CN113572521A

CN113572521A - Automatic testing method compatible with multi-manufacturer OLT intercommunication testing

Info

Publication number: CN113572521A
Application number: CN202110832823.0A
Authority: CN
Inventors: 巫伟
Original assignee: Xinhe Semiconductor Technology Wuxi Co Ltd
Current assignee: Xinhe Semiconductor Technology Wuxi Co Ltd
Priority date: 2021-07-23
Filing date: 2021-07-23
Publication date: 2021-10-29
Anticipated expiration: 2041-07-23
Also published as: CN113572521B

Abstract

The invention discloses an automatic testing method compatible with interconnection testing of OLTs of multiple manufacturers, which comprises a testing system consisting of ONU equipment, a program-controlled optical fiber switcher, the OLTs of the manufacturers, a gigabit switch, a flow testing instrument and a control host; the process comprises the following steps: the control host is connected with the ONU and issues service configuration according to the requirement; the control host is connected with the optical fiber switcher and is ready for DUT registration; the control host is connected with the OLT to be butted, authorizes the ONU, and then performs a series of operations according to the test content; the control host is connected with an upper-layer switchboard which is interconnected with the OLT, service configuration is carried out, and service continuity is ensured; the control host is connected with the test instrument to perform actual service test. The invention is uniformly deployed, can control the test flow through the program script and does not need manual intervention; through the optical fiber switcher, multiple devices to be tested can be tested simultaneously and concurrently, and more OLT models of different manufacturers can be butted.

Description

Automatic testing method compatible with multi-manufacturer OLT intercommunication testing

Technical Field

The invention relates to the field of automatic testing, in particular to an automatic testing method compatible with multi-manufacturer OLT intercommunication testing.

Background

The OLT intercommunication test is a very important link in the telecommunication network access test. The tester needs to manually connect the tested ON U to a corresponding service board card of an OLT of a certain manufacturer model for testing. Since the OLT of different manufacturers or the service boards of different models of the same manufacturer may be used in the actual network (sometimes, the versions of the boards of the same model are different), it is necessary to perform as many comprehensive coverage tests as possible in a laboratory. Generally, the existing testing method is to manually switch and butt corresponding OLTs and manually execute a testing process, and is not efficient.

Because the existing testing method mainly adopts manual work, the testing is realized by means of manual intervention, the efficiency is low, and errors are easy to occur. Sometimes, manual intervention is not timely, occupied time of a program can not be released, a test resource can be monopolized by the program, and the utilization rate of a test environment is not high. Therefore, when the interworking test is to improve the coverage, test more types of OLTs, or test more ONUs, an automated testing framework is required.

Disclosure of Invention

The invention aims to provide an automatic testing method compatible with the OLT intercommunication testing of multiple manufacturers, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an automatic test method compatible with interconnection test of a plurality of manufacturers OLT, wherein a system for testing comprises ONU equipment, a program control optical fiber switcher, the manufacturers OLT, a gigabit switch, a flow test instrument and a control host.

An ONU device; namely, the number of the tested DUT equipment can be one to more; the ONU equipment is the equipment to be tested, is divided into EPON equipment and GPON equipment, and can be registered and authorized to be accessed only by butting the corresponding EPON or GPON board card.

A program-controlled optical fiber switcher; the optical splitter is used for switching optical path connection, and can be switched on and off through an Ethernet controller to support socket communication.

A manufacturer OLT; the OLT of a manufacturer generally has various models, wherein each model of OLT can be provided with different models of service board cards; generally, in order to meet the requirement of the intercommunication test, different types of OLTs of different manufacturers need to be docked, and different types of service board cards also exist in the same OLT to perform the compatibility test.

A ten thousand million switches; the gigabit switch is connected with an upper connection port of the OLT, and service division is carried out through the VLAN.

A flow test meter; such as Testcenter, may simulate actual business testing.

A control host; the device is mainly used for controlling each test component and test equipment; the test cases and test scripts of the testers are stored in the host, and the corresponding test scripts can be executed during testing.

The test process using the test system comprises the following steps:

s1, a tester connects ONU 1-ONUn through an Ethernet (or a serial port) through a control host, logs in a Web GUI (graphical user interface) or an equipment serial port as required to issue service configuration;

s2, connecting a testing person with the optical fiber switcher through the Ethernet through the control host, and controlling an optical path to enable the ONU to be tested, which is usually called a DUT (device under test), to be connected with the corresponding OLT (optical line terminal) board card when the script is executed to the corresponding test case, so as to complete the connection of a PON (passive optical network) link and prepare for DUT registration;

s3, connecting the OLT to be butted through the Ethernet by a tester through the control host to authorize the ONU, and then performing a series of operations according to the test content;

s4, testing personnel connect with an upper-layer switchboard interconnected with the OLT through the Ethernet through the control host to carry out service configuration so as to ensure service communication;

and S5, connecting the testing instrument (such as a flow instrument) through the Ethernet by the testing personnel through the control host to perform actual service testing.

As a further scheme of the invention: the control host is provided with a plurality of network cards and can communicate with devices in different network segments through static IP addresses.

As a further scheme of the invention: the control program used in the test system is developed and maintained through Python and mainly comprises three parts: control system, test instrument and equipment management, the equipment management that awaits measuring, it specifically is respectively:

(1) the control system comprises:

including a main program, functional modules and a library of libs. The main program calls the functions of the packaged functional modules or Lib libraries to butt the instrument equipment or the equipment to be tested, so that the purposes of configuration and management are achieved.

(2) Test instrument and equipment management:

1) the OLT and the switch belong to network equipment and support connection management in a telnet mode;

2) the optical fiber switcher communicates by using a Socket, a main control program is connected to the equipment through an Ethernet, and a Socket interface is called to establish a link with a Socket Server of the equipment so as to manage the optical fiber switcher to adjust the on-off of a corresponding optical path;

3) the flow test instrument opens API interfaces supporting different development languages, and the control system can directly use a third-party Lib library and then call functions such as Start (), Set (), get () and the like in the corresponding API interfaces to control the operation of the test instrument and store test data.

(3) Managing the equipment to be tested:

the equipment to be tested supports three modes for management and configuration:

the serial port mode is as follows: the control system can communicate with the equipment to be tested by calling the Pyrerial module, and the tester issues the configuration to the equipment to be tested in a command form by means of serial port connection, and the mode also supports the collection of real-time running logs of the equipment to be tested for analysis.

HTTP service: the control system is provided with a Selenium functional module, so that a tester can freely write a corresponding script program, call a web driver of a browser and simulate a real user to access a web UI through http service to perform configuration management on the device to be tested.

Telnet mode: the control system also supports a Telnet mode, is connected to the LAN port of the equipment to be tested through the Ethernet, and then calls various functions in a TelnetLib library to control and manage the equipment to be tested. The method is simple and efficient.

OAM/OMCI management: this approach is managed indirectly through the OLT, which is also a function that is tested; and the control program is connected with the OLT through telnet, and then controls the OLT to configure and manage the equipment to be tested through an OAM/OMCI protocol.

Compared with the prior art, the invention has the advantages that:

1. the system of the invention can effectively improve the test continuity by uniform deployment, avoid manual intervention and greatly improve the execution efficiency.

2. The test system of the invention can support the concurrent execution of intercommunication tests by OLT and ONU of multiple manufacturers, has wider traversal and higher coverage rate, and can improve the execution efficiency by times due to the concurrent execution.

3. The test system can independently repeat a certain test item or even a certain test step according to the requirements of testers through actual verification, and has strong expansibility; the advantages are very obvious in later iteration and regression tests.

Drawings

FIG. 1 is a flow chart of a test system according to the present invention.

FIG. 2 is a diagram of the control program architecture of the test system in the method of the present invention.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Referring to fig. 1, an automated testing method compatible with the inter-working test of the OLT of multiple manufacturers includes a testing system composed of an ONU device, a program-controlled fiber switch, the OLT of a manufacturer, a gigabit switch, a flow test instrument, and a control host.

A flow test meter; such as Testcenter, may simulate actual business testing.

A control host; the device is mainly used for controlling each test component and test equipment; the test cases and test scripts of the testers are stored on the host, and the corresponding test scripts can be executed during testing; the control host is provided with a plurality of network cards and can communicate with the devices in different network segments through static IP addresses.

The control program used in the test system is developed and maintained through Python and mainly comprises three parts: control system, test instrument and equipment management, the equipment management that awaits measuring, it specifically is respectively:

(1) the control system comprises:

(2) Test instrument and equipment management:

(3) Managing the equipment to be tested:

The test process using the test system comprises the following steps:

The invention can be deployed uniformly, and can control the test flow through the program script without manual intervention; through the optical fiber switcher, multiple devices to be tested can be tested simultaneously and concurrently, and more OLT models of different manufacturers can be butted. The automatic testing process is visible in the using process, and a tester can sense the testing process and the testing progress through the log in real time and stop or re-execute the testing process according to actual needs; furthermore, since the testing process is highly automated, any single testing step can be repeatedly performed.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims

1. An automatic test method compatible with interconnection test of a multi-manufacturer OLT is characterized by comprising a test system consisting of ONU equipment, a program-controlled optical fiber switcher, the manufacturer OLT, a gigabit switch, a flow test instrument and a control host;

ONU equipment, namely DUT equipment to be tested, is divided into EPON equipment and GPON equipment, and can be registered and authorized to be accessed only by butting a corresponding EPON or GPON board card;

the optical splitter is used for switching optical path connection, can be switched on and off through an Ethernet controller, and supports socket communication;

the OLT of a manufacturer generally has multiple models, wherein each model of OLT can be provided with different models of service board cards;

the gigabit switch is in butt joint with an upper connection port of the OLT and performs service division through the VLAN;

the flow test instrument can simulate actual service test;

the control host is mainly used for controlling each test component and test equipment; the test cases and test scripts of the testers are stored on the host, and the corresponding test scripts can be executed during testing;

the process of adopting the automatic test system is as follows:

s1, a control host is connected with ONU 1-ONUn through Ethernet or a serial port, and logs in Web GUI or an equipment serial port as required to issue service configuration;

s2, the control host is connected with the optical fiber switcher through the Ethernet, when the script is executed to the corresponding test case, the optical path is controlled, so that the ONU to be tested is connected with the corresponding OLT board card, the connection of the PON link is completed, and preparation is made for DUT registration;

s3, connecting the OLT to be butted with the control host through the Ethernet, authorizing the ONU, and then performing a series of operations according to the test content;

s4, the control host is connected with an upper-layer switchboard which is interconnected with the OLT through the Ethernet to carry out service configuration so as to ensure the service to be communicated;

and S5, connecting the control host with the test instrument through the Ethernet to perform actual service test.

2. The method of claim 1, wherein at least one ONU device is provided.

3. The automatic testing method of claim 1, wherein said control host is equipped with multiple network cards and can communicate with devices of different network segments via static IP addresses.

4. The method as claimed in claim 1, wherein the testing process is controlled by a program, and the control program comprises a control system, a tester, a device management unit, and a device under test management unit.

5. The method according to claim 4, wherein the control system comprises a main program, functional modules and a lib library; the main program calls the functions of the packaged functional modules or Lib libraries to butt the instrument equipment or the equipment to be tested, so that the purposes of configuration and management are achieved.

6. The method according to claim 4, wherein the test instruments and the device management are as follows:

7. The automatic testing method compatible with the multi-vendor OLT interconnection test of claim 1, wherein the device under test supports three modes for management and configuration:

the serial port mode is as follows: the control system can communicate with the equipment to be tested by calling the Pyrerial module, and a tester is connected with the equipment to be tested by virtue of a serial port and issues the configuration to the equipment to be tested in a command form, so that the mode also supports the collection of real-time running logs of the equipment to be tested for analysis;

HTTP service: the control system is provided with a Selenium functional module, a tester can freely write a corresponding script program, call a web driver of a browser and then simulate a real user to access a web UI through http service to carry out configuration management on the device to be tested;

telnet mode: the control system also supports a Telnet mode, is connected to the LAN port of the equipment to be tested through the Ethernet, and then calls various functions in a TelnetLib library to control the equipment to be tested;