RU2811373C1 - Microwave filter - Google Patents

Abstract

FIELD: control devices.

SUBSTANCE: microwave filter contains input and output transmission lines, between which there is a coupled resonator made of two cascaded elements, each of which contains two transmission line segments of the same length, connected electromagnetically, with the input transmission line connected to the first end of the first segment of the first element, the first end of the second segment of the first element is open, the first end of the second segment of the first element is open, the second end of the second segment of the first element is connected to the first end of the first segment of the second element, the second end of the first segment of the second element is open, the second end of the second segment of the second element is connected to the output transmission line. The resonator contains two identical resistors, one end of each resistor is grounded through a section of the transmission line, and the second end of the first resistor is connected to the second end of the first section of the first element, and the second end of the second resistor is connected to the first end of the second section of the second element. The length of each section transmission line is a multiple of an odd number of a quarter of the wavelength propagating in this section of the transmission line at the central frequency.

EFFECT: suppressing reflections of the microwave signal outside the operating frequency band of the filter and increasing the steepness of the edges of the transmission coefficient of the microwave filter.

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Description

The invention relates to microwave devices, namely to band-pass microwave filters.

Microwave filters are designed to pass a microwave signal with a frequency that lies within the operating frequency band, and block a microwave signal with a frequency that lies outside the operating frequency band.

A microwave filter is known, containing two transmission lines with identical wave impedances, one is intended for the input of the microwave signal, the other for the output, two sections of the transmission line, while one end of the first section of the transmission line of the first link is connected to the transmission line at the input, the other - with one end of the second transmission line segment, the other end of the second transmission line segment is connected to the output transmission line.

In this case, the lengths of the first and second sections of the transmission line are multiples of an odd number of quarters of the wavelengths propagating in these sections of the transmission line at the central frequency of the operating passband of the microwave filter, and have wave impedances that differ by an order of magnitude [Almazov - Dolzhenko K.I., Korolev A .N. Technical electrodynamics Fig. 4.124].

In such a microwave filter, a section of a transmission line with a large value of wave impedance is equivalent to a series inductance, and a section of a transmission line with a small value of wave resistance is equivalent to a parallel capacitance, so it has low microwave losses at low frequencies and high losses at high frequencies.

Such a filter allows filtering a signal only at low frequencies (from frequency f = 0 to cutoff frequency fc) and does not allow filtering in the operating frequency band, limited by the lower f1 and upper f2 frequencies of the operating band.

A known microwave filter contains input and output transmission lines, between which there is a connected resonator, which is made of two cascade-connected elements, each of which contains two transmission line segments of the same length, connected electromagnetically, with the input transmission line connected to the end of the first segment of the first element, the first end of the second segment of the first element is open, its second end is connected to the first end of the first segment of the second element, the second end of this segment is open, the second end of the second segment of the second element is connected to the output transmission line [Almazov - Dolzhenko K.I., Korolev A.N. Technical electrodynamics Fig. 4.125] – prototype.

The presence in such a microwave filter of elements from two sections of connected transmission lines with a length that is a multiple of a corresponding odd number of quarter wavelengths ensures small microwave losses near the central frequency and large ones far from this frequency and thereby allows filtering of the microwave signal in the operating frequency band limited by the lower f1 and upper f2 frequencies of the operating band.

However, as in the analogue, in this filter the input microwave signal with a frequency lying outside the operating frequency band is reflected from the input of the microwave filter. Since in the vast majority of cases the microwave filter is not used on its own, but as part of various microwave devices (amplifiers, frequency converters, generators, etc.), such reflection of the microwave signal from the filter input, followed by its repeated re-reflection, leads to undesirable ( parasitic) oscillations ultimately lead to excitation of devices containing this microwave filter.

In addition, the coupled resonator is a resonant system, in which the frequency dependence of the transmission coefficient has a resonant (bell-shaped) form with relatively flat fronts. To increase the steepness of these fronts, a multi-link microwave filter design is used, which leads to an increase in its mass and size.

The technical result is the suppression of microwave signal reflections outside the operating frequency band of the microwave filter and an increase in the steepness of the microwave filter transmission coefficient edges.

The specified technical result is achieved by the fact that the microwave filter contains input and output transmission lines, between which there is a connected resonator, which is made of two cascade-connected elements, each of which contains two sections of the transmission line of the same length, connected electromagnetically, while the input transmission line connected to the end of the first segment of the first element, the first end of the second segment of the first element is open, its second end is connected to the first end of the first segment of the second element, the second end of this segment is open, the second end of the second segment of the second element is connected to the output transmission line. The resonator additionally contains a resistor, one of the ends of which is grounded, and the other is connected to one end of the first section of the transmission line, the other end of which is open, and through the second section of the transmission line with the second end of the second section of the first element, wherein the length of each section of the transmission line is an odd multiple the number of a quarter of the wavelength propagating in this section of the transmission line at the central frequency of the operating passband of the microwave filter.

Suppression of reflections outside the operating frequency band of the microwave filter is based on the physical laws of absorption of the microwave signal by a resistor and its conversion into thermal energy.

The proposed microwave filter, its essential features, namely the introduction of an additional resistor and two sections of the transmission line, each and in their totality, as well as in combination with known features, as well as in combination with the proposed connection of microwave filter elements, will provide, namely:

- the presence of an additional resistor, as an element for absorbing the microwave signal and converting it into thermal energy, ensures suppression of reflections of the microwave signal from the filter,

- the proposed inclusion of a resistor, one of the ends of which is grounded, and the other is connected to one end of the first section of the transmission line, the other end of which is open, and through the second section of the transmission line with the second end of the second section of the first element, with sections of the transmission line of the connected resonator, while the lengths of all segments are multiples of an odd number of quarter wavelengths, which ensures the active activation of the resistor as an element of microwave signal absorption only at frequencies lying outside the operating frequency band of the microwave filter, and as a result, suppression of reflections of the microwave signal outside the operating frequency band of the microwave filter,

- disconnecting the resistor within the operating frequency band leads to the fact that a resonator consisting of open at one ends and interconnected by other ends of the second segment of connected lines of the first element and the first segment of connected lines of the second element is connected to a resonator consisting of interconnected first and second sections of transmission lines, which leads to an increase in the total number of resonators, and as a consequence - to an increase in the steepness of the fronts of the microwave filter transmission coefficient,

- inclusion of a resistor using two additional segments of the transmission line in the middle of the resonator, consisting of a second segment of connected lines of the first element, open at one end and connected to each other by other ends, and a first segment of connected lines of the second element, ensures symmetry in the frequency dependence of the transmission coefficient of the microwave filter relative to the central one frequency, and therefore the symmetry of the fronts, and the fact that this junction is the antinode of the electromagnetic field is the implementation of the most effective conditions for the propagation of a signal with a frequency lying within the frequency band and, as a consequence, a symmetrical increase in the steepness of the fronts of the microwave filter transmission coefficient.

So, the claimed set of essential features implements the specified technical result, namely the suppression of microwave signal reflections outside the operating frequency band of the microwave filter and an increase in the steepness of the fronts of the microwave filter transmission coefficient.

The invention is illustrated by drawings.

Figure 1 shows the topology of the proposed microwave filter, where

- transmission lines at the input and output – 1, 2, respectively,

- the first and second sections of connected transmission lines – 3 and 4, respectively,

- third segment of transmission line 5,

- the first and second segments of the transmission line are 6 and 7, respectively.

In FIG. Figure 2 shows the electrical diagram of the proposed microwave filter, where

- additional resistor R,

- transmission line l _1,

- transmission line l ₂ .

In FIG. Figure 3 shows graphs of the dependence of the squared modules of the transmission coefficients Nper, reflection Kotr and absorption Kpogl on frequency.

An example of a specific implementation of the proposed microwave filter with output parameters:

- filter center frequency 3 GHz,

- operating frequency band 0.3 GHz,

The microwave filter is made in a hybrid integral design on a dielectric substrate - polycor - with a relative dielectric constant of 9.6 and a thickness of 0.5 mm using thin-film technology with a copper film thickness of 5 microns.

The transmission lines at input 1 and output 2, the first 3, second 4 and third 5 sections of the transmission line in each link are made with a characteristic impedance of 50 Ohms, which corresponds to a conductor width of 0.48 mm.

The resistor has a resistance of 50 Ohms and is made of tantalum film 5 microns thick, 0.48 mm wide and 0.48 mm long. Grounding of identical sections of the transmission line is carried out through metallized holes in the dielectric substrate with a diameter of 1 mm.

The wavelength propagating in sections of the transmission line at the central frequency of the operating band of the microwave filter is 40 mm.

The lengths of identical segments of the transmission line are 10 mm.

The proposed microwave filter works as follows.

A signal with a frequency lying within the operating frequency band is supplied to the filter input; such a signal is not absorbed or reflected in the filter, so this signal passes to the filter output practically unchanged.

A signal with a frequency lying outside the operating frequency band is supplied to the filter input; such a signal is not reflected in the filter, as was the case in the prototype, but is absorbed and therefore this signal practically does not pass to the filter output.

From the graphs of the dependences of the squared modules of the transmission coefficients Nper, absorption Kpogl and reflection Cotr on frequency (see Fig. 3) it follows that:

- in the operating frequency band (2.85 - 3.15 GHz) the square of the modulus of the transmission coefficient is noticeably equal to 0.75, and outside the band it sharply decreases to almost zero, that is, 75% of the microwave signal power is transmitted from the input to the output of the filter, and 25% of the microwave signal power is lost,

- in the operating frequency band, the square of the absorption coefficient modulus does not exceed 0.15, and outside the band it increases to 1, that is, in the operating frequency band the microwave signal is practically not absorbed, and outside the band almost the entire microwave signal is absorbed,

- the square of the modulus of the reflection coefficient both in the operating frequency band and beyond it does not exceed 0.1, that is, the reflected microwave signal is practically absent.

Thus, the proposed design of the microwave filter, in comparison with the prototype, will allow: to suppress the reflected microwave signal outside the operating frequency band of the microwave filter and increase the steepness of the fronts by 1.5 times.

Claims (1)

A microwave filter containing input and output transmission lines, between which there is a connected resonator, which is made of two cascade-connected elements, each of which contains two segments of the transmission line of the same length, connected electromagnetically, with the input transmission line connected to the end of the first segment of the first element, the first end of the second segment of the first element is open, its second end is connected to the first end of the first segment of the second element, the second end of this segment is open, the second end of the second segment of the second element is connected to the output transmission line, characterized in that the resonator additionally contains a resistor, one of the ends of which is grounded, and the other is connected to one end of the first section of the transmission line, the other end of which is open, and through the second section of the transmission line with the second end of the second section of the first element, the length of each section of the transmission line being an odd multiple the number of a quarter of the wavelength propagating in this section of the transmission line at the central frequency of the operating passband of the microwave filter.