JPH09162635A - Microstrip antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To change the antenna characteristic impedance, etc., and to facilitate the production of a microstrip antenna by adhering a metallic film of a small size onto a part of a loop-shaped circuit to change the antenna characteristics and also providing a feeder line and a matching line. SOLUTION: An antenna element 2 consists of a metallic film which is adhered to a loop-shaped circuit on the surface of a dielectric plate 1 having small thickness compared with the radiation wavelength of the radiated electromagnetic wave. Then a small rectangular metallic plate 41 is adhered on the plate 1 including the metallic film constructing the loop-shaped antenna circuit. Thus the section shape of the loop-shaped circuit is partly changed, and the characteristic of current flowing through the changed section of the circuit is also changed. Therefore, the electrical characteristics of a microstrip antenna such as the characteristic impedance, the resonance wavelength, the directional pattern, etc., can be changed. As a result, the antenna can easily be designed and the antenna size can be reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna for a wireless communication system, and more particularly to an antenna suitable for use as a wireless base station antenna for a mobile communication system.

[0002]

2. Description of the Related Art Various antennas are used as radio base station antennas in mobile communication systems. For example, a collinear antenna is used for a PHS system, which is a typical mobile radio system in Japan. Other,
Brown antennas, sleeve antennas, etc. are also used. These antennas are called linear antennas, and most of them are currently in a form in which electromagnetic waves are transmitted from linearly formed antenna elements. The above antenna is a linear antenna of the type in which a metal film is adhered to the surface of the dielectric plate with the advent of a high-quality and inexpensive dielectric plate recently.
Usually, this is called a microstrip antenna. On the other hand, there is an antenna type called "folded dipole antenna" in which the tips of the dipole antennas are connected to each other and one of these dipoles is fed in the center. Generally, an antenna that forms an electric circuit in which the entire antenna is closed when viewed from the power feeding section is called a loop antenna, but a "folded dipole antenna" also falls within this category. The "folded dipole antenna" is also widely used in amateur radio and special communications. However, it does not seem to be used as a radio base station antenna for mobile communication systems.

[0003]

The "folded dipole antenna" (hereinafter abbreviated as loop antenna) is not used as a radio base station antenna of a mobile communication system for the following reason. It is difficult to obtain an antenna having a high gain. When the frequency used is given, the total length of the antenna that resonates with it is determined, and the antenna length cannot be changed to an arbitrary value. Given the shape of the antenna, its characteristic impedance is fixed and cannot be changed. Therefore, the cable feeding the antenna must be chosen so that the characteristic impedance of the cable matches that of the antenna. The shape of the antenna usually has to be included in a two-dimensional plane, and the directional characteristics of the electromagnetic wave transmitted from the antenna are determined according to the shape, so in order to obtain arbitrary directivity, Other circuits / means must be used. The weather resistance of the antenna is inferior to that of the linear antenna. In a nutshell, the above items are difficult to use,
Some improvement was desired.

[0004]

In order to improve the electrical characteristics of the solid loop antenna (folded dipole antenna) described above, the present invention uses a recent good-quality and inexpensive dielectric plate, and has a metal film on the surface thereof. A microstrip antenna was formed by forming and depositing a circular shape, a rectangular shape, a loop-shaped circuit shape, or the like to form an antenna element. This is largely because it was possible to reduce the size of the antenna because the operating frequency became 1 GHz or more, and as a result, many antennas could be installed on the dielectric plate,
The drawbacks of the above are alleviated. Further, by changing the shape of a part of the cross section on the loop circuit, it is possible to change the electrical characteristics of the antenna described above. In addition, the disadvantage that the weather resistance is inferior to the conventional linear antenna is that the operating frequency is a high frequency of 1 GHz or more (hence the wavelength is 30 cm or less),
The miniaturization of the entire antenna has made it possible to solve the problem by covering the entire antenna with a resin material from the outside.

[0005]

In the antenna of the present invention, the shape of a part of the cross section (perpendicular to the direction of current flow) on the loop-shaped circuit formed on the surface of the dielectric plate is changed, and the current flowing through the changed cross section is changed. Due to the change in the characteristic of (1), the characteristic which the loop-shaped circuit had in the past was changed. The degree of this change varies depending on the size of the difference from the original shape of the changed cross section, and also exhibits various aspects depending on the position of the loop antenna circuit of the changed cross section. That is,
A variety of things, such as places that greatly affect the resonance wavelength (resonance frequency) of the antenna, places that affect the characteristic impedance, places that change the directional characteristics, places that affect both of the above two, etc. Becomes Along with this, various characteristics of the electromagnetic wave emitted from the antenna element can be changed.

[0006]

1 to 7 are views showing an embodiment of the present invention. First, FIG. 1 shows a basic circuit of a loop antenna circuit. In FIG. 1, 1 is a dielectric plate that is thinner than the wavelength of radiated electromagnetic waves, 2 is an antenna element using a loop circuit, and 3
Is a feeder line, and a matching line (not shown) is provided at this tip. Figure 2 (a) ~ (b) the shaded area of the other of the rectangular small metal plate 4 _{1 (Figure} on the dielectric plate 1 that includes a metal film that constitutes the loop antenna circuit shown in FIG. 1 (a) ) Is a plan view in the case of being attached to the position shown in the figure. Also, FIG. 2 (b) shows a small metal plate 4 _{1 (hatched} portion in the figure) and the cross section of the loop circuit 2 when cut by the broken line X-Y in FIG. 2 (a). When a small metal plate is attached to the position as shown in FIG. 2A, the characteristic impedance of the original loop circuit seems to change slowly near the resonance frequency.

[0007] FIG. 3 (a) ~ FIG. 5 (a) small metal plates 4 ₃ other rectangular on the dielectric plate 1 that includes a metal film that constitutes the loop antenna circuit of Figure 1 (a) ~ 4 5 shows a plan view of a case where is deposited _(FIG hatched portion) to such positions in each figure, FIGS. 3 (b) ~ FIG. 5 (b) by the broken line X-Y in each figure small metal plate 4 _{2 to} 2 when cut _(hatched portion in the figure) and shows a cross section of the looped circuit 2. FIG.
When a small metal plate is attached to the position as shown in (a), it seems that the characteristic impedance of the original loop circuit changes slightly near the resonance frequency. Next, FIG.
When a small metal plate is attached to the position as shown in (a), it seems that the resonance frequency of the characteristic impedance of the original loop circuit moves to a slightly higher frequency.

Further, when a small metal plate is attached to the position shown in FIG. 5A, the resonance frequency of the original loop circuit moves to a slightly lower frequency. 6 to 7 show an embodiment in which a loop-shaped antenna circuit provided on a thin dielectric plate is modified from the beginning to the circuit part as shown. First, in the case of FIG. 6, the obtained characteristics are almost the same as those of FIG. This is suitable for carrying out a small width correction in which there are variations in characteristics when many loop antennas are manufactured and they are put in a predetermined standard. That is, it is assumed that a large number of loop antennas are manufactured by setting the resonance frequency of the loop circuit to a slightly low frequency at the design stage. Many antennas will meet the standard. However, it is assumed that the resonance frequency of a certain antenna manufactured is slightly higher than the standard due to variations in the manufacturing process. Then, the standing wave ratio may not satisfy the standard. In this case, by deleting a part of the deformed portion of FIG. 6, the resonance frequency shifts to a lower frequency.
It is possible to bring the characteristics of the loop antenna into the standard. Next, in the case of FIG. 7, by increasing the width of the metal film on the upper part of the loop antenna circuit toward the inside of the loop as shown in FIG. 7, the main directional characteristics of the antenna can be directed downward. Becomes The above change in the characteristics of the loop antenna is an analogy from the experimental result described below, and it will be quite difficult to theoretically obtain it.

When the dielectric plate 1 shown in FIGS. 1 to 7 is formed by using, for example, a glass cloth base material fluororesin copper clad laminate, an unnecessary metal film is removed by a method similar to the printing method to obtain a dielectric film. On the surface of the body plate 1, the antenna element 2, the feed line 3,
Is formed. When a simple dielectric plate is used as the dielectric plate 1, the antenna element 2 and the feed line 3 are formed by depositing a film of copper or the like on the surface by means such as vapor deposition. These fabrication methods are applicable to all the antennas of the present invention. Also, the metal of the loop circuit and the metal plate deposited on it are in close contact with each other to the extent that they are electrically considered to be the same metal, and the current is made to flow as if it were the same metal. Has been done.

The results of measuring the characteristics of the prototype antenna of the present invention will be described below. The actual dimensions of the antenna element using the loop circuit shown in FIG. 1 are 5.1 cm in the horizontal direction (longitudinal direction of the dielectric plate), 2.9 cm in the vertical direction (both are external peripheral length), and 0.2 cm in width The standard thickness of the coating is 0.03 cm. In theoretical calculation, the loop antenna has a characteristic impedance of about 50 ohms, a resonance wavelength (resonance frequency) of about 15.5 cm, (about 1.94 GH).
z) is estimated. FIG. 8 shows the standing wave ratio of the antenna originally possessed by the loop antenna element. That is, there is a loop-shaped microstrip antenna formed on the surface of a dielectric plate, and the original standing wave ratio (SWR) characteristic is shown when there is no other metal film piece on the metal film. The standing wave ratio mentioned here indicates the ratio of the input wave and the reflected wave at the antenna feeding terminal point. The characteristic impedance of the power supply line to this antenna is 50 ohms. In FIG. 8, the markers 1 to 3 each have a frequency of 1.9 GHz.
The measurement results of the standing wave ratio at z, 2.1 GHz and 1.9 GHz are shown. The standing wave ratio at each of these frequencies is 1.2894, as shown in the upper right of the figure.
2.8494, 4.0884 and 1.156. The marker 4 indicates the resonance frequency of the loop-shaped microstrip antenna, the frequency is 1.94 GHz, and the standing wave ratio is 1.156. Also, the characteristic impedance of the antenna at this frequency is 53.6 + j6.7 ohms.

FIG. 9 shows the loop antenna element shown in FIG.
The standing wave ratio characteristic of the microstrip antenna when a small metal film is deposited on the position shown in (a) is shown.
The small metal plate had a length of 10 mm, a width of 2 mm, and a height (perpendicular to the substrate) of 1.57 mm. FIG. 10 shows the standing wave ratio characteristic of the microstrip antenna when a small metal film is deposited on the loop antenna element at the position shown in FIG. 3 (a). The size of the small metal plate is 20mm in width,
The width was 2 mm and the height (perpendicular to the substrate) was 1.57 mm. FIG. 11 shows the standing wave ratio characteristic of the microstrip antenna when a small metal film is deposited on the loop antenna element at the position shown in FIG. 4 (a). The size of the small metal plate is 19mm in length (up and down like the circuit) and 2m in width.
m, the height (perpendicular to the substrate) was 1.57 mm. FIG.
2 shows the standing wave ratio characteristic of the microstrip antenna when a small metal film is deposited on the loop antenna element at the position shown in FIG. 5 (a). The dimensions of the small metal plate were 15 mm in length (direction perpendicular to the circuit), 2 mm in width, and 1.57 mm in height (perpendicular to the substrate). The measurement results obtained above show that the change in the characteristics of the loop-shaped antenna as described above appears. It is obvious that the degree of deformation of the loop circuit may be increased or decreased in order to further increase or decrease the change in the characteristics of the loop antenna. In addition to the modifications of the loop-shaped circuit described above, there are modifications of various shapes, but each has its own characteristic change in the loop-shaped antenna and can be used depending on the purpose.

[0012]

Since the antenna of the present invention can change the characteristic impedance, the resonance frequency and the directivity peculiar to the antenna, the shape of the antenna is different from the conventional one, including the ease of matching between the antenna and the feed line. The antenna can be shaped, and the antenna design can be facilitated and the antenna can be easily downsized. Further, since the antenna can be downsized, a large number of antennas can be coupled in multiple stages, and it is possible to increase the gain of the loop antenna, which has been difficult in the past. Therefore, the effect of the present invention is great.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing another embodiment of the present invention.

FIG. 3 is a diagram showing another embodiment of the present invention.

FIG. 4 is a diagram showing another embodiment of the present invention.

FIG. 5 is a diagram showing another embodiment of the present invention.

FIG. 6 is a diagram showing another embodiment of the present invention.

FIG. 7 is a diagram showing another embodiment of the present invention.

FIG. 8 is a diagram showing characteristics of the antenna of the present invention.

FIG. 9 is a diagram showing characteristics of another antenna of the present invention.

FIG. 10 is a diagram showing characteristics of another antenna of the present invention.

FIG. 11 is a diagram showing characteristics of another antenna of the present invention.

FIG. 12 is a diagram showing characteristics of another antenna of the present invention.

[Explanation of symbols]

1 Dielectric Plate 2 Antenna Element 3 Feed Line 4 ₁ to 4 ₄ Metal Film Piece

Claims (4)

[Claims] 1. In an antenna element having a structure in which a metal film is deposited and formed on a loop-shaped circuit on the surface of a dielectric plate that is thinner than the radiation wavelength, the cross-sectional shape of a part of the loop-shaped circuit is changed, A microstrip antenna characterized in that the electric characteristics of the antenna can be changed by changing the characteristics of the current flowing through the changed cross section. 2. An antenna element having a structure in which a metal film is adhered to and formed on a loop-shaped circuit on the surface of a dielectric plate that is thinner than the radiation wavelength, the shape of the cross section of a part of the loop-shaped circuit is changed, A microstrip antenna capable of changing the resonance frequency that the loop circuit has conventionally by changing the characteristics of the current flowing through the changed cross section. 3. In an antenna element having a structure in which a metal film is adhered to and formed on a loop-shaped circuit on the surface of a dielectric plate that is thinner than the radiation wavelength, the cross-sectional shape of a part of the loop-shaped circuit is changed, A microstrip antenna capable of changing the characteristic impedance that the loop-shaped circuit has conventionally by changing the characteristics of the current flowing through the changed cross section. 4. In an antenna element having a structure in which a metal film is attached to and formed on a loop-shaped circuit on the surface of a dielectric plate that is thinner than the radiation wavelength, the cross-sectional shape of a part of the loop-shaped circuit is changed, A microstrip antenna capable of changing the directional characteristics that the loop circuit has conventionally by changing the characteristics of the current flowing through the changed cross section.