SU1626274A1 - Tunable bandpass filter with magnetostatic waves - Google Patents

Abstract

The invention relates to a microwave technique. The purpose of the invention is to increase attenuation. The input is outside the passband. The microwave signal supplied to the input transducer 7, excites in the input resonator 4 oscillations of various types. Through the slit 9, the transmission coefficient of which is maximum for the oscillations of the main type and drops sharply for the higher oscillation types, the signal enters the coupling element 6, which reflects it at a right angle to the slit 10, identical to the slit 9, while the reflection coefficient modulus is close to unit only for magnetostatic waves with a low wavenumber. The slit 10 excites the output resonator 5, the energy of which is transmitted to the output transducer 8. The adjustment of the bandwidth and the losses in it is made by independently changing the width of the slits 9 and 10. 2 Il. 00 С о. About about VJ 1 7 H M Figure 1

Description

This invention relates to a microwave technique.

The purpose of the invention is to increase attenuation outside the passband.

FIG. 1 shows a tunable bandpass filter on magnetostatic waves; in fig. 2 is a section A-A in FIG. one.

The filter contains a ferromagnetic film 1 placed on a dielectric substrate 2 with a conductive base 3, made on a ferromagnetic film 1 identical to the input 4 and output 5 resonators, which are connected by a coupling element 6 made in the form of a reflecting mirror. The input 4 and output 5 resonators are located symmetrically with respect to the communication element 6 and are orthogonal to one another and are connected with the input 7 and output 8 converters, respectively. In the ferromagnetic film 1 between the coupling element 6 and each on the resonators 4 and 5 there are slots 9 and 10 with the possibility of independently changing the width of each of them. The reflecting mirror is made in the form of a section 11 of a ferromagnetic film 1 with a thickness reduced by at least 40%, onto which a strip conductor 13 is installed through an inserted dielectric layer 12. the waves, and its reflecting side 14 is located at an angle of 45 ° to slots 9 and 10. The ferromagnetic film 1 is orthogonally magnetized by the field Ho.

The filter works as follows. The microwave signal supplied to the input transducer 7 with a frequency that coincides with the tuning frequency of the input resonator 4, excites oscillations of different types in the input resonator 4. Through the gap

9, the transmission coefficient of which is maximum for vibrations of the main type and sharply reduced for vibrations of higher types, the signal enters the coupling element 6, which reflects it at a right angle to the slit

10, while the reflection coefficient modulus is close to unity only for magnetostatic waves with small wavenumber values and decreases rapidly with increasing wavenumber. The magnetostatic wave reflected by the coupling element 6 through the slit 10, which, like the slit 9, attenuates higher-type oscillations, excites the output resonator 5, whose energy is transmitted to the output converter 8, where it is converted into a microwave signal. The frequency tuning of the filter is carried out by changing the magnitude of the external magnetic field Ho, and the adjustment of the bandwidth and the losses in it is independent of

the width of the slits 9 and 10 in the range from one to three thicknesses of the ferromagnetic film 1 beyond the boundaries of the section 11.

Due to the small diffraction divergence of magnetostatic waves with small wavenumbers and a sharp decrease in the reflection coefficient with increasing wavenumber upon reflection of magnetostatic waves from coupling element 6, it is possible to achieve an additional positive effect — a reduction in transmission loss.

In the case of applying a filter as a frequency setting element in the feedback circuit of the generator to eliminate

when the generator is modulated in a wide frequency band and multi-mode, the thickness of the ferromagnetic film 1 in section 11 must be at least 0.4 of its thickness outside this section.

Claims (1)

Claims of Invention A tunable magnetostatic band-pass filter containing an orthogonally magnetized ferromagnetic film that is placed on a dielectric substrate with a conductive base, made on a ferromagnetic film identical to the input and output resonators, which are connected a coupling element, made in the form of a reflecting mirror, with input and output converters, respectively; a ferromagnetic film between the coupling element and each of the resonators slits are made with the possibility of independently changing the width of each of them, and the reflecting mirror is made in the form of a section of a ferromagnetic film with a thickness reduced by at least 40% 0 which has a strip conductor installed through the injected dielectric layer, the width of which is chosen to be more than half the length of the magnetostatic wave and which is galvanically connected to the conductive 5 with a base, and its reflecting side is located at an angle of 45 ° to the slits.