KR102053914B1 - Interior test apparatus for performance of wireless telecommunication system - Google Patents

Abstract

Disclosed is an interior experimental apparatus of wireless communication system performance capable of improving the reliability of radio wave measurement by reducing a beam incident angle to an absorber to improve radio wave absorption performance. The experimental apparatus comprises: an electromagnetic wave reflection chamber having a horizontal cross-section polygonal structure; a base station antenna disposed in the center of the electromagnetic wave reflection chamber; a transmission device transmitting radio waves to the base station antenna in the electromagnetic wave reflection chamber; and a support stand disposed at the center of each surface of the polygon to support a wireless communication terminal as a test target and simulating shortening of a transmission distance due to propagation loss.

Description

Interior test apparatus for performance of wireless telecommunication system

The present invention relates to an experimental apparatus implemented to perform a wireless communication system transmission characteristics performed in a conventional field experiment in an indoor space.

In general, the performance of a wireless communication system is determined by the output and input characteristics of a transmitting and receiving device including a transmitting and receiving antenna.

The performance evaluation of the existing wireless communication system is conducted by experimenting individual characteristics of each component in the indoor space, designing a link budget to be implemented, and then implementing the system and finally performing the characteristics through field experiments. Will be verified.

In addition, the method of testing the reception sensitivity of various wireless communication terminals such as cellular phones, DMB phones, GPS terminals, and wireless Internet of Things devices can be carried out by placing the terminals in a reverberation chamber or a small TEM cell. The performance was measured relatively easily by adjusting the input power considering the transmission loss occurring in the environment.

However, in the latest 5G wireless communication system, the optimal combination position between the wireless communication transmitter and the terminal changes frequently due to the beam forming characteristics of the transmitting and receiving antennas. In addition, it is considered that the measurement error will be larger than that when the experiment is performed in the field of outdoor space with a lot of radio wave scattering.

The performance of wireless communication systems, including transmitters and receivers, is typically based on field experiments. In addition, a variety of methods for measuring the characteristics of the individual transmission, reception apparatus, etc. constituting the wireless communication system is known, but as the most commonly used method, the electromagnetic wave reflection room measurement method is disclosed.

According to the electromagnetic radiation reflection room measurement method, by installing an absorber on the inner wall of the chamber to form a predetermined space to create an electromagnetic radiation-free reflection environment, if one side of the chamber transmits test radio waves, cell phones, DMB phones, GPS terminals and wireless devices located inside the chamber The reception performance is tested by measuring radio waves received from various wireless communication terminals such as IoT devices.

The conventional electromagnetic wave reflection room measurement method has some problems.

First, the conventional electromagnetic wave reflection chamber is provided with a radio wave absorber on the inner wall, but it is inevitable that the transmitted test radio waves are partially reflected from the inner wall of the electromagnetic wave reflection chamber to be received at the wireless communication terminal, and the reflection as much as possible It is desirable for measurement reliability.

However, as the incident angle of the radio wave beam incident on the absorber increases, the absorbing performance (often expressed as the reflection loss of the radio wave absorber) decreases, and the conventional electromagnetic wave reflection chamber has a rectangular cross section and has a large beam incidence angle. Since a larger radio wave is reflected from the absorber, there is a problem in that the quality of the internal test zone is reduced and the reliability of the measurement is deteriorated.

Second, the cuboid-shaped electromagnetic wave reflection chamber is difficult to maintain a constant transmission distance for a plurality of receivers, and also because the radio wave quality in the space where each receiver is placed is different from each other for the first reason, it is reliable. There is a problem that cannot be measured.

Third, in order to simulate a field experiment of a wireless communication system in an indoor space, an enormous sized electromagnetic wave reflection room is required, and therefore, there is a problem of enormous construction cost.

Accordingly, it is an object of the present invention to provide an indoor experimental apparatus for wireless communication system performance that can improve the reliability of radio wave measurement by reducing beam incidence angle to an absorber to improve radio wave absorption performance.

Another object of the present invention is to install a radome having a propagation loss between the transmission and reception transmission channels to simulate transmission loss in various reception situations according to the transmission, reception distance or environment, very short transmission, reception It is to provide an experimental device for evaluating wireless communication system performance indoors at a distance.

Another object of the present invention is to provide an efficient space use and construction method of the electromagnetic wave reflection chamber for realizing the above object.

An object of the present invention is to implement a transmission characteristic of a wireless communication system in an indoor space, the electromagnetic wave reflection room; A base station antenna disposed in the center of the electromagnetic wave reflection chamber; A communication device for transmitting and receiving a radio wave with the base station antenna in the electromagnetic radiation reflection room; And a support stand for supporting a wireless communication terminal for transmitting and receiving radio waves between the base station and the base station antenna, wherein the support stand shortens a transmission distance due to a propagation loss transmitted between the base station antenna and the wireless communication terminal. It is achieved by an indoor laboratory apparatus of wireless communication system performance characterized by simulating.

Preferably, the electromagnetic wave reflection chamber is formed by connecting the bending shield plate and the flat shield plate, the bending shield plate is bent in the center corresponding to the bent portion of the electromagnetic wave reflection chamber, the absorber is attached to each inside of the shield plate do.

Preferably, the electromagnetic wave reflection chamber may have a hexagonal structure in which a horizontal plane simulates the structure of a mobile communication cell.

Preferably, the support stand, the base; A turn table capable of rotating and moving by mounting the wireless communication terminal; And a spherical radome coupled to the base and surrounding the turn table.

Preferably, the propagation loss can be adjusted by adjusting the complex dielectric constant and the complex permeability according to the thickness, size or material of the radome.

Preferably, the communication device, the communication unit is installed outside the electromagnetic wave reflection chamber; A beam forming antenna installed inside the electromagnetic wave reflection chamber; And connectors for connecting them, the waveguide or the shielded transmission line.

According to the above configuration, by selecting an appropriate polygon having a larger number of planes than the square of the conventional electromagnetic wave reflection chamber, the beam incident angle of the radio wave to the absorber can be reduced to improve the radio wave absorption performance, thereby improving the reliability of radio wave measurement.

In addition, it is possible to simulate a variety of communication conditions according to the communication distance or environment wrapped around the radio communication terminal to be tested with a radio wave loss type radome.

In addition, by applying the electromagnetic wave reflection chamber of the hexagonal cell structure that simulates the mobile communication cell structure, the cell shape of the mobile communication system can be simulated and the space can be efficiently used.

1 shows an indoor experimental apparatus of a wireless communication system performance according to the present invention.
2 shows a support stand for mounting a wireless communication terminal.

Technical terms used in the present invention are merely used to describe particular embodiments, it should be noted that it is not intended to limit the present invention. In addition, the technical terms used in the present invention should be interpreted as meanings generally understood by those skilled in the art unless the present invention is defined in any other meaning in the present invention, and is excessively comprehensive. It should not be interpreted in the sense of or in the sense of being excessively reduced. In addition, when the technical terminology used in the present invention is an incorrect technical term that does not accurately express the spirit of the present invention, it should be understood as being replaced by a technical term that can be properly understood by those skilled in the art. In addition, the general terms used in the present invention should be interpreted as defined in the dictionary or according to the context before and after, and should not be interpreted in an excessively reduced sense.

Hereinafter, an indoor experimental apparatus of a wireless communication system performance according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 shows an indoor experimental apparatus of a wireless communication system performance according to the present invention.

The performance test apparatus 100 includes an electromagnetic wave reflection chamber 110, a support stand 130 installed inside the electromagnetic wave reflection chamber 110, a communication device 150, and a base station antenna 140.

Hereinafter, each component is demonstrated in detail.

<Electromagnetic Radiation Reflection Room 110>

The electromagnetic wave reflection chamber 110 of this embodiment has a hexagonal cell structure.

According to this structure, since the incident angle of the propagation beam incident from the base station antenna 140 located in the center to the absorber 120 becomes smaller on average compared to the incident angle of the propagation beam of the conventional electromagnetic radiation reflection chamber having a rectangular horizontal cross section, the absorber The radio wave absorbing performance in the wavelet is improved, and as a result the measurement reliability is improved.

In other words, as the number of planes corresponding to the base station antenna 140 increases, the average value of the incident angles of the propagation beams decreases, and ultimately, the most ideal radio wave absorption performance can be obtained when the horizontal cross section is circular.

However, considering the structural aspect, manufacturing cost, and efficient use of space of the electromagnetic wave reflection chamber 110, it is possible to select an appropriate polygon having a larger number of planes than a rectangle, and in this embodiment, it is possible to simulate the cell structure of mobile communication. It has a hexagonal cell structure that does not have overlapping space and can effectively arrange external devices.

In particular, when the quadrangle indicated by the dotted line in FIG. 1 is the building layout 10, the transmission unit 152 or the power supply device may be installed in the space between the electromagnetic radiation reflection chamber 110 having the hexagonal cell structure and the building layout 10. (Not shown) or other necessary facilities can increase the efficiency of space use.

The electromagnetic wave reflection chamber 110 is configured by combining the flat shielding plate 112 and the bending shielding plate 113 in a horizontal direction with a bolt-nut 114, and the bent portion of the electromagnetic wave reflection chamber 110 is bent. Corresponding to the bent center portion of the shield plate 113, the radio wave absorber 120 is installed inside the shield plates 112 and 113.

1, since the hexagonal cell structure is provided, six bent shield plates 113 are used to reduce the risk of electromagnetic leakage, and the appropriate number of flat shield plates 112 may be used depending on the width.

In addition, the sliding door 160 for entering and exiting the electromagnetic wave reflection chamber 110 may be installed on the sidewall of the electromagnetic wave reflection chamber 110 in contact with a path in which the worker moves, such as a corridor.

<Support stand 130>

2 shows a support stand for mounting a wireless communication terminal.

The support stand 130 is configured to mount the wireless communication terminal 20, and referring to FIG. 2, the base 132 and the turn table 136 and the base 132 mounted to the wireless communication terminal 20 are coupled to each other. And a spherical radome 134 surrounding the turn table 136.

The support stand 130 is configured to simulate transmission loss in a limited space called the electromagnetic wave reflection chamber 110.

One of the reasons for field test for performance test of wireless communication terminal is that it can secure long transmission distance and provide various transmission loss environment, but it requires a large area and a lot of time and cost. There is a problem in that the reliability of the measurement is low.

Therefore, as a structure for implementing the advantages of the field test at the electromagnetic wave reflection chamber 110 level, the support stand 130 having a radome 134 is proposed.

The turn table 136 fixed to the wireless communication terminal 136 may be rotated and moved, and beam search may be performed by controlling the rotation and movement of the turn table 136.

In addition, the spherical radome 134 simulates transmission loss of radio waves transmitted from the base station antenna 140 or transmitted from the wireless communication terminal 20 in a state in which the wireless communication terminal 20 is accommodated therein. . Therefore, by generating a transmission loss through the radome 134 in the narrow electromagnetic radiation reflection chamber 110, it is possible to simulate the performance as long as the transmission distance from the position of the wireless communication terminal 20.

The radome 134 may be replaced according to the frequency of transmitted radio waves, and may adjust the amount of transmission loss through a complex dielectric constant, a complex permeability, and a size according to a thickness or a material.

The support stand 130 may be disposed at an intermediate portion of each surface of the electromagnetic wave reflection chamber 110 around the base station antenna 140 in the center to make the measurement uniform.

<Communication device 150>

The communication device 150 includes a communication unit 152 installed outside the electromagnetic wave reflecting room 110, a beam forming antenna 154 installed inside the electromagnetic wave reflecting room 110, and a connector 153 connecting them. .

Here, the connector 153 may be a waveguide or a shielded transmission line.

In the indoor experimental apparatus of the performance of the wireless communication system having the structure as described above, the wireless communication terminal 20 as a test target is mounted on each support stand 130 installed in the electromagnetic wave reflection chamber 110 to perform the performance test of the wireless communication system. do.

Radio waves transmitted from the communication unit 152 installed outside the electromagnetic wave reflecting room 110 to the beam forming antenna 154 installed inside the electromagnetic wave reflecting room 110 through the connector 153 are located in the base station antenna ( 140).

The base station antenna 140 monitors the signal strength of each wireless communication terminal 20 and transmits radio waves to the matched wireless communication terminal 20.

The radio wave transmitted to the radio communication terminal 20 is received by the radio communication terminal 20 after passing a predetermined radio wave loss through the radio wave loss radome 134 of the support stand 130.

Therefore, various transmission distances can be simulated as much as the amount of propagation loss, which can cause measurement errors through the electromagnetic radiation reflection chamber 110 while providing an environment such as a field test in a narrow space inside the electromagnetic radiation reflection chamber 110. Eliminating possible causes can improve the reliability of the measurement.

In the above description, the embodiment of the present invention has been described, but various changes can be made at the level of those skilled in the art. For example, since the wireless communication terminal can naturally transmit and receive, the performance test of the wireless communication system as described above may be performed by transmitting radio waves from the wireless communication terminal to the communication apparatus through the base station antenna. Therefore, the scope of the present invention should not be construed as limited to the above embodiment, but should be construed by the claims described below.

100: indoor laboratory apparatus of wireless communication system performance
110: electromagnetic wave reflection room
112, 113: shield plate
114: bolt-nut
120: absorber
130: support stand
140: base station antenna
152: sending unit
153: connector
154: beamforming antenna
160: sliding door

Claims (6)

Experimental apparatus that implements the transmission characteristics of the wireless communication system in the indoor space,
Electromagnetic wave reflection room;
A base station antenna disposed in the center of the electromagnetic wave reflection chamber;
A communication device for transmitting and receiving a radio wave with the base station antenna in the electromagnetic radiation reflection room; And
It includes a support stand for supporting a wireless communication terminal for transmitting and receiving radio waves with the base station antenna,
The support stand simulates a shortening of a transmission distance due to propagation loss transmitted between the base station antenna and the wireless communication terminal. In claim 1,
The electromagnetic wave reflection chamber is formed by connecting a bending shielding plate and a flat shielding plate, the bending shielding plate is bent at the center corresponding to the bent portion of the electromagnetic wave reflection chamber,
Indoor test apparatus of the wireless communication system performance, characterized in that the absorber is attached to the inside of each of the shielding plate. In claim 1,
The electromagnetic radiation reflection chamber has a horizontal plane has a hexagonal structure that simulates the structure of the mobile communication cell, the indoor experimental apparatus of the wireless communication system performance. In claim 1,
The support stand,
Base;
A turn table capable of rotating and moving by mounting the wireless communication terminal; And
Indoor laboratory apparatus of the wireless communication system performance, characterized in that consisting of a spherical radome (radome) coupled to the base and wraps the turn table. In claim 4,
Indoor experimental apparatus of the wireless communication system performance, characterized in that to adjust the propagation loss by adjusting the complex dielectric constant and complex permeability according to the thickness, size or material of the radome. In claim 1,
The communication device,
A communication unit installed outside the electromagnetic wave reflecting room;
A beam forming antenna installed inside the electromagnetic wave reflection chamber; And
An indoor laboratory apparatus for wireless communication system performance, comprising: connecting them, and comprising a connector of a waveguide or a shielded transmission line.

Images