JP2001119234A - Method for adjusting characteristic of microstrip antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new means for adjusting input impedance in a microstrip antenna and also to provide a characteristic adjusting method which suppresses the fluctuations of the input impedance due to the variations of the insulation intervals and makes the microstrip antenna have stable characteristics. SOLUTION: The input impedance can stably be matched to a 50 Ωfeeding line because the input impedance is adjusted by shifting the position of a feeding line 5 from the center of a dielectric substrate 2 by a prescribed quantity. Even though there is variations in the insulation intervals with the feeding line by positioning a feeding line in the aforementioned way, it is possible to suppress the effect to the utmost because the input impedance is made flat against the variations of the insulation intervals between a ground conductor 4 and the line 5 by shifting the position of the line 5 from the center of the substrate 2 by a prescribed quantity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microstrip antenna used for a mobile communication device such as an airplane, a car phone, and a mobile phone.

[0002]

2. Description of the Related Art A microstrip antenna in which a radiating conductor is provided on the front surface of a dielectric substrate and a ground conductor is provided on the back surface is small, light, and thin, so that it can be used in small mobile communications such as aircraft, car phones, and mobile phones. It is suitable as an antenna member of a device.

Here, a rectangular microstrip antenna a
Has a configuration shown in FIG. 5, in which a radiation conductor c is provided on one surface of a dielectric substrate b and a ground conductor d is provided on the other surface, and a feed line e penetrating the dielectric substrate b is provided as a radiation conductor c. The radiating conductor c is connected to the radiating conductor c through a feeding line e. The power supply line e is insulated by forming an insulation interval f with the ground conductor d on the back surface. When power is supplied from the power supply line e, radio waves are radiated from the open peripheral end of the radiation conductor c and operate as, for example, linearly polarized waves.

[0004]

As described above, the microstrip antenna a in which the radiating conductor c is disposed on the front surface of the dielectric substrate b and the ground conductor c is disposed on the back surface thereof, depends on the input impedance, and the reflection characteristics of the microstrip antenna a depend on the input impedance. Changes greatly. That is, if the input impedance is not matched with the 50 Ω feed line, the reflection characteristics deteriorate, and efficient transmission and reception cannot be performed.

By the way, the feeder line e has a ground conductor c
In the conventional configuration, a ground conductor d is formed by printing a screen pattern on the back surface of the dielectric substrate b, and the power supply line e and the ground conductor d are formed by the printed pattern. Between them, a circular insulating surface f having a predetermined diameter is formed, thereby forming an insulating interval f.

On the other hand, it has been found that the input impedance greatly changes due to the insulation interval f between the power supply line e and the ground conductor d. However, in the conventional configuration, a conductive paint is applied by screen pattern printing, and the insulating interval f is defined. Therefore, blurring occurs at a boundary edge with the circular insulating surface, and blurring occurs due to variation in ink density. In addition, if the screen is incompletely positioned, the relative position with respect to the dielectric substrate b may be slightly varied, resulting in a positional deviation, and there is a problem that the insulation interval f cannot be accurately kept constant. Was. By the way,
As will be understood from FIG. 4 to be described later, if the radius of the insulation interval f differs by only about 0.5 mm, the input impedance changes by about 100Ω and dissociates largely from the target value of 50Ω.

The present invention provides a new input impedance adjusting means and a characteristic adjusting method capable of suppressing a change in the input impedance due to the above-described variation in the insulation interval and providing a microstrip antenna having stable characteristics. It is intended for.

[0008]

According to the present invention, a radiation conductor is formed on a front surface of a dielectric substrate, a ground conductor is formed on a rear surface, and a feed line connected to the radiation conductor is provided through the dielectric substrate. In a microstrip antenna in which the feed line is insulated from the ground conductor on the back side, by shifting the position of the feed line by a predetermined amount from the center of the dielectric substrate,
A microstrip antenna characterized in that input impedance is adjusted.

It has been found that changing the position of the feed line changes the input impedance. For this reason, it is possible to stably match the input impedance with the 50Ω feed line.

Further, by shifting the position of the feed line by a predetermined amount from the center of the dielectric substrate, it is possible to flatten the input impedance with respect to the variation in the insulation interval between the ground conductor and the feed line.

That is, as described above, the input impedance fluctuates due to the variation of the insulation interval. By the way, when the position of the feed line is changed from the center of the dielectric substrate, the variation of the insulation interval and the mode of the transition of the input impedance are greatly changed, and it is found that a flat transition characteristic is obtained at a certain position. . This means that the input impedance can be flattened by the predetermined shift amount. For this reason, by such positioning, even if there is a variation in the insulation interval from the power supply line, the influence can be suppressed as much as possible.

Therefore, since the conductive paint is applied by screen pattern printing to define the insulating interval, blurring occurs at the boundary edge with the insulating surface, blurring occurs due to variation in ink density, and the like. Even if the screen positioning is incomplete, the required input impedance can be stably obtained.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A configuration of a rectangular microstrip antenna 1 to which an adjusting means of the present invention is applied will be described with reference to FIGS.

The microstrip antenna 1 has a circular radiation conductor 3 on a surface of a planar square plate-like dielectric substrate 2.
And a basic configuration in which a ground conductor 4 is formed on the back surface.

In order to supply power to the radiation conductor 3, a power supply pin 5 serving as a power supply line is inserted into a through hole 6 formed in the dielectric substrate 2, and the grounding conductor 4 is formed on the back surface where the grounding conductor 4 is formed. The conductor 4 is insulated, and the upper end thereof is folded to be electrically connected to the radiation conductor 3 by soldering or the like. The power supply pins 5 are longer than the thickness of the dielectric substrate 2 and protrude downward from the back surface of the dielectric substrate 2 in the connected state.

Then, the microstrip antenna 1 having such a structure is provided with a dielectric substrate 2 as shown in FIG.
The power supply pins 5 protruding from the rear surface of the printed circuit board 2 are inserted into through holes 21 formed in the
0 is attached. Thus, the electric path on the printed circuit board 20 is connected to the 50Ω power supply line via the power supply pin 5, and transmission and reception are performed from the radiation conductor 3.

The insulation distance between the ground conductor 4 and the power supply pin 5 is greatly related to the input impedance. Therefore, in the configuration shown in FIG.
To form a circular recess 8 having a predetermined diameter centered on
The insulation interval is defined by the diameter of the recess 8. In this manner, by defining the diameter of the concave portion 8 and eliminating variations due to the printing environment, it is possible to experimentally specify the relationship between the diameter and the input impedance, that is, the relationship between the input impedance and the variation of the insulation interval. it can.

That is, before the power supply pins 5 are inserted into the through holes 6, the back surface of the dielectric substrate 2 is coated with a conductive paint such as a silver paint by a method such as solid coating, so that the surface without the concave portions 8 is formed. Only the ground conductor 4 is formed, and the portion where the concave portion 8 is formed becomes an insulating surface. Since the ground conductor 4 is formed evenly to the edge of the concave portion 8, the distance between the peripheral edge of the concave portion 8 and the power supply pin 5 becomes an insulating interval. That is, the insulation interval is defined by the inner diameter of the recess 8.

Further, the dielectric substrate 2 is made of BaO-TiO ₂
System, BaO-TiO ₂ - dielectric constant as a rare earth oxide or the like is formed by a dielectric ceramic material of 30 to 90. The microstrip antenna 1 has a side of 10.00 mm and a thickness of 4.00 mm, for example. Here, the radiation conductor 3 has no circular shape. The power supply pin 5 is deviated from the center of the dielectric substrate 2 by a predetermined amount. Further, the power supply pin 5 is made of a wire conductor having a diameter of 0.5 mm and is 2.50 m from the back surface of the dielectric substrate 2.
m. Further, the power supply pin 5 is deviated from the center of the dielectric substrate 2.

The input impedance with respect to the diameter of the concave portion 8 of each sample having a different shift amount t (see FIG. 3) is as shown in Table 1 below.

[0021]

[Table 1]

FIG. 4 is based on the data shown in Table 1, and shows the shift amount t (m) of the feed pin 5 from the center of the dielectric substrate.
m) are different. 1 to No. 4 is a graph showing the transition of the input impedance with respect to the diameter s (gap diameter) of the concave portion 8 for each of the four types of samples. Here, the sample No.
Sample No. 1 is the amount of slip t = 0 mm, sample No. 2 is the shift amount t =
0.2 mm, sample No. 3 is a shift amount t = 0.5 mm,
Sample No. 4 is a shift amount t | 1.0 mm.

Here, the sample No. In the case of 1, the input impedance changes greatly as the gap diameter s increases. The gap diameter s of 50Ω is about 3.5 mm. Sample No. In 2, also, as the gap diameter s increases, the input impedance greatly changes. 50Ωg
The ap diameter s is about 2.5 mm. Sample No. 3 is g
The input impedance changes greatly as the ap diameter s increases. The gap diameter s of 50Ω is about 2.2 mm.

On the other hand, the sample No. In No. 4, even if the gap diameter s becomes large, the input impedance only slightly changes up and down in the vicinity of 50Ω and does not change much.

As described above, the shift amount t is greatly related to the input impedance. Therefore, by adjusting the shift amount t, the input impedance can be adjusted. Therefore, the input impedance can be adjusted to 50Ω by adjusting the shift amount t.

On the other hand, the sample No. As shown in FIG.
Is adjusted, the value of the input impedance with respect to the variation in the insulation interval between the ground conductor and the feed line can be made small, and flattening can be achieved.

That is, as described above, the input impedance fluctuates due to the variation in the insulation interval. However, when the position of the feed line is changed from the center of the dielectric substrate,
The variation of the insulation interval and the manner of transition of the input impedance greatly change, and a flat transition characteristic is obtained at a certain position. This means that the input impedance can be flattened by the predetermined shift amount.

Therefore, the shift amount t of the feed pin 5 is set so that the input impedance is at a position where the input impedance is flattened.
Is determined, even if there is a variation in the insulation interval defined on the insulating surface of the concave portion 8, the effect can be suppressed as much as possible. Therefore, since a conductive paint is applied by screen pattern printing to define the insulating interval, bleeding occurs at the boundary edge with the insulating surface, blurring occurs due to variations in ink density, and the like. Even if the positioning is incomplete, the required input impedance can be stably obtained. Thus, the matching with the 50Ω feed line can be easily achieved, and the microstrip antenna 1 having the best transmission / reception efficiency can be formed.

The microstrip antenna 1 is mounted on a printed circuit board on which a power supply circuit is printed, and electrically connects the power supply circuit to the radiation conductor 3 via the power supply pin 5 and the inner conductor 6 of the power supply pin 5. Used.

In the above-described configuration, the present invention is applied to the microstrip antenna 1 in which the feed line is formed by the feed pin 5, and the feed line is formed in the through hole formed in the dielectric substrate by the conductive paint. Can also be applied to the microstrip antenna 1 configured by supplying

[0031]

According to the present invention, in a microstrip antenna in which a radiation conductor is provided on one surface of a dielectric substrate and a ground conductor is provided on the other surface, the position of a feed line is shifted by a predetermined amount from the center of the dielectric substrate. Since the input impedance is adjusted, the input impedance can be stably matched with the 50Ω feed line. Then, the resonance frequency of the microstrip antenna is
The center frequency of the signal transmitted from the power supply line can be matched, the frequency can be matched, and the transmission / reception efficiency is improved.

Further, by displacing the position of the feed line from the center of the dielectric substrate by a predetermined amount, the input impedance is flattened with respect to the variation of the insulation interval between the ground conductor and the feed line. Due to the positioning of the line, even if there is a variation in the insulation interval from the power supply line, the effect can be suppressed as much as possible. Therefore, since a conductive paint is applied by screen pattern printing to define the insulating interval, bleeding occurs at the boundary edge with the insulating surface, blurring occurs due to variations in ink density, and the like. Even if the positioning is incomplete, the required input impedance can be stably obtained.

Thus, it is possible to stably match the input impedance with the 50 Ω feed line, thereby making the resonance frequency of the microstrip antenna coincide with the center frequency of the signal transmitted from the feed line. Therefore, there is an excellent effect that frequency matching can be achieved, transmission and reception efficiency can be improved, and a microstrip antenna optimal for a mobile communication device can be provided.

[Brief description of the drawings]

FIG. 1 is a vertical sectional side view of a microstrip antenna 1 to which an adjusting means of the present invention is applied.

FIG. 2 is a plan view of the microstrip antenna 1. FIG.

FIG. 3 is a back view of the microstrip antenna 1. FIG.

FIG. 4 shows a diameter s of a concave portion 8 of the microstrip antenna 1.
6 is a graph showing a relationship between the input impedance and the input impedance.

FIG. 5 is a vertical sectional side view of a microstrip antenna a having a conventional configuration.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Microstrip antenna 2 Dielectric substrate 3 Radiating conductor 4 Grounding conductor 5 Feeding line (feeding pin) 8 Depression t Displacement

Claims (2)

[Claims] A radiation conductor is formed on a front surface of a dielectric substrate, a ground conductor is formed on a rear surface, a feed line connected to the radiation conductor is provided through the dielectric substrate, and the feed line is provided on the rear surface side with a ground conductor. A characteristic adjustment method of a microstrip antenna, wherein the input impedance is adjusted by shifting a position of a feed line by a predetermined amount from a center of a dielectric substrate. . 2. A radiation conductor is formed on a front surface of a dielectric substrate, and a ground conductor is formed on a rear surface. A feed line connected to the radiation conductor is provided through the dielectric substrate, and the feed line is connected to the ground conductor on the rear surface side. In a microstrip antenna that is insulated from the ground, the position of the feed line is shifted by a predetermined amount from the center of the dielectric substrate, thereby flattening the input impedance with respect to variations in the insulation distance between the ground conductor and the feed line. A characteristic adjustment method of a microstrip antenna.