RU2793575C1 - Monolithic strip filter - Google Patents

Abstract

FIELD: radio technology; filters.

SUBSTANCE: monolithic strip filter is made using the technology of multilayer printed circuit boards by pressing dielectric substrates. The strip conductors of the resonators are made with two layers, and the prepreg connecting them is located between these layers. The two-layer strip conductors of the resonators are closed by adjacent ends on one side to the screen, and on the other side are open. In the layer of outer metallization of the filter deposited on the outer surfaces of the filter and acting as a screen, through holes are made, and they are located above the places where the strip conductors of the resonators are connected to the screen. The area of each hole is in the range from w² to 16 w² mm², where w is the width of the strip conductor at the location of the hole, mm.

EFFECT: increase in the repeatability of the characteristics of monolithic strip filters manufactured using the technology of multilayer printed circuit boards.

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Description

The invention relates to microwave technology and is intended to create devices for frequency selection of microwave signals, filters, diplexers, etc.

The design of a stripline resonator and a filter based on it is known [Belyaev B.A., Izotov A.V., Lexikov A.A., Serzhantov A.M., Sukhin F.G. Stripline resonator on a double suspended substrate // Patent for useful model no. 99248, publ. November 10, 2010, Bull. No. 31]. The filter contains two dielectric substrates suspended between the screens of the housing, on both surfaces of which strip metal conductors of the resonators are deposited, electromagnetically coupled to each other and having the shape of a rectangle. The filter is characterized by miniaturization, but has significant drawbacks in mass production. First, the manufacturing process of such a filter is labor-intensive due to the need to use a large number of solder joints and is poorly compatible with automatic production processes. Secondly, the repeatability of the filter characteristics turns out to be low due to the need for manual labor, which reduces the manufacturing accuracy, as well as the impossibility of adjusting the device without opening the screen housing.

The closest analogue is a strip filter made using the technology of multilayer printed circuit boards [A. A. Lexikov. Multilayer multi-conductor strip resonators and devices for frequency selection of signals based on them: dis. doc. tech. Sciences: 1.3.4. - Siberian Federal University, Krasnoyarsk, 2022. - 354 p.]. In such a filter, in order to eliminate the influence of the prepreg material on the characteristics of strip elements in a filter manufactured using the technology of multilayer printed circuit boards by pressing dielectric substrates, all the strip conductors of the resonators are made of two layers, and the prepreg is located between these layers. In this case, the two-layer conductors are closed by adjacent ends on one side to the screen, and on the other side are open. As a result, at operating frequencies, the voltage at the open ends has the same sign, which makes the electric field in the prepreg layer equal to zero, and thus its effect on the characteristics of the resonator is significantly reduced. Compared to other known designs, this approach reduces the influence of the prepreg material on the characteristics of the resonators, which makes it possible to increase the intrinsic quality factor of the resonators and improve the repeatability of device characteristics in mass production. The disadvantage of the device is that good repeatability of device characteristics is provided only at frequencies of the meter and decimeter wavelength ranges (operating frequencies less than 3 GHz), as well as at wide bandwidths (relative bandwidth of 10% or more). At frequencies in the centimeter wavelength range, the repeatability of the characteristics deteriorates significantly due to the limited accuracy of manufacturing the stripe structure of the filter. At the same time, it is impossible to improve repeatability by adjusting after manufacturing, due to the presence of a continuous outer metallization that acts as a screen.

The technical result of the invention is to increase the repeatability of the characteristics of monolithic strip filters manufactured using the technology of multilayer printed circuit boards.

The specified technical result is achieved by the fact that in a monolithic strip filter, which includes several dielectric substrates connected by pressing, with metal strip two-layer conductors of resonators located on them, between which there is a prepreg binding layer, as well as a screen made in the form of an external metallization layer, while two-layer conductors are closed by adjacent ends on one side to the screen, and on the other side are open, what is new is that holes are made in the screen on the outer surface of the filter, and they are located above those places where the strip conductors of the resonators are closed to the screen, while the area of each hole s is in the range from w ² to 16∙w ² mm ² , where w is the width of the strip conductor at the location of the hole in mm.

The essential difference between the proposed method and the prototype lies in the fact that holes are made in the outer metallization layer, which is the screen of the device, and they have such a shape that allows a technically simple change in their area in the process of adjusting the filter characteristics after its manufacture. It is also important that the holes are located above the places where the strip conductors of the resonators are connected to the screen, and the area of each hole s is in the range from w ² to 16 ∙ w ² mm ² , where w is the width of the strip conductor at the location of the hole in mm, which makes it possible to change the resonant frequency of stripline resonators up to ~10%.

Thus, the above distinguishing features from the prototype allow us to conclude that the proposed technical solution meets the criterion of "novelty". The features that distinguish the claimed technical solution from the prototype are not identified in other technical solutions and, therefore, ensure that the claimed solution meets the criterion of "inventive step".

The essence of the invention is illustrated by the following figures. On FIG. 1 shows the design of a monolithic strip-pass filter of the claimed design, mounted on a printed circuit board, and Fig. 2 shows the filter separately. On FIG. 3–7 show separately the design elements of the inventive bandpass filter. On FIG. Figure 8 shows the dependence of the resonant frequency of a multiconductor stripline resonator on the area of holes in the outer metallization layer.

The inventive monolithic strip filter1 manufactured using the technology of multilayer printed circuit boards and placed (Fig. 1) on the printed circuit board2 target device. Filter1 has (Fig. 2) two ports3 and is covered with a layer of metallization on the outside - a screen4in which holes are made5. Under the screen4 located (Fig. 3, 4) thick external dielectric substrates6, between which are placed (Fig. 5) thin dielectric substrates7and prepreg bonding layers8. Between layers of substrates6,7 and prepreg8 conductors are located9 resonators. Over those places10(Fig. 6, 7), where the strip conductors9 closed to common ground buseselevenconnected (Fig. 2) with the screen4, holes are located5. Area of each hole5 s is in the interval fromw ² before16w ² mm², Wherew – strip conductor width9 at the location of the hole5 in mm. Specific hole sizes5 are determined at the stage of numerical electrodynamic modeling, corrected during the production of experimental series of filters, and selected based on the required range of resonator frequency adjustment and the absence of radiation in electromagnetic energy into free space.

As is known, to design bandpass filters with unique characteristics, in particular, high miniaturization, large stopband width, with high repeatability of characteristics in mass production, it is possible to use the technology of multilayer printed circuit boards. At the same time, known manufacturing methods do not allow creating devices for frequency selection of centimeter-wavelength signals suitable for mass production, which could be of interest to developers, for example, of civil radio electronics systems. When using known methods for the manufacture of civilian products, the final cost of the device increases many times due to the low percentage of yield of suitable products and turns out to be high relative to other known technologies for the production of filters. To solve this problem, it is necessary to provide in the design of the band pass filter the possibility of adjusting the characteristics of the device after its manufacture. The proposed design of the strip filter allows to solve this problem to a large extent.

Monolithic strip filter works as follows. The input and output transmission lines are connected as shown in Fig. 1. The distance from the grounded ends of the strip conductors of the resonators to the connection points of the external transmission lines is determined by the given level of reflections in the filter passband. Signals whose frequencies fall within the passband pass to the filter output with minimal loss, while signals outside the passband are reflected from the input of the device.

The claimed technical result is achieved as follows. Due to the possibility of changing the area of through holes 5 (Fig. 2) in the outer metallization layer - screen 4 after the filter is manufactured, for example, using known methods of solder deposition or deposition of a plastic conductive material (indium, etc.), it is possible to adjust the frequencies of stripline resonators and achieve the required electrical characteristics of the device without compromising its integrity.

As is known [Leferink F. B. J. Inductance calculations; methods and equations // IEEE International Symposium on Electromagnetic Compatibility, 1995, Pp. 16–22], an increase in the screen height in a strip transmission line leads to an increase in its linear inductance. Thus, for stripline resonators made on the basis of segments of a stripline transmission, when the screen height changes, their equivalent inductance will also change, which will lead to a change in their resonant frequency. In the proposed filter design, the greatest effect of through holes will be achieved if they are located near the antinode of the magnetic field of the stripline resonators, i.e., in those areas of the filter where the stripline conductors are closed to the screen. Studies conducted in the electrodynamic analysis program showed that in the proposed filter design, an increase in the area of through holes in the outer metallization layer is equivalent to an increase in the height of the screen and will lead to a decrease in the resonant frequency. From a practical point of view, the maximum dimensions of through holes are limited by their influence on the intrinsic quality factor of the resonators. Moreover, if at the operating frequencies of the filter the size of the holes is much smaller than the wavelength in vacuum, then their presence practically does not lead to a decrease in the intrinsic quality factor of the stripline resonators caused by the radiation of electromagnetic energy into free space.

To confirm the claimed technical result in Fig. 8 shows the dependence of the resonant frequency of a multiconductor stripline resonator on the area of the hole in the outer metallization layer. The calculation was carried out by electrodynamic analysis of 3D models of resonators in the CST Studio Suite software package. The multiconductor resonator consists of six strip conductors. Five dielectric layers between conductors made of RO4350BTM material with a relative permittivity ε=3.66 had a thickness of 0.102 mm, and two outer layers of the same material had a thickness of 0.51 mm. The width of all strip conductors of the structure is 1 mm, their length is 13.1 mm, while the total length of the resonator is 15 mm. The maximum size of the through holes in the outer metallization layer was 1.6×3 mm ² , while in the course of the study the area of the holes varied from zero to ~ 5∙w ² due to a decrease in their length at a fixed width of 1.6 mm. As seen from FIG. 8, the relative change in the resonant frequency of the stripline resonator f _res was ~ 3% when the area of the holes in the outer metallization layer changed from the minimum value to the maximum, which is quite sufficient to adjust the devices in most practical cases and confirms the claimed technical result. At the same time, the presence of through holes practically did not change the intrinsic Q factor of the resonator. It is important to note that in the range from w ² to 5∙w ² the dependence of the resonant frequency on the area is close to linear (Fig. 8), and when the area is less than w ² the dependence is weakly expressed. With a hole area up to approximately 16∙w ^2, a resonant frequency shift of up to ~10% will be observed, which with a margin covers the range of resonant frequency spread due to the limited manufacturing accuracy of stripline filter structures.

Thus, the claimed design makes it possible to increase the repeatability of the electrical characteristics of monolithic strip filters manufactured using the technology of multilayer printed circuit boards, due to the possibility of their adjustment after manufacture and, thus, to increase the percentage of yield of suitable products in mass production.

Claims (1)

A monolithic strip filter, which includes several dielectric substrates connected by pressing with metal strip two-layer conductors of resonators located on them, between which there is a prepreg bonding layer, as well as a screen made in the form of an outer metallization layer, while the two-layer conductors are closed by adjacent ends on one side at screen, and on the other hand open, characterized in that holes are made in the screen on the outer surface of the filter, and they are located above those places where the strip conductors of the resonators are closed to the screen, while the area of \u200b\u200beach hole s is in the range from w ² to 16 ∙w ² mm ² , where w is the width of the strip conductor at the location of the hole, mm.

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