RU2758540C1 - Frequency multiplier on a thin magnetic film - Google Patents

Abstract

FIELD: ultra-high frequencies equipment.

SUBSTANCE: invention relates to the ultra-high frequencies equipment of and is intended for multiplying the frequency of microwave signals in communication, radar, radio navigation, various measuring and special radio equipment systems. The frequency multiplier on a thin magnetic film contains an irregular quarter-wave resonator grounded from one edge. The dimensions of the resonator conductors are selected in such a way that the resonant frequency of its second mode of oscillation is exactly twice the resonant frequency of the first mode of oscillation, and the resonant frequency of the third mode is not a multiple of the resonant frequency of the first mode of oscillation. A thin magnetic film is placed between the strip conductors of the resonator and the grounded base near the short-circuited part of the resonator.

EFFECT: increase in the conversion coefficient of the device while maintaining radiation resistance.

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Description

The invention relates to microwave technology and is intended to multiply the frequency of microwave signals in communication systems, radar, radio navigation, various measuring and special radio equipment.

Known frequency multiplier [RF patent No. 2108656, publ. 10.04.1998, Bul. No. 10], containing a cascade-connected input and output microstrip filters and varactor diodes connected in parallel to them. The output resonator of the input filter is simultaneously the input resonator of the output filter; one or both halves of its strip conductor are shorted to ground through varactor diodes. The first resonant frequency of the output resonator of the input filter is equal to the frequency of the input signal, the second resonant frequency is equal to the frequency of the output signal. The first resonant frequency of the input resonator of the input filter is equal to the frequency of the input signal, the third resonant frequency is higher than the frequency of the output signal, and the input power enters it at the point of the voltage node at the frequency of the second resonance. The second resonant frequency of the output resonator of the output filter is equal to the frequency of the output signal, and the output signal is taken from the resonator at the point of the voltage node at the frequency of the input signal. The first resonant frequency of the output resonator of the output filter is equal to the frequency of the output power.

The disadvantage of the design of the known device is low radiation resistance, since it uses a varactor diode as a nonlinear element.

The closest analogue in terms of a set of essential features is a frequency multiplier [RF patent No. 2734448, publ. 10/16/2020, Bul. No. 29], containing cascade-connected input and output microstrip filters, in which the output resonator of the input filter is simultaneously the input resonator of the output filter, its first resonant frequency is equal to the frequency of the input signal, the second resonant frequency of the output resonator of the input filter is equal to the frequency of the output signal of the device, when the resonant frequency of the output resonator of the output filter is also equal to the frequency of the output signal. The device uses a magnetic film placed on the strip conductor of the output resonator of the input filter as a nonlinear element. The device has increased radiation resistance, since it uses a thin magnetic film as a nonlinear element.

A significant drawback of the prototype design is the low conversion coefficient (with an input signal frequency of 1 GHz and an input power of 10 W, the conversion coefficient is only 0.01%).

The technical result of the claimed invention is to increase the conversion factor of the device while maintaining radiation resistance.

The claimed technical result is achieved by the fact that in a frequency multiplier on a thin magnetic film containing a screen, a dielectric substrate, segments of microstrip lines and a thin magnetic film used as a nonlinear element, it is new that it contains segments of microstrip lines on a dielectric substrate together with a segment of an asymmetric air strip line form an irregular quarter-wave resonator, the dimensions of the strip conductors of which are selected in such a way that the resonant frequency of its second vibration mode is exactly two times higher than the resonant frequency of the first vibration mode ƒ ₁ , and the resonant frequency of the third vibration mode is not a multiple of the frequency ƒ ₁ , in this case, a thin magnetic film is placed between the strip conductor and the screen in a segment of an asymmetrical air strip line, one end of which is connected to the screen.

Comparative analysis with the prototype shows that the claimed device is characterized by the presence of an irregular quarter-wave resonator, in which one end of a segment of an asymmetrical air stripe line containing a thin magnetic film is connected to the screen.

A significant difference is that the dimensions of the strip conductors of the quarter-wave resonator are selected in such a way that the resonant frequency of its second oscillation mode is exactly twice the resonance frequency of the first oscillation mode, and the resonant frequency of the third oscillation mode is not a multiple of the resonance frequency of the first oscillation mode.

Another significant difference is that a thin magnetic film is placed between the strip conductor and the screen in a section of an asymmetrical air stripe line, one end of which is connected to the screen.

Thus, the above-listed features distinguishing from the prototype make it possible to conclude that the proposed technical solution meets the "novelty" criterion.

The features that distinguish the claimed technical solution from the prototype are not identified in other technical solutions and, therefore, ensure compliance with the "inventive step" criterion for the claimed solution.

The essence of the invention is illustrated by drawings: FIG. 1 shows the design of the inventive frequency multiplier on a thin magnetic film; in fig. 2 shows the orientation of the axis of easy magnetization (ELN) of a thin magnetic film, as well as the direction of the high-frequency H _microwave and constant magnetizing H ₀ magnetic fields in the device; in fig. 3 shows the amplitude-frequency characteristic of the frequency multiplier, FIG. 4 shows its transfer characteristic.

The claimed frequency multiplier on a thin magnetic film contains (Fig. 1) a metal base (1) on which a dielectric substrate (2) is placed. Sections of microstrip lines (3), (4) and (5) connected in series are applied on the substrate (2). A segment of a microstrip line (5) is connected to a conductor (6) of a segment of an asymmetrical air stripe line. The second end of the strip conductor (6) is connected to the base (1). Thus, the strip conductors (3), (4), (5) and (6) form a quarter-wave resonator, at the point of connection of the conductor (6) with the base is the antinode of the microwave magnetic field, both for the first oscillation mode of the resonator and for the second ... Under the conductor (6), there is a thin magnetic film (TMF), for example, made of permalloy, deposited on a substrate (7). The lengths and widths of the conductors (3), (4), (5) and (6) are selected so that the ratio of the resonant frequency of the second mode of resonator oscillations to the resonant frequency of the first mode ƒ _{1 is} equal to 2, and the resonant frequency of the third mode is not a multiple of the frequency ƒ ₁ ... A signal source is connected to the strip conductor (3) through the coupling capacitance (8), and the signal with doubled frequency is removed from the strip conductor (5) through the coupling capacitance (9). FIG. 2 shows a substrate (7) with a thin magnetic film and the orientation of the easy magnetization axis (EA) of a thin magnetic film, as well as the directions of the high-frequency H _microwave and constant magnetizing H ₀ magnetic fields in the device. The orientation of the ELL of a thin magnetic film coincides with the direction of the high-frequency magnetic field H of the _microwave generated by the microwave current in the strip line (6, Fig. 1). An external source creates a constant magnetizing field H ₀ (Fig. 2) at an angle ϕ to the EA.

The frequency multiplier on a thin magnetic film works as follows. The input power of the signal with a frequency ƒ _{1 is} fed through the coupling capacitance (8) to the input of a quarter-wave resonator (Fig. 1) formed by strip conductors (3), (4), (5) and (6). In a quarter-wave resonator, electromagnetic oscillations are excited at its resonance frequency ƒ ₁ , under the influence of which forced oscillations of the magnetic moment in the ferromagnetic film occur, in the spectrum of which there are harmonic frequencies that are multiples of the frequency ƒ ₁ . Oscillations of the magnetic moment in the film create an alternating magnetic flux at all harmonics, generating electric microwave oscillations in the stripline conductor of the resonator. However, the signal in the strip resonator is generated most efficiently from the second harmonic of the oscillations of the magnetic moment, since its frequency 2ƒ ₁ coincides with the resonant frequency of the second oscillation mode of the quarter-wave resonator. The output power of the generated signal having a frequency of 2ƒ ₁ is removed through the coupling capacitance (9).

To illustrate the performance of the claimed device, a working model of the frequency multiplier on a thin magnetic film was made (Fig. 1). We used a dielectric substrate (2) with a relative permittivity ε = 3.55, a thickness of 0.5 mm, and dimensions of 16 mm × 25.6 mm. Sections of microstrip lines (3), (4), and (5) are 2.45 mm × 4.1 mm, 15.3 mm × 0.2 mm, and 8.75 mm × 4.65 mm, respectively. The conductor (6) is made 1 mm wide and 5.9 mm long. The device is designed to double the frequency of the input signal ƒ ₁ = 1 GHz. A thin single-layer magnetic film of permalloy of composition Ni ₈₀ Fe ₂₀ , 100 nm thick, obtained by vacuum deposition on a glass substrate 0.5 mm thick, was placed between the conductor (6) and the metal base (1). Uniaxial magnetic anisotropy in the TMF plane was induced by a planar constant magnetic field applied during film deposition, while the induced anisotropy field was H _k = 3.3 Oe. A uniform uniform magnetizing field H ₀ = 7.2 Oe was applied at an angle ϕ = 35 ° to the easy magnetization axis TMP. Surface-mounted capacitors with a nominal capacity of 0.5 pF were used as coupling capacitors (8) and (9) to provide the necessary degree of coupling of the quarter-wave resonator with external transmission lines. The overall dimensions of the device were 16 mm × 31.5 mm. To suppress higher harmonics of the microwave generator during testing, it was connected to the input of the device through a narrow-band band-pass filter with a central frequency of 1 GHz, and the output of the device was connected to a spectrum analyzer. FIG. 3 shows the frequency response of the multiplier. It can be seen that the resonant frequency of the second oscillation mode of the multiplier is exactly two times higher than the resonant frequency of the first oscillation mode ƒ ₁ , and the resonant frequency of the third oscillation mode is not a multiple of ƒ ₁ . FIG. 4 shows the transfer characteristic of the multiplier, showing the dependence of the output power of the signal at a frequency of the second harmonic of 2 GHz on the power of the input signal at a frequency of 1 GHz. With an input power of 2150 mW, the output power was 17.6 mW, which corresponds to the conversion factor of the device equal to 0.8% (the conversion factor of the prototype design is 80 times less - 0.01%).

Claims (1)

A frequency multiplier on a thin magnetic film containing a screen, a dielectric substrate, segments of microstrip lines and a thin magnetic film used as a nonlinear element, characterized in that the segments of microstrip lines on a dielectric substrate together with a segment of an asymmetric air stripe line form an irregular quarter-wave resonator , the dimensions of the strip conductors of which are selected in such a way that the resonant frequency of its second vibration mode is exactly two times higher than the resonant frequency of the first vibration mode f ₁ , and the resonant frequency of the third vibration mode is not a multiple of the frequency f ₁ , while a thin magnetic film is placed between the strip conductor and screen in a segment of an asymmetrical air stripe line, one end of which is connected to the screen.

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