RU171355U1 - MICRO-STRIP BAND FILTER - Google Patents

Abstract

The utility model relates to the field of microwave radio engineering and can be used in frequency conversion systems to extract a useful signal and suppress power at frequencies above and below the operating frequency range, for example, suppressing the power of a local oscillator and a mirror channel. The microstrip bandpass filter contains a dielectric substrate, on one side of which there is a metal base, and on the other side a conductor of the connecting line, the ends of which are the input and output of the filter, and the conductors are connected perpendicular to its opposite edges. The lengths of these conductors located on one side of the connecting line conductor are less than the lengths of conductors located on the other side. Pieces of additional conductors are connected to the ends of the conductors, the other ends of which are open and electromagnetically coupled to each other. The segments of additional conductors are located along the axis of the main ones, and their width is greater than the width of the main conductors. In another embodiment, segments of additional conductors are located between the main conductors, parallel to them. The technical result achieved by the implementation of the claimed invention is the ability to obtain high blocking at given frequencies near the passband with a small number of resonators in the filter and, therefore, with its small dimensions, means of introducing into the composition of the resonators segments of connected lines. 2 cp, 2 ill.

Description

The utility model relates to the field of microwave radio engineering and can be used in frequency conversion systems to extract a useful signal and suppress power at frequencies above and below the operating frequency range, for example, suppressing the power of a local oscillator and a mirror channel.

Known band-pass filter on parallel coupled half-wave resonators (see. Reference on elements of strip technology. Edited by A. L. Feldstein. - M. Communication. 1979 p. 196 Fig. 7.5). The filter is a cascade inclusion of quarter-wave connected strip lines, two diagonally opposite shoulders of which are connected to adjacent cascades and to the input and output, and the other two are open. The microstrip filter allows for a bandwidth of no more than 15%. At the same time, the frequency response of the filter has no locking poles near the passband, and to obtain the frequency response with a high slope slope, an increase in the number of resonators is required, which leads to an increase in size and loss in the passband.

A wider bandwidth is provided by a microstrip filter (see USSR AS No. 1681344, publ. 09/30/91). The microstrip filter contains a dielectric substrate, on one side of which there is a metal base, and on the other side a conductor of the connecting line, to the ends of which the conductors of the input and output lines are connected. Perpendicularly open conductors are connected to the same edge of the connecting line conductor, at a distance of less than a quarter of the wavelength from each other, while the length of these conductors is less than a quarter of the wavelength. The other edge of the conductor of the connecting line along the entire length is connected to the metal base, while its width is less than a quarter of the wavelength. The disadvantage of the filter is the low slope of the slope of the frequency response from the low frequencies, as well as the need to connect the conductor to the metal base.

Closest to the claimed one is a loop-pass bandpass filter with half-wave resonators (see. Reference on elements of strip technology. Edited by A. L. Feldstein. - M .: Communication. 1979 p. 196 Fig. 7.7a), selected as prototype. Known filter contains a conductor of the connecting line, the ends of which are the input and output of the filter. To the conductor of the connecting line, at a quarter of the wavelength of each other, to its opposite edges are connected perpendicularly from both sides, open at the ends, conductors, the total length of two conductors connected on opposite sides is equal to half the wavelength. The length of the conductors located on one side of the conductor of the connecting line is less than the lengths of the conductors located on the other side. The filter allows you to implement different bandwidths by changing the location of the inclusion of half-wave conductors to the connecting line. It has locking poles below and above the passband at frequencies where the length of the line segments formed by the connected conductors is equal to a quarter of the wavelength. The disadvantage of the prototype is that it has insufficient steepness of the frequency response, to increase which it is necessary to increase the number of resonators, which will lead to an increase in size and loss in the passband. In addition, the filter has narrow locking bands below and above the passband.

The purpose of the utility model is to increase the steepness of the slopes of the frequency response and the expansion of the fence strip with a decrease in size. To achieve this goal, a microstrip bandpass filter containing a dielectric substrate, on one side of which a metal base is placed, and on the other side is a connecting line conductor, at which the ends are the input and output of the filter, and connected to the opposite edges perpendicularly from both sides of the conductors, while the lengths of these conductors located on one side of the conductor of the connecting line are less than the lengths of conductors located on the other side, according to the utility model , additionally introduced segments of conductors, some ends of which are connected to the ends of the conductors, while others are open and electromagnetically coupled to each other.

In one embodiment, the segments of additional conductors are located along the axis of the main ones, and their width is greater than the width of the main conductors.

In another embodiment, the segments of additional conductors are located between the main conductors, parallel to them.

The introduction of additional electromagnetically coupled conductors makes it possible to provide additional locking poles below and above the passband, due to which to obtain a high slope of the slope of the frequency response and widening of the locking band with a small number of resonators. The location of the additional conductors between the main ones, parallel to them, reduces the size of the filter.

As a result of the search, no information was found that allows us to conclude that the distinguishing features of the claimed technical solution are known, therefore, the claimed technical solution meets the novelty condition

In FIG. 1 shows the topology (a) and frequency response (b) of the proposed microstrip bandpass filter of three resonators with extended electromagnetically coupled segments of conductors, FIG. 2 - topology (a) and frequency response (b) of the proposed microstrip bandpass filter with parallel conductors. Moreover, in FIG. 1b and 2b, the solid line is the attenuation of the filter, the scale on the left; dotted line - VSWR, scale on the right.

The proposed microstrip bandpass filter (Fig. 1a, Fig. 2a) contains a dielectric substrate 1, on one side of which there is a metal base, and on the other side a conductor 2 of the connecting line, the ends of which are the input and output of the filter. Conductors 3, 4, 5 and 6, 7, 8 are connected to opposite edges of conductor 2 on both sides. Additional segments of conductors 9, 10, 11 and 12, 13, 14, the other ends of which are open and connected at the ends of these conductors, are respectively connected at one end. are electromagnetically interconnected ..

Conductors 3, 9, 6, 12 form the first filter cavity, conductors 4, 10, 7, 13 form the second resonator, conductors 5, 8, 11, 14 form the third resonator. In this case, the filter resonators are connected through a line segment of the conductor 2 and are connected at the open ends by electromagnetic coupling.

In the filter shown in FIG. 1a, the width of the conductors 9, 10, 11 and 12, 13, 14 is greater than the width of the conductors 3, 4, 5, 6, 7, 8 and is determined by the gap between the conductors 9, 10, 11 and 12, 13, 14 and the length of the line segment conductor 2 between the connection points of the resonators 3 and 4, 4 and 5 (step resonators).

In the filter shown in FIG. 2a, conductors 9, 10, 11 and 12, 13, 14 are located between conductors 3, 4, 5, 6, 7, 8 parallel to them, forming hairpin resonators.

The lengths of the segments of the connecting line of the conductor 2 between adjacent resonators of the filter are less than a quarter of the wavelength, while the smaller its length, the smaller the width.

The lengths of the conductors of the filter resonators on one side of the conductor of the connecting line of the conductor 2 are less than on the other side, and this difference is determined by the bandwidth, while it is greater for filters with a wider passband. The total length of the conductors of each resonator is selected from the resonance condition at the middle frequency of the filter passband. The length of the sections of the resonators connected by electromagnetic coupling, that is, the conductors 9, 10, 11 and 12, 13, 14, is approximately equal to the length of the sections of the filter cavities not connected by electromagnetic coupling, that is, the conductors 3, 4, 5 and 6, 7, 8. The gap between the conductors 9, 10, 11 and 12, 13, 14 is determined by the required value of the electromagnetic coupling, which provides the attenuation pole at a given frequency behind the filter passband. The smaller the gap, the stronger the electromagnetic coupling and the closer the attenuation pole frequency to the passband. In this case, the electromagnetic coupling between the conductors 9, 10, 11 of the "short" part of the resonators provides a decay pole at frequencies above the passband, the electromagnetic coupling between the conductors 12, 13, 14 of the "long" part of the resonators provides a decay pole at frequencies below the passband.

The proposed microstrip bandpass filter operates as follows. The microwave signal entering the input passes through conductor 2 to the output in the passband of the filter, since the total input conductivity of each strip resonator formed by conductors 3-14 at the resonance frequency is zero, and with a slight detuning, they cancel each other, since the electric the length of the communication line between the resonators is 90 degrees. When the length of the segment is less than a quarter of the wavelength, this condition is provided by a small elongation of the conductors 3, 4, 5.

At frequencies beyond the passband of the filter, the resonators bypass the connecting line 2, and the attenuation of the signal increases with the detuning from the cutoff frequencies of the passband of the filter. At the same time, a small part of the signal passes between the connection points of neighboring resonators through electromagnetic links between them. If the amplitudes and phase difference are equal to 180 degrees, the signal passing through conductor 2 through the resonators is compensated by the signal passing through the resonator conductors through the capacitive gap. In this case, full compensation takes place, i.e. pole attenuation. Equality of amplitudes on the slope of the frequency response of the filter is ensured by the size of the gap between adjacent resonators. The required phase difference is provided by the lengths of the conductors and the connecting line. The analysis shows that the electromagnetic coupling of the "short" part of the resonators provides the attenuation pole at frequencies above the passband, the electromagnetic coupling of the "long" part of the resonators provides the attenuation pole at frequencies below the passband. Perhaps setting the pole to a specific frequency, such as the frequency of the local oscillator. With an increase in the number of filter resonators, the number of locking poles increases, due to which an increase in attenuation in the filter locking band is achieved.

On fig 1.b and fig. 2.b presents the calculated frequency response of a three-link filter with step and with hairpin resonators, respectively. It can be seen that the proposed filter provides additional locking poles on both sides of the passband.

The technical and economic effect of the proposed microstrip bandpass filter is as follows. The introduction of connected lines into the composition of the resonators makes it possible to obtain high blocking at given frequencies near the passband with a small number of resonators in the filter and, therefore, with its small dimensions.

The enterprise produced prototypes of a frequency converter with the proposed filters used to suppress the power of the mixer at the local oscillator frequency and the frequencies of the mirror channel at the signal input. During the experimental verification, results were obtained confirming the achievement of the goal. The filters provided suppression of power at the local oscillator frequency and the frequencies of the mirror channel at least 35 dB with additional signal losses of no more than 0.8 dB. Thus, the proposed filter, in comparison with the prototype, provided an increase in attenuation with a small detuning from the passband and a wide obstacle band. At the same time, since the filter contained only three “rolled-up” resonators, it occupied a small area on the board.

Claims (3)

1. Microstrip band-pass filter containing a dielectric substrate, on one side of which is a metal base, and on the other side is a conductor of the connecting line, the ends of which are the input and output of the filter, and conductors are connected perpendicular to both sides of the filter, while the lengths of these conductors located on one side of the conductor of the connecting line are less than the lengths of conductors located on the other side, characterized in that they are additionally introduced from cutt ing conductors, one ends of which are connected to the ends of the conductors, and the other open and electromagnetically linked. 2. Microstrip bandpass filter according to claim 1, characterized in that the segments of the additional conductors are located along the axis of the main ones, and their width is greater than the width of the main conductors. 3. Microstrip bandpass filter according to claim 1, characterized in that the segments of the additional conductors are located between the main conductors, parallel to them.

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