JPH0575282B2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Industrial Application Field This invention is applicable to, for example, microwave transmission lines,
The present invention relates to so-called triplate strip lines used in filters or microwave integrated circuits using them.

(b) Summary of the Invention The triplate stripline according to the present invention has two dielectric substrates each having a ground electrode formed on one main surface and a line electrode formed on the other main surface, and a low dielectric conductor between them. Regarding the so-called triplate type strip line, in which the line electrodes are stacked so as to face each other with a sheet of wire in between, and the opposing line electrodes are electrically connected by a conductive material that penetrates the sheet, the resonant frequency and the coupling coefficient are particularly important. This allows for easy adjustment.

(c) Prior Art Conventionally, a stripline used as a filter, for example, has been used in which a line electrode is sandwiched between two dielectric substrates each having a ground electrode formed on one main surface. This type of stripline has the characteristics of low conductor loss and no electromagnetic field leakage.

However, in conventional strip lines using two dielectric substrates, the dielectric substrate may warp or a gap may occur between the dielectric substrate and the line electrode. There was a problem in that it greatly affected the circuit constants of the line. Therefore, the same applicant proposed in Japanese Patent Application No. 60-210599 a triplate-type stripline that improves the accuracy of circuit constants while suppressing conductor loss and electromagnetic field leakage to the same level as conventional striplines. I have already applied.

(d) Problems to be solved by the invention However, even in the stripline shown in this application, the characteristics of the resonant frequency and coupling coefficient are uniquely determined by the substrate material, electrode dimensions, etc., and therefore it is difficult to obtain the desired characteristics. In order to obtain the desired characteristics, it is necessary to make many design changes, it takes a long time to develop the product, and even if the desired characteristics are obtained, extremely strict precision is required to prevent variations, making production difficult. It was hot.

The object of the present invention is to provide a triplate type stripline having the structure shown in the above application, whose characteristics can be easily and finely adjusted.

(e) Means for explaining the problem The triplate type stripline of the present invention consists of two dielectric substrates each having a ground electrode formed on one main surface and a line electrode formed on the other main surface. The conductive material is provided by stacking the line electrodes so as to face each other with a low dielectric constant sheet sandwiched between them, and by providing conduction between the opposing line electrodes with a conductive material penetrating the sheet, or in a strip line. It is characterized by adjusting the resonance frequency and coupling coefficient by determining the lengthwise position, inner diameter, and number of the through holes of the line electrodes.

(f) Effect In the triplate stripline of the present invention, the line electrodes formed on each of the two dielectric substrates are formed on a low dielectric constant sheet sandwiched between the two dielectric substrates. Conductivity is provided by the provided conductive material. Therefore, the two line electrodes are electrically connected to each other so that currents in the same phase flow, and the line electrodes are used as a triplate type strip line. The above-mentioned conductive material is provided in the through hole of the low dielectric constant sheet.
The resonant frequency and coupling coefficient of the stripline vary depending on the longitudinal position, inner diameter, and number of line electrodes. Therefore, by determining the position, inner diameter, and number of through holes in the length direction of the line electrodes, a triplate type stripline having desired characteristics is constructed.

(g) Embodiment Fig. 1 is a partially cutaway perspective view showing the structure of a triplate type stripline according to an embodiment of the present invention, Fig. 2 is a cross-sectional view of a specific part thereof, and Fig. 3
The figure is a plan view showing the shape of one dielectric substrate and the electrodes formed on the dielectric substrate.

This stripline consists of two dielectric substrates 11a and 11b, each having ground electrodes 14a and 14b formed on one main surface and line electrodes 15a and 15b formed on the other main surface, in other words, a so-called microstripe. The lip line is connected to each line electrode 15a, 15 with a thin resin sheet 12 in between.
b are stacked so as to face each other to form a so-called triplate stripline. Then, a resin sheet 1 is inserted between the opposing line electrodes 15a and 15b.
2 is electrically connected by a conductive member 20 that passes through it.

The dielectric substrates 11a and 11b are made of, for example, alumina ceramics, and the line electrodes 15a and 15b are respectively formed in advance by, for example, printing or baking with silver paste. The resin sheet 12 is made of a resin sheet with a low dielectric constant and elasticity such as polytetrafluoroethylene, and the line electrodes 15a,
A through hole is made in the part sandwiched between the parts 15b. Then, a conductive paste such as silver paste, which is the same electrode material as the line electrodes 15a and 15b, or other solder paste, is injected in advance into the through hole as the conductive material 20.
By pressing from both sides with a and 15b, or by further heating as necessary,
The line electrodes 15a and 15b are electrically connected. Alternatively, the through holes provided in the resin sheet 12 may be through-hole plated with copper as the conductive material 20 by an electroless plating method.
Conductivity is established between 5a and 15b.

As shown in FIG. 3, a ground electrode is formed on one main surface (the back surface in the figure) of each dielectric substrate 11, and this ground electrode is connected to the other main surface (the surface shown in the figure) through the end surface of the substrate. An electrode 16, which is a part of the ground electrode, is formed in a part of the ground electrode, and a plurality of line electrodes 15 are formed to extend from this electrode 16, thereby forming a so-called combline type stripline. Note that the electrodes 17 and 18 are external extraction electrodes. In a stripline constructed in this way, the resonance frequency is mainly determined by the length of the line electrodes, and the coupling coefficient is mainly determined by the distance between each line electrode. Therefore, in order to obtain a stripline with the desired characteristics, the shape and dimensions of the line electrodes are designed in advance, but the position and size of the conductive material that connects the line electrodes formed on the two dielectric substrates must be determined in advance. The resonant frequency and coupling coefficient vary within a minute range depending on the size and number of the elements. In the example shown in FIG. 1, one through hole is formed in the resin sheet 12 for each line electrode, for example, through holes 19a, 19b, 19
The inner diameters of c are designed to be a, b, and c, respectively, and the distances in _{the length direction of the line electrodes from the ends of the resin sheet are determined as la, l b ,} and l _c, respectively. By determining the position, inner diameter, and number of through holes in this manner, the resonance frequency and coupling coefficient of the stripline can be finely adjusted. At the time of this fine adjustment, there is no need to change the shape of the line electrode to be formed on the dielectric substrate, and it can be done by changing only the design of the through hole to be formed in the resin sheet 12.

In the embodiment, a combline type stripline is used as an example, but the same can be applied to an interdigital type stripline. Furthermore, although a resin sheet with a low dielectric constant was used in the embodiment, it is also possible to use glass or ceramic with a lower dielectric constant than the two dielectric substrates.

(h) Effects of the Invention As described above, according to the present invention, in order to obtain a stripline with predetermined characteristics, it is possible to obtain a stripline with low cost without changing the design of the dielectric substrate or the shape or dimensions of the electrodes to be formed on the substrate. Desired characteristics can be easily obtained by only modifying the through holes in the dielectric constant sheet. Therefore, it is not necessary to strictly control the dimensional accuracy of the dielectric substrate and the electrodes to be formed on the dielectric substrate, and productivity can be easily improved.

[Brief explanation of drawings]

FIG. 1 is a partially cutaway perspective view showing the structure of a triplate stripline according to an embodiment of the present invention, FIG. 2 is a partial sectional view thereof, and FIG. FIG. 3 is a plan view showing the configuration of the body substrate. 11a, 11b...Dielectric substrate, 12...Resin sheet (low dielectric constant sheet), 15, 15b...Line electrode, 19a-19c...Through hole, 20...
Conductive material.

Claims (1)

[Claims] 1. Two dielectric substrates each having a ground electrode formed on one main surface and a line electrode formed on the other main surface, with a low dielectric constant sheet sandwiched between them, and each line electrode formed on the other surface. In a stripline in which the line electrodes are overlapped to face each other and electrically conductive between the opposing line electrodes by a conductive material penetrating the sheet, the lengthwise position and inner diameter of the line electrodes of the through hole in which the conductive material is provided, A triplate type stripline whose resonant frequency and coupling coefficient are adjusted by determining the number and number of plates.