KR102411398B1 - High gain antenna for radar system for monitoring coastline erosion environment - Google Patents

Abstract

The present invention relates to a high-gain antenna for a radar system for monitoring a coastline erosion environment. More specifically, it relates to a high-gain antenna for a radar system for monitoring a coastline erosion environment, which has low power supply loss and transmission loss, and easily secures a bandwidth for real-time large-capacity signal processing.
To this end, the present invention includes: a middle-layer conductor plate in which a power feeding unit having a cavity structure is formed, and waveguides are formed on both sides of the feeding unit; an upper conductor plate having resonant slots arranged at equal intervals on both sides of the power supply unit; And it provides a high-gain antenna for a radar system for monitoring a coastline erosion environment, comprising a lower-layer conductor plate having a connector for power supply and a fixing pin for fixing each conductor plate.

Description

High gain antenna for radar system for monitoring coastline erosion environment}

The present invention relates to a high-gain antenna for a radar system for monitoring a coastline erosion environment. More specifically, it relates to a high-gain antenna for a radar system for monitoring a coastline erosion environment, which has low power supply loss and transmission loss, and is easy to secure a bandwidth for real-time large-capacity signal processing.

Due to the complex coastline of Korea, which is surrounded by sea on three sides, there are problems such as a decrease in cognitive ability when infiltrating spies, difficulty in monitoring shoreline erosion, and inaccuracy in recognizing objects at a short distance. Various radar systems are being studied in Korea to monitor the sea and sea level. is becoming

Such a near-field recognition radar system for the sea requires a high-performance, high-gain antenna to detect small floating objects that are very difficult to detect with general radar and minute movements of the seawater surface.

As a high-performance, high-gain antenna, the slot-arrayed waveguide antenna is most suitable and used for radar, and the frequency band of the slot-arrayed waveguide antenna mainly used for marine radars is X-band or S-band.

However, in the case of X-band or S-band radar, it has a limitation in not being able to precisely process large-capacity in real time for small target and floating object detection at a short distance due to low precision.

For example, small ships and islands exist in real short distances, but in a virtual screen, it is not possible to precisely identify small ships and islands that actually exist in short distances, and clutter occurs and information such as wave heights is difficult to observe.

Therefore, it is very urgent to develop a radar system capable of real-time large-capacity signal processing in order to improve the limitations of the existing radar system.

Prior art literature: KR Registered Patent Publication No. 10-0818161 (2008.03.31. Announcement)

The present invention has been devised to solve the above problems, and has low power supply loss and transmission loss, easy to secure bandwidth for real-time large-capacity signal processing, enables beam control, and realizes high gain at high frequencies. The purpose of this study is to provide a high-gain antenna for a radar system for monitoring the coastline erosion environment that is easy to realize the high-resolution characteristics required for

A high-gain antenna for a radar system for monitoring a coastline erosion environment according to the present invention, which has been devised to achieve the above object, includes: a middle-layer conductor plate having a cavity structure-formed feeding part and waveguides formed on both sides of the feeding part; an upper conductor plate having resonant slots arranged at equal intervals on both sides of the power supply unit; and a lower-layer conductor plate on which a connector for feeding power and a fixing pin for fixing each conductor plate are disposed.

In addition, the intermediate-layer conductor plate is formed with a power feeding unit composed of a cavity structure, and waveguides arranged in six rows on both sides of the feeding unit; an upper conductor plate in which 13 resonant slots are arranged at equal intervals on both sides of the feeding unit; and a lower conductor plate on which a connector for power supply and a fixing pin for fixing each conductor plate are disposed, wherein the resonance slot of the upper conductor plate is formed in a rectangular shape with rounded angles.

In addition, the intermediate-layer conductor plate is formed with a power feeding unit composed of a cavity structure, and waveguides arranged in six rows on both sides of the feeding unit; an upper conductor plate in which 13 resonant slots are arranged at equal intervals on both sides of the feeding unit; and a lower conductor plate on which a connector for power supply and a fixing pin for fixing each conductor plate are disposed, wherein the resonance slot of the upper conductor plate is formed in a rectangular shape with rounded angles; and the power feeding part of the middle-layer conductor plate is composed of six slots, and the slots are formed at a predetermined angle in the central part of the middle-layer conductor plate.

According to the present invention, it is possible to realize a high gain at a high frequency, so that it is easy to realize the high-resolution characteristic required for the radar.

1 is a front view of a high-gain antenna for a radar system for monitoring a coastline erosion environment according to a preferred embodiment of the present invention;
Figure 2 is a rear view of Figure 1;
3 is a plan view of FIGS. 1 and 2 ;
4 is a view showing the arrangement of the resonance slots of the upper conductive plate;
5 is a view showing one row of resonant slots formed in an upper conductive plate;
6 is a view showing one resonance slot of the upper conductive plate;
7 is a front view of the intermediate layer conductor plate;
8 is a rear view of the intermediate layer conductor;
9 is a view showing a power supply part of the intermediate layer conductor plate;
10 is a view showing a slot formed in the power supply part of the intermediate-layer conductor plate;
11 is a front view of the lower layer conductor plate;
12 is a side view of the lower layer conductor plate;
13 is a graph showing reflection coefficient results of simulation and measurement of a slot array waveguide antenna according to the present invention;
14 is a graph showing simulation and measured vertical polarization results at a frequency f0 of a slot array waveguide antenna according to the present invention;
15 is a graph showing the simulated and measured horizontal polarization results at the frequency f0 of the slot array waveguide antenna according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, preferred embodiments of the present invention will be described below, but the technical spirit of the present invention is not limited thereto and may be variously implemented by those skilled in the art without being limited thereto.

1 is a front view of a high-gain antenna for a radar system for monitoring a coastline erosion environment according to a preferred embodiment of the present invention, FIG. 2 is a rear view of FIG. 1, FIG. 3 is a plan view of FIGS. 1 and 2, and FIG. 4 is Fig. 5 is a view showing one row of resonance slots formed in the upper conductor plate, Fig. 6 is a view showing one resonance slot of the upper conductor plate, Fig. 7 is a front view of the middle-layer conductor plate, FIG. 8 is a rear view of the intermediate-layer conductor plate, FIG. 9 is a view showing the power feeding part of the middle-layer conductor plate, and FIG. Fig. 11 is a front view of the lower conductor plate, Fig. 12 is a side view of the lower conductor plate, Fig. 13 is a graph showing the results of the simulation and measurement of the slot array waveguide antenna according to the present invention, and Fig. 14 is a graph showing the results of the measurement. 15 is a graph showing simulation and measured vertical polarization results at frequency f0 of the slot array waveguide antenna according to the present invention. FIG. 15 is a graph showing simulation and measured horizontal polarization results at frequency f0 of the slot array waveguide antenna according to the present invention.

1 to 15, a high-gain antenna for a radar system for monitoring a coastline erosion environment according to a preferred embodiment of the present invention is an upper conductor plate 200, a middle conductor plate 100, and a lower conductor plate 300 ) is included.

Referring to FIG. 1 , in the upper conductive plate, 13 Elliott resonant slots are arranged at equal intervals on both sides based on the cavity structure of the feeding unit, and the resonant slots in 6 rows are all formed with the same size, and the length of the slot is preferably 8.00 to 8.50 mm, the slot width is 1.00 to 1.20 mm, and the offset is 0.90 to 1.20 mm.

The light wall and narrow wall of the waveguide use the standard waveguide established by EIA through the optimized design of the antenna suitable for the purpose of monitoring coastal erosion. An optimized waveguide was used.

4, assuming that the width of the slot is very small compared to the length of the slot, the approximate width of the slot is set to about λg/15∼λg/8, and the length of the slot considering the width of the slot is λg/3∼ The theoretical design was started in the range of 3λg/8. The length, width, and offset of the slot were obtained through repeated calculations with precision in units of 0.01 mm.

The optimal slot length obtained by repeated calculation is 8.00 to 8.50 mm, the width of the slot is 1.00 to 1.20 mm, the offset is 0.90 to 1.20 mm, and the slot interval is designed at λg/2 equal intervals so that the susceptance part converges to 0 as much as possible. The array elements were designed to have the same phase.

Referring to FIG. 6 , the resonance slot 210 formed in the upper conductor plate 200 has rounded corners, and the higher the frequency, the more difficult and difficult to manufacture the slot, so a precise design is required. In consideration of manufacturing using a round drill in the process, each end of the resonance slot is formed in a round shape.

The resonant slots, which are formed in a round shape at the ends, are arranged in an equal diameter, and the phase is adjusted so that the susceptance part converges to zero as much as possible.

13 symmetrically placed on both sides of the cavity of the feeding part, in 6 rows, overall, it shows the shape of a 6*26 slot array waveguide antenna.

Referring to FIG. 7 , the intermediate layer conductor plate 100 has a cavity structure that is a power feeding part, and slots placed in a row in the cavity to improve the impedance bandwidth are arranged in an octagonal shape, which minimizes coupling through phase control and The purpose is to improve the impedance bandwidth.

The cavity structure, which is the feeding part, is located in the center of the intermediate layer conductor plate, and the vertical length of the cavity structure is the electrical length, and the horizontal length of the cavity structure is the light wall length.

In the cavity structure, six resonant slots are formed in the vertical direction at an angle in the shape of an octagon on the upper surface of the light wall of the waveguide so that current is well distributed in both directions by supplying power from the center.

In the case of feeding in a single-layer structure in the conventional waveguide antenna, if the number of slots is increased to increase the gain of the antenna, the impedance bandwidth becomes very narrow. Impedance bandwidth was improved through phase adjustment by minimizing coupling between slots.

The slot of the cavity structure of the middle-layer conductor is relatively large compared to the resonant slot of the upper-layer conductor due to the optimal design for increasing the current.

There are waveguides arranged in six columns on both sides of the cavity on the back of the intermediate layer, and the signal is well distributed and can serve to improve the half-maximum beam width of vertical polarization.

The feeding part of the intermediate layer conductor plate is formed with a plurality of slots spaced apart from each other by a predetermined interval along the height direction of the feeding part, and each slot has a slope, and the slope increases from the top to the bottom, based on the central axis in the height direction of the feeding part. are alternately formed in the opposite direction of the slope.

Since the parameters and angles of the slots are very sensitive at higher frequencies, coupling is minimized by finely adjusting the angle of the slots. Because it flows, the phase is adjusted by making the angle of the slot at the bottom the largest so that the current flows well in all six slots.

Through this optimal phase control, power was fed from the center so that the current of 6*26 slots formed on both sides of the upper conductor plate was well distributed.

Referring to FIG. 11 , the lower conductive plate 300 includes a connector 310 for feeding power and fixing screws and fixing pins for fixing the conductive plate, and the fixing screws and fixing pins are the upper conductive plate and the middle layer conductive plate. , and the lower conductive plate, as well as serving as a via hole, has the effect of better transmitting current.

Referring to FIG. 12 , the cross-section of the lower layer conductor plate is formed in a 'C' shape, and the top and bottom stages are formed to minimize the loss that occurs when the cable is connected to the connector.

Referring to FIG. 13 , as a result of the simulation and measurement of the slot array waveguide antenna according to the present invention, the antenna measurement according to the present invention measured the reflection coefficient using Vector Newwork Analyzer and compared with the simulation.

When the center frequency is f0 and the center wavelength is 1λ, it can be seen that the simulation results from 0.997λ to 1.02λ, the target bandwidth, are very well matched.

The target bandwidth is improved wider than the conventional antenna, which is an improvement by the precise selection of the phase adjustment angle of the slot in the design of the cavity structure of the feeder.

Also, referring to FIG. 14, as the simulation results and measurement results for the vertical polarization at the center frequency f0 of the slot array waveguide antenna according to the present invention, the antenna measurement was measured in an anechoic chamber and compared with the simulation.

In both simulation and measurement results, the peak gain at the center frequency shows a high gain characteristic of 28dBi or more, and the half-maximum beamwidth has a wide beamwidth of about 20˚. This is because the vertical beam width is controlled by changing the height of the narrow-wall waveguide.

In the coastline, a wide vertical beam width is required due to sea conditions such as wave height, wavelength, wave direction, and surface current.

15, as the simulation results and measurement results for horizontal polarization at the center frequency f0 of the slot array waveguide antenna according to the present invention, the antenna measurement was measured in an anechoic chamber and compared with the simulation.

In both simulation and measurement results, the peak gain at the center frequency shows a high gain characteristic of about 28 dBi or more, and in the case of the half-maximum beam width, it is about 5˚, a technique that implements a narrow beam width by controlling the length of the light wall to control the horizontally polarized beam tip. was applied.

Since the antenna installed in the radar rotates 360˚, in the case of horizontal polarization, the gain is increased by reducing the beam width and at the same time, the effect of increasing the size of the antenna can be obtained.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes and substitutions within the scope without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are for explaining, not limiting, the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments and the accompanying drawings . The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100 - middle layer conductor plate 110 - power supply part
120 - waveguide 200 - upper conductor plate
210 - resonant slot 300 - lower conductor plate
310 - connector 320 - fixed pin

Claims (3)

a middle-layer conductor plate having a power feeding part having a cavity structure and having waveguides formed on both sides based on the cavity of the power feeding part;
an upper conductor plate having resonant slots arranged at equal intervals on both sides of the power supply unit; and
connector for power supply,
Fixing pins for fixing upper and middle layer conductors
The lower layer conductor plate on which this is placed
Including, a high-gain antenna for a radar system for monitoring the coastline erosion environment. A middle-layer conductor plate on which a power feeding unit composed of a cavity structure is formed, and waveguides arranged in 6 rows are formed on both sides based on the cavity of the power feeding unit
an upper conductor plate in which 13 resonant slots are arranged at equal intervals on both sides of the feeding unit; and
connector for power supply,
Fixing pins for fixing upper and middle layer conductors
The lower layer conductor plate on which this is placed
including,
The resonant slot of the upper conductor plate is formed in a rectangular shape with rounded angles.
Including, a high-gain antenna for a radar system for monitoring the coastline erosion environment. A middle-layer conductor plate on which a power feeding unit composed of a cavity structure is formed, and waveguides arranged in 6 rows are formed on both sides based on the cavity of the power feeding unit
an upper conductor plate in which 13 resonant slots are arranged at equal intervals on both sides of the feeding unit; and
connector for power supply,
Fixing pins for fixing upper and middle layer conductors
The lower layer conductor plate on which this is placed
including,
The resonant slot of the upper conductive plate is formed in a rectangular shape with rounded angles; and
The feeding part of the middle layer conductor plate is formed with a plurality of slots spaced apart from each other by a predetermined interval along the height direction of the feeding part, and each slot has a slope, and the slope increases from the top to the bottom, based on the central axis in the height direction of the feeding part. formed alternately in the opposite direction of the slope
Including, a high-gain antenna for a radar system for monitoring the coastline erosion environment.

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