipment to be detected in the batch are detected, and the equipment to be detected exits the first network. The test equipment is ready for the next batch of test.

When testing a function of the device to be tested, the testing device only needs to send a testing command and a reading command to the testing address, and the device to be tested waits for feedback information to be sent and then is tested. The test equipment only needs to send two commands to test the same function of a plurality of equipment to be detected, and the test equipment sends the commands according to the number of the functions of the equipment to be detected when detecting, so that the test equipment does not need to test one equipment to be detected independently, and only after the test is finished, the next equipment to be detected is tested, and when the batch of equipment to be detected is tested, the test time can be reduced, the batch of equipment to be detected can be tested quickly, and the test efficiency of the production line is improved.

The foregoing is merely a preferred embodiment of the present invention, but the inventive design concept is not limited thereto, and many other equivalent embodiments can be included without departing from the scope of the invention, as will be apparent to those skilled in the art.

Claims (10)

1. A device testing method based on Bluetooth MESH comprises the following steps:

the test equipment and the equipment to be detected enter a first network and subscribe to a test address;

the test equipment sends an inquiry network access equipment instruction to the test address;

after the equipment to be detected receives the inquiry network access equipment instruction from the test address, equipment information of the equipment to be detected is sent to the test address;

after the test equipment receives the equipment information from the test address, the equipment information is stored in a memory of the test equipment;

the method is characterized in that:

the test equipment sets preset times and first preset time;

the test equipment sends a first detection command to the test address, wherein the first detection command comprises a set attribute value of a first function;

the test equipment sends a first reading command to the test address;

the test equipment judges whether first feedback information of the equipment to be detected is received in the first preset time or not;

if the testing equipment receives the first feedback information within the first preset time, judging whether the feedback attribute value of the first function in the first feedback information is the same as the set attribute value of the first function of the first detection command, and if so, testing the residual functions of the equipment to be detected by the testing equipment.

2. The bluetooth MESH-based device testing method according to claim 1, wherein:

if the feedback attribute value of the first function in the first feedback information is different from the set attribute value of the first function of the first detection command, the test equipment records that the test of the equipment to be detected fails.

3. The bluetooth MESH-based device testing method according to claim 2, wherein:

and if the test equipment does not receive the first feedback information within the first preset time, the test equipment further executes:

the test equipment judges whether the sending times of the first detection command are larger than the preset times;

and if the sending times of the first detection command are smaller than the preset times, the test equipment sends the first detection command to the test address again.

4. A bluetooth MESH-based device testing method according to claim 3, wherein:

if the number of times of sending the first detection command is greater than the preset number of times, the test equipment records that the equipment to be detected fails in test.

5. The bluetooth MESH-based device testing method according to claim 4, wherein:

after the test equipment records that the equipment to be detected fails in test, the method further comprises the following steps:

the test equipment generates a first test report, wherein the first test report comprises a node and a failure function point of the equipment to be detected, a first test total duration and a first average signal strength of a Bluetooth MESH module of the equipment to be detected.

6. The bluetooth MESH-based device testing method according to claim 1, wherein:

the testing device testing the remaining functions of the device to be tested comprises:

the test equipment sends a second detection command to the test address, and then sends a second reading command to the test address;

after the test equipment sends a second read command to the test address, if a second function feedback attribute value in the second feedback information of the equipment to be detected is consistent with a second function setting attribute value in the second detection command, judging whether the functions of the equipment to be detected are all detected, and if so, recording that the test of the equipment to be detected is successful by the test equipment.

7. The bluetooth MESH-based device testing method according to claim 6, wherein:

after the test equipment records that the equipment to be detected is tested successfully, the method further comprises the following steps:

and the test equipment generates a second test report of the equipment to be detected, wherein the second test report comprises equipment information of the equipment to be detected, a second total detection duration and second average signal intensity of a Bluetooth MESH module of the equipment to be detected.

8. A bluetooth MESH-based device testing method according to any one of claims 1 to 6, wherein:

the test device further includes, after sending the first detection command to the test address:

the test device sends the first read command to the test address after a second preset time.

9. The bluetooth MESH-based device testing method according to claim 4, wherein:

and after the test equipment generates a first test report, exiting the first network.

10. The bluetooth MESH-based device testing method according to claim 6, wherein:

and after the test equipment generates a second test report, exiting the first network.