KR101092752B1 - The conformal antenna structure for a improving input impedance - Google Patents

Abstract

PURPOSE: A conformal antenna structure for increasing input impedance is provided to replace a frame of an aircraft with a radome and increase the input impedance of a conformal antenna which prints an antenna on the radome, thereby facilitating antenna matching. CONSTITUTION: An antenna insertion space unit is covered by a radome(21) along with the surface of the frame in which an antenna is formed. An antenna power supply unit(40) is connected to an antenna radiating unit which is printed on the radome by the bottom of the antenna insertion space unit. A monopole antenna(31) and a dipole antenna(32) are connected to the antenna power supply unit. The dipole antenna has a bent shape to surround a monopole antenna. The dipole antenna has an induction coupling structure with the monopole antenna.

Description

CONFORMAL ANTENNA STRUCTURE FOR A IMPROVING INPUT IMPEDANCE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the design of a conformal antenna in an aircraft that may pose a risk to flight safety and combat power when aerodynamic characteristics are weakened or reduced by an external projecting antenna. It's about structure.

All aircraft are equipped with antennas for voice and data communications with ground control stations for safe flight, and most aircraft are equipped with pole-type antennas or aircraft mounted on top of tail wings for FM radio communications. It is shaped like a tail wing and uses a blade antenna attached to the back of the aircraft.

Antennas protruding from the outside may pose a danger to flight safety and combat power when the aerodynamics are weakened or reduced. Therefore, the antenna of pole or blade type has a large effect on the aerodynamics as the antenna protrudes out of the aircraft. By giving it can not be free from the above problems, durability also has a weak problem.

In addition, the weight of the antenna also has a problem of increasing the total weight of the aircraft corresponding to a few kg.

Recently, in order to solve these problems, a conformal antenna has been developed and used to print an antenna on a part of an aircraft tail.

However, the conventional conformal antenna has a form in which a part of the surface of a structure composed of a conductor is replaced with a radom and the antenna is printed on the radom, so that the input impedance is low at the operating frequency, making it difficult to match the antenna and reducing the antenna radiation characteristics. Has

In view of this, the present invention proposes a design method of increasing an input impedance of a conformal antenna for replacing a replaceable frame of an aircraft with a radom and printing an antenna on the radom.

The pole and blade antennas used in the aircraft have a high input impedance due to the antenna protruding to the outside and can improve antenna matching, but the conformal antenna has a very low input impedance due to the structure ground.

Therefore, in the present invention, an inductive coupling structure for generating a double resonance between antennas by printing an antenna to an antenna radiator and a conformal antenna structure for generating parasitic capacitance using the distance between the antenna and the ground and thereby improving matching characteristics It is intended to provide.

The conformal antenna structure for improving the input impedance of the present invention,

An antenna insertion space portion and an antenna formed in the antenna insertion space portion to form a conductor space for inserting the antenna in the fuselage to be formed the antenna and cover the top with a radom along the surface of the fuselage to be formed antenna The antenna formed in the antenna insertion space portion is formed by printing an antenna radiation portion on the radom, and constitutes an antenna feeder connected to the antenna radiation portion printed on the radom through the bottom portion of the antenna insertion space portion,

The antenna radiation unit has a monopole antenna connected to the antenna feeding unit, a monopole antenna and an inductive coupling structure bent to surround the monopole antenna, and is formed in consideration of the parasitic capacitor generated according to the distance from the wall in the antenna insertion space. It is characterized by including a dipole antenna.

According to the present invention in the configuration of the conformal antenna for replacing the replaceable frame of the fuselage with the radom and printing on the surface of the radom, the parasitic capacitance using the inductive coupling structure to generate a double resonance and the distance between the antenna and the ground It is possible to provide a conformal antenna that can improve the input impedance to facilitate antenna matching and improve antenna radiation characteristics.

1 to 3 show the conformal antenna structure for improving the input impedance of the present invention, Figure 1 is a view showing the structure of the antenna configured on the vertical pin, Figure 2 shows the configuration of the antenna radiator, 3 is a view for showing the configuration of the antenna feeder.
FIG. 4 is a view showing an embodiment of an optimized antenna shape in which the matching impedance is improved by increasing the input impedance of the antenna. FIG.
5 is an equivalent circuit diagram of a conformal antenna according to the present invention.
6 is a view showing the return loss performance of the conformal antenna in the present invention.
7A to 7D illustrate the four-way antenna gain of the conformal antenna according to the present invention. FIG. 7A is a front view, FIG. 7B is a rear direction, FIG. 7C is a right direction, and FIG. 7D is a left direction. .
8A to 8D illustrate an azimuth radiation pattern of a conformal antenna according to the present invention. FIG. 8A illustrates a radiation pattern at 40 MHz, FIG. 8B illustrates a radiation pattern at 50 MHz, and FIG. 8C illustrates a radiation at 600 MHz. Pattern, Fig. 8D shows a radiation pattern at 70 MHz.
9 is a view showing another embodiment of the present invention, a diagram showing the shape of the antenna feeding portion further includes an L-matching line.
10 is an equivalent circuit diagram of an antenna feeding unit and an antenna radiating unit according to another embodiment of the present invention including an antenna feeding unit to which an L-matching line is added.
11 is a view showing antenna return loss performance according to another embodiment of the present invention.

Hereinafter, the structure and operation of the present invention will be described in detail with reference to an embodiment of the conformal antenna structure for improving the input impedance of the present invention shown in FIGS. 1 to 8.

An antenna insertion space portion 20 formed of a form in which a conductor space for inserting an antenna in a vertical pin 10 portion of the aircraft is covered with a radom 21 along the surface of the vertical pin 10, and an antenna insertion The antenna is formed in the space portion 20, the antenna formed in the antenna insertion space 20 is formed by printing the antenna radiation unit 30 on the radom 21, the antenna insertion space of the By connecting the plate to the antenna radiator 30 printed on the radom 21 through the bottom portion to configure the antenna feeding portion 40,

The antenna radiation unit 30 has a monopole antenna 31 connected to the antenna feeding unit 40 and a dipole antenna 32 having an inductive coupling structure with the monopole antenna 31 in a bent form to surround the monopole antenna 31. It consists of.

Such a technical feature of the present invention is a conformal antenna for generating a parasitic capacitance formed through the space between the inductive coupling structure of the monopole antenna and the dipole antenna and the wall in the antenna insertion space.

1 to 3 show the conformal antenna shape including the inductive coupling structure and parasitic capacitance proposed in the present invention.

As shown in FIG. 1, the antenna insertion space portion 20 is formed according to the vertical pin 10 shape, and the surface of the antenna insertion space portion 20 is disposed along the surface of the vertical pin 10 to the radom 21. The antenna insertion space portion 20 formed in a covered shape and thus formed in the vertical pin 10 portion is formed in a conductor space of 120 cm, 45 cm, and 50 cm.

The antenna formed in the antenna insertion space 20 is composed of an antenna radiator 30 printed on the radom 21, and an antenna feeder 40 feeding power to the antenna radiator 30 through the bottom surface. The antenna radiation unit 30 is printed along the surface of the radom 21, the antenna feed unit 40 is configured by connecting the plate to the antenna radiation unit 30 through the bottom surface as shown in FIG.

As shown in FIG. 2, the antenna radiator 30 includes a monopole antenna 31 and a bent dipole antenna 32 connected to the antenna feeder 40, and a dipole antenna bent to surround the monopole antenna. 32) to increase the input impedance due to the occurrence of double resonance due to inductive coupling between the two components.

In addition, by adjusting the distance between the bent dipole antenna 32 and the wall surface of the conductor space, the parasitic capacitance is generated to increase the input impedance matching.

The length of the monopole antenna 31 ( l ₁ ) and the length of the bent dipole antenna ( l ₂ ), the distance between the monopole antenna 31 and the dipole antenna 32 ( d ₁ ), the dipole antenna 32 and the conductor space wall surface. By using the design variable of the distance ( d ₂ ) can be designed to maximize the matching characteristics of the antenna.

4 illustrates an embodiment of an optimized antenna shape in which the input impedance of the antenna is increased to improve matching characteristics.

The antenna feeder 40 may be positioned obliquely in the vertical direction from the bottom of the antenna insertion space 20, and the antenna radiator 40 may be concentrated below the antenna insertion space 20.

This shows that the parasitic capacitance is generated when the antenna insertion space portion 20, that is, the wall surface of the conductor space and the antenna radiation portion 30 are close to each other.

FIG. 5 shows an equivalent circuit of a conformal antenna optimally designed as in FIG.

The antenna feed unit 40 and the monopole antenna 31 are resonant at 41 MHz, and there is an inductive coupling between the monopole antenna and the dipole antenna, so it can be seen that another resonance occurs at 64 MHz.

It is also shown that a parasitic capacitance C _p of 12 pF occurs in close proximity between the dipole antenna 32 and the conductor space wall.

Table 1 below shows device values of the resistors R, the inductance L, and the capacitor C in the equivalent circuit of FIG. 5.

6 shows the return loss performance of the conformal antenna of the present invention.

When only the antenna feed unit 40 and the monopole antenna 31 are configured, a single resonance occurs less than 3-dB, and when a dipole antenna 32 is added and inductive coupling occurs, double resonance occurs. have.

In addition, when parasitic capacitance occurs, it can be seen that the matching characteristic is better at 64 MHz.

The parasitic capacitance represents a phenomenon in which a capacitor is equivalently connected to the virtual capacitance. In the embodiment of the present invention, the parasitic capacitance C _p is generated due to the space between the conductor walls.

The capacitance characteristics of the capacitor (capacitor) is higher impedance, the lower the impedance, the lower the frequency, the higher the impedance, so the frequency affects the input impedance of the antenna, it is intended to design the antenna in consideration of this.

As shown in FIG. 6, the antenna is optimally designed according to the present invention, and the return loss is measured by mounting the 1/10 scale model of the aircraft.

7A to 7B show four-way antenna gains of a conformal antenna optimally designed according to the present invention, and it can be seen that simulation and measurement are very similar.

7A shows a front direction, FIG. 7B shows a rear direction, FIG. 7C shows a right direction, and FIG. 7D shows a left direction.

The antenna gains of FIGS. 7A to 7D are measured by constructing a 1/10 scale model of an aircraft (Korea Utility Helicopter (KUH) 'Surion') in the present invention and constructing an antenna at a corresponding portion, and proposed FM. The radio communication frequency band was measured at a frequency of 300 MHz to 880 MHz in the 1/10 scale model from 30 MHz to 88 MHz.

The antenna performance was verified by comparing the performance of the simulated antenna in two cases, the reduced model and the actual size. The average radiation gain at the FM frequencies in four directions is -5.87 dBi (front), -14.62 dBi (rear), -6.70 dBi (right), and -8.32 dBi (left), which is higher than -10 dBi except for the rear. The gain is similar to that of a monopole antenna projecting outside.

8A to 8D show the results from 40 MHz to 70 MHz as azimuth radiation patterns of a conformal antenna optimally designed according to the present invention. FIG. 8A illustrates a radiation pattern at 40 MHz, and FIG. 8B illustrates a radiation pattern at 50 MHz. 8c shows a radiation pattern at 600 MHz, and FIG. 8D shows a radiation pattern at 70 MHz.

From this, simulation and measurement radiation pattern is very similar, the average gain of the pattern at each frequency is -10dBi or more, and the gain deviation of the pattern shows the non-directional pattern characteristics within 20dB.

This is a very important result in the nature of aircraft having to transmit and receive FM radio signals in all directions and shows that the system can operate smoothly under all conditions in various environments.

9 shows a conformal antenna to which L-matching is added, which shows another embodiment of the conformal antenna of the present invention.

An input impedance is increased by adding an L-matching line to the antenna feeder 40 'in addition to the line directly connected to the antenna radiation section 30'.

At this time, the antenna matching characteristics are determined by the lengths and positions of L-matching lines l ₃ and l ₄ .

FIG. 10 illustrates an equivalent circuit of the antenna feeder 40 'and the monopole antenna 31 in the conformal antenna to which the L-matching line is added in another embodiment of the present invention as shown in FIG. Resonance occurs at 48 MHz by the feed section 40 'and monopole antenna 31, and additional resonance occurs at 64 MHz by the added L-matching lines ( l ₃ and l ₄ components).

11 shows return loss performance of a conformal antenna using L-matching according to another embodiment of the present invention.

In the case where only the antenna feeder 40 and the antenna radiator 30 are present, a single resonance occurs at less than 3-dB at 48 MHz, and the antenna feeder 40 'is inserted into which an L-matching structure is inserted. As the antenna resonates at MHz, the matching characteristic is improved.

In the embodiment of the present invention, in the configuration of the antenna radiation unit 30, the inductive coupling structure of the dipole antenna 32 surrounding the monopole antenna 31 and the monopole antenna 31 is shown, but the inductive coupling structure of these antennas In this case, it is possible to implement variously without being limited by the shape.

In addition, although the configuration is described as an embodiment configured in the vertical pin 10 of the aircraft, the configuration is not limited to the aircraft, the antenna insertion space portion 20 is formed at a predetermined position of the fuselage, such as aircraft, automobiles and exposed to the outside Applicable to various embodiments of forming a conformal antenna that is not.

10: vertical pin 20: insertion space
21: Radom 30: antenna radiator
31: monopole antenna 32: dipole antenna
40: antenna feeder

Claims (6)

An antenna insertion space portion and an antenna formed in the antenna insertion space portion to form a conductor space for inserting the antenna in the fuselage to be formed the antenna and cover the top with a radom along the surface of the fuselage to be formed antenna The antenna formed in the antenna insertion space portion is formed by printing an antenna radiation portion on the radom, and constitutes an antenna feeder connected to the antenna radiation portion printed on the radom through the bottom portion of the antenna insertion space portion,
The antenna radiator comprises a monopole antenna connected to an antenna feeding unit, and a dipole antenna having an inductive coupling structure with a monopole antenna in a bent form to surround the monopole antenna. . The conformal antenna structure of claim 1, wherein the antenna feeding unit further includes an L-matching line in addition to a line directly connected to the antenna radiation unit. The bent dipole antenna according to claim 1 or 2, wherein the length of the monopole antenna ( l ₁ ) and the curved dipole antenna are increased so as to increase the coupling coefficient through the width adjustment between the inductive coupling structure of the monopole antenna and the dipole antenna to improve the input impedance. The length of ( l ₂ ), the distance between the monopole antenna and the dipole antenna ( d ₁ ) to determine the conformal antenna structure for improving the input impedance. The conformal for improving the input impedance according to claim 1 or 2, wherein the distance d ₂ between the dipole antenna and the conductor space wall, which determines the parasitic capacitor value according to the antenna matching characteristic, is determined. Antenna structure. The conformal antenna structure of claim 1, wherein the antenna insertion space portion is formed according to a vertical pin shape of the aircraft and has a radom covered shape according to a surface shape of the vertical pin. The method of claim 2, wherein the conformal antenna structure to enhance the input impedance, characterized in that to determine the length and the location (l ₃ and l ₄₎ of L- matching track included in the antenna feeding portion in accordance with the antenna matching characteristics .

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