JPH11340710A - Matching method and matching device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform matching by separated two frequencies. SOLUTION: To a position where the normalized conductance component of admittance at a first frequency is about 1.0 and the normalized susceptance component is positive on a power feeder 101, a first stab ST1 of an electric length of the susceptance component of about zero at a second frequency higher than the first frequency is connected. To the position where the normalized conductance component of the admittance at the second frequency is about 1.0 and the normalized susceptance component is negative on the power feeder 101, the second stab ST2 of the electric length of the susceptance component of about zero at the first frequency is connected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a matching method and a matching device for an antenna capable of matching at two separated frequencies or a wide frequency band.

[0002]

2. Description of the Related Art In recent years, a frequency band required for a communication system has been widened to about 5% of a used center frequency, or a wider frequency band exceeding 5% has been required. An omnidirectional antenna installed in a fixed station in such a communication system is required to have an improved antenna gain. In order to improve the antenna gain, the omnidirectional antenna generally has a vertically stacked antenna structure. ing.

[0003]

If the antenna gain is improved by stacking the antennas, there is a problem that the frequency band of the antenna becomes narrower as the number of stacked stages increases. Therefore, it becomes impossible to operate the antenna well at two separated frequencies. Conventionally, in order to solve this problem, the radiating element in the antenna is made thicker, or after matching is achieved with the antenna alone, the antenna is broadened by coupling the antenna in parallel with a distributor or the like to broaden the operating frequency band of the antenna. Was like that. However, this conventional method requires a plurality of matching devices and a distributor, and furthermore,
There has been a problem that the power supply cable must be connected between them, and the antenna device becomes large and its configuration becomes complicated.

A stub method is generally known as an antenna matching method. This matching method utilizes the fact that when a feeder is connected to an antenna, the voltage standing wave ratio (VSWR) on the feeder is constant and the impedance changes with the line length of the feeder. That is, a stub is connected to the position of the feeder line where the resistance on the feeder line has a value equal to the characteristic impedance of the feeder line (normalized resistance is 1.0), and the imaginary component at that position is canceled to perform matching. I am taking it. This matching method can be a simple matching method because the stub can be configured using the feeder line. However, since this matching method presupposes a matching method at one frequency, there is a problem that it is difficult to achieve matching at two or more frequencies or a wide frequency band.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a matching method and a matching device which can achieve matching at two frequencies or a wide frequency band with a simple configuration.

[0006]

In order to achieve the above object, the matching method according to the present invention is characterized in that the normalized admittance of the admittance at the first frequency on the feed line is approximately 1.0, and the normalized admittance is 1.0. At a position where the susceptance component is positive, a first stub having an electrical length at which the susceptance component becomes substantially zero at a second frequency higher than the first frequency is connected, and the admittance of the admittance at the second frequency on the feeder line is The normalized conductance component is approximately 1.
At 0, a second stub having an electrical length at which the susceptance component becomes substantially zero at the first frequency is connected to a position where the normalized susceptance component is negative. Further, in the matching method, the first frequency and the second frequency may be frequencies on both sides of a predetermined frequency band.

According to another matching method of the present invention which can achieve the above object, a normalized admittance conductance component at a first frequency on a feed line is approximately 1.0, and a susceptance component at that position is represented by: A first stub having an electrical length in which a susceptance component of the opposite polarity that can be almost canceled is connected, and the first stub is connected on the power supply line.
The normalized conductance component of the admittance at the second frequency higher than the frequency is approximately 1.0, and the normalized susceptance component is at a negative position.
At this frequency, a second stub having an electrical length at which the susceptance component becomes substantially zero is connected.

[0008] Still another matching method of the present invention that can achieve the above object is that a normalized conductance component of admittance at a first frequency on a feeder line is approximately 1.
0, a first stub having an electrical length whose susceptance component is substantially zero at a second frequency higher than the first frequency is connected to a position where the normalized susceptance component is positive, and At a position where the normalized conductance component of the admittance at the second frequency is approximately 1.0, a second stub having an electrical length that generates a susceptance component of the opposite polarity that can substantially cancel the susceptance component at that position is connected. Like that.

A matching device that can achieve the above-mentioned object embodies the above-described matching method.

According to the present invention, the stub has a susceptance component of zero at the first frequency or the second frequency, which is equivalent to no connection. From this, a stub that matches by canceling the susceptance component at one frequency has zero susceptance component at the other frequency, so that it does not adversely affect the matching at the other frequency. Therefore, matching can be achieved even when the first frequency and the second frequency are separated from each other, and matching can be achieved even in a wide frequency band from the first frequency to the second frequency. Become. Note that the configuration of the matching device is simple and can be mainly configured using a coaxial cable, so that the matching device can be provided at low cost.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the matching method according to the present invention will be described with reference to FIGS. However, FIG.
FIG. 2 is a diagram showing the principle of the matching method of the present invention, and FIG. 2 is a Smith chart for explaining the matching method. In FIG. 1, a load 100 is, for example, an antenna or the like.
Feed line 101 is derived in the characteristic impedance Z _0, for example is a 50Ω from 0. The admittance of the load (RL) 100 changes according to the frequency as indicated by RL in FIG.

The first stub ST1 is connected to a position on the feeder line 101 where the normalized conductance component is "1.0" at the matching first frequency fa, and the second stub ST2 Is the second frequency f to be matched
It is connected to a position on the feeder line 101 where the conductance component normalized at b (where fb> fa) is “1.0”. At this time, the electric length of the power supply line 101 from the load 100 to the position where the first stub ST1 is connected is indicated as L1, and the electric length of the power supply line 101 from the position where the second stub ST2 is connected is indicated as L2. ing. Also,
The length L3 of the first stub ST1 is an electrical length at which the susceptance component becomes zero (reactance component is infinite) at the second frequency fb, and the second stub S1 has a length L3.
The length L4 of T2 is an electrical length at which the susceptance component becomes zero (the reactance component is infinite) at the first frequency fa.

A specific description will be given of the matching method.
The admittance Y on 01 is expressed by the following equation. Y = G + jB (1) where G is a conductance component and B is a susceptance component. Here, the load 100 having the frequency characteristic shown in FIG.
Is connected to the power supply line 101 to which the power supply line 10 is connected.
As shown in FIG. 2, the admittance at the position of the electric length L1 is a point obtained by rotating the point plotted as the first frequency fa by the electric length L1 clockwise around the center of the Smith chart as the rotation center. fa ′. At this time, the electric length L1 is adjusted so that the conductance of the admittance indicated by the point fa 'is substantially "1.0" (the conductance indicated by the point fa' is located on the circle of 1.0). . In this case, the electrical length of the feeder line 101 is set to the first
Electrical length L1 normalized by the wavelength λa of the frequency fa
(Fa).

The electric length L3 of the first stub ST1
Is adjusted to an electrical length at which the susceptance component of the first stub ST1 becomes substantially zero at the second frequency fb.
At this time, the electrical length of the first stub ST1 is converted into an electrical length L3 (fb) normalized by the wavelength λb of the second frequency fb.
Shall be expressed as The first stub ST1 is configured by short-circuiting or opening the end of the same coaxial cable as the power supply line 101, and the admittance Ys of the stub when the end is short-circuited is as follows: Ys = −jB = −jY ₁ cotβL3 (Fb) It is represented by (2). However, Y ₁ is characteristic admittance of the coaxial cable constituting a stub, beta is expressed by 2 [pi / lambda When the wavelength is phase constant lambda.

Accordingly, in order for the first stub ST1 to have its susceptance component substantially zero at the second frequency fb, the electrical length L3 (fb) normalized by the wavelength λb of the second frequency fb is required. , L3 (fb) = (λb / 4 + n · λb / 2) (3) Here, n = 0, 1, 2,.... Admittance Ys of first stub ST1 at this time
_{L3 is, Ys L3 = -jY 1 cotβ (} λb / 4 + n · λb / 2) and made (4).

In the admittance Ys _L3 , at the first frequency fa, since the wavelength changes from λb to λa, the electrical length changes and the susceptance does not become zero. In this case, the change L3 'in the electrical length is as follows: L3' = fa / fbｂ (λb / 4 + n ／ λb / 2)-(λb / 4 + n ・ λb / 2) = (fa / fb-1) ・ (λb / 4 + n · λb / 2) (5) Therefore, when the first frequency fa is higher than the second frequency fb, the admittance Ys _L3 of the first stub ST1 becomes a positive component, and when the first frequency fa is lower than the second frequency fb. Is the first
The admittance Ys _L3 of the stub ST1 is a negative component.

Here, when the first frequency fa is lower than the second frequency fb, the first stub ST1
The admittance Ys _L3 becomes a negative component, and when the first frequency fa is set, matching is performed by canceling the positive susceptance component indicated by a point fa ′ in FIG. 2 by the susceptance component of the first stub ST1. Can be taken. This matching is performed by adjusting the value of n so as to be canceled by the susceptance component of the first stub ST1. Also, the second stub ST2
Is adjusted to an electrical length at which the susceptance component of the second stub ST2 becomes substantially zero at the first frequency fa. The electrical length of the second stub ST2 at this time is
It is represented as an electrical length L4 (fa) normalized by the wavelength λa of the first frequency fa.

Since the second stub ST2 is also formed by short-circuiting or opening the end of the same coaxial cable as the power supply line 101, it is similar to the first stub ST1, and the second stub ST2 is connected to the coaxial cable. L4 (fa) = (λa / 4 + n · λa / 2) (6) Therefore, the admittance Ys _L4 of the second stub ST2 is expressed as: Ys _L4 = −jY ₁ cotβ (λa / 4 + n · λa / 2) (7) Further, in the admittance Ys _L4 , at the second frequency fb, since the wavelength changes from λba to λb, the electrical length changes and the susceptance does not become zero. In this case, the change L4 ′ in the electrical length is as follows: L4 ′ = (fb / fa−1) · (λa / 4 + n · λa / 2) (8)

That is, when the second frequency fb is higher than the first frequency fa, the admittance Ys _L4 of the second stub ST2 becomes a positive component, and the second frequency fb is lower than the first frequency fa. In the case of a frequency, the admittance Ys _L4 of the second stub ST2 is a negative component. Here, since the second frequency fb is higher than the first frequency fa, the second stub S
The admittance Ys _L4 of T2 becomes a positive component,
, The negative susceptance component indicated by the point fb ′ in FIG.
Can be matched by canceling with the susceptance component. This alignment is based on the second stub ST
N so that it can be canceled by the susceptance component of 2.
By adjusting the value of.

By the way, when the first frequency fa is set, the susceptance component of the second stub ST2 becomes substantially zero, which is equivalent to not being connected to the feeder line 101. The second stub ST2 does not adversely affect the matching by the second stub ST2. When the second frequency fb is set, the susceptance component of the first stub ST1 becomes substantially zero, which is equivalent to not being connected to the power supply line 101. The first stub ST1 has no adverse effect.

Next, the configuration of an embodiment of the matching apparatus of the present invention, which embodies the above-described matching method of the present invention, will be described with reference to FIGS. However, FIG.
Shows a configuration of an antenna for matching, and FIG. 4 shows a configuration example of a matching device. The antenna 1 shown in FIG. 3 is configured by stacking a coaxial dipole antenna formed of a sleeve in multiple stages. A part of the radiating element in this coaxial dipole antenna is shown as a radiating element A11 and a radiating element B12, and each radiating element is approximately λ / 2.
Of a conductive sleeve having an electrical length of The radiating elements are connected by a power supply cable 15, and a central portion, which is a feeding point of each radiating element, is held by an insulating holder 13.

The antenna 1 in which coaxial dipole antennas are stacked in multiple stages is built in a cylindrical FRP (Fiber Reinforced Plastic) cover 14 that is transparent and strong against electromagnetic waves. At this time, each radiating element is held at substantially the center of the FRP cover 14 by the holder 13. Note that the antenna 1 is an antenna that operates at two frequencies, for example, a frequency band near 848 MHz and a frequency band near 902 MHz. The frequency characteristics of the impedance of the antenna 1 viewed from the point A are shown in the Smith chart shown in FIG. It is shown. Referring to FIG. 5, the frequency characteristics do not operate well at the two frequencies. Therefore, by performing matching using the matching device of the present invention, it is possible to operate well at the two frequencies.

The matching device 2 will be described with reference to FIG. As shown in FIG. 4, the end of the power supply cable 21 connected to the antenna 1 is fixed to a metal fixing plate 24. At this time, both ends of the fixed plate 24 are machined to form holders 24-1 and 24-2. The end of the power supply cable 21 is held by the holder 24-1 and fixed to the fixed plate 24. It is fixed. In addition, power supply cable 2
A rigid cylindrical outer conductor tube is fitted to one end of the outer conductor tube, and the outer conductor tube is electrically connected to a shielding knitting wire of the power supply cable 21. One end of the first stub ST1 is also fixed to the holder 24-1 of the fixing plate 24. A rigid cylindrical outer conductor tube is also fitted to one end of the first stub ST1, and this outer conductor tube is held by the holder 24-1. The outer conductor tube holds the first stub ST1. It is electrically connected to the knitting wire for shielding of the constituting coaxial cable. The tip of the first stub ST1 is short-circuited.

The connection cable 2 in which a rigid cylindrical outer conductor tube is fitted as an earth conductor is fixed to the fixing plate 24.
2 are fixed by soldering or the like, and the core wire of the connection cable 22, the core wire of the power supply cable 21 held by the holder 24-1, and the core wire of the first stub ST1 are fixed on the fixing plate 24. It is connected. Furthermore, the end of the power supply cable 23 connected to the radio is connected to the holder 24.
-2 and is fixed to the fixing plate 24. A rigid cylindrical outer conductor tube is fitted to the end of the power supply cable 23, and this outer conductor tube is electrically connected to the shielding braid of the power supply cable 23. One end of the second stub ST2 is also fixed to the holder 24-2 of the fixing plate 24. A rigid cylindrical outer conductor tube is also fitted to one end of the second stub ST2, and this outer conductor tube is held by a holder 24-2, and the outer conductor tube holds the second stub ST2. It is electrically connected to the knitting wire for shielding of the constituting coaxial cable. The tip of the second stub ST2 is short-circuited.

The other core wire of the connection cable 22 fixed to the fixing plate 24, the core wire of the power supply cable 23 held by the holder 24-2, and the second stub S
The core wire of T2 is connected on the fixing plate 24. Thus, the power supply cables 21 and 23 and the stubs ST1 and ST
Since the rigid outer conductor tubes are fitted to the ends of the two, they can be securely fixed to the fixing plate 24, and the fixing posture can be maintained.
The electric length L of the power supply cable 21 from the point A (the same as the point A shown in FIG. 3) to the connection of the first stub ST1.
The electrical length L2 from point 1, A to the connection of the second stub ST2 is the electrical length described above with reference to FIGS. 1 and 2, the electrical length L3 of the first stub ST1, and the electrical length L2 of the second stub ST2. The length L4 is also the electrical length described above with reference to FIGS.

Next, the operation of the matching device 2 of the present invention will be described. The Smith chart shown in FIG. 5 shows the frequency characteristics of the impedance of the antenna 1 before the matching at the point A shown in FIGS. As the two frequencies to be matched by the matching device 2, the first frequency f1 is 848M
Hz, and the second frequency f2 is 902 MHz. An example of each electric length at this time is as follows.
Approximately 0.179λ in MHz, electrical length L2 is 902MHz
Is approximately 0.264λ, the electrical length L3 is approximately 2.75λ at 902 MHz, and the electrical length L4 is approximately 1.75 at 848 MHz.
λ. When matching is performed by the matching device 2 shown in FIG. 4 configured as described above, the impedance has frequency characteristics shown in the Smith chart shown in FIG.

As can be understood with reference to FIG. 6, good matching is performed and 1 (846 MHz), 2 (850 MHz), 3 (90
Good SWR is obtained at the working frequencies indicated by 1 MHz) and 4 (903 MHz). FIG. 7 shows the frequency characteristics of the SWR at this time. As shown in FIG.

Incidentally, the matching method of the present invention is shown in FIGS.
It is not limited to the matching method described with reference to FIG. 2. When matching is performed at two frequencies, a stub connected to a position where the normalized conductance on the feeder line at one frequency is 1.0 at one frequency is used. A stub connected to a position where the normalized conductance on the feeder line at that frequency is 1.0 at the other frequency is used as a conventional matching method for canceling the susceptance at the connection point. A matching method may be used in which the electrical length becomes zero and the susceptance at the connection point can be canceled.

Further, the matching method of the present invention can also perform matching in a wide frequency band on both sides of the matched center frequency. At this time, two frequencies on both sides of the frequency band to be matched are set as a first frequency and a second frequency, and matching is performed by the matching method of the present invention described with reference to FIGS. do it. For example, when the SWR before the matching has the frequency characteristic shown in FIG. 8, if the matching is performed by this matching method, a good SWR can be obtained over a wide frequency band as shown in FIG. . That is, in FIG.
If the frequency band within is about 40 MHz,
The first frequency is about 815 MHz and the second frequency is about 8
When the above-mentioned matching is performed by setting to 75 MHz, the frequency band in which the SWR after the matching is within 1.5 becomes a wide band of about 90 MHz as shown in FIG.

Although the stub is short-circuited in the above description, the stub may be open-ended. In the case of a stub having an open end, its electric length is an integral multiple of λ / 2, that is, n · λ / 2, so that the electric length for the other frequency changes finely, and n is changed. Thereby, the susceptance can be adjusted more precisely.

[0031]

As described above, according to the present invention, the susceptance of each stub is zero at the first frequency or the second frequency, which is equivalent to no connection. From this, the stub that cancels out the susceptance at one frequency and matches is
Since the susceptance is zero at the other frequency,
No adverse effects will occur during matching at the other frequency. Therefore, matching can be achieved even when the first frequency and the second frequency are separated from each other, and matching can be achieved even in a wide frequency band from the first frequency to the second frequency. Become. Note that the configuration of the matching device is simple, and can be mainly configured by a power supply cable, so that the matching device can be provided at low cost.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the principle of a matching method for describing an embodiment of a matching method according to the present invention.

FIG. 2 is a Smith chart for explaining an embodiment of the matching method of the present invention.

FIG. 3 is a diagram illustrating a configuration example of an antenna according to an embodiment of the matching device of the present invention.

FIG. 4 is a diagram illustrating a configuration example of a matching device according to the embodiment of the present invention.

5 is a Smith chart showing frequency characteristics of impedance of the antenna shown in FIG. 4 before matching.

6 is a Smith chart showing frequency characteristics of impedance of the antenna shown in FIG. 4 after matching by the matching device of the present invention.

7 is a diagram showing the frequency characteristics of the SWR after the antenna shown in FIG. 4 is matched by the matching device of the present invention.

FIG. 8 is a diagram illustrating frequency characteristics of SWR of an antenna before matching.

FIG. 9 is a diagram illustrating frequency characteristics of SWR after matching by another matching method of the present invention.

[Explanation of symbols]

 Reference Signs List 1 antenna 2 matching device 11 radiating element A 12 radiating element B 13 holder 14 FRP cover 15 power supply cable 21, 23 power supply cable 22 connection cable 24 fixing plate 24-1, 24-2 holder ST1, ST2 stub 100 load 101 power supply line

Claims (8)

[Claims] 1. A normalized conductance component of admittance at a first frequency on a feed line is approximately 1.0,
A first stub having an electrical length such that the susceptance component becomes substantially zero at a second frequency higher than the first frequency is connected to a position where the normalized susceptance component is positive, and the second stub is connected on the power supply line. A second stub having an electrical length at which the susceptance component becomes substantially zero at the first frequency is connected to a position where the normalized conductance component of the admittance at the frequency is approximately 1.0 and the normalized susceptance component is at a negative position. A matching method, characterized in that: 2. The matching method according to claim 1, wherein the first frequency and the second frequency are frequencies on both sides of a predetermined frequency band. 3. The electrical length of the electrical length at which the normalized conductance component of the admittance at the first frequency is approximately 1.0 on the feeder line and a susceptance component of the opposite polarity that can substantially cancel the susceptance component at that position. A first stub is connected, and a normalized conductance component of admittance at a second frequency higher than the first frequency is approximately 1.0 on the feeder line, and the normalized susceptance component is at a negative position. A matching method, characterized in that a second stub having an electrical length at which the susceptance component becomes substantially zero at the first frequency is connected. 4. A second frequency higher than the first frequency, wherein the normalized conductance component of the admittance at the first frequency on the feeder line is approximately 1.0, and the normalized susceptance component is at a plus position. A first stub having an electrical length such that the susceptance component at
On the feeder line, the normalized conductance component of the admittance at the second frequency is approximately 1.0,
A matching method comprising connecting a second stub having an electrical length in which a susceptance component of an opposite polarity capable of substantially canceling a susceptance component at that position is connected. 5. A power supply line having one end connected to a load and the other end connected to a supply source, wherein a normalized conductance component of admittance at the first frequency is approximately 1.0, and the normalized susceptance component is Is connected to a positive position on the feeder line, a first stub having an electrical length at which a susceptance component becomes substantially zero at a second frequency higher than the first frequency, and a normal admittance at the second frequency. A second stub having an electrical length of approximately 1.0 and having a normalized susceptance component connected to a position on the feeder line where the susceptance component is approximately zero at the first frequency. And a matching device. 6. The matching device according to claim 1, wherein the first frequency and the second frequency are frequencies on both sides of a predetermined frequency band. 7. A power supply line having a load connected to one end and a supply source connected to the other end, and a position on the power supply line having a normalized conductance component of admittance at a first frequency of about 1.0. A first stub of an electrical length in which a susceptance component of the opposite polarity capable of substantially canceling the susceptance component at that position is generated, and a normalized conductance component of admittance at a second frequency higher than the first frequency. A second stub having an electrical length of approximately 1.0 and having a normalized susceptance component connected to a position on the feeder line that is negative and having a susceptance component of approximately zero at the first frequency. A matching device, characterized in that: 8. A power supply line having one end connected to a load and the other end connected to a supply source, wherein a normalized conductance component of admittance at the first frequency is approximately 1.0, and the normalized susceptance component is Is connected to a positive position on the feeder line, a first stub having an electrical length at which the susceptance component at the second frequency higher than the first frequency is substantially zero, and a normal admittance at the second frequency. A second stub connected to a position on the feeder line where the converted conductance component is approximately 1.0 and having an electrical length that produces a susceptance component of the opposite polarity that can substantially cancel the susceptance component at that position. A matching device, characterized in that: