EA020744B1 - Miniature strip-line resonator - Google Patents

Abstract

The invention relates to microwave engineering and is intended for designing drive circuits for generators, frequency-selective microwave devices etc. In a strip-line resonator, having a dielectric substrate suspended between screens, wherein a metallic strip-line conductor which is short-circuited at one end is deposited on one surface of said substrate, the novelty lies in that over the first strip-line conductor there are first metallic strip-line conductors with an identical shape and size, separated by thin dielectric layers, wherein the names of the strip-line conductors with odd numbers are short-circuited by one end on the same side of the substrate as the first strip-line conductor, and with even numbers - on the opposite side of the substrate. The technical inventive effect provides smaller size of a strip-line resonator and higher basic Q-factor thereof.

Description

The invention relates to techniques for microwave frequencies and is intended to create a driving circuit of generators, frequency-selective microwave devices, etc.

A known design of a strip resonator on a multilayer substrate suspended between the screens [RF patent No. 2352032, IPC Н01Р 1/203, publ. 04/10/2010, Bull. No. 10 (analog)]. The strip resonator is implemented on the basis of a multilayer substrate containing strip conductors that are identical in shape and location and separated by dielectric layers. Such a resonator, due to a decrease in losses in it, allows one to increase one's own Q factor.

The disadvantage of this resonator is the relatively large size, especially in the meter wavelength range.

The closest analogous combination of essential features is the strip resonator, on the basis of which a tunable band-pass filter is implemented [A.K. Vgo \ pack. CM. ReBe1 /. And uatas1og-1ipeb KR Y11eg // 1EEE Ttapk. οη MTT. 2000, νοί. 48, No. 7, p. 1157-1160]. The resonator is made on a dielectric substrate suspended between the screens, on one side of which a strip conductor is short-circuited on the screen from one end.

The disadvantages of this resonator design are the large size and relatively low quality factor in the meter wavelength range, which complicates the development of miniature frequency-selective devices in this range based on planar technologies.

The technical result of the invention is to reduce the size of the strip resonator and increase its own quality factor.

This technical result is achieved in that in a strip resonator containing a dielectric substrate suspended between the screens, on one surface of which a strip metal conductor short-circuited at one end is applied, the new one is that metal strip conductors identical to the first in shape and size are located above the first strip conductor separated by thin dielectric layers, and the said strip conductors with odd numbers at one end are short-circuited with the same Torons substrate as the first strip conductor, and the even-numbered - on the opposite side of the substrate.

The differences of the claimed device from the closest analogue are that above the first conductor through thin dielectric layers metal strip conductors are identical in shape and size, and the conductors with odd numbers at one end are closed to the screen on the same side of the substrate as the first conductor, and even-numbered conductors are closed at one end to the screen on the opposite side of the substrate. These differences allow us to conclude that the claimed technical solution meets the criterion of novelty. Signs that distinguish the claimed technical solution from the prototype are not identified in other technical solutions when studying this and related areas of technology and, therefore, provide the claimed solution with the criterion of inventive step.

The invention is illustrated by drawings.

FIG. 1 - design of a specific implementation of the proposed strip resonator on a suspended dielectric substrate, FIG. 2 - dependence of the frequency of the first resonance of the inventive resonator on the number of its conductors, FIG. 3 - dependence of the intrinsic Q factor of the strip resonator on the number of its conductors; FIG. 4 - experimental resonance curves of two manufactured resonators with the number of conductors N = 2 and N = 4; FIG. 5 - the calculated amplitude-frequency characteristics (AFC) of losses through a two-link bandpass filter based on the inventive resonator.

The inventive device (Fig. 1) contains a dielectric substrate 1 suspended between two screens in a metal housing 2, on one surface of which are applied strip metal conductors 3, electromagnetically coupled to each other and separated by thin dielectric layers 4. The conductors may, for example, have the shape of a rectangle . The totality of all metal strip conductors, separated by dielectric layers, together with the body forms a strip resonator. It should be noted that the shape of the conductors from which the strip resonators are formed (in the considered case is rectangular) can be any.

It is known that the value of the intrinsic Q factor of strip resonators in practice in the meter wavelength range usually does not exceed two hundred, and it decreases with decreasing frequency. This is due to several factors, the main of which are the small thickness of the conductors compared to the depth of the skin layer, the final conductivity of the metal from which the strip conductors are made, and the uneven distribution of currents in the cross section of the conductors. Moreover, in the meter wavelength range, not only the Q factor often becomes insufficient, but the large sizes of traditional strip resonators are unacceptable.

The inventive design can significantly reduce the size and increase the own quality factor of the strip resonator, which, in turn, can reduce the size and improve the characteristics of devices based on it.

The resonator operates as follows.

At the lowest resonant frequency of the structure, when a quarter of the wavelength of the electromagnetic wave is stacked along the length of each strip conductor, all the conductors in the resonator have

- 1 020744 the same distribution of high-frequency currents and voltages along their length, i.e. the current in the resonator is equally divided into all conductors. As a result, the Joule losses in the cavity are reduced, and, accordingly, its own Q factor increases. Moreover, due to the strong electromagnetic coupling of the conductors, the magnitude of the inductance of the oscillating system in the inventive resonator is much larger than that of traditional designs of strip resonators, which leads to a significant reduction in its length for a fixed frequency. It is important to note that even with a large number of conductors, the total thickness of the multilayer resonator can be quite small (hundreds of micrometers) and, therefore, not have a noticeable effect on the overall dimensions.

In FIG. Figures 2 and 3 show the calculated dependences of the resonance frequency £ _{0 of the} inventive strip resonator and its own Q factor C ₀ on the number of strip conductors N. The thickness of the quartz substrate (ε = 3.7) on which the conductors were located was 1 mm, the width of the conductors was \\ = 2 mm, and the thickness of the dielectric layers is 10 μm with their dielectric constant ε = 10. Such a thickness of the dielectric layer, for example, of silicon monoxide δίΘ is often optimal from a technological point of view. The length of the conductors was 20 mm; the distance from the upper and lower surfaces of the substrate to the screen was 5 mm. Hereinafter, the material of the conductors is copper 10 microns thick. The internal dimensions of the resonator body were 20x11x8 mm ³ . It is seen that with an increase in the number of conductors, the intrinsic Q factor of the strip resonator increases, and the resonant frequency decreases. This means that with an increase in the number of conductors of the inventive resonator at a fixed resonant frequency, the dimensions will decrease significantly, and the quality factor will increase significantly. An electrodynamic calculation showed that a single-conductor resonator prototype with the same design parameters and the same resonant frequency should have a length of about two orders of magnitude greater, and its Q factor will not exceed 100.

To confirm the claimed technical result, two strip resonators with the number of conductors N = 2 and N = 4 on a substrate of 0.4 mm thick quartz were made. The resonators had the same design parameters: the width of the copper strip conductors No. = 3 mm, their thickness 10 μm, the distance from the upper and lower surface of the substrate to the screen 4 mm, the thickness of the dielectric layers of fluoropolymer between the conductors 125 μm, their dielectric constant ε = 2.8 . In FIG. Figure 4 shows the amplitude-frequency characteristics (AFC) of the losses through the passage of the fabricated resonators when they are weakly coupled to transmission lines. Here, the insets give the internal dimensions of the body of the manufactured resonators. The resonators had the same resonant frequency £ ₀ "300 MHz and differed only in length: the length of the resonator with the number of conductors N = 2 was 35 mm with the measured Q factor of _{0 0} 150 and internal dimensions of 35x15x8.5 mm ³ , and the length of the resonator with the number of conductors N = 4 was 23 mm with a measured figure of merit Q ₀ 190 and internal dimensions 23x15x8.5 mm ³ .

Thus, an increase in the number of conductors from which the resonator is formed leads to a substantial decrease in its size and an increase in the intrinsic Q factor at a fixed resonant frequency.

In FIG. Figure 5 shows the calculated amplitude-frequency characteristics of the losses due to the passage of a two-link bandpass filter based on strip resonators of the proposed design with the number of conductors in each resonator N = 2 (points) and N = 10 (solid line). Filters have the same relative bandwidth A £ ₃ / £ ₀ = 2% (at a level of -3 dB) with a center frequency of £ ₀ = 90 MHz and a reflection level of microwave power in the passband SWR = 1.5. The design parameters of both filters, with the exception of the length of the resonators, were the same: the width of the strip conductors was 2 mm, the distance between the resonators was 11 mm, and the distance from the upper and lower surfaces of the substrate to the screen was 5 mm. The dielectric constant of the layers was ε = 10 at a thickness of 10 μm.

It can be seen that the approach proposed in the invention can significantly increase the miniature size and reduce direct losses in the passband of the filter. So for the first filter, in which the resonators had the number of conductors N = 2, their length was 20 mm, while for the second filter, the length of the resonators with the number of conductors N = 10 was 8 mm. Thus, with an increase in the number of conductors in the cavity from N = 2 to N = 10, their length decreased by 2.5 times, all other things being equal. In this case, the minimum loss in the passband decreased from 2.6 to 1 dB. It is important to note that the use of a larger number of conductors in the resonator will lead to a significantly larger effect in reducing the size and increasing the quality factor.

Thanks to the use of the proposed approach to create strip resonators, their higher miniature size and their own quality factor are achieved. An important advantage of the invention is that the inventive resonator can be manufactured by integrated technology. The proposed approach can be used to create high-Q resonators for the driving circuits of generators and narrow-band pass-pass filters with low insertion loss, for radar systems, radio navigation and communications.

Claims (1)

A strip resonator containing a dielectric substrate suspended between the screens, on one surface of which a strip metal conductor is short-circuited at one end, characterized in that metal strip conductors identical to the first in shape and size, separated by thin dielectric layers, are located above the first strip conductor, and these are strip conductors with odd numbers at one end are short-circuited on the same side of the substrate as the first strip conductor, but with tnym numbers - on the opposite side of the substrate.