CN116016293A

CN116016293A - Multi-task queue testing method, system and platform for network communication product production

Info

Publication number: CN116016293A
Application number: CN202310285278.7A
Authority: CN
Inventors: 余鑫龙; 陈政; 王周锋
Original assignee: Shenzhen Yilian Unlimited Technology Co ltd
Current assignee: Shenzhen Yilian Unlimited Technology Co ltd
Priority date: 2023-03-22
Filing date: 2023-03-22
Publication date: 2023-04-25
Anticipated expiration: 2043-03-22
Also published as: CN116016293B

Abstract

The invention provides a method, a system and a platform for testing a multi-task queue for production of a network communication product, wherein the method comprises the following steps: s1, configuring calibration parameters of WIFI and BOB and line loss files of the WIFI and the BOB; s2, connecting a product to be tested with a WIFI calibration instrument and a BOB calibration instrument; s3, judging whether the network of the product to be tested is normal or not by utilizing a ping communication technology, if so, configuring a test flow file of the product to be tested, and if not, executing S2; s4, judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, if so, testing the product to be tested, and if not, executing S2; s5, according to the judgment result of the S4, corresponding calibration is carried out on the products to be tested, and after the calibration data are uploaded to the system, the S2 is executed until the calibration of all the products to be tested is completed, so that the combination of a plurality of production post sites is realized, the process is saved, and the production efficiency is further improved.

Description

Multi-task queue testing method, system and platform for network communication product production

Technical Field

The invention relates to the technical field of production calibration of network communication products, in particular to a method, a system and a platform for testing a multi-task queue for production of network communication products.

Background

With the rapid development of communication networks, the demands for network communication products are increasing, and the performance demands for network communication products are also increasing. There is therefore a need for performance calibration of a netcom product during its production, including WIFI, BOB (Bosa on board) calibration of the product. For example, a method for calibrating a series of parameters of WIFI to ensure the communication performance of the product and enable the transmitting power of the WIFI to reach a target range is needed in the network communication product based on the WIFI design; and (3) a network communication product based on the BOB design is a method for calibrating a series of parameters of the BOB to ensure the communication performance of the product and enable the transmitting power of the BOB to reach a target range. At present, the existing calibration equipment can calibrate only one parameter in one network communication product, and if multiple parameters of multiple products need to be calibrated, different calibration equipment is needed to calibrate a single product.

Disclosure of Invention

The invention provides a multi-task queue testing method, a system and a platform for production of a network communication product, which are used for solving the defect that single calibration parameters can only be used in the prior art, realizing combination of a plurality of production post sites and providing production efficiency.

The invention provides a multi-task queue testing method for production of a network communication product, which comprises the following steps:

s1, configuring calibration parameters of WIFI and BOB and line loss files of the WIFI and the BOB;

s2, connecting a product to be tested with a WIFI calibration instrument and a BOB calibration instrument;

s3, judging whether the network of the product to be tested is normal or not by utilizing a ping communication technology, if so, configuring a test flow file of the product to be tested, and if not, executing the step S2;

s4, judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, if so, testing the product to be tested, and if not, executing the step S2;

s5, according to the judging result of the step S4, carrying out corresponding calibration on the products to be tested, uploading the calibration data to the system, and then executing the step S2 until the calibration of all the products to be tested is completed.

In one possible embodiment, the stations include a WIFI calibration station and a BOB calibration station.

In a possible implementation manner, after the product to be tested is calibrated correspondingly according to the determination result in step S4 and the calibration data is uploaded to the system, the method specifically includes:

when the current product to be tested is judged to accord with the current WIFI calibration station according to the step S4, carrying out WIFI module calibration and WIFI module function test on the current product to be tested, and uploading the WIFI calibration and test result and test process to a system;

and (4) when the current product to be tested accords with the current BOB calibration station according to the judgment in the step (S4), performing BOB module calibration and BOB module function test on the current product to be tested, and uploading BOB calibration and test results and test processes to the system.

In one possible implementation manner, the step S2 is executed if the product to be tested meets the current station according to the serial number of the product to be tested, and if the product to be tested meets the current station, the product to be tested is tested, and if the product to be tested does not meet the current station, the step S specifically includes:

if the product to be tested accords with the current station, testing the product to be tested, and if the product to be tested does not accord with the current station, giving a FALL prompt by the system.

In one possible implementation manner, the connecting the product to be tested with the WIFI calibration instrument and the BOB test instrument specifically includes:

connecting a product to be tested with a WIFI calibration instrument through an RF radio frequency line;

and connecting the product to be measured with a BOB calibration instrument through an optical fiber.

The invention also provides a system for testing the multi-task queue for the production of the network communication products, which comprises the following components:

the configuration module is used for configuring calibration parameters of the WIFI and the BOB and line loss files of the WIFI and the BOB;

the test connection module is used for judging whether the network of the product to be tested is normal or not by utilizing a ping communication technology, and if so, configuring a test flow file of the product to be tested;

the judging and calibrating module is used for judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, and if so, testing the product to be tested;

and the calibration module is used for carrying out corresponding calibration on the product to be tested according to the judging result of the judging module and uploading the calibration data to the system.

In one possible implementation, the calibration module includes a WIFI calibration unit and a BOB calibration unit;

the WIFI calibration unit is used for carrying out WIFI module calibration and WIFI module function test on the current product to be tested, and uploading the WIFI calibration and test result and test process to the system;

the BOB calibration unit is used for performing BOB module calibration and BOB module function test on the current product to be tested, and uploading BOB calibration and test results and test processes to the system.

In one possible implementation, the judging module includes a scanning unit, and the scanning unit is used for scanning the serial number of the product to be tested.

The invention also provides a multi-task queue test platform for the production of the network communication products, which comprises the following steps: the system comprises a test station, a WIFI calibration instrument and a BOB calibration instrument, wherein the WIFI calibration instrument is connected with the test station through a network port line, the test station is connected with the BOB calibration instrument through a serial port line, and a test product is connected with the test station through the network port line;

the test product is connected with the WIFI calibration instrument through an RF radio frequency line;

the test product is connected with the BOB calibration instrument through an optical fiber line.

According to the method, the system and the platform for testing the multi-task queue for the production of the network communication product, the multi-task queue is used for completing the calibration of the WIFI and the BOB parameters in the production of the network communication product by utilizing the WIFI and the BOB calibration parameters which are imported in advance on the basis of multi-threading, so that one machine is multipurpose, the testing process is saved, and the production efficiency is improved.

Drawings

In order to more clearly illustrate the invention or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic flow chart of a method for testing a multi-task queue for production of a network communication product according to the present invention;

FIG. 2 is a second flow chart of a method for testing a multi-task queue for production of a network communication product according to the present invention;

FIG. 3 is a schematic diagram of a system for testing a multi-task queue for production of a network communication product according to the present invention;

fig. 4 is a schematic structural diagram of a multi-task queue testing platform for production of a network communication product according to the present invention.

Description of the embodiments

In order to make the objects, technical solutions and advantages of the present invention become more apparent, the technical solutions in the embodiments of the present invention will be described in more detail below with reference to the accompanying drawings in the embodiments of the present invention.

It should be noted that: in the drawings, the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The described embodiments are some, but not all, embodiments of the invention, and the embodiments and features of the embodiments in this application may be combined with each other without conflict. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the scope of the present invention.

A first embodiment of a method of testing a multi-tasking queue for production of a netcom product according to the present disclosure is described in detail below with reference to fig. 1-2.

In one possible implementation, the test system on which the test method depends is installed on the test platform before the test mode of the present invention is executed.

As shown in fig. 1-2, the present embodiment mainly includes the following steps:

s1, configuring calibration parameters of WIFI and BOB and line loss files of the WIFI and the BOB.

Specifically, before executing step S1, the method further includes:

before the network product is calibrated, various calibration standard parameter data of different types of products to be tested are obtained through product test software, and different types of product calibration parameters are built for a test system based on the standard parameter data so as to provide standard calibration parameter data for the test system before the test, wherein the product test software in the application refers to a production test platform for the network product.

In a possible implementation manner, in step S1, calibration parameters of WIFI and BOB are configured, and specifically include: the test system is started, and a standard calibration parameter file corresponding to the product to be tested is loaded, wherein the calibration data comprises, but is not limited to, TX (uplink rate) index and RX (downlink rate) index of the product WIFI, such as calibration parameters of a power range, EVM (error vector) index, RX receiving sensitivity and the like of the product in a WIFI OFDM (orthogonal frequency division multiple access) mode.

In one possible implementation manner, in step S1, a line loss file of WIFI and BOB is configured, where the WIFI line loss file refers to a line loss of a connection line between a product and a WIFI measurement instrument, and is used for measuring TX power of the product and RX reception test of the product; the BOB line loss file refers to the line loss of an optical fiber connection line between the BOB calibration auxiliary machine and the product optical module, is used for testing the BOSA (optical transmitting and receiving assembly) optical power of the product and testing TX and RX tests, and the calibration line loss is a necessary parameter for calculating the received and transmitted power of the tested product.

S2, connecting the product to be tested with a WIFI calibration instrument and a BOB calibration instrument.

In step S2, connecting a product to be tested with a WIFI calibration instrument through an RF radio frequency line; and connecting the product to be tested with a BOB calibration instrument, namely a BOB calibration auxiliary machine through an optical fiber.

In one possible embodiment, at least one product to be tested is connected to the WIFI calibration device and the BOB calibration device, so that a plurality of products to be tested can be tested simultaneously, wherein the number of connectable products to be tested by the calibration device depends on the number of connection ports of a single calibration device.

S3, judging whether the network of the product to be tested is normal or not by utilizing a ping communication technology, if so, configuring a test flow file of the product to be tested, and if not, executing the step S2.

In one possible implementation, a ping command is used to determine whether the network between the product under test and the test system can be properly connected.

In step S3, specifically, the method includes: after the product to be tested is electrified and started, clicking the start of the test system, connecting the network port in the test system with the gateway of the product to be tested through the monitoring module in the test system according to the connection quantity set by the test system, and when the gateway of the product to be tested is continuously ping-connected, the product to be tested is normally communicated with the test system.

If the current product to be tested is communicated with the testing system normally, the testing system automatically configures a testing flow file corresponding to the current product to be tested, if the current product to be tested is communicated with the testing system abnormally, the current product to be tested is always in a waiting ping on state, and the current product to be tested is a bad product and needs to be maintained.

In one possible implementation manner, when the current product to be tested is in the waiting ping state, it indicates that the current device is abnormal, and the uncalibrated product to be tested needs to be switched, that is, step S2 is performed.

In one possible embodiment, multiple products are calibrated simultaneously according to the number of network ports and the maximum number of connections of the measuring instrument. The system tests the products to be tested through the network port, and the products to be tested start to be tested after ping is conducted in an unordered mode, so that the products to be tested can be tested at one time, and the calibration instrument can support serial and parallel products to be tested.

S4, judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, if so, matching the current product to be tested, and if not, executing the step S2.

In step S4, specifically, the method includes: scanning an SN (serial number) of a label of a product to be tested, calling and inquiring whether the product to be tested accords with the station test flow through an MES interface (data transmission interface), if so, testing the product to be tested, if not, giving a FALL prompt by a system, and after giving the FALL prompt, indicating that the product is out of station or the SN is invalid, and the like by the system.

In one possible implementation manner, the station refers to each process in the production flow, for example, when the current station is calibrated by a WIFI function module, and when the product to be tested reaches the station, the SN code of the product to be tested is scanned and detected, so as to determine whether the product to be tested needs calibration by the WIFI function module, if so, the product to be tested is tested at the current station, and if not, a prompt of a FALL is given.

In one possible implementation, after the system gives a prompt such as a FALL, it indicates that the current device is abnormal, and the uncalibrated product to be tested needs to be switched, that is, step S2 is performed.

In step S5, according to the determination result in step S4, the product to be tested is calibrated correspondingly, and after the calibration data is uploaded to the system, the method specifically includes:

In one possible implementation manner, the WIFI module calibration refers to adjusting the value of an internal register of a product, and is that indexes such as TX, RX and the like of WIFI reach production standards; the BOB module calibration refers to adjusting the value of a register in a product, and is that indexes such as TX, RX, extinction ratio and the like of the BOB reach production standards.

In one possible implementation, the calibration method uses instrumentation to measure the value of the adjustment register to a specified standard and saves it.

In step S5, after uploading the calibration and test result and test process to the system, the system compresses and packages the SN code of the product to be tested and the calibration and test result and test process corresponding to the product to be tested, and stores the SN code and the calibration and test result and test process, so as to trace the product in the later period.

In one possible implementation, writing the customized information into the product to be tested specifically includes: the product customer customization information is written into an embedded software configuration file in the product, wherein the customization information comprises a product SN code, a MAC address and the like.

The traditional test flow of the production test software of the network communication product comprises the following steps: step one: connecting the product with WIFI calibration equipment; step two: starting the product, performing WIFI calibration on the product, and transferring the product after the calibration is finished; step three: connecting the product with a BOB calibration device; step four: starting the product, performing BOB calibration on the product, and transferring the product after the calibration is finished; step five: connecting the product with a system; step six: and starting the product, and writing product customization information into the product. The production test method of the application under the same product only needs to carry out one-time equipment and instrument connection and product startup without extra product transfer, and compared with the traditional process, the production test method saves two-time equipment connection, two-time product transfer and two-time product startup, and has obvious efficiency improvement.

The following describes a multi-task queue test system for production of a network communication product, and the multi-task queue test system for production of a network communication product and the multi-task queue test method for production of a network communication product described below can be referred to correspondingly.

As shown in fig. 3, the present embodiment mainly includes: the device comprises a configuration module, a connection module, a judging module and a calibration module.

The configuration module is used for configuring calibration parameters of WIFI and BOB and line loss files of WIFI and BOB, wherein the calibration parameters comprise, but are not limited to, TX and RX indexes of the WIFI product, such as calibration parameters of a power range, an EVM index, RX receiving sensitivity and the like of the WIFI product in a WIFI OFDM mode; the WIFI line loss file refers to line loss of a connecting line between a product and a WIFI measuring instrument and is used for measuring TX power of the product and RX receiving test of the product; the BOB line loss file refers to the line loss of an optical fiber connecting line between the BOB calibration auxiliary machine and the product optical module, is used for testing the BOSA optical power of the product and testing TX and RX tests, and the calibration line loss is a necessary parameter for calculating the received and transmitted power of the tested product.

The connection module is connected with the configuration module and is used for judging whether the network of the product to be tested is normal or not by utilizing the ping communication technology, and if so, the test flow file of the product to be tested is configured.

Specifically, firstly, connecting a product to be measured with a WIFI calibration instrument through an RF radio frequency line; and connecting the product to be tested with the BOB calibration instrument, namely, a BOB calibration auxiliary machine in the BOB calibration instrument through an optical fiber.

And secondly, judging whether a network between the product to be tested and the test system can be normally communicated by utilizing the ping through command, if so, automatically configuring a test flow file corresponding to the current product to be tested, and if not, keeping the current product to be tested in a state of waiting for ping through all the time.

The judging module is connected with the connecting module and is used for judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, and if so, the product to be tested is tested.

The calibration module is connected with the judging module, and is used for carrying out corresponding calibration on the product to be tested according to the judging result of the judging module and uploading the calibration data to the system.

In one possible implementation manner, the calibration module comprises a WIFI calibration unit and a BOB calibration unit, wherein the WIFI calibration unit is used for performing WIFI module calibration and WIFI module function test on a current product to be tested, and uploading WIFI calibration and test results and test processes to the system; the BOB calibration unit is used for performing BOB module calibration and BOB module function test on the current product to be tested, and uploading BOB calibration and test results and test processes to the system.

Based on the testing method, the system is used for testing the product to be tested, and specifically comprises the following steps: firstly, a configuration module configures calibration parameters of WIFI and BOB and line loss files of the WIFI and the BOB, the calibration parameters and the line loss files are obtained through product test software, secondly, a product to be tested is connected with a WIFI calibration instrument through an RF radio frequency line respectively, and is connected with the BOB calibration instrument, namely, a BOB calibration auxiliary machine in the BOB calibration instrument through an optical fiber, a connection module judges whether a network between the product to be tested and a test system can be normally communicated or not by utilizing a ping command, if the network is normal, a test flow file corresponding to the current product to be tested is automatically configured, and if the network is abnormal, the current product to be tested is always in a waiting ping state. Secondly, the scanning unit scans the serial number of the product to be tested, the judging module judges whether the product to be tested accords with the current station according to the serial number of the product to be tested scanned by the scanning unit, if so, the product to be tested is tested, finally, the calibrating module correspondingly calibrates the product to be tested according to the judging result of the judging module and uploads the calibrating data to the system, for example, if the current product to be tested accords with the current WIFI calibrating station, the WIFI module calibration and the WIFI module function test are carried out on the current product to be tested, and the WIFI calibration and test result and the test process are uploaded to the system.

The following describes a multi-task queue test platform for production of a network communication product, and the multi-task queue test platform for production of a network communication product and the multi-task queue test method for production of a network communication product described in the following can be referred to correspondingly.

As shown in fig. 4, the present embodiment mainly includes: the system comprises a test station, a WIFI calibration instrument, a BOB calibration instrument and a test product, wherein the BOB calibration instrument comprises a BOB calibration auxiliary machine and a BOB oscilloscope, and the BOB calibration auxiliary machine is connected with the BOB oscilloscope through a serial port and an optical fiber connecting wire.

The WIFI calibration instrument and the BOB calibration instrument in the platform are respectively connected with the test station, and the WIFI calibration instrument is connected with the test station through a network port-to-USB connecting line; and a BOB calibration auxiliary machine in the BOB calibration instrument is connected with the test station through a connecting line of the serial port and the TCPIP.

When the product to be tested is tested, the product to be tested is connected with a testing station through a network port line, a WIFI calibration instrument through an RF radio frequency line and a BOB calibration auxiliary machine through an optical fiber connecting line.

In one possible implementation, one or at least two WIFI calibration instruments and BOB calibration instruments may be provided in the platform.

In one possible embodiment, the test station in the platform may be connected to one or at least two products to be tested.

The product to be tested is tested through the platform, and the method specifically comprises the following steps: placing a product to be tested on a test station, connecting the product to be tested with the test station through a network port connecting wire, connecting the product to be tested with a WIFI calibration instrument through an RF (radio frequency) line and connecting the product to be tested with a BOB calibration auxiliary machine through an optical fiber connecting wire, starting a test system, and testing the product to be tested by adopting the test method.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any changes or substitutions easily contemplated by those skilled in the art within the scope of the present invention should be included in the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. A method for testing a multi-task queue for the production of a network communication product is characterized by comprising the following steps:

2. The method of claim 1, wherein the stations comprise a WIFI calibration station and a BOB calibration station.

3. The method for testing the multi-task queue for the production of the internet access product according to claim 2, wherein the step S4 of performing corresponding calibration on the product to be tested and uploading the calibration data to the system specifically comprises:

4. The method for testing the multi-task queue for the production of the network communication product according to claim 1, wherein the step S2 is executed if the product to be tested meets the current station according to the serial number of the product to be tested, and if the product to be tested does not meet the current station, the step S2 is executed specifically including:

5. The method for testing the multi-task queue for the production of the network communication product according to claim 1, wherein the connecting the product to be tested with the WIFI calibration instrument and the BOB test instrument specifically comprises:

6. A multi-task queue testing system for production of a web-enabled product, comprising:

the judging module is used for judging whether the product to be tested accords with the current station according to the serial number of the product to be tested, and if so, testing the product to be tested;

7. The test system of claim 6, comprising: the stations comprise a WIFI calibration station and a BOB calibration station.

8. The test system of claim 6, comprising: the calibration module comprises a WIFI calibration unit and a BOB calibration unit;

9. The test system of claim 6, comprising: the judging module comprises a scanning unit, wherein the scanning unit is used for scanning the serial number of the product to be detected.

10. A multi-task queue testing platform for production of a web-enabled product, comprising: the system comprises a test station, a WIFI calibration instrument and a BOB calibration instrument, wherein the WIFI calibration instrument is connected with the test station through a network port line, the test station is connected with the BOB calibration instrument through a serial port line, and a test product is connected with the test station through the network port line;