JPS60214602A - Branch line coupler - Google Patents

Abstract

PURPOSE:To set optionally lead-out directions of four plate lines as input and output terminals and to increase the package density of microwave parts by constituting a multilayered dielectric substrate in three dimensions in the thickness direction. CONSTITUTION:A through hole provided to strip patterns 5 and 6 is plated to connect the pattern to a strip pattern 7 and the pattern 5 of a dielectric substrate 1a to the pattern 5 of a dielectric substrate 1d electrically through base metal 3 of each dielectric substrate. A converter constituted by using dielectric substrates as mentioned above allows the transmission mode of substrates 1b and 1c to be considered equivalently as a coaxial mode. In this case, the distance between adjacent through hole plating parts of the pattern 5 is made shorter than wavelength and the characteristic impedance of this coaxial line is easily adjusted by varying the external diameter of the through hole provided to the pattern 6 and the size of an electric equivalent short-circuit surface.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to an improvement of a triplate line type branch line coupler used in microwaves. r [Prior Art] FIG. 1 shows a partially cutaway perspective view of a triplate strip line (hereinafter referred to as triplate line).

In the figure, (la) shows a dielectric material with relative dielectric constant e, which has a strip conductor (2) with line width W attached to a part of one surface and a ground plate (3) made of metal attached to the entire surface of the other surface. Dielectric substrate A, (1b) consisting of a body has only one side as a ground plate (3)
This is a dielectric substrate B that has been closely attached.

Compared to microstrip lines (hereinafter referred to as MIC), this triplate line has the advantage of having a closed system (2), so there is no radiation loss, and there is no effect of leakage power on other equipment. Therefore, it is often used in antenna feeding circuits, etc.

FIG. 2 shows a plan view of a branch line coupler using this triplate line.

In the figure, (4a) indicates input/output terminals Pi, P2 . P3. P4 is the triplate line.

(4b) and (4C,) are triplate lines having different characteristic impedances and forming a branch line coupler. The characteristic impedances Zob and Zoc of the triplate lines (4b) and (4c) are determined by the characteristic impedance Zoa of the triplate line M (4a) and the output power ratio.1For example, when the output power to the output 2 terminal is -3 dB, Zoa When is 500, Zob is 50Ω
, Zoc is 33.4Ω. Furthermore, the axial length 1 of the triplate lines (4b) and (4C) at this time, for example, λ
It becomes g4. Here, λg is the propagation wavelength.

At this time, this branch line coupler is one, for example, the second
The microwave power input from Pl in the figure is.

The output power is equally distributed and becomes the output power of P3 and P4. Also.

(3) P2 is a radiation terminal, and microwaves do not propagate.

A dielectric substrate using a conventional branch line coupler configured as described above has the following drawbacks.

(1) Since one dielectric substrate is surrounded on all four sides by triplate lines each side having a length of λg/4, the exclusive area on one plane is large, and The packaging density of microwave components becomes low.

(2) When using a large number of branch line couplers, the number of dielectric substrates must be increased because the number that can be arranged on the same plane is limited.

(3) 4 serves as the input/output terminal of the branch line coupler
Because there is no degree of freedom in the direction of the book's triplate line,
There are restrictions on the implementation and arrangement of branch line couplers.

[Summary of the invention]

This invention was made with the aim of improving these drawbacks (4), and by providing a triplate line (4b) in the thickness direction of a dielectric substrate, the branch line coupler, which was conventionally composed of a planar circuit, was developed. The proposed method is to configure the circuit as a three-dimensional circuit so that the direction in which the triplate lines, which serve as the four input/output terminals, are taken out can be designed arbitrarily, thereby increasing the packaging density of microwave components on one dielectric substrate.

[Embodiments of the invention]

First, we will introduce a triplate line/triplate line converter (hereinafter referred to as a converter) that connects nine different levels of triplate lines when the dielectric substrate used in microwave is multilayered to the extent necessary for explaining this invention. ) is explained.

FIG. 3 is a partially cutaway perspective view of this transducer.

In the figure, (5), f6L (71 are strip patterns B, C, and A, respectively.

On one side of the dielectric substrate (1a) of this converter.

Strip pattern A (
71.

A strip pattern B(5) is provided. Also.

(5) On the other surface (base plate (3) side) of the dielectric substrate (1a),
A strip pattern shown in FIG. 4('B) is provided. Similarly, on the dielectric substrate (1b), as shown in FIG.
Strip pattern C (6) and strip pattern B (5) shown in enlarged view are shown in Figure 5 (B) on the main plate (3) side.
A strip pattern C(6) shown in FIG.

The dielectric substrate (1c) has a strip pattern C (6) and a strip pattern B (5) shown in an enlarged view in FIG. A dielectric substrate (ld) Ic is provided with a strip pattern C(6) shown in FIG.

Strip pattern B (5) whose enlarged view is shown in Figure 7 (4).
), but the strip pattern shown in FIG. 7(B) is provided on the main plate (3) side.

The surfaces on which the strip patterns shown in (N and (B) in FIG. )and(
The surfaces on which the strip pattern shown in B) is formed are the front and back sides of the dielectric substrate (lb) and (ICL (ld), respectively).

Strip pattern B (51, Strip pattern (
6) C (set in 61) Plating is applied to the through-hole portion using a plating method called through-hole plating.

FIG. 8 shows a cross-sectional view of the through-hole portion after through-hole drilling. As a result, strip pattern C (
6) is strip pattern A (7).

In addition, the strip pattern B (5) of the dielectric substrate (1a)
) is connected to the dielectric substrate (
1d) is electrically connected to the strip pattern B(5). In other words, through-hole plating is used to electrically connect strip patterns on the front and back sides of a dielectric substrate.

In a converter configured using such a dielectric substrate, the propagation mode of the dielectric substrate (16) and (Ic) portion can be considered as a coaxial mode with equal constraints.In other words, from the strip pattern C (6) Strip pattern A (7)
It is considered that the outer diameter of the through-hole plating connecting the two becomes the inner conductor outer diameter, and the electrically equivalent short-circuit surface formed by the plurality of through-hole plating outer diameters in strip pattern B (5) becomes the inner conductor inner diameter.

(7) Here, it is assumed that the distance between adjacent through-hole portions in the strip pattern B(5) is sufficiently small compared to the wavelength. Therefore, the characteristic impedance of this coaxial line can be easily adjusted by changing the outer diameter of the through-hole plating provided in the strip pattern C(6) and the dimensions of the electrically equivalent short-circuit surface.

FIG. 9 is a partially removed perspective view of a branch line coupler of a three-dimensional circuit showing an embodiment of the present invention.

In the figure, (5a) is strip pattern D, (5b) is strip pattern DI', (6a) is strip pattern E, (6b) is strip pattern E, (7a) is strip pattern p-yF, (7b) is This is a strip pattern F'.

The branch line coupler according to the present invention is composed of a tri-plate line (4b), a dielectric substrate (1b), and an equi-axis line (4c) formed within the dielectric substrate (1b) and (1c).

The dielectric substrate of the branch line coupler of this three-dimensional circuit (
1a), enlarged views are shown in Figures 10 (5) and (B) (
8) Strip pattern F (7a), strip pattern D (5a), and strip pattern D' (5b) are provided, and on the ground plate (3) side of the dielectric substrate (1a),
A strip pattern is provided whose enlarged views are shown in FIG. 10 (Q and (B). Here, the strip pattern F (
A strip conductor (2a) is connected to Ia).

Similarly, the dielectric substrate (1b) and (IC) are shown in FIG.
Strip pattern E (6a), strip pattern D (5a), and strip pattern D shown in enlarged view at At
'(5b) and the tri-plate track (4b) are connected to the main plate (3).
A strip pattern C(6), an enlarged view of which is shown in FIG. 11(B), is provided on the side.

The dielectric substrate (1d) has a strip pattern F (7a), a strip pattern D (5a), and a strip pattern D' (
5b) is provided, and a strip pattern shown in FIG. 12 (enlarged views at 0 and @) is provided on the main plate (3) side.

Here, a strip conductor (2b) is connected to the strip pattern F (7a). In addition, the through-holes (9) of strip pattern D (5a) and strip pattern B (6a) are plated on the through-hole portions as shown in FIG. 2a) and (2b) are electrically connected via each dielectric substrate.

FIG. 13 is a sectional view of a branch-in coupler constructed from the three-dimensional circuit of the present invention shown in FIG. 9. In the figure, (8
) is a dielectric substrate (la) I (lb) I (IC)
, (ld) is a metal plate for fixing it.

The branch line coupler according to the present invention has triplate lines (4b) and (4c) having different characteristic impedances.
As before, the characteristic impedance of each is 50Ω and 35.40Ω, and the electrical length of each is λ.
Consists of RI/4.

Therefore, in this branch line coupler, the microwave power input from 9, for example, Pl is divided into 9 equal parts to P3 and P4.
The output power will be . Further, P2 is an isolation terminal, and microwaves do not propagate.

From now on, the branch line coupler of this invention
It can be seen that, like the conventional branch line cup (10) shown in the figure, it exhibits good characteristics.

In the above, the description has been given of a branch line coupler that equally distributes microphone four-wave power, but it goes without saying that the present invention is not limited to this, and can also be applied to a branch line coupler that distributes unequal distribution. Although the description has been made using four dielectric substrates, the present invention can also be applied to a multilayer dielectric substrate composed of four or more dielectric substrates. moreover,
The characteristic impedance and axial length of the triplate line constituting the branch line coupler are not limited to the numerical values used in the explanation.

〔Effect of the invention〕

As described above, the present invention has the effect of increasing the mounting density of microwave components on one dielectric substrate by using a branch line coupler of a three-dimensional circuit.

Furthermore, by using a three-dimensional circuit branch line coupler instead of a planar circuit branch line coupler, there is a degree of freedom in the directionality of the four triplate lines that serve as the input/output terminals of the branch line coupler.

(11) Even when a large number of microwave components are required, there are no restrictions on the mounting and arrangement of the microwave components, which has the effect of preventing an increase in the number of dielectric substrates.

[Brief explanation of drawings]

Figure 1 is a partially removed perspective view of the triplate line, Figure 2
The figure is a plan view of a conventional branch line coupler, and FIG. 3 is a partially removed perspective view of a converter that connects triplate lines in different layers when a dielectric substrate used in a conventional microwave is multilayered. FIGS. 4(4) and 4(B) are enlarged views of strip patterns A and B and the strip patterns formed on the back surface of the substrate. FIGS. 5(8) and 5(B) are enlarged views of strip patterns B and C and strip pattern C formed on the back surface of the substrate. FIGS. 6(4) and 6(B) are enlarged views of strip patterns B and C and strip pattern C formed on the back surface of the substrate. Figures 7 (4) and (B) are enlarged views of the strip pattern B and the strip pattern formed on the back side of the substrate, Figure 8 is a question diagram of through-hole plating, and Figure 9 is a diagram of a branch line coupler according to the present invention. Perspective view with parts removed, No. 10
Figures (6), (B), (C), and (D) are enlarged views of strip (12) patterns D and D-F and the strip pattern formed on the back side of the substrate, and Figure 11 (4) and (B). is an enlarged view of the strip patterns D, I)', E, the triplate line, and the strip pattern C formed on the back side of the board. Figure 12 (5), (B), (C'l, (D)
is strip pattern D. FIG. 13 is an enlarged view of the strip pattern formed on the back surface of the substrate along the line D-E, and is a sectional view of the branch line coupler according to the present invention. In the figure, (1a), (xb), (tc), and (td) are dielectric substrates, 12+. (2a) and (2b) are strip conductors, (3) is the ground plane, and (4) is a branch line coupler (4a) (4b).
) is the triplate line (5) (5a) (5b) f61
(6a) f71 (7a) is a strip pattern. (8) is a metal plate. Note that in FIG. 9, the same reference numerals indicate the same or corresponding parts. Agent Masuo Oiwa (13) Fig. 1 Fig. 21!0 /A Fig. 3 Fig. 9-19- Fig. 10 rA) ” ) (B) CD) Fig. 11 Fig. 12 (A) (C) ( B) (D)

Claims (1)

[Claims] One of the two dielectric substrates is coated with copper foil on only one side, and a conductor is coated on one side of the other dielectric substrate, and a conductor is coated on one side of the other dielectric substrate. (b) In a branch line coupler using a triplate strip line constructed by overlapping two dielectric substrates with IJ tube conductors on each side and overlapping the two dielectric substrates with their respective conductors on the outside, the dielectric In addition to multi-layering the dielectric substrate, a plurality of through holes are provided perpendicularly to the thickness direction of the dielectric substrate from the triplate strip line between different triplate strip lines on one level, and a plating layer is formed on the inner wall of the through hole. By providing K, a plurality of triplate line/triplate line converters are formed by electrically connecting triplate strip lines in different layers, and the branches are three-dimensionally connected in the thickness direction of the multilayer dielectric substrate. (1) A branch line coupler comprising a line coupler and configured such that the direction in which the triplate strip lines serving as the four input/output terminals are taken out can be arbitrarily set.