CN117992345A - Vehicle-mounted multimedia automatic test system based on Internet of things - Google Patents

Abstract

The invention discloses a vehicle-mounted multimedia automatic test system based on the Internet of things, which comprises a dynamic test module, an automatic monitoring module, an audio and video quality assurance module, a user experience assurance module, a test instrument board display module and a continuous integration module; the invention realizes the functions of automatically generating test cases, dynamically adjusting test flows, automatically diagnosing and troubleshooting faults by means of artificial intelligence, machine learning and big data analysis, greatly improves the test efficiency and precision, differentially designs and perfects each module and unit, can cover all key fields of vehicle-mounted multimedia equipment, including audio and video quality, user experience and continuous integration, greatly improves the comprehensiveness and accuracy of the test, and therefore well solves the problems of low test precision, limited test coverage and to-be-improved test accuracy when the existing vehicle-mounted multimedia is tested.

Description

Vehicle-mounted multimedia automatic test system based on Internet of things

Technical Field

The invention relates to the technical field of automobile accessories, in particular to a vehicle-mounted multimedia automatic test system based on the Internet of things.

Background

The vehicle-mounted multimedia integrates various functions such as audio, video, communication and navigation, interaction is realized through modes such as a touch screen and voice recognition, so that passengers can enjoy convenient information service and entertainment experience of the vehicle-specific informationized product anytime and anywhere, the problems of low testing precision and limited testing coverage rate exist in the conventional vehicle-mounted multimedia during testing, and the testing accuracy is also to be improved, so that the continuously-increased testing requirement cannot be met.

Disclosure of Invention

The invention aims to provide a vehicle-mounted multimedia automatic test system based on the Internet of things, which aims to solve the technical difficulties that the existing vehicle-mounted multimedia has low test precision, limited test coverage rate and test accuracy to be improved when being tested in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

A vehicle-mounted multimedia automatic test system based on the Internet of things comprises a dynamic test module, an automatic monitoring module, an audio and video quality assurance module, a user experience assurance module, a test instrument board display module and a continuous integration module; the dynamic test module is used for realizing real-time dynamic test of the vehicle-mounted multimedia system, including functional test, performance test, safety test and compatibility test, and improving efficiency and precision by continuous test, and ensuring stability and reliability of the vehicle-mounted multimedia system; the automatic monitoring module monitors and collects performance parameters of the vehicle-mounted multimedia system including a CPU, a memory, a hard disk, a bandwidth and a power supply in real time through a sensor and a monitoring tool so as to discover and solve the fault problem in time; the audio and video quality assurance module is used for evaluating and optimizing the audio and video quality of the vehicle-mounted multimedia system so as to ensure the definition, fluency and high fidelity of audio and video playing, and the audio and video quality optimization means comprise audio and video coding and decoding algorithm selection, acoustic parameter analysis and signal processing; the user experience guaranteeing module is used for evaluating and improving the user experience of the vehicle-mounted multimedia system, and comprises resolution of a display screen, friendliness of a use interface and accuracy of voice recognition so as to optimize interaction flow with a user; the test instrument board display module is used for visual presentation and data statistics of vehicle-mounted multimedia test results, including fault report, data analysis and chart display, and effectively supports monitoring and decision-making of test results by testers and managers; the continuous integration module is used for realizing continuous integration and automatic deployment of the vehicle-mounted multimedia software product, and realizing quick test result feedback and iterative updating, and the test period is shortened by continuously optimizing the test flow and tools.

The dynamic test module comprises a use case generation unit and a self-adaptive test unit, wherein the use case generation unit is responsible for automatically generating a test use case for the vehicle-mounted multimedia equipment by utilizing a machine learning technology and a voice recognition technology; the self-adaptive test unit dynamically adjusts test cases or test flows according to the equipment state and the user behavior data, and determines which test case is executed next by analyzing the equipment running state and the user operation behavior in the test process so as to improve the test efficiency and coverage rate.

The automatic monitoring module comprises an equipment monitoring unit and an automatic repairing unit, wherein the equipment monitoring unit monitors the hardware state and the operation log information of the vehicle-mounted multimedia equipment in real time and feeds the information back to the system so as to perform accurate fault analysis and investigation; when detecting that a certain device has faults, the automatic repairing unit automatically repairs the device in a preset fault processing mode, and the downtime of the device is shortened.

The audio and video quality assurance module comprises an audio and video quality test unit and a multimedia format compatibility test unit; the audio and video quality testing unit uses high-precision microphone, camera and computer vision technology to analyze and evaluate the sound and video output by the vehicle-mounted multimedia equipment, and the testing includes but is not limited to sound or video definition, audio distortion and image jitter index; the multimedia format compatibility testing unit is responsible for testing the compatibility of various audio and video formats supported by the vehicle-mounted multimedia equipment and the peripherals.

The user experience assurance module comprises an interactive interface test unit and a user operation flow test unit, wherein the interactive interface test unit is used for testing response speed, operation convenience and interface attractiveness of an interactive interface and providing corresponding improvement strategies for test results; the user operation flow test unit is responsible for simulating the use condition of the vehicle-mounted multimedia equipment by a user under different scenes, testing the response speed and the operation convenience of the equipment, and generating a detailed test report for the monitored abnormal condition.

The test instrument board display module comprises a data display unit, wherein the data display unit performs visual display on test result data and presents the test result to a user in an intuitive and understandable mode.

The test instrument board display module further comprises a monitoring reminding unit, wherein the monitoring reminding unit is used for monitoring abnormal conditions in the test process and sending an alarm or generating error alarm information to a user.

The continuous integration module comprises a source code management and version control unit, wherein the source code management and version control unit is responsible for managing a source code and version control system, ensuring that software from construction to release of a test is consistent, and avoiding problems caused by inconsistent versions.

The continuous integration module further comprises a construction tool and an automatic test tool application unit, wherein the construction tool and the automatic test tool application unit are responsible for realizing compiling, packing and deployment of application programs by using the construction tool, and the automatic test tool is utilized to complete corresponding test flow, and the continuous integration module has the main functions of rapidly feeding back integration and test results and improving test efficiency and stability.

Compared with the prior art, the invention has the beneficial effects that:

(1) More intelligent: by means of the technical means of artificial intelligence, machine learning and big data analysis, the functions of automatically generating test cases, dynamically adjusting test flows, automatically diagnosing and troubleshooting faults are achieved, and the test efficiency and the test accuracy are greatly improved.

(2) More comprehensive: the method has the advantages that the differentiated design and perfection of each module and unit can cover all key fields of the vehicle-mounted multimedia equipment, including audio and video quality, user experience and continuous integration, and the comprehensiveness and accuracy of the test are greatly improved.

(3) More reliable: by means of the monitoring and predicting system, real-time monitoring and data collection of the running state of the vehicle-mounted multimedia equipment are achieved, and the stability and reliability of the system are improved by combining an automatic repairing technology.

(4) More scalability: by adopting a modularized design, each module and each unit are independent, can be added or deleted according to the test requirement, can support the rapid access of new technology and algorithm, and is convenient for the later project upgrade and expansion.

Drawings

FIG. 1 is a schematic diagram of a system architecture of an on-board multimedia automated test system based on the Internet of things of the present invention;

fig. 2 is a system structure refinement diagram of a vehicle-mounted multimedia automatic test system based on the internet of things.

1-A dynamic test module; 2-an automatic monitoring module; 3-an audio and video quality assurance module; 4-a user experience assurance module; 5-test dashboard display module; 6-a continuous integration module; 7-use case generation unit; 8-an adaptive test unit; 9-an equipment monitoring unit; 10-an automatic repair unit; 11-an audio and video quality testing unit; 12-a multimedia format compatibility test unit; 13-an interactive interface test unit; 14-a user operation flow test unit; 15-a data display unit; 16-monitoring and reminding unit; 17-a source code management and version control unit; 18-build tool and automated test tool handling unit.

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 are not representative of all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus consistent with some aspects of the disclosure as detailed in the accompanying claims.

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. 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.

Example 1

As shown in fig. 1 to 2, an on-vehicle multimedia automated testing system based on the internet of things comprises a dynamic testing module 1, an automatic monitoring module 2, an audio and video quality assurance module 3, a user experience assurance module 4, a test instrument panel display module 5 and a continuous integration module 6.

The dynamic test module 1 is used for realizing real-time dynamic test of the vehicle-mounted multimedia system, including functional test, performance test, safety test and compatibility test, and improving efficiency and precision by continuous test, and ensuring stability and reliability of the vehicle-mounted multimedia system; the dynamic test module 1 comprises a use case generating unit 7 and an adaptive test unit 8, wherein the use case generating unit 7 is responsible for automatically generating test cases for the vehicle-mounted multimedia equipment by utilizing a machine learning technology and a voice recognition technology; the self-adaptive test unit 8 dynamically adjusts test cases or test flows according to the equipment state and the user behavior data, and determines which test case is executed next by analyzing the equipment running state and the user operation behavior in the test process so as to improve the test efficiency and coverage rate.

The automatic monitoring module 2 monitors and collects performance parameters of the vehicle-mounted multimedia system including a CPU, a memory, a hard disk, a bandwidth and a power supply in real time through a sensor and a monitoring tool so as to discover and solve the fault problem in time; the automatic monitoring module 2 comprises an equipment monitoring unit 9 and an automatic repairing unit 10, wherein the equipment monitoring unit 9 monitors the hardware state and the operation log information of the vehicle-mounted multimedia equipment in real time and feeds the information back to the system so as to perform accurate fault analysis and investigation; when detecting that a certain device fails, the automatic repairing unit 10 automatically repairs the device in a preset failure processing mode, so that the downtime of the device is shortened.

The audio and video quality assurance module 3 is used for evaluating and optimizing the audio and video quality of the vehicle-mounted multimedia system so as to ensure the definition, fluency and high fidelity of audio and video playing, and the audio and video quality optimization means comprise audio and video encoding and decoding algorithm selection, acoustic parameter analysis and signal processing; the audio and video quality assurance module 3 comprises an audio and video quality testing unit 11 and a multimedia format compatibility testing unit 12, wherein the audio and video quality testing unit 11 uses a high-precision microphone, a camera and a computer vision technology to analyze and evaluate the sound and video output by the vehicle-mounted multimedia equipment, and the testing includes but is not limited to sound or video definition, audio distortion and image jitter indexes; the multimedia format compatibility test unit 12 is responsible for testing the compatibility of various audio and video formats supported by the vehicle-mounted multimedia device, as well as peripherals.

The user experience guaranteeing module 4 is used for evaluating and improving the user experience of the vehicle-mounted multimedia system, and comprises resolution of a display screen, friendliness of a use interface and accuracy of voice recognition so as to optimize the interaction flow with a user; the user experience assurance module 4 comprises an interactive interface test unit 13 and a user operation flow test unit 14, wherein the interactive interface test unit 13 is used for testing response speed, operation convenience and interface attractiveness of an interactive interface and providing corresponding improvement strategies for test results; the user operation flow test unit 14 is responsible for simulating the use condition of the vehicle-mounted multimedia device by the user in different scenes, testing the response speed and the operation convenience of the device, and generating a detailed test report for the monitored abnormal condition.

The test instrument board display module 5 is used for visual presentation and data statistics of vehicle-mounted multimedia test results, including fault report, data analysis and chart display, and effectively supports monitoring and decision-making of test results by testers and managers; the test instrument board display module 5 comprises a data display unit 15 and a monitoring reminding unit 16, wherein the data display unit 15 performs visual display on test result data and presents the test result to a user in an intuitive and easily understood manner; the monitoring reminding unit 16 is used for monitoring abnormal conditions in the testing process and sending out an alarm or generating error alarm information to a user.

The continuous integration module 6 is used for realizing continuous integration and automatic deployment of the vehicle-mounted multimedia software product, and realizing quick test result feedback and iterative update, and the test period is shortened by continuously optimizing the test flow and tools; the continuous integration module 6 comprises a source code management and version control unit 17 and a construction tool and automatic test tool application unit 18, wherein the source code management and version control unit 17 is responsible for managing source codes, documents and test cases, and team cooperation and version control are realized to ensure consistency and maintainability of software; the build tool and automated test tool application unit 18 utilizes the concept of CI/CD to automatically compile, package and deploy application programs through the Jenkins automated build tool, and complete corresponding test procedures in combination with the JUnit and the Appium automated test tools.

The invention realizes the functions of automatically generating test cases, dynamically adjusting test flows, automatically diagnosing and troubleshooting faults by means of artificial intelligence, machine learning and big data analysis, greatly improves the test efficiency and precision, differentially designs and perfects each module and unit, can cover all key fields of vehicle-mounted multimedia equipment, including audio and video quality, user experience and continuous integration, greatly improves the comprehensiveness and accuracy of the test, and therefore well solves the problems of low test precision, limited test coverage and to-be-improved test accuracy when the existing vehicle-mounted multimedia is tested; on the other hand, through the monitoring and predicting system, the real-time monitoring and data collection of the running state of the vehicle-mounted multimedia equipment are realized, the stability and the reliability of the system are improved by combining an automatic repair technology, finally, each module and each unit are independent by adopting a modularized design, can be added or deleted according to the test requirement, can support the quick access of a new technology and an algorithm, and are convenient for the later-stage project upgrade and expansion.

Example two

As shown in fig. 1 to 2, the present embodiment is different from the first embodiment in that:

A vehicle-mounted multimedia automatic test system based on the Internet of things comprises a dynamic test module 1, an automatic monitoring module 2, an audio and video quality assurance module 3, a user experience assurance module 4, a test instrument board display module 5 and a continuous integration module 6.

The dynamic test module 1 is used for realizing real-time dynamic test of the vehicle-mounted multimedia system, including functional test, performance test, safety test and compatibility test, and improving efficiency and precision by continuous test, and ensuring stability and reliability of the vehicle-mounted multimedia system; the dynamic test module 1 comprises a use case generating unit 7 and an adaptive test unit 8, wherein the use case generating unit 7 is responsible for extracting key information from the existing test use cases, and then generating new test use cases by using natural language processing and machine learning technology; the self-adaptive test unit 8 dynamically adjusts the test cases or the test flow according to the equipment state and the user behavior data, and feeds back the test cases according to the test results in the test process, so that the test cases are optimized rapidly, and the test efficiency and the coverage rate are improved.

The automatic monitoring module 2 monitors and collects performance parameters of the vehicle-mounted multimedia system including a CPU, a memory, a hard disk, a bandwidth and a power supply in real time through a sensor and a monitoring tool so as to discover and solve the fault problem in time; the automatic monitoring module 2 comprises an equipment monitoring unit 9 and an automatic repairing unit 10, wherein the equipment monitoring unit 9 is responsible for integrating a sensor in the vehicle-mounted multimedia equipment, monitoring the running state, the temperature and the electric quantity of the equipment through a data acquisition and transmission technology, and feeding back the information to the system; when detecting that a fault occurs in a certain device, the automatic repair unit 10 rapidly locates the cause and the position of the fault by analyzing the log and the monitored data generated by the device, generates a detailed fault report, and simultaneously can automatically sequence the faults according to a preset priority and provide a corresponding solution to rapidly repair the problem.

The audio and video quality assurance module 3 is used for evaluating and optimizing the audio and video quality of the vehicle-mounted multimedia system so as to ensure the definition, fluency and high fidelity of audio and video playing, including audio and video encoding and decoding algorithm selection, acoustic parameter analysis and signal processing; the audio and video quality assurance module 3 comprises an audio and video quality test unit 11 and a multimedia format compatibility test unit 12, wherein the audio and video quality test unit 11 uses an algorithm based on deep learning to analyze and evaluate the sound and video output by the vehicle-mounted multimedia equipment in real time, and simultaneously utilizes an AI intelligent optimization algorithm to improve the quality of the sound and video; the multimedia format compatibility testing unit 12 performs adaptive, concurrent and batch compatibility testing on various audio and video formats supported by the vehicle-mounted multimedia device by means of a cloud platform and heterogeneous system clusters.

The user experience guaranteeing module 4 is used for evaluating and improving the user experience of the vehicle-mounted multimedia system, and comprises resolution of a display screen, friendliness of a use interface and accuracy of voice recognition so as to optimize the interaction flow with a user; the user experience assurance module 4 comprises an interactive interface test unit 13 and a user operation flow test unit 14, wherein the interactive interface test unit 13 simulates a driving environment by means of an AR/VR technology, and performs structural optimization by an ergonomic method, so that functions of sketch design, interactive interface analysis, rendering and dynamic demonstration are realized, and a more real test environment is provided; the user operation flow testing unit 14 performs data collection and analysis on the vehicle-mounted multimedia device from multiple dimensions based on natural language processing and collaborative filtering algorithm, establishes an omnibearing user behavior model, realizes accurate simulation by using a deep network technology, and improves testing efficiency and accuracy.

The test instrument board display module 5 is used for visual presentation and data statistics of vehicle-mounted multimedia test results, including fault report, data analysis and chart display, and effectively supports monitoring and decision-making of test results by testers and managers; the test instrument board display module 5 comprises a data display unit 15 and a monitoring reminding unit 16, wherein the data display unit 15 performs cloud display and analysis on test result data by utilizing a big data technology and a visualization tool to form an omnibearing and real-time panoramic monitoring view so as to help a customer to quickly find and solve a problem; the monitoring reminding unit 16 establishes a prediction model by utilizing massive historical fault data based on an intelligent pushing technology, so that intelligent reminding and automatic repair are realized, and more stable product service is provided for customers.

The continuous integration module 6 is used for realizing continuous integration and automatic deployment of the vehicle-mounted multimedia software product, and realizing quick test result feedback and iterative update, and the test period is shortened by continuously optimizing the test flow and tools; the continuous integration module 6 comprises a source code management and version control unit 17 and a construction tool and automatic test tool application unit 18, wherein the source code management and version control unit 17 realizes functions of code hosting, code auditing and branch management by means of a GitLab open source cooperation platform, and simultaneously adopts a agile development mode to quickly and iteratively develop versions and product prototypes; the construction tool and the automated testing tool use the unit 18 to combine with the Docker technology, and utilize the automated construction and deployment tool to perform interface-free operation, so as to realize rapid construction and automated testing of various application programs and different environments, and realize omnibearing performance detection and monitoring by means of a Prometaus monitoring system.

The invention realizes the functions of automatically generating test cases, dynamically adjusting test flows, automatically diagnosing and troubleshooting faults by means of artificial intelligence, machine learning and big data analysis, greatly improves the test efficiency and precision, differentially designs and perfects each module and unit, can cover all key fields of vehicle-mounted multimedia equipment, including audio and video quality, user experience and continuous integration, greatly improves the comprehensiveness and accuracy of the test, and therefore well solves the problems of low test precision, limited test coverage and to-be-improved test accuracy when the existing vehicle-mounted multimedia is tested; on the other hand, through the monitoring and predicting system, the real-time monitoring and data collection of the running state of the vehicle-mounted multimedia equipment are realized, the stability and the reliability of the system are improved by combining an automatic repair technology, finally, each module and each unit are independent by adopting a modularized design, can be added or deleted according to the test requirement, can support the quick access of a new technology and an algorithm, and are convenient for the later-stage project upgrade and expansion.

Claims (9)

1. The utility model provides a on-vehicle multi-media automatic test system based on thing networking which characterized in that: the system comprises a dynamic test module (1), an automatic monitoring module (2), an audio and video quality assurance module (3), a user experience assurance module (4), a test instrument board display module (5) and a continuous integration module (6); the dynamic test module (1) is used for realizing real-time dynamic test of the vehicle-mounted multimedia system, including functional test, performance test, safety test and compatibility test, and the efficiency and the precision are improved through continuous test, so that the stability and the reliability of the vehicle-mounted multimedia system are ensured; the automatic monitoring module (2) monitors and collects performance parameters of the vehicle-mounted multimedia system including a CPU, a memory, a hard disk, a bandwidth and a power supply in real time through a sensor and a monitoring tool so as to discover and solve the problem of faults in time; the audio and video quality assurance module (3) is used for realizing the evaluation and the optimization of the audio and video quality of the vehicle-mounted multimedia system so as to ensure the definition, the fluency and the high fidelity of the audio and video playing, and the audio and video quality optimization means comprise audio and video encoding and decoding algorithm selection, acoustic parameter analysis and signal processing; the user experience guaranteeing module (4) is used for evaluating and improving the user experience of the vehicle-mounted multimedia system, and comprises resolution of a display screen, friendliness of a use interface and accuracy of voice recognition so as to optimize the interaction flow with a user; the test instrument board display module (5) is used for visual presentation and data statistics of vehicle-mounted multimedia test results, including fault report, data analysis and chart display, and effectively supports monitoring and decision-making of test results by testers and managers; the continuous integration module (6) is used for realizing continuous integration and automatic deployment of the vehicle-mounted multimedia software product, and realizing quick test result feedback and iterative updating, and the test period is shortened by continuously optimizing the test flow and tools.

2. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the dynamic test module (1) comprises a use case generation unit (7) and an adaptive test unit (8), wherein the use case generation unit (7) is responsible for automatically generating test cases for the vehicle-mounted multimedia equipment by utilizing a machine learning technology and a voice recognition technology; the self-adaptive test unit (8) dynamically adjusts test cases or test flows according to the equipment state and the user behavior data, and determines which test case is executed next through analyzing the equipment running state and the user operation behavior in the test process so as to improve the test efficiency and coverage rate.

3. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the automatic monitoring module (2) comprises an equipment monitoring unit (9) and an automatic repairing unit (10), wherein the equipment monitoring unit (9) monitors the hardware state and the operation log information of the vehicle-mounted multimedia equipment in real time and feeds the information back to the system so as to perform accurate fault analysis and investigation; when detecting that a certain device is in fault, the automatic repair unit (10) automatically repairs the device in a preset fault processing mode, so that the downtime of the device is shortened.

4. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the audio and video quality assurance module (3) comprises an audio and video quality test unit (11) and a multimedia format compatibility test unit (12); the audio and video quality testing unit (11) uses high-precision microphone, camera and computer vision technology to analyze and evaluate the sound and video output by the vehicle-mounted multimedia equipment, and the testing includes but is not limited to sound or video definition, audio distortion and image jitter indexes; the multimedia format compatibility test unit (12) is responsible for testing the compatibility of various audio and video formats supported by the vehicle-mounted multimedia device and the peripherals.

5. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the user experience assurance module (4) comprises an interactive interface test unit (13) and a user operation flow test unit (14), wherein the interactive interface test unit (13) is used for testing response speed, operation convenience and interface attractiveness of an interactive interface and providing corresponding improvement strategies for test results; the user operation flow test unit (14) is responsible for simulating the use condition of the vehicle-mounted multimedia equipment by the user in different scenes, testing the response speed and the operation convenience of the equipment, and generating a detailed test report for the monitored abnormal condition.

6. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the test instrument board display module (5) comprises a data display unit (15), wherein the data display unit (15) is used for visually displaying test result data and displaying the test result to a user in an intuitive and understandable mode.

7. The internet of things-based vehicle-mounted multimedia automated testing system of claim 6, wherein: the test instrument board display module (5) further comprises a monitoring reminding unit (16), wherein the monitoring reminding unit (16) is used for monitoring abnormal conditions in the test process and sending an alarm or generating error alarm information to a user.

8. The vehicle-mounted multimedia automatic test system based on the internet of things according to claim 1, wherein: the continuous integration module (6) comprises a source code management and version control unit (17), and the source code management and version control unit (17) is responsible for managing a source code and a version control system, so that the consistency of software from construction to release of a test is ensured, and the problem caused by inconsistent versions is avoided.

9. The internet of things-based vehicle-mounted multimedia automated testing system of claim 8, wherein: the continuous integration module (6) further comprises a construction tool and an automatic test tool application unit (18), wherein the construction tool and the automatic test tool application unit (18) are responsible for realizing compiling, packing and deployment of application programs by using the construction tool, and completing corresponding test flows by using the automatic test tool, and the continuous integration module has the main functions of rapidly feeding back integration and test results and improving test efficiency and stability.