CN112689250A - Device and method for testing fusion 5G signaling - Google Patents
Device and method for testing fusion 5G signaling Download PDFInfo
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- CN112689250A CN112689250A CN202011537904.XA CN202011537904A CN112689250A CN 112689250 A CN112689250 A CN 112689250A CN 202011537904 A CN202011537904 A CN 202011537904A CN 112689250 A CN112689250 A CN 112689250A
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Abstract
The invention relates to a method for testing a fusion 5G signaling, which comprises the steps of establishing connection between a parameter acquisition device for acquiring a test signaling parameter in a device for testing the fusion 5G signaling and a tested signaling to acquire the signaling parameter; the first signaling test module receives a signaling parameter mechanical test transmitted by a parameter acquisition device for acquiring test signaling parameters, processes a first test result in the processor and stores the first test result in the storage unit in a standard sequence, and displays the first test result through a visual screen and keeps a picture. The advantages are that: the test can be carried out by high-speed signaling generated by 5G ultra-dense networking, and the test result is accurate.
Description
Technical Field
The invention relates to a device and a method for testing a fusion 5G signaling.
Background
In recent years, under the efforts of international standardization organization and governments and operators of various countries, the 5G standardization process is accelerated, 5G spectrum plans of countries and regions such as korea in the middle and united states and europe are developed successively, and most mainstream operators around the world have started to lay out and deploy 5G networks. Compared with a 4G system, the 5G system has remarkable improvements in the aspects of peak rate, spectrum efficiency, coverage, connection number, delay, reliability, user experience, power consumption control and the like. The method provides powerful support for large-scale application of the Internet of things, the Internet of vehicles, virtual reality, augmented reality, unmanned driving and the like.
The density of the existing 5G network base station is greatly improved, and the network testing and data acquisition workload is huge due to a multi-system heterogeneous networking mode.
Disclosure of Invention
The invention aims to solve the defects in the prior art and provides a device for fusing a 5G signaling test.
In order to achieve the purpose, the invention adopts the following technical scheme: a method for fusing a 5G signaling test,
the first step is as follows: establishing connection with a tested signaling through a parameter acquisition device for acquiring a test signaling parameter in a device for fusing 5G signaling test, and acquiring a signaling parameter;
secondly, the first signaling test module receives a signaling parameter mechanical test transmitted by a parameter acquisition device for acquiring test signaling parameters, processes a first test result in a processor and stores the standard sequence in a storage unit, and displays the first test result through a visual screen and keeps a picture;
thirdly, the second signaling test module receives the signaling parameter mechanical test transmitted by the parameter acquisition device for acquiring the test signaling parameter, processes the second test result in the processor and stores the standard sequence in the storage unit, and displays the second test result at the lower end of the first test result through the visual screen;
and fourthly, comparing the first test result with the second test result through the storage result of the storage unit to determine whether the test is correct.
Further, a parameter acquiring device for acquiring the test signaling parameter establishes a signaling carrying channel with the tested signaling, initiates access with the 5G network through the signaling carrying channel, and transmits data after the 5G network verifies the signaling carrying channel.
The device for testing the fused 5G signaling comprises a processor, wherein the processor is connected with a parameter acquisition device and a storage unit, wherein the parameter acquisition device is used for acquiring testing signaling parameters; the parameter acquisition device for acquiring the test signaling parameters is provided with a signaling interface for being connected with a unit to be tested, the processor is externally provided with a shell for wrapping the processor, the shell is provided with an accessory support frame and a visual screen, and the shell is internally provided with a first signaling test module and a second signaling test module which are connected with the processor.
Furthermore, the shell is wrapped by the parameter acquisition device, the storage unit, the first signaling test module and the second signaling test module which are used for acquiring the testing signaling parameters, the signaling interface is exposed, the visual screen is installed outside the shell through a connecting piece and is in signal connection with the processor, and the accessory support frame is arranged outside the shell.
Further, the slider of accessory support frame upper end is established in the track in the casing outside, and the slider both sides are along spacing with the outer of track lateral wall inboard laminating and through track lateral wall lower extreme, and two outer edges set up in opposite directions, and keep the clearance.
Further, a plurality of first round holes which are uniformly arranged are arranged on the side wall of the track, 2 second round holes are arranged on the side wall of two sides of the sliding block, a communicated telescopic cavity is arranged at the inner side of the second round hole at the same side of the 2 second round holes, a hollowed-out track is arranged at the lower end of the telescopic cavity, a limiting block is arranged in the telescopic cavity, two limiting shafts at the front end of the limiting block are positioned in the two second round holes, a handle at the lower end of the limiting block penetrates through the hollowed-out track and is exposed out of the sliding block, a cylindrical bulge is arranged at the rear end of the limiting block, a reset spring is arranged between the cylindrical bulge and the inner wall of the telescopic cavity corresponding to the cylindrical bulge, the broadband of the limiting block is smaller than the width of the telescopic cavity, the length of the limiting shafts is larger than that of the second round holes, the accessory support frame is arranged as a telescopic, the arc skeleton both ends are connected with mount pad both sides hub connection, and soft cloth one end is connected on the arc skeleton each section and is connected in mount pad one side, and the mount pad front end is equipped with the structure with mount pad opposite side block.
Further, the connecting piece is the ball groove, and the visual screen back is equipped with the ball axle, and the ball axle surface is equipped with the arch, and ball inslot surface is equipped with the recess, and protruding and recess correspond the cooperation, can be at multi-angle adjustment and fixed visual screen.
The invention has the beneficial effects that: the test can be carried out by high-speed signaling generated by 5G ultra-dense networking, and the test result is accurate; multiple test results can be observed; the position of the accessory support frame is convenient to adjust; the visualization screen is adjustable by 180 degrees.
Drawings
FIG. 1 is a schematic diagram of the process.
Fig. 2 is a front view of the present apparatus.
Fig. 3 is a side view of the device.
Fig. 4 is a sectional view of the accessory support bracket connection.
Fig. 5 is a cross-sectional view of the connector.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to fig. 1 to 5 in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.
Example 1 referring to fig. 1-5, a method of fusing 5G signaling tests,
the first step is as follows: establishing connection with a tested signaling through a parameter acquisition device 1 for acquiring a test signaling parameter in a device for fusing 5G signaling test, and acquiring a signaling parameter;
secondly, the first signaling test module 2 receives a signaling parameter mechanical test transmitted by a parameter acquisition device for acquiring a test signaling parameter, processes a first test result in the processor 3, stores the standard sequence in the storage unit 4, displays the first test result through the visual screen 5, and keeps a picture;
thirdly, the second signaling test module 6 receives the signaling parameter mechanical test transmitted by the parameter acquisition device for acquiring the test signaling parameter, processes the second test result in the processor and stores the standard sequence in the storage unit, and displays the second test result at the lower end of the first test result through the visual screen;
and fourthly, comparing the first test result with the second test result through the storage result of the storage unit to determine whether the test is correct.
A method for integrating 5G signaling test, a parameter acquisition device for acquiring test signaling parameters and a tested signaling establish a signaling bearing channel, access is initiated with a 5G network through the signaling bearing channel, and data is transmitted after the 5G network verifies the signaling bearing channel.
The device for testing the fused 5G signaling comprises a processor 3, wherein the processor is connected with a parameter acquisition device and a storage unit for acquiring testing signaling parameters; the parameter acquisition device for acquiring the test signaling parameters is provided with a signaling interface for being connected with a unit to be tested, the processor is externally provided with a shell for wrapping the processor, the shell is provided with an accessory support frame and a visual screen, and the shell is internally provided with a first signaling test module and a second signaling test module which are connected with the processor.
Fuse 5G signaling test's device, casing 7 will be used for acquireing the parameter acquisition device, memory cell, first signaling test module and the parcel of second signaling test module of test signaling parameter to expose the signaling interface, visual screen 8 passes through connecting piece 9 and installs outside the casing and with treater signal connection, and accessory support frame 11 is established outside casing 7.
Fuse device of 5G signaling test, the slider of accessory support frame 11 upper end is established in the track 10 in the casing outside, and slider both sides and the inboard laminating of track lateral wall are spacing through outer edge 17 of track lateral wall lower extreme, and two outer edges set up in opposite directions, just keep the clearance.
A device for testing 5G signaling is integrated, a plurality of first round holes 12 which are uniformly arranged are arranged on the side wall of a track, 2 second round holes 18 are arranged on the side wall of two sides of a sliding block, a communicated telescopic cavity is arranged at the inner side of the second round hole at the same side of the 2 second round holes, a hollowed-out track is arranged at the lower end of the telescopic cavity, a limiting block 19 is arranged in the telescopic cavity, two limiting shafts 16 at the front end of the limiting block are positioned in the two second round holes, a handle 13 at the lower end of the limiting block penetrates through the hollowed-out track and is exposed at the outer side of the sliding block, a cylindrical bulge is arranged at the rear end of the limiting block, a reset spring 22 is arranged between the cylindrical bulge and a corresponding telescopic cavity inner wall 21, the broadband of the limiting block is smaller than the width of the telescopic cavity, the length of the limiting shafts 16 is larger than that of the second round holes, the shelter shed comprises an arc-shaped framework 15 and soft cloth 14, the two ends of the arc-shaped framework are connected with the two side shafts of the installation seat, one end of the soft cloth is connected to the arc-shaped framework, each section of the soft cloth is connected to one side of the installation seat, and the front end of the installation seat is provided with a structure clamped with the other side of the installation seat.
Fuse device of 5G signaling test, connecting piece 9 is the ball groove, and the visual screen back is equipped with ball 23, and the ball surface is equipped with arch 24, and the ball inslot surface is equipped with the recess, and arch and recess correspond the cooperation, can be at multi-angle adjustment and fixed visual screen.
Fuse 5G signaling test's device, the casing lateral wall is equipped with the wind hole for the cooling.
The device for fusing 5G signaling test is also provided with an opening baffle on the shell.
The device for fusing the 5G signaling test is used for automatically planning a route by the parameter acquisition device for acquiring the test signaling parameters, intelligently acquiring test data and timely transmitting the test data to a storage unit for storage, so that a processor can analyze the test data, and the workload of network test and data acquisition in a multi-system heterogeneous networking mode is reduced.
The device for fusing the 5G signaling test also comprises a test perception module, a test management decision module and an execution module. The test perception module is responsible for perceiving the 5G wireless network interference environment, so that the distribution of test contents on the space and the structural characteristics of the test method are obtained; the test management decision module consists of a test management mode library and a test management mode fusion strategy; the test management mode library comprises available test management modes; the test management mechanism module generates a fused test management strategy through an intelligent algorithm by means of an adoptable test management mode according to the state characteristics of the test, predicts the performance of the network after the test is adopted, and performs resource allocation and signal processing on a 5G network side or a terminal by the execution module according to the decision.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.
Claims (7)
1. The method for testing the fusion 5G signaling is characterized in that:
the first step is as follows: establishing connection with a tested signaling through a parameter acquisition device for acquiring a test signaling parameter in a device for fusing 5G signaling test, and acquiring a signaling parameter;
secondly, the first signaling test module receives a signaling parameter mechanical test transmitted by a parameter acquisition device for acquiring test signaling parameters, processes a first test result in a processor and stores the standard sequence in a storage unit, and displays the first test result through a visual screen and keeps a picture;
thirdly, the second signaling test module receives the signaling parameter mechanical test transmitted by the parameter acquisition device for acquiring the test signaling parameter, processes the second test result in the processor and stores the standard sequence in the storage unit, and displays the second test result at the lower end of the first test result through the visual screen;
and fourthly, comparing the first test result with the second test result through the storage result of the storage unit to determine whether the test is correct.
2. The method of claim 1, wherein the method comprises: the parameter acquiring device for acquiring the test signaling parameter establishes a signaling bearing channel with the tested signaling, initiates access with the 5G network through the signaling bearing channel, and transmits data after the 5G network verifies the signaling bearing channel.
3. An apparatus for converged 5G signaling testing according to claim 1, comprising a processor, wherein: the processor is connected with a parameter acquisition device and a storage unit for acquiring the test signaling parameters; the parameter acquisition device for acquiring the test signaling parameters is provided with a signaling interface for being connected with a unit to be tested, the processor is externally provided with a shell for wrapping the processor, the shell is provided with an accessory support frame and a visual screen, and the shell is internally provided with a first signaling test module and a second signaling test module which are connected with the processor.
4. The apparatus of claim 2, wherein the apparatus is configured to: the shell is used for acquiring a parameter acquisition device for testing signaling parameters, a storage unit, a first signaling testing module and a second signaling testing module, a signaling interface is exposed, the visual screen is installed outside the shell through a connecting piece and is in signal connection with the processor, and the accessory supporting frame is arranged outside the shell.
5. The apparatus of claim 1, wherein the apparatus is configured to: the slider of accessory support frame upper end is established in the track in the casing outside, and the slider both sides are with the inboard laminating of track lateral wall and spacing through the outer edge of track lateral wall lower extreme, and two outer edges set up in opposite directions, and keep the clearance.
6. The apparatus of claim 5G signaling fused test, in which: the side wall of the track is provided with a plurality of first round holes which are uniformly arranged, the side walls at two sides of the sliding block are provided with 2 second round holes, the inner sides of the second round holes at the same side of the 2 second round holes are provided with communicated telescopic cavities, the lower ends of the telescopic cavities are provided with hollowed-out tracks, the limiting block is arranged in the telescopic cavities, two limiting shafts at the front end of the limiting block are positioned in the two second round holes, a handle at the lower end of the limiting block penetrates through the hollowed-out tracks and is exposed at the outer side of the sliding block, the rear end of the limiting block is provided with a cylindrical bulge, a reset spring is arranged between the cylindrical bulge and the inner wall of the telescopic cavity corresponding to the cylindrical bulge, the broadband of the limiting block is smaller than the width of the telescopic cavities, the length of the limiting shafts is larger than that of the second round holes, the accessory support frame is arranged, the arc skeleton both ends are connected with mount pad both sides hub connection, and soft cloth one end is connected on the arc skeleton each section and is connected in mount pad one side, and the mount pad front end is equipped with the structure with mount pad opposite side block.
7. The apparatus of claim 3, wherein the apparatus is further configured to: the connecting piece is the ball groove, and the visual screen back is equipped with the ball axle, and the ball axle surface is equipped with the arch, and ball inslot surface is equipped with the recess, and protruding and recess correspond the cooperation, can be at multi-angle adjustment and fixed visual screen.
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