KR100710820B1 - A planar helical resonator and a microwave oscillator using it - Google Patents

Abstract

The present invention provides a planar helical resonator and an ultra-high frequency oscillator using the same, which can be manufactured in a simpler process and more efficiently reduce phase noise of the oscillator.

In the planar helical resonator of the present invention, a metal line is formed therein and a CPW (Coplanar Waveguide) transmission line in which first and second ground metal plates are formed at predetermined intervals on both sides of the metal line. A space for forming a resonator is formed between the second ground metal plates, and a plurality of rings having open ends at both ends thereof are connected to each other so as to have a helical structure as a whole, and formed between the metal line and the first ground plate. The space formed between the metal line and the second ground plate is formed to be symmetrical with each other, and the ring disposed in the helical structure in the space is connected to each other by a metal connecting the through-holes formed between the rings. Are arranged in a structure.

Planar Helical Resonators, Microwave Oscillators, Phase Noise

Description

Planar helical resonator and a microwave oscillator using it

1 is a block diagram of a typical oscillator.

2 is a structural diagram of a planar helical resonator according to the present invention;

3 is a size comparison of the planar helical resonator and the conventional miniaturized hairpin resonator according to the present invention.

4 is a scattering coefficient comparison diagram of a planar helical resonator and a conventional hairpin resonator according to the present invention;

5 is a view showing the layout of an oscillator using the structure of FIG.

6 illustrates an inter-digital capacitor.

7 shows the output spectrum of an oscillator according to the present invention.

8 illustrates the output spectrum of an oscillator without using the structure of the present invention.

<Description of the symbols for the main parts of the drawings>

100: high frequency substrate 101: metal line

103, 105: Ground metal plate 107a, 107b: Rings with open ends at both ends

109: through hole

The present invention relates to a planar helical resonator and an ultra-high frequency oscillator using the same. Particularly, a planar helical resonator and a helical resonator for selecting an oscillation frequency in an oscillator have a planar helical resonator structure in which a fabrication process is simple, thereby reducing phase noise of the oscillator. It relates to the ultra-high frequency oscillator used.

An oscillator is a part for generating a reference signal in a wireless transceiver, etc. FIG. 1 shows a block diagram of a general oscillator.

A general oscillator as shown in FIG. 1 maintains an oscillation started once by compensating an inevitable resistance component in the resonator 10 and the resonator 10 that select an oscillation frequency through LC resonance or structure resonance. The amplifier 20 and a matching circuit 30 that combines the resonator 10 and the amplifier 20 to form an oscillator loop as a whole are composed of a matching circuit (30).

Such a conventional oscillator is simply made of an LC resonant circuit combining an inductor and a capacitor or a dielectric resonator.

However, in case of LC resonator, accurate oscillation frequency prediction is not easy due to the parasitic effect of the circuit generated from harmonics.In case of dielectric resonator, noise characteristics are good but efficiency is not improved. Thereafter, there was inconvenience in manufacturing such as attaching to a circuit board using a bond or the like.

Meanwhile, the conventional "High-Q helical resonator for oscillators and filters in mobile communications systems (JKA Everard, KKM Cheng, and PA Dallas, IEE Electronics Letters, pp. 1648-1650.)" Manufactured an oscillator using a three-dimensional helical resonator. However, the three-dimensional helical resonator has a disadvantage that the manufacturing process is complicated.

Therefore, by applying the planar helical resonator as the resonator of the oscillator, an additional process such as the conventional resonator is not required, and a method of effectively reducing the phase noise of the oscillator with the resonator of a much smaller size than the conventional planar resonators is proposed.

SUMMARY OF THE INVENTION The present invention has been made in view of this point, and an object of the present invention is to provide a planar helical resonator and an ultra-high frequency oscillator using the same, which can be manufactured in a simpler process and more efficiently reduce phase noise of an oscillator.

In the planar helical resonator according to the present invention for achieving the above object, in the CPW transmission line in which metal lines are formed in the center and first and second ground metal plates are formed at predetermined intervals on both sides of the metal lines, A space for forming a resonator is formed between the line and the first and second ground metal plates, and a plurality of rings having open ends at both ends thereof are connected to each other so as to have a helical structure as a whole.

First and second spaces are formed between the metal line and the first ground plate, and third and fourth spaces are formed symmetrically with the first and second spaces between the metal line and the second ground plate. .

In addition, the rings arranged in the helical structure in the space are connected to each other by a metal connecting the through-holes formed between the rings are arranged in a helical structure, the plurality of rings are two, the ring is a total of 4/4 One quarter of them have an open shape.

The ultra-high frequency oscillator of the present invention for achieving the above object, in the CPW transmission line formed with a metal line in the center and the first and second ground metal plate at predetermined intervals on both sides of the metal line, A space for forming a resonator is formed between the first and second ground metal plates, and a plurality of rings having open ends at both ends thereof are connected to each other so as to have a helical structure as a whole.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the following examples are merely to illustrate the present invention is not limited to the contents of the present invention.

Figure 2 shows the structure of a planar helical resonator according to the present invention, the ultra-high frequency substrate 100 used is an RT / Duroid 6010 substrate having a dielectric constant of 10.2 and a thickness of 25 mils. The thickness of was set to 0.9 mm, and the distance between the center metal line 101 and both ground metal plates 103 and 105 was 0.55 mm.

In addition, a planar helical resonator (PHR: planar) is provided between a central metal line 101 and two ground metal plates 103 and 105 in a conventional Coplanar Waveguide (http://www.rfdh.com/) transmission line. A space is formed to form a helical resonator, and the through holes 109 are connected by metal so that the two rings 107a and 107b having open ends at both ends have a helical structure as a whole.

At this time, the same structure is symmetrical on both sides to achieve a higher effect. That is, two spaces for forming the planar helical resonator are formed between the metal line 101 and the ground metal plate 103, and the planar helical resonator is also disposed between the metal line 101 and the ground metal plate 105 in a symmetrical manner. Two spaces to be formed are formed, and two rings 107a and 107b having open ends at both ends thereof are arranged to have a helical structure.

Rings 107a and 107b having open ends at both ends are manufactured in a ring shape corresponding to 3/4 with 1/4 open in the entire 4/4 ring-type structure, and penetrating between rings corresponding to 3/4. The ball 109 is connected to the metal to create a helical structure as a whole. This can be understood to be similar to the Fabry-Parret resonator in optics.

In other words, there is an open reflector at both ends where structural resonance occurs to collect waveforms.

Also note that in this structure, the standing wave generated in the helical resonator is zero in the upper ring and the lower ring, that is, in the part where the through hole 109 between the ring 107a and the ring 107b is located. It is possible to reduce the loss of the resonator that may be present in the through hole (109).

This leads to an increase in the quality factor (Q-factor) of the resonator, resulting in a reduction in the phase noise of the oscillator.

CPW, on the other hand, includes the term waveguide, but is actually a type of transmission line using a TEM mode. CPW is similar to a microstrip line, but is present on both sides of the signal line, with no GND at the bottom. In some cases, additional GNDs can be placed or removed underneath.

CPW is easy to implement Via because signal line and GND are on one side, and it is much simpler to implement circuits such as short stubs. First of all, the CPW has a vertical field between the co-existing signal line and GND, so unlike the microstrip, a full TEM mode can be implemented. Therefore, the higher the frequency, the better the transmission characteristics of the CPW than the microstrip.

In other words, CPW is formed by combining the advantages of microstrip, which is easy to implement a circuit by etching, and stripline, which is realized in a complete TEM mode.

3 shows a layout of a miniaturized hairpin resonator known as the smallest structure of the conventional planar resonators for comparison with the planar helical resonator of the present invention. For accurate size comparison, the resonant frequencies of these two resonators were set equal to 5.5 GHz.

The horizontal length a1 of the planar helical resonator is 5mm, the length b1 is 2mm, the width a2 of the conventional miniaturized hairpin resonator is 8.87mm, and the length b2 is 2.84mm.

In conclusion, the size of the planar helical resonator proposed in the present invention is about 4/10 the size of less than half the size of the conventional miniaturized hairpin resonator.

This is different from the conventional planar resonator structure, which required 1/4 wavelength length. In the planar helical resonator structure, the stationary wave is distributed on the upper and lower sides of the substrate by 1/2, so the standing wave for resonance is 1/8 on one side. If the length of the wavelength is only a side effect of the resonance is obtained.

4 shows the scattering coefficient of the planar helical resonator structure according to the present invention and the scattering coefficient of the miniaturized hairpin resonator which is a conventional planar resonator.

As can be seen in Figure 4, the planar helical resonator of the present invention, the quality factor (Q-factor) showing a measure of loss is 160, which is about 3 times higher than that of the hairpin resonator whose value is about 62. Could.

The layout of a circuit for fabricating an oscillator with improved phase noise using the planar helical resonator structure having such a structure as an oscillator resonator is shown in FIG. 5.

An amplifier stage was fabricated by using a transistor to position the resonator of the present invention in the gate portion of the oscillator and to compensate for the resistance of the resonator to start and maintain the oscillation. A stub was attached to the source terminal of the transistor to produce a negative resistance at the gate terminal. The output of the oscillator was measured through a spectrum analyzer by connecting a connector to the drain terminal of the transistor.

The DC bias of the circuit used a radial stub and a high impedance line, and an inter-digital capacitor was attached to the output to prevent the DC voltage from being applied directly to the output.

Conventional capacitors in microwave engineering are in the form of chips and are attached to a substrate by a soldering process. However, in the case of such a conventional capacitor, there may be an error of a circuit element value due to soldering or the like, and the process is also inconvenient.

Recently developed to improve this is a planar inter-digital capacitor of the shape as shown in FIG. This is realized through the etching process of the metal pattern of the shape as shown in Figure 6 on the existing CPW substrate, in this case, the capacitance is implemented to the extent that electromagnetic waves are coupled (coupling) in the gap of the sinuous shape, the soldering process This eliminates the need for a new capacitor that is simpler and reduces process errors (http://www.imst.de/coplan/online_manual/c_idc.html).

Figure 7 shows the output spectrum of the oscillator manufactured according to the present invention. The oscillation frequency was 5.34 GHz and the phase noise was measured at -112 dBc / Hz at 1 MHz offset.

8 shows an output spectrum of an oscillator manufactured without using the resonator structure of the present invention.

As shown in Fig. 8, the phase noise of the oscillator at a 1 MHz offset under the same bias condition is also measured at -101.44 dBc / Hz, which improves the performance of approximately 11 dB when the resonator structure of the present invention is applied to the oscillator resonator. It can be seen that.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications of the present invention without departing from the spirit and scope of the invention described in the claims below Or it may be modified.

As described above, the present invention can reduce the phase noise of the oscillator by replacing the resonator that selects the oscillation frequency in the oscillator by a planar helical resonator structure with a simple manufacturing process. The present invention can be used in a high efficiency signal generation circuit of a wireless transceiver.

Claims (8)

A resonator between the metal line and the first and second ground metal plates in a CPW (Coplanar Waveguide) transmission line having a metal line formed therein and having first and second ground metal plates formed at predetermined intervals on both sides of the metal line. A planar helical resonator, comprising: a space for forming, wherein a plurality of rings having open ends at both ends thereof are connected to each other so as to have a helical structure as a whole. The planar helical resonator of claim 1, wherein a space formed between the metal line and the first ground plate and a space formed between the metal line and the second ground plate are symmetrically formed. 3. The method of claim 2, wherein first and second spaces are formed between the metal line and the first ground plate, and third and fourth spaces are formed between the metal line and the second ground plate. Planar helical resonator, characterized in that is formed symmetrically with each other. The ring of claim 1, wherein the ring is disposed in the space in a helical structure. Planar helical resonator, characterized in that arranged in a helical structure connected to each other by a metal connecting the through-holes formed between the ring. 2. The planar helical resonator of claim 1, wherein the plurality of rings are two. 6. The planar helical resonator according to claim 5, wherein the ring has an open shape in a quarter of a quarter of the rings. A high frequency oscillator using the resonator of any one of claims 1 to 6. 8. The high frequency oscillator according to claim 7, wherein an output terminal further comprises an inter-digital capacitor.

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