RU51789U1 - BAND FILTER FILTER - Google Patents

Abstract

The utility model relates to microwave technology and allows to reduce losses in the passband of the filter, to provide wider passbands in combination with simplification of tuning. The filter contains a segment of the waveguide 1, shorted at both ends by the walls 2, consisting of n hollow sections 3 made in the form of hollow conductive cylinders, conductive walls 4 with communication holes 5, open disk dielectric resonators 6 installed each in the corresponding section 3, starting with the second section from the edge of the length of the waveguide and ending with the (n-1) th section of the length of the waveguide 1, and fixed in it with the holder 7, coaxial resonators 8, made in each of the extreme hollow sections 3, each of which is formed by conducting them with a rod 9 mounted on one of the walls 10 of the waveguide 1, tuning elements 11 installed in the second and (n-2) hollow sections, conductive screws 12 for setting the resonant frequency of the resonators 8, each installed coaxially with the conducting rod 9 on the wall 13 of the extreme hollow sections 3 segments of the waveguide 1, conductive screws 14, communication settings between open resonators 6 installed in the second and (n-1) -th hollow sections and resonators 8, coaxial connectors 15 for communication with supply lines mounted on the end walls, communication elements 16 s resonantly 8 connected to central conductors 17 of connectors 15. After the connectors 15 connecting in circuit with the microwave propagating wave coupling elements 16 provide input and energy output to a filter system - the transmission line. Separate sections of the filter 3, interconnected to form a segment of the waveguide 1, beyond the working frequency band of the filter, which eliminates out-of-band energy transfer between the input and output and provides electromagnetic coupling between open disk dielectric resonators 6.

Description

The utility model relates to microwave technology and is intended for use in the decimeter and long wavelengths of the centimeter wavelength range.

Known band-pass filters with planar arrangement of open dielectric resonators (see Dielectric resonators / under the editorship of Professor M.E. Ilchenko. - M .: Radio and communications, 1989, 328 p., P. 250, Fig. 10.12), containing a segment of the waveguide filter beyond the working frequency band, in which open disk dielectric resonators with a lower vibration mode are placed on dielectric supports.

Planar filters are characterized by a wide range of parasitic passband frequencies close to the working frequency band due to higher vibration modes of open disk dielectric resonators, which increases as the dielectric density of the supports increases. In addition, such filters are characterized by higher bandwidth losses in combination with narrower achievable bandwidths than bandpass filters with a coaxial arrangement of open disk dielectric resonators.

Known band-pass filters with coaxial placement of open disk dielectric resonators (see. Dielectric resonators / under the editorship of Professor M.E. Ilchenko. - M .: Radio and communications, 1989, 328 p., S.246-253, Fig. 10.10), containing a segment of a cylindrical waveguide that acts as a screen beyond the filter in the working frequency band, consisting of n hollow cylindrical sections according to the number of filter links, which are made with ledges on the outer and inner diameters at the ends and which partially enter one another, and open disk dielectric resonators with a lower mode of vibration, the number of which is equal to the number of filter links and each of which is mounted coaxially in the corresponding hollow cylindrical section and is held in it with

using a dielectric sleeve, and at each end of the screen using threaded connections, terminal hollow cylindrical metal sections are installed, each of which is shorted at one end with a metal end wall perpendicular to the longitudinal axis of the screen, on which communication elements are made for communication with the supply lines, made in in the form of conductors connected to the central conductors of coaxial connectors mounted on the lateral cylindrical surface of the terminal hollow metal sections.

However, such band-pass filters are characterized by a wide range of spurious pass-bands due to higher vibration modes of open disk dielectric resonators. The ordinary value of detuning with the use of special measures, including the use of dielectric bushings made of dielectrics with a small (unit) relative permittivity, is approximately 30%. Moreover, for filters designed to operate in high power paths, in which to ensure good heat dissipation from open disk dielectric resonators, dielectric bushings made of denser dielectrics (for example, boronite, polycor, quartz, etc.) are used, the parasitic pass bands are sharply approaching to the working frequency band (up to units of percent) due to the approach of higher types of oscillations to the frequency of the lowest (working) type.

Closest to the proposed bandpass filter is a filter (see "The Design of Band-Pass Filters made of Both Dielectric and coaxial Resonators" by Hee-yong Hwang and etc. - RF & Microwave Products Head office, KMW Inc.) a rectangular waveguide, which acts as a screen beyond the filter in the working frequency band and shorted at both ends by end walls, consisting of n hollow sections that are formed by internal transverse walls with communication holes, and (n-2) open disk dielectric resonators with a lower mode of vibration, setting every

in the corresponding hollow section, starting from the second section from the edge of a segment of a rectangular waveguide and ending with the (n-1) th section of a segment of a rectangular waveguide, and is held in it with a dielectric stand, and all the end walls of open disk dielectric resonators are parallel to one of the walls of the segment a rectangular waveguide, and in each of the extreme sections of the screen there is a coaxial resonator formed by a conductive rod mounted on one of the walls of a segment of a rectangular waveguide and parallel to goy of its walls, tuning elements of the resonant frequencies of open disk dielectric resonators, made in the form of screws mounted on the walls of a segment of a rectangular waveguide parallel to the end walls of open disk dielectric resonators, tuning elements of the resonant frequency of coaxial resonators, made in the form of conductive screws installed coaxially conductive a rod on the wall of a segment of a rectangular waveguide, elements for setting communication between open disk dielectric resonators and between extreme open disk dielectric resonators and coaxial resonators, made in the form of conductive screws placed in communication holes in the inner transverse walls of a segment of a rectangular waveguide, coaxial connectors for communication with supply lines installed on the end walls, to the central conductors of which loop elements are connected communication with a coaxial resonator.

This technical solution provides through the use of coaxial resonators in the extreme sections additional suppression of spurious filter passband.

The disadvantages of this technical solution for the bandpass filter are the higher losses in the bandwidth inherent to filters with planarly placed dielectric resonators in combination with narrower achievable bandwidths than for bandpass filters with a coaxial arrangement of open disk

dielectric resonators, which is determined by the higher quality factor of resonant links with the coaxial placement of dielectric resonators than with their planar placement, the greater complexity of tuning, which is realized by conductive screws located in the communication holes in the internal transverse walls of a segment of a rectangular waveguide, generating additional spurious transmission channels.

The technical task of the proposed utility model is to reduce losses in the passband of the filter, providing wider passbands in combination with simplified settings.

The solution to this problem is achieved by the fact that the known filter containing a segment of the waveguide, with end walls located at both ends, includes n hollow sections, the first, second, (n-1) th and n-th hollow sections are separated by conductive walls with holes communication, and (n-2) open disk dielectric resonators with the lowest type of vibrations, each installed in the respective hollow section on the holders, starting from the second section from the edge of the waveguide segment and ending with the (n-1) th section of the waveguide segment, coaxial resonators, located in each of the extreme hollow sections, each of which is formed by a conductive rod mounted on one of the walls of the waveguide segment, the tuning elements of the resonant frequencies of the open disk dielectric resonators installed in the second and (n-2) hollow sections, which are made in the form of screws, mounted on the walls of a section of the waveguide parallel to the end walls of open disk dielectric resonators, conductive screws adjusting the resonant frequency of the coaxial resonators, each installed coaxially with a rod on the wall of the extreme hollow sections of the waveguide segment located in the communication holes in the walls separating the first, second, (n-1) and n-th hollow sections conductive screws for adjusting the communication of open disk dielectric resonators installed in the second and (n-1 ) th hollow sections and coaxial resonators, coaxial connectors connected to the supply lines,

located on the end walls, communication elements with a coaxial resonator connected to the central conductors of the coaxial connectors, the hollow sections are made in the form of hollow conductive cylinders, and the cylinders forming the first and second and (n-1) and n-th hollow sections are arranged orthogonally, their cylindrical surfaces intersect, forming holes in which conductive walls with a communication hole are located, coinciding with the surface of respectively the hollow conductive cylinders of the second and (n-1) -th hollow sections, and the cylinders from the second to ( n-2) -th hollow sections are coaxial, open disk dielectric resonators are mounted coaxially in hollow conducting cylinders, resonator holders are made axisymmetric, for example, in the form of dielectric bushings, in the center of which open disk dielectric resonators are installed, hollow sections from the second to (n -1) th are interconnected by threaded connections, the end walls are formed by the cylindrical surfaces of the hollow conductive cylinders of the first and nth hollow sections, respectively.

In addition, the elements of communication with the coaxial resonator can be made in the form of flat conductive washers, the planes of which are parallel to the generators of the conductive rods.

The holder of each open disk dielectric resonator can be made in the form of metal plates, the planes of which are oriented along the radius of the metal cylinders, with one of the ends of each of the metal plates abut against the cylindrical surface of the open disk dielectric resonator, and the opposite end of this metal plate is fixed relative to the inner surface hollow conductive cylinder.

The essence of the proposed technical solution of the band-pass filter is illustrated by drawings, in which figure 1 shows the band-pass filter, figure 2 shows the end hollow sections of the band-pass filter, figure 3 shows the holder of each open

disk dielectric resonator in the form of thin metal plates, figure 4 shows an example of the amplitude-frequency characteristic of a nine-link filter with a passband of 120 MHz and a loss in passband of less than 1 dB.

The band-pass filter contains a segment of the waveguide 1, which acts as a screen beyond the filter in the working frequency band and shorted at both ends by end walls 2, consisting of n hollow sections 3 made in the form of hollow conducting cylinders, conducting walls 4 with communication holes 5, open disk dielectric resonators 6, each installed in the corresponding hollow section 3, starting from the second section from the edge of the waveguide segment and ending with the (n-1) th section of the waveguide segment 1, and held therein by For 7, coaxial resonators 8, made in each of the extreme hollow sections 3, each of which is formed by a conductive rod 9, mounted on one of the walls 10 of the waveguide segment 1, tuning elements 11 of the resonant frequencies of the open disk dielectric resonators 6 installed in the second and ( n-2) hollow sections, conductive screws 12 adjusting the resonant frequency of coaxial resonators 8, each installed coaxially to the conductive rod 9 on the wall 13 of the extreme hollow sections 3 of the waveguide segment 1, conductive screws 14 adjusting the communication between open by disc disk dielectric resonators 6 installed in the second and (n-1) -th hollow sections and coaxial resonators 8, coaxial connectors 15 for communication with supply lines mounted on the end walls, communication elements 16 with coaxial resonator 8 connected to the central conductors 17 coaxial connectors 15.

The communication elements 16 with the coaxial resonator 8 are made in the form of flat conductive washers, the planes of which are parallel to the generators of the conductive rods 9.

In addition, the holder of each open disk dielectric resonator is made in the form of metal plates 18, the plane of which

In addition, the holder of each open disk dielectric resonator is made in the form of metal plates 18, the planes of which are oriented along the radius of the hollow conductive cylinders of the hollow sections 3, while one of the ends 19 of each of the metal plate 18 abuts against the cylindrical surface 20 of the open disk dielectric resonator 6, and the opposite end 21 of this metal plate 18 is fixed relative to the inner surface 22 of the hollow conductive cylinder of the hollow section 3.

The bandpass filter operates as follows.

After connecting the coaxial connectors 15 to the circuit with a propagating microwave wave, the communication elements 16 installed in the terminal hollow sections of the screen 3 provide input and output of energy in the filter-transmission line system. Separate hollow sections of the filter 3, made in the form of hollow conducting cylinders, interconnected form a segment of the waveguide 1, beyond the working frequency band of the filter, which eliminates out-of-band energy transfer between the input and output and provides electromagnetic coupling of open disk dielectric resonators 6 to each other.

The number of sections n determines the number of resonant links of the bandpass filter and is selected from the condition n≥3, where n is an integer, which in turn is associated with the form of the required frequency response of the filter. For example, a three-link filter typically implements a passband of the order of 1-1.5%, and a seven-link filter provides a bandwidth of 4-5%.

The threaded connections of the hollow conducting cylinders of the hollow sections 3 due to the possibility of changing the distances between the open disk dielectric resonators 6 allow adjusting the coupling coefficients between the open disk dielectric resonators 6. The coupling coefficients between the outermost ones and the coaxial resonators 8 are controlled by elements bonds formed by conductive core members

the transmission lines are controlled by communication elements 16. The tuning elements 11 of the resonant frequencies of the open disk dielectric resonators 6 installed in the second and (n-2) -th hollow sections allow you to adjust the change in the resonant frequencies of these resonators 6 that occurs when adjusting their connection with coaxial resonators 8. The conductive screws 12 adjusting the resonant frequency of the coaxial resonators 8 provide the adjustment of their resonant frequencies that occurs when adjusting their connection with open disk dielectric resonators 6 installed in the second and (n-2) -th hollow sections. The adjustment of the connection between the dielectric resonators 6 installed in the second and (n-2) -th hollow sections with coaxial resonators 8 is provided with conductive screws 14.

The implementation in the filter design of the principle of coaxial placement of open disk dielectric resonators 6 in combination with the implementation of extreme resonant links in the form of coaxial resonators 8 made it possible to comprehensively solve the problem of creating easy-to-configure filters with high parameters, namely, to suppress spurious passband (due to the properties of coaxial resonators ) and at the same time provide the device with the advantages of filters with coaxial placement of dielectric resonators.

It was experimentally established that the implementation of the holders 7 of each open disk dielectric resonator 6 in the form of metal plates 18, the planes of which are oriented along the radius of the hollow conducting cylinders of the hollow sections 3, allows to exclude spurious passband in the coaxial filter on open disk dielectric resonators 6 associated with their nearest ( second) type of oscillation. This is confirmed by the frequency response.

In addition, when one of the ends 19 of each of the thin metal plates 18 abuts against the cylindrical surface 20 of the open disk dielectric resonator 6, and the opposite end 21 of this metal

the plate 18 is fixed relative to the inner surface 22 of the hollow conducting cylinder of the hollow section 3, this embodiment of the holders 7 can dramatically improve the heat removal from the dielectric resonators 6, which allows the use of such a filter design in high power paths.

In addition, it was experimentally established that when the communication elements 16 with the coaxial resonator 8 are made in the form of flat conductive washers, the planes of which are parallel to the generatrix of the conductive rods 9, a smoother adjustment of the required connection of the coaxial resonators 8 with the supply lines is achieved than in the case of the loop used in the prototype elements of communication.

The application of the proposed technical solutions made it possible to create nine-band bandpass filters with open disk dielectric resonators in the frequency range 4-5 GHz (passband ~ 3%, loss in the band no worse than 1.1 dB), which have a spurious passband tuning at 1 GHz, and within the locking band providing a level of attenuation> -80 dB, designed to work in paths with a power level of 100 watts.

Claims (3)

1. A band-pass filter containing a segment of a waveguide with end walls located at both ends, including n hollow sections, the first, second, (n-1) th and n-th hollow sections being separated by conductive walls with communication holes, and (n-2) open disk dielectric resonators with the lowest type of vibrations, each installed in the corresponding hollow section on the holders, starting from the second section from the edge of the waveguide segment and ending with the (n-1) th section of the waveguide segment, coaxial resonators located in each from the extreme sex sections, each of which is formed by a conductive rod mounted on one of the walls of the waveguide segment, tuning elements of the resonant frequencies of the open disk dielectric resonators installed in the second and (n-2) hollow sections, which are made in the form of screws mounted on the walls of the waveguide segment parallel to the end walls of open disk dielectric resonators, conductive screws for adjusting the resonant frequency of coaxial resonators, each installed coaxially to the conductive rod on the wall of the extreme fields sections of the waveguide segment located in the communication holes in the walls separating the first, second, (n-1) and n-th hollow sections conductive screws for adjusting the communication of open disk dielectric resonators installed in the second and (n-1) -th hollow sections and coaxial resonators, coaxial connectors connected to the supply lines located on the end walls, communication elements with a coaxial resonator connected to the central conductors of the coaxial connectors, characterized in that the hollow sections are made in the form of hollow wires cylinder, and the cylinder generators of the first and second and (n-1) and n-th hollow sections are arranged orthogonally, their cylindrical surfaces intersect, forming holes in which conductive walls with a communication hole are located, coinciding with the surface, respectively, of the hollow conductive cylinders of the second and (n-1) -th hollow sections, and cylinders from the second to (n-2) -th hollow sections are coaxial, open disk dielectric resonators are installed coaxially in the hollow conductive cylinders, the holders of the resonators are made axisymmetric for example, in the form of dielectric bushings, in the center of which open disk dielectric resonators are installed, hollow sections with the second through the (n-1) th are interconnected by threaded connections, the end walls are formed by the cylindrical surfaces of the hollow conducting cylinders of the first and n-th hollow sections, respectively. 2. The band-pass filter according to claim 1, characterized in that the communication elements with the coaxial resonator are made in the form of flat conductive washers, the planes of which are parallel to the generators of the conductive rods. 3. The band-pass filter according to claims 1 and 2, characterized in that the holder of each open disk dielectric resonator is made in the form of metal plates, the planes of which are oriented along the radius of the hollow metal cylinders, while one of the ends of each of the metal plates abuts against a cylindrical the surface of the open disk dielectric resonator, and the opposite end of this metal plate is fixed relative to the inner surface of the hollow conductive cylinder.