RU2659321C1 - Miniature strip filter - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention relates to radio engineering, in particular to microstrip filters. Filter contains a dielectric substrate suspended between the shields, on one side of which there are screened conductors of resonators, short-circuited to the screen from one edge of the substrate, and strip conductors shorted to the other edge of the substrate are also applied to the screen on the second side of the substrate. Between the conductors of the resonators, on both sides of the substrate, additional strip conductors are placed opposite each other, galvanically connected to the free ends of the conductors of the resonators. In this case, the filter is configured to form poles of attenuation near the attenuation band.

EFFECT: reduction in size and improvement of the frequency-selective properties of the narrow-band filter.

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Description

The invention relates to techniques for superhigh frequencies (microwave) and is intended for use in transceiver communication systems, radar and radio navigation, various measuring and special radio equipment.

A known design of a band-pass filter [A. with. No. 886106, IPC Н01Р 1/205, publ. 11/30/81, bull. No. 44,], which contains a dielectric substrate metallized on one side, on the other side of which there are strip conductors shorted from one end to the screen. Due to the fact that in this design the strip conductors forming the filter resonators are shorted to the screen at adjacent ends, the coefficients of the inductive and capacitive interaction of the resonators are subtracted from each other, and they are close in magnitude. Therefore, the total coupling coefficient, which is proportional to the bandwidth, can be small even at small distances between the resonators. The implementation of narrow-band filters based on this design does not require a significant increase in the distance between the resonators, and therefore, an increase in the area of the substrate. A significant drawback of this design is that its use at the frequencies of the meter wavelength range is difficult due to the fact that the topology of the filter conductors does not fit on standard sized substrates. In addition, at such frequencies, the intrinsic quality factor of microstrip resonators, as a rule, does not exceed 100, which does not allow the creation of narrow-band filters with an acceptable attenuation of microwave power in the passband on their basis.

The closest analogous combination of essential features is a band-pass filter [RF patent No. 2237320, IPC 7 Н01Р 1/203, publ. 09/27/2004, bull. No. 27 (prototype)]. The filter contains a suspended dielectric substrate, on one side of which are strip conductors that are short-circuited on the screen from one edge of the substrate, and strip conductors that are short-circuited on the screen from the other edge of the substrate, are applied to the second side of the substrate, instead of a grounded base. A filter of this design has a significantly shorter length of strip conductors compared to the first counterpart, and therefore smaller substrate sizes. This allows you to design bandpass filters at lower frequencies. In addition, the intrinsic Q factor of such strip resonators is significantly greater than that of microstrip resonators. Despite the fact that in the described construction the inductive and capacitive coupling coefficients are also subtracted from each other, the total coupling coefficient of the resonators is determined almost exclusively by their inductive interaction, since the capacitive coupling coefficient of the resonators is negligible [B. Belyaev, AM Sergeantov, A. Lexikov BUT. // Radio engineering and electronics. - 2010. - T. 55. - No. 12. - Page 1426]. Therefore, when implementing a device with a narrow passband, it is necessary to significantly increase the distance between the resonators, and thereby the filter dimensions, especially in multi-link structures. In addition, in a narrow-band filter of this design, the attenuation poles are either absent or relatively far from the passband, therefore, the slope of the passband slopes, which determines the selectivity of the device, is relatively small.

The technical result of the invention is to reduce the size and improve the frequency-selective properties of the filter.

The specified technical result is achieved by the fact that in a strip filter containing a dielectric substrate suspended between the screens, on one side of which strip conductors of resonators are short-circuited on the screen from one edge of the substrate, and strip conductors are short-circuited on the screen from the other edge of the substrate, are applied to the second side of the substrate, new is that between the conductors of the resonators on both sides of the substrate opposite to each other placed additional strip conductors, galvanically connected s with the free end of the resonator conductors.

The differences of the claimed device from the closest analogue are that between the conductors of the resonators on both sides of the substrate opposite each other placed additional strip conductors connected to the free ends of the conductors of the resonators. This difference allows us to conclude that the proposed 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 is a design of a particular implementation of the inventive second-order strip filter on a suspended dielectric substrate; FIG. 2 - calculated amplitude-frequency characteristics (AFC) of the claimed filter (solid line) and prototype filter (dashed line); FIG. 3 is a topology of conductors of an embodiment of the inventive fourth-order strip filter having improved selective properties; FIG. 4 - measured frequency response of a fourth-order bandpass filter of the claimed design.

The inventive device (Fig. 1) contains a dielectric substrate 1 suspended between two screens of a metal housing 2, on both surfaces of which are applied strip metal conductors 3, short-circuited to the screen and electromagnetically coupled to each other. A pair of strip conductors located on different surfaces of the substrate forms a strip resonator, while the resonator conductors can be, for example, rectangular, identical in shape and arranged one above the other, and the conductors forming the resonator are connected to the screen at opposite edges of the substrate. Between the conductors of the resonators on both sides of the substrate, additional conductors 4 are made, connected to the corresponding free ends of the conductors of the resonators. Additional conductors can also be rectangular in shape and arranged one above the other.

As is known, the relative bandwidth of the filter is proportional to the total coupling coefficient of their resonators, which in this case is equal to the difference between the coefficients of inductive and capacitive interaction of two-conductor resonators on a suspended substrate [B. Belyaev, AM Sergeants, A. A. Lexikov // Radio engineering and electronics. - 2010. - T. 55. - No. 12. - Page 1426]. In the proposed design of the strip filter, the magnitude of the coupling coefficient of the resonators at the resonant frequencies is significantly lower compared to the prototype, ceteris paribus. This fact is proved by comparing the frequency response (Fig. 2) of the filter of the claimed design (solid line) and the frequency response of the prototype filter (dashed line), which were obtained in the program of electrodynamic analysis of 3D models. Both filters had the same design parameters except for the presence of additional strip conductors in the claimed filter: the dielectric constant of the substrate ε = 9.8, its thickness 0.5 mm, the area of the strip structure 13.25 × 6.4 mm ² , the distance from the surface of the substrate to the screen 3.5 mm, the distance between the resonators S = 2.4 mm, the width of the strip conductors is 2 mm. The filters are tuned to the center frequency of the passband ƒ ₀ = 1 GHz. It can be seen that the relative bandwidth Δƒ / ƒ ₀ , measured at a level of -3 dB, for the filters under consideration varies significantly. So, for the filter prototype, it is 22%, and for the filter of the claimed design - only 3%. To obtain the same narrow passband in the filter prototype, it is necessary to increase the distance S between the resonators to 5 mm. In this case, the area of the strip structure of the prototype filter will be 13.25 × 9.4 mm ² , which is 30% more than the claimed filter. In the case when the relative bandwidth of the filters will be less, this advantage will manifest itself even more significantly.

Thus, from those shown in FIG. 2 frequency response it is seen that in the filter of the claimed design, the interaction between the resonators is almost an order of magnitude less compared to the filter prototype at the same distances between the conductors of the resonators. The small value of the coupling coefficient of the resonators of the inventive filter is explained by the fact that the interaction of the resonators is significantly attenuated by subtracting from the inductive interaction of the resonators a similar capacitive interaction, the value of which is determined by the capacitance formed by additional conductors 4 located opposite each other on different sides of the substrate.

Another advantage of the claimed design, in addition to reducing the size, is that in such filters near the passband, zeros of the transmission coefficient (attenuation poles) are formed, which significantly improve the frequency-selective properties of the devices.

The inventive filter operates as follows. The input and output transmission lines are connected to the conductors of the extreme resonators of the structure. 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 specified level of microwave power reflections in the filter passband. Signals whose frequencies fall into the passband pass to the filter output with minimal losses, while at frequencies outside the passband, signals from the input of the device are reflected.

As you know, one of the most effective ways to improve the selective properties of filters is to increase the number of resonators in them. In FIG. 3 shows the topology of a four-cavity filter of the claimed design, and FIG. 4 - its measured frequency response. The filter design parameters were as follows: dielectric constant of the substrate ε = 9.8, its thickness 0.5 mm, the area of the strip structure 16.4 × 12.5 mm ² , the distance from the surface of the substrate to the screens 3.5 mm, the distance between the resonators S = 2.8 mm, the width of the strip conductors of the resonators 2.4 mm . The filter has a center passband frequency of ƒ ₀ ≈1 GHz. The relative bandwidth Δƒ / ƒ ₀ , measured at a level of 3 dB, is 5%. For comparison, the filter prototype, ceteris paribus, should have an area of the strip structure, 30% larger. Moreover, with a decrease in the relative bandwidth, the gain in decreasing dimensions will increase. In addition, the presented frequency response shows that the filter of the claimed design has significantly higher selective properties compared to the filter prototype due to the formation of zeros of the transmission coefficient near the passband.

Thus, the introduction of additional strip conductors between the filter resonators connected to the open ends of the resonator conductors on opposite sides of the substrate leads to a significant increase in the capacitive interaction of the resonators, which allows not only to significantly reduce the size of narrow-band filters on the suspended substrate, but also to form coefficient zeros on the frequency response Transmission near bandwidth. These attenuation poles provide a steep slope of the frequency response compared to traditional designs of strip and microstrip filters.

Claims (1)

A strip filter containing a dielectric substrate suspended between the screens, on one side of which are strip conductors of resonators short-circuited on the screen from one edge of the substrate, and strip conductors short-circuited on the screen from the other edge of the substrate, characterized in that between the resonator conductors are applied to the second side of the substrate On both sides of the substrate opposite each other, additional strip conductors are placed galvanically connected to the free ends of the resonator conductors.

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