RU2809348C1 - Magnonic tunable microwave generator - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: tunable magnon microwave generator is proposed, containing spin-wave delay line 2 made of a nanometer-thick microwave guide, input 3 and output 4 three-strip spin wave microantennas connected to coplanar transmission lines tapering towards the microantenna. Spin-wave delay line 2 is placed in magnetic system 5. The output of the spin-wave delay line is connected to the input of microwave amplifier 6. The output of microwave amplifier 6, through microwave directional coupler 7, is connected to the input three-strip microantenna of spin waves 3.

EFFECT: reduced size of a tunable magnon microwave oscillator and reduced phase noise level.

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Description

The proposed device relates to radio engineering and can be used in telecommunications and microwave measurement systems as a planar tunable source of a monochromatic signal with a low level of phase noise.

A microwave signal generator is known from the existing level of technology (Chang N. S., Hayamizu T., Matsuo Y., YIG-tuned Gunn effect oscillator // Proceedings of the IEEE. Vol. 55. No. 9. p. 1621-1621, 1967, US 3546624 A, US 3573659 A), consisting of a spherical resonator made of yttrium iron garnet (YIG resonator) located in a magnetic system, a microwave amplifier and a microwave directional coupler connected in series in a ring circuit. The frequency tuning of the generator is realized using a YIG resonator through a change in the bias field created by the magnetic system. The disadvantage of this generator is its bulky design. This disadvantage arises from the volumetric shape of the YIG resonator and the need to manually install the YIG resonator into the generator circuit.

A generator is known from existing publications (Nikitin A.B., Khabitueva E.I. Voltage-controlled broadband microwave generator // Problems of microwave electronics, T. 3, pp. 89-90, 2017), consisting of a silicon-germanium heterojunction a bipolar transistor, two control varicaps connected to the emitter and base of the transistor, as well as a matching load circuit made in microstrip design. This generator has a planar design due to the size of the elements that make up this generator. The frequency adjustment of the generated signal is carried out by changing the capacitance of the control varicaps through a change in voltage. The disadvantage of this generator is the high level of phase noise. This disadvantage is due to the low quality factor of the microstrip filter.

The closest in technical essence to the claimed generator is the microwave signal generator described in the article “TunablemagnetostaticwaveoscillatorsusingpureanddopedYIGfilms” (Ishak W., Reese E., Baer R. & Fowler M. TunablemagnetostaticwaveoscillatorsusingpureanddopedYIGfilms // IEEETransactionsonMagnetics, vol. 20, no. 5, p. 1229-1231, 1984). This microwave signal generator consists of a spin-wave delay line located in the magnetic system, a microwave amplifier and a microwave directional coupler connected in series in a ring circuit. This generator is manufactured in planar design. The frequency adjustment of the generated signal is carried out by adjusting the operating frequency of the frequency-setting element - the spin-wave delay line, by changing the magnetic field created by the magnetic system.

The known prototype design has a significant drawback, namely a high level of phase noise, and is large in size. This fact is due to the fact that the spin-wave delay line used in this design introduces large losses on the propagation of the microwave signal of the order of 20 dB/μs and is made on a thick film (Vapne G.M., Microwave devices on magnetostatic waves // Electronic Engineering Reviews, Series 1, Issue 8-1060, pp. 125, 1984). Increasing the delay time of the spin-wave delay line requires an increase in the distance between the spin-wave antennas, which leads to an increase in the size of the generator, measured in square centimeters, to an increase in losses in the ring system and to an increase in the level of phase noise.

The problem to be solved by the proposed technical solution is the miniaturization of a tunable magnon microwave oscillator with a low level of phase noise.

To solve the problem, the proposed design of a tunable microwave generator, just like the known one, contains a spin-wave delay line placed in a magnetic system, made with the ability to change the magnitude of the bias field to tune the resonant frequencies, a microwave amplifier, the output of which is connected to the input antenna through a microwave directional coupler, the output antenna is connected to a microwave amplifier. But, unlike the known solution, in the proposed device the delay line is made on the basis of a nanometer-thick film microwave guide, and each antenna is made in the form of a three-strip microantenna connected to a coplanar transmission line tapering to the microantenna, and the width of the microstrips is selected to ensure matching and decoupling between the antennas, while the ends of the central and side strips of the microantennas are connected, and the beginning of the central strip is connected to the central signal strip of the coplanar transmission line, while the beginnings of the side strips are connected to the grounded side electrodes of the coplanar transmission line, and the monochromatic microwave signal created by the system is output from the generator using a microwave directional coupler.

The technical result consists in reducing the size of the generator. This result is achieved by reducing the thickness of the YIG film and switching from a mounted to a planar design of the generator. As the thickness of the spin-wave delay line decreases, the propagation losses of the microwave signal increase. To reduce losses, it is necessary to reduce the distance between the antennas, but at the same time the electromagnetic interference from the input spin-wave antenna to the output one will increase. The specially developed three-strip antenna design allows reducing electromagnetic interference.

The invention is illustrated by drawings. In fig. Figure 1 shows a block diagram of a useful generator model. In fig. Figure 2 shows the results of calculating the pickup from the input antenna to the output antenna in the absence of a ferromagnetic film. In fig. Figure 3 shows the result of a theoretical calculation of the proposed generator design up to the generation threshold. In fig. Figure 4 shows the results of an experimental and theoretical study of the phase noise of a magnon tunable microwave oscillator.

Let us consider the design of the microwave generator shown in Fig. 1. A YIG layer is applied to gallium gadolinium garnet (GGG) substrate 1. Then, a spin-wave delay line is etched on the substrate 1, which can be made in the form of a magnetic film microwave guide of spin waves 2. Next, the input 3 and output 4 copper antennas are manufactured, each of which consists of a three-strip microantenna applied to the surface of the waveguide 2, and a coplanar transmission line (TL) placed on the rest of the substrate 1. The side electrodes of the coplanar TL are grounded, the central electrode is used to supply the signal. The coplanar LM tapers at the end and connects to a three-strip microantenna. The spin-wave delay line is placed in the magnetic system 5. The output of the spin-wave delay line is connected to the input of the microwave amplifier 6. The output of the microwave amplifier 6 is connected through the microwave directional coupler 7 to the input three-strip spin wave antenna 3.

The operating principle of the generator is based on the following sequence of processes: thermal noise present in the system excites a broadband microwave signal in the microwave amplifier 6, which amplifies the signal and, through a microwave directional coupler 7, supplies it to the spin-wave delay line 2 to the input three-strip spin wave antenna 3. The microwave signal, having passed the spin-wave delay line, arrives at the output three-strip spin wave antenna 4. The spin-wave delay line, which includes a spin wave waveguide 2, an input three-strip spin wave antenna 3 and an output three-strip spin wave antenna 4, is located inside the magnetic system 5. The microwave signal from the output of the spin-wave delay line is supplied to the input of the microwave amplifier 6 and, through the microwave directional coupler 7, is supplied to the input antenna of the spin-wave delay line 3. The generation of a microwave signal in the generator occurs when the total signal losses in the generator circuit by microwave amplifier 6. The described circuit is resonant and selects within itself, based on the phase balance law and the amplitude balance law, the only frequency at which the signal is generated. The monochromatic microwave signal created by the system is output from the generator using a microwave directional coupler 7. The resonant frequencies are adjusted by changing the magnitude of the bias field created by the magnetic system 5. The advantages of the generator circuit are the possibility of planar implementation of the frequency-setting element of the generator, the low level of phase noise of the generated microwave signal , as well as the small size of the entire structure.

Let's consider the design of a spin-wave delay line using the example of its use to build a generator. The ferromagnetic film used in the delay line is made of a YIG film with a thickness of 100 nm, a saturation magnetization of 1750 Gauss and a half-width of the ferromagnetic resonance curve of 0.7 Oe. The magnetization of the YIG film is carried out by a permanent magnet with a field strength of 1083 Oe. The excitation of spin waves occurs due to an alternating magnetic field, created by alternating current flowing through a three-strip microantenna. The length of the three-strip microantenna is 35 µm. The thickness of the microantenna strips is 100 nm. Microantennas consist of three strips: one central strip and two side strips. The width of the central stripe is 648 nm, and the width of the side stripes is 324 nm. The side stripes are spaced from the central stripe at a distance of 334 nm. The distance between the centers of symmetry of the input and output microantennas is 58 microns. The ends of the central and side strips of the microantennas are connected. The beginning of the central strip is connected to the central signal strip of the coplanar transmission line. The beginnings of the side strips are connected to the grounded side electrodes of the coplanar transmission line.

In fig. Figure 2 presents the results of modeling the S-parameters of a delay line without a ferromagnetic film in the AnsysHFSS package. These results show that the interference level ( S ₂₁ and S ₁₂ ) from the input antenna to the output antenna is about -85 dB. This means that the input antenna will not distort the signal carried by the spin waves through the ferromagnetic film. In the presence of a ferromagnetic film, the amplitude-frequency response (AFC) of the delay line was calculated using the original theory. The calculation results showed that the minimum loss introduced by such a delay line is 35 dB.

The frequency response of the generator up to the self-generation threshold is shown in Fig. 3. It was calculated using the formula

(1)

where κ is the attenuation coefficient of the directional coupler used to input and output the microwave signal; G is the amplitude gain of the microwave amplifier; And – the magnitude and phase of the transmission coefficient of the spin-wave delay line, taking into account the excitation and reception of spin waves by antennas, respectively.

As can be seen from Fig. 3, the frequency response of the generator is a set of equidistant resonant peaks. Resonant peaks correspond to the in-phase addition of waves circulating in the generator. In this case, the phase shift of the waves is proportional to 2π. Signal generation is possible when the amplifier compensates for all losses in the ring.

Thus, the description of the generator proves the achievement of a technical result - reducing the size of a tunable magnon microwave generator and reducing the level of phase noise.

Claims (1)

Magnonic tunable microwave generator containing a spin-wave delay line placed in a magnetic system configured to change the magnitude of the bias field to tune resonant frequencies, a microwave amplifier, the output of which is connected to the input antenna through a microwave directional coupler, the output antenna is connected to the microwave - an amplifier, characterized in that the delay line is made on the basis of a nanometer-thick film microwave guide, and each antenna is made in the form of a three-strip microantenna connected to a coplanar transmission line tapering towards the microantenna, and the width of the microstrips is selected from the condition of ensuring matching and isolation between the antennas, with in this case, the ends of the central and side strips of the microantennas are connected, and the beginning of the central strip is connected to the central signal strip of the coplanar transmission line, while the beginnings of the side strips are connected to the grounded side electrodes of the coplanar transmission line, and the monochromatic microwave signal created by the system is output from the generator using a directional microwave coupler.