CN212696220U - Multi-directional throughput testing system of wireless router - Google Patents

Abstract

The utility model discloses a multidirectional throughput testing system of a wireless router, which comprises a wired terminal, a wireless terminal, a device to be tested and a microwave darkroom, wherein the wireless terminal and the device to be tested are arranged in the microwave darkroom, the wired terminal is arranged outside the microwave darkroom, and the wired terminal is in wired connection with the device to be tested; the microwave oven also comprises signal probes and a probe switching module, wherein the signal probes are positioned in the microwave darkroom and distributed around the equipment to be tested in space, each signal probe is in wired connection with a wireless terminal, and the wireless terminal is in wireless connection with the equipment to be tested through the signal probe; the probe switching module is in wired connection with the wired terminal, so that the wired terminal can select the signal probe currently started by the wireless terminal through the probe switching module. The test system can verify the throughput performance of the wireless router in different directions, and has the characteristics of high automation degree, high accuracy, strong flexibility and the like.

Description

Multi-directional throughput testing system of wireless router

Technical Field

The utility model relates to a network communication capability test field especially relates to a test system of wireless router.

Background

With the development of science and technology and the progress of society, more and more devices with wifi modules are carried, so that the wireless router needs to access more devices, which puts higher requirements on the performance of the wireless router.

The throughput is an important index for measuring the network performance of the equipment, and can be used for expressing the size of data transmission quantity on the network in unit time, and the throughput of the wireless router directly reflects the performance of the router; during the research and development and production of the router, a wireless router manufacturer needs to perform various performance tests on the wireless router, wherein the throughput test is an important link.

The current general method for testing the wireless router is to place a desk in a microwave darkroom and place the wireless router and an accompanying terminal at two ends of a desktop respectively; and after the test accompanying terminal is connected to the wireless router, carrying out flow transmission between the wireless router and the test accompanying terminal, thereby obtaining throughput data through the performance test software test.

However, since the router antenna has a certain directivity, the above test method can only test the throughput performance of the wireless router in the same plane; in practical use, for example, in a home, a mall, and other scenes, the wireless router is located at a position higher or lower than the wireless router due to the complexity of the environment and the limitation of the installation condition, and sometimes even hangs upside down on the ceiling, and the directions of the devices connected to the wireless router are different from each other with respect to the wireless router; in the face of such a situation, the throughput of the wireless router in each direction in a spatial range cannot be completely verified by the current common performance testing method; in order to ensure the user experience, the requirement of omnibearing three-dimensional verification of the data throughput of the wireless router is urgent.

SUMMERY OF THE UTILITY MODEL

To the above problem, an object of the utility model is to provide a wireless router multidirectional throughput test system, this test system can verify the throughput performance in the different position of wireless router, has characteristics such as degree of automation height, accuracy height, flexibility are strong simultaneously.

In order to achieve the above object, the utility model provides a wireless router multidirectional throughput testing system, including wired terminal, wireless terminal, equipment to be tested and microwave darkroom, wireless terminal and equipment to be tested locate in the microwave darkroom, wired terminal locates outside the microwave darkroom, wired terminal with the equipment to be tested wired connection; the wired terminal and the wireless terminal are provided with test software;

the microwave oven also comprises a group of signal probes and a probe switching module, wherein the signal probes are positioned in the microwave darkroom and distributed around the equipment to be tested in space, each signal probe is in wired connection with the wireless terminal, and the wireless terminal is in wireless connection with the equipment to be tested through the signal probes; the probe switching module is in wired connection with the wired terminal, so that the wired terminal can select the signal probe currently started by the wireless terminal through the probe switching module.

According to the utility model discloses a multidirectional throughput test system of wireless router, its beneficial effect lies in: the wireless terminal is wirelessly connected with the equipment to be tested through the signal probe, and during testing, the signal probe for transmitting signals to the wireless terminal is switched through the probe switching module, so that the throughput of the equipment to be tested can be tested in multiple directions.

Preferably, the test system further comprises a rotary table, the wired terminal is in wired connection with the rotary table to control the rotary table to rotate, and the device to be tested is placed on the rotary table; because the revolving stage drives the equipment to be tested and rotates, the signal probe rotates around the equipment to be tested when the equipment to be tested is motionless, and the orientation relation between the signal probe and the equipment to be tested can be greatly expanded by controlling the revolving stage to rotate.

Furthermore, each signal probe and the equipment to be tested are positioned on the same vertical surface; therefore, the position relation of the signal probe and the two-dimensional plane of the equipment to be tested can be expanded into the position relation in the three-dimensional space by controlling the rotation of the rotary table, so that the number of the signal probes required to be arranged for realizing the technical purpose is greatly reduced.

Furthermore, each signal probe is uniformly distributed on a ring taking the equipment to be tested as the center of the circle; under the condition, the aim of testing the equipment to be tested in all directions in the space can be fulfilled by using as few signal probes as possible.

Preferably, the probe switching module is an independent probe switcher, and each signal probe is connected to the wireless terminal through the probe switcher in a wired mode.

Preferably, the test system further comprises a signal attenuation module, and the signal transmitted between the signal probe and the wireless terminal is attenuated by the signal attenuation module; the wired terminal is in wired connection with the signal attenuation module to control the signal attenuation degree; therefore, by adjusting the signal attenuation degree, the throughput performance of the signal probe and the equipment to be tested at different distances can be simulated and tested while the actual distance between the signal probe and the equipment to be tested is not changed.

Further, the signal attenuation module is an adjustable attenuator independent from the wireless terminal; the number of the adjustable attenuators is not less than the number of the antennas of the equipment to be tested.

Preferably, the signal probe is a dual-polarization probe; furthermore, the frequency range of the signal probe is 400MHz-8.5GHz, so that the signal probe can be used for testing equipment to be tested in 2.4G and 5G frequency bands.

Drawings

Fig. 1 is a diagram of a hardware architecture according to an embodiment of the present invention.

FIG. 2 is a flow chart of a testing method in the embodiment shown in FIG. 1.

Detailed Description

The following is a detailed description of a preferred embodiment of the present invention:

the system for testing the multi-directional throughput of the wireless router shown in fig. 1 includes a wired terminal 1, a wireless terminal 2, a device to be tested 3 and a microwave darkroom 4; the wireless terminal 2 is a host provided with a wireless network card, and the microwave darkroom 4 is used for isolating external electromagnetic interference and improving the testing precision; the wireless terminal 2 and the equipment to be tested 3 are arranged in the microwave darkroom 4, and the wired terminal 1 is arranged outside the microwave darkroom 4.

In addition, the system also comprises a group of signal probes 5, a circular ring 8, a probe switcher 60 and an adjustable attenuator 90; the circular ring 8 is fixed on a vertical plane by taking the equipment to be tested 3 as a circle center, and the signal probes 5 are uniformly distributed on the circular ring 8 and are fixed with the circular ring 8; each signal probe 5 is connected with the wireless terminal 2 through a probe switcher 60 and an adjustable attenuator 90 in a wired manner, and the wireless terminal 2 performs wireless signal transmission with the equipment to be tested 3 through the signal probes 5.

Wherein the probe switcher 60 is used to switch the signal probe 5 to which the wireless terminal 2 is currently connected.

The intensity of the signal received by the wireless terminal 2 can be controlled by adjusting the attenuation parameter of the adjustable attenuator 90, so that the throughput performance of the signal probe 5 and the device to be tested 3 at different distances can be simulated under the condition that the actual distance between the two devices to be tested is not changed.

In addition, the number of the adjustable attenuators 90 is not less than the number of the antennas of the device to be tested 3; in the implementation, the device to be tested 3 may have a plurality of transmitting antennas, and at least a corresponding number of signal probes 5 need to be used for performing the signal transceiving test, and at this time, by setting the plurality of adjustable attenuators 90, the signals of the plurality of signal probes 5 can be respectively processed, so that the situation that the signals mutually interfere with each other is avoided, and the accuracy of the test can be improved.

It should be noted that in the present embodiment, the probe switching module 6 and the signal attenuation module 9 are independent equipment probe switcher 60 and adjustable attenuator 90; in practical implementation, if the probe switching module 6 and the signal attenuation module 9 are integrated in other devices, the technical purpose can be achieved, and such implementation should be included in the protection scope.

In addition, the test system also comprises a rotary table 7, and the equipment to be tested 3 is placed on the rotary table 7 and rotates along with the rotary table 7; in this embodiment, the signal probe 5 is stationary and the device under test 3 rotates, which is equivalent to the signal probe 5 rotating around the device under test 3, so that under the condition that the number of the signal probes 5 is not changed, the azimuth relationship between the signal probe 5 and the device under test 3 can be greatly expanded, and the cost required for realizing the technical purpose is greatly reduced.

It should be noted that, in the implementation process, the turntable 7 is not limited, and any manner or device that can rotate the device under test 3 can achieve the technical purpose, and should be included in the protection scope.

The wired terminal 1 is in wired connection with the probe switcher 60, the adjustable attenuator 90 and the rotary table 7 respectively; the wired terminal 1 is in wired connection with the equipment to be tested 3, and the wireless terminal 2 is in wireless connection with the equipment to be tested 3 through the signal probe 5, so that network intercommunication of throughput testing is formed.

The wired terminal 1 and the wireless terminal 2 are provided with the running test software for running test.

The test system is additionally provided with automatic control software, and comprises a host end deployed on the wired terminal 1 and a client end deployed on the wireless terminal 2, wherein the client end can read the current signal intensity and the connection speed according to an instruction of the host end and transmit data to the host end; automatic control of the probe switching module 6, the signal attenuation module 9 and the rotary table 7 can be realized through automatic control software, meanwhile, the automatic control software can realize the flow test through flow test software, and count the throughput result to finally generate a test report.

In addition, the signal probe 5 is a dual-polarized probe; further, the frequency range of the signal probe 5 is 400MHz-8.5 GHz; thereby enabling the signal probe 5 to be used to test devices under test 3 in the 2.4G and 5G frequency bands.

In the present embodiment, the device under test 3 includes all kinds of wireless routers.

The test system can realize the technical purpose of carrying out all-around throughput test on the equipment to be tested 3 in space with less signal probes 5 and lower cost by switching the signal probes 5, rotating the rotary table 7 and adjusting the adjustable attenuator 90.

As shown in fig. 2, the multi-directional throughput testing system for wireless router of the present invention provides a testing method, which comprises the following steps:

s1: configuring IP addresses of the wired terminal 1, the wireless terminal 2 and the equipment to be tested 3 to enable the three to be in network intercommunication;

s2: running a running test software and an automatic control software;

s3: configuring the running parameters, including parameters such as a running protocol and running time; configuring switching parameters of the probe switching module 6; configuring attenuation parameters of the signal attenuation module 9; configuring rotation parameters of the rotary table 7, including a starting value, an ending value and a step parameter value;

s4, when the turntable 7 rotates to an initial angle, the probe switching module 6 is switched to the initial signal probe 5, and the wireless terminal 2 is connected to the equipment to be tested 3 through the current signal probe 5;

s5: starting a race flow test;

s6: after the flow test is finished, the probe switching module 6 automatically switches to the next signal probe 5 to perform the flow test until the last signal probe 5 is set;

s7: after all the signal probes 5 are tested, the rotary table 7 rotates to the next testing angle according to the configured step parameter values, and all the signal probes 5 are tested in sequence until all the set testing angles are tested;

s8: and counting the test results to generate a space throughput test report.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, but rather as the subject matter of the invention is intended to cover all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

Claims (10)

1. A wireless router multi-directional throughput testing system comprises a wired terminal (1), a wireless terminal (2), a device to be tested (3) and a microwave darkroom (4), wherein the wireless terminal (2) and the device to be tested (3) are arranged in the microwave darkroom (4), the wired terminal (1) is arranged outside the microwave darkroom (4), and the wired terminal (1) is in wired connection with the device to be tested (3); the wired terminal (1) and the wireless terminal (2) are provided with test software;

the method is characterized in that: the microwave oven is characterized by further comprising a group of signal probes (5) and a probe switching module (6), wherein the signal probes (5) are located in the microwave darkroom (4) and distributed around the equipment to be tested (3) in space, each signal probe (5) is in wired connection with the wireless terminal (2), and the wireless terminal (2) is in wireless connection with the equipment to be tested (3) through the signal probes (5); the probe switching module (6) is in wired connection with the wired terminal (1), so that the wired terminal (1) can select the signal probe (5) which is connected with the wireless terminal (2) in the current starting mode through the probe switching module (6).

2. The wireless router multi-directional throughput testing system of claim 1, wherein: the device to be tested is characterized by further comprising a rotary table (7), the wired terminal is in wired connection with the rotary table (7) to control the rotary table (7) to rotate, and the device to be tested (3) is placed on the rotary table (7).

3. The wireless router multi-directional throughput testing system of claim 2, wherein: and each signal probe (5) and the equipment to be tested (3) are positioned on the same vertical surface.

4. The wireless router multi-directional throughput testing system of claim 3, wherein: the signal probes (5) are uniformly distributed on a circular ring (8) with the equipment to be tested (3) as the center of a circle.

5. The wireless router multi-directional throughput testing system of claim 1, wherein: the probe switching module (6) is a probe switcher (60) independent of the wireless terminal (2), and each signal probe (5) is connected to the wireless terminal (2) through the probe switcher (60) in a wired mode.

6. The wireless router multi-directional throughput testing system of claim 1, wherein: the system also comprises a signal attenuation module (9), and signals transmitted between the signal probe (5) and the wireless terminal (2) are attenuated by the signal attenuation module (9); the wired terminal (1) is in wired connection with the signal attenuation module (9) so as to adjust the signal attenuation degree.

7. The wireless router multi-directional throughput testing system of claim 6, wherein: the signal attenuation module (9) is an adjustable attenuator (90) independent of the wireless terminal (2).

8. The wireless router multi-directional throughput testing system of claim 7, wherein: the number of the adjustable attenuators (90) is not less than that of the antennas of the equipment to be tested (3).

9. The wireless router multi-directional throughput testing system of claim 1, wherein: the signal probe (5) is a dual-polarized probe.

10. The wireless router multi-directional throughput testing system of claim 9, wherein: the frequency range of the signal probe (5) is 400MHz-8.5 GHz.

Images