KR100550909B1 - Capacitively loaded multi layer 1/4 wavelength resonator - Google Patents

Abstract

The present invention relates to a multilayer quarter wave resonator loaded with a capacitor.

The multilayer quarter-wave resonator loaded with the capacitor of the present invention includes a bi-connected or uni-connected strip line comprising a pair of conductor thin films on both sides with a dielectric substrate interposed therebetween; Technical features include a first connection part for connecting a capacitor through a via hole to one side end of the strip line and a second connection part for connecting the other end of the strip line to a ground plane through the via hole.

Therefore, the multilayer quarter-wave resonator loaded with the capacitor of the present invention can reduce the size of the resonator by a desired size, thereby basically reducing the size of the circuit, and the first resonant frequency and the first resonant frequency Since the frequency difference between the first spurious resonant frequency is much larger than that of the conventional quarter wave transmission line resonator, it is possible to design a filter having a wide upper stopband. In addition, the ability to control spurious signals has the technical advantages and effects of designing broadband circuits.

Strip line, resonator, quarter wave, capacitor.

Description

Capacitively loaded multi layer 1/4 wavelength resonator             

1 shows an open transmission line with conventional losses.

Figure 2 shows the voltage distribution of a conventional lossy open transmission line.

3A shows a three-dimensional structure of a resonator according to a first embodiment of the present invention.

3B shows an equivalent circuit of the resonator according to the first embodiment of the present invention.

4A shows a three-dimensional structure of a resonator according to a second embodiment of the present invention.

4B shows an equivalent circuit of the resonator according to the second embodiment of the present invention.

5 shows a simulation result of resonance characteristics of a multilayer quarter-wave resonator loaded with a capacitor according to the present invention.

<Description of Symbols for Major Parts of Drawings>

100: first strip line. 110: first connecting portion.

120: second connecting portion. 130: first capacitor equivalent circuit.

The present invention relates to a multilayer quarter-wave resonator loaded with a capacitor, and more particularly, a capacitor can be connected to a strip line composed of a pair of conductor thin films on both sides with a dielectric substrate interposed therebetween, and one end of the strip line. A multi-layer quarter-wave resonator is loaded with a capacitor comprising a first connection portion and a second connection portion for connecting a capacitor to the other end of the strip line.

Conventionally, there has been a quarter wave resonator having both ends resonating at a quarter wavelength and having an open transmission line.

1 shows a general configuration of a conventional lossy open transmission line.

In FIG. 1, l denotes a length of a transmission line, Z _in denotes an input impedance, Z ₀ denotes a characteristic impedance, and α and β denote a loss phase constant and a propagation phase constant, respectively.

Figure 2 shows the voltage distribution in a conventional lossy open transmission line.

As shown in FIG. 2, when the length l of the transmission line is an integer multiple of 1/4 wavelength (λ / 4) or 1/4 wavelength (λ / 4), a lossy open transmission line is similar to a parallel resonance circuit. It works.

The general operation principle of the quarter-wave resonator of the open circuited length of transmission line will be described in detail below.

First, the input impedance Z _in of an open transmission line of length l can be obtained by the following equation.

If the length of the transmission line is l = λ / 4 at the resonant frequency ω = ω ₀ , and ω = ω _{0 +} Δω, a series of results can be obtained.

Using the above equation, an input impedance Z _in value as shown _{in the} following equation can be obtained.

On the other hand, in the case of a parallel resonant circuit composed of an ideal concentrated element (Lumped element), the input impedance (Z _in ) value can be represented by the following equation.

By comparing the input impedances represented by the two equations with each other, it can be seen that the conventional open transmission line becomes a parallel resonant circuit. In the equivalent parallel resonant circuit, the resistance (R), reactance (L), and capacitance (C) You can derive the value.

In the equivalent parallel resonant circuit induced by comparing the equation of the input impedance, the resistance (R), reactance (L), capacitance (C) value, and the Q of the resonator can be expressed by the following equation.

However, the conventional quarter-wave resonator of the conventional open transmission line as described above has a limitation that the length of the resonator should be one-quarter wavelength, and thus, the size of the resonator is large and there are technical obstacles in designing a compact filter.

In addition, when looking at the frequency characteristics of the resonator, there was a technical limitation that resonance occurs even at a desired reference frequency f ₀ and 2n + 1 times of the reference frequency, for example, 3f ₀ , 5f ₀ . When designing a filter by using a harmonic signal component for the desired signal in addition to the signal desired by the designer, there is a technical problem of deteriorating the characteristics of the entire circuit.

Accordingly, the present invention is to solve the above-mentioned disadvantages and problems of the prior art, it is possible to connect a capacitor to one side of the strip line and a strip line consisting of a pair of conductor thin film on both sides with a dielectric substrate therebetween. The first connection part and the second connection part for connecting a capacitor to the other end of the strip line can reduce the size of the circuit when designing a resonator, and a filter having a wide upper stopband and a wide bandwidth An object of the present invention is to provide a multilayer quarter-wave resonator loaded with a capacitor having excellent spurious characteristics capable of designing a circuit having a characteristic.

The object of the present invention is a bi-connected or uni-connected strip line comprising a pair of conductor thin films on both sides with a dielectric substrate interposed therebetween; Multilayer 1/4 wavelength loaded capacitor having a first connection part for connecting a capacitor via a via hole to one side of the strip line and a second connection part for connecting the other end of the strip line to a ground plane through a via hole Achieved by a resonator.

That is, in the three-dimensional structure of the multilayer quarter-wave resonator loaded with the capacitor of the present invention, one end of the strip line is connected to a pattern through a via hole (Via-Hole), and the pattern is connected to the ground plane. A capacitance component of a certain capacity is achieved. The other end of the line is connected directly to the ground plane via a via-hole, thus forming a new quarter-wave resonator as a whole.

In this case, because of the slow wave effect, the fundamental resonant frequency and the spurious resonant frequencies occur at low frequencies as a whole. Therefore, in the conventional quarter-wave resonator, the resonance frequency is generated at 2n + 1 (constant n = 1, 2, 3, ...) times the reference resonance frequency. In the case of a multilayer quarter-wave resonator loaded with a capacitor, the first spurious resonant frequency is generated at three times or more of the fundamental resonant frequency according to the capacitance value of the connected capacitance. It is possible to design an ultra-small filter with an up stop band.

Details of the above object and technical configuration of the present invention and the effects thereof according to the present invention will be more clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 3a shows a three-dimensional structure as a first embodiment of a multilayer quarter-wave resonator loaded with a capacitor with a strip line according to the present invention.

The basic structure of the resonator has a shape in which a capacitor pattern having a capacitance of a constant capacitance is connected through a via hole at both open ends of a conventional quarter-wave strip line resonator. That is, the first capacitor CP1 is placed on the downward ground plane, the second capacitor CP2 is placed on the upward ground plane, and a strip line is disposed therebetween.

Figure 3b shows an equivalent circuit for a multilayer quarter-wave resonator loaded with a capacitor with a strip line according to the present invention.

As shown in FIG. 3B, the multilayer quarter-wave resonator loaded with the capacitor is composed of a bilaterally connected open first strip line 100, which has both ends to which the capacitor can be connected.

 One side end 110 of the first strip line 100 is connected to a first equivalent capacitor circuit 130 synthesized by connecting the first capacitor CP1 and the second capacitor CP2 in parallel with each other. .

 The other end 120 of the strip line is directly connected to the ground through the via hole without connecting any capacitor.

 In FIG. 3B, two planar patterns are used as the loading capacitance, which is to increase the capacitance value, and the number of capacitors may vary according to the capacitance value. That is, when the required capacitance value is smaller than the reference capacitance value, only one pattern may be used, and when the desired capacitance value is large, two or more may be required.

Figure 4a shows a three-dimensional structure as a second embodiment of a multilayer quarter-wave resonator loaded with a capacitor with a strip line according to the present invention.

The basic structure of the resonator has a shape in which a capacitor pattern having a capacitance of a constant capacitance is connected through a via hole at both open ends of a conventional quarter-wave strip line resonator. That is, in the basic structure of the resonator, one side of the strip line is shorted to ground through a via hole (Via-Hole), and the other side is connected to a flat pattern having a predetermined shape through the via hole (Via-Hole).

Figure 4b shows an equivalent circuit of a second embodiment of a multilayer quarter-wave resonator loaded with a capacitor with a strip line according to the present invention.

The one-sided open second strip line 200 has both side ends that can be connected to the capacitor.

 In the one-sided open second strip line, one side end 210 is connected to the first capacitor CP, and the other end 220 in the open strip line is directly connected to the ground through the via hole without any capacitor connection. It is connected.

3b and 4b show a representative resonator structure according to the present invention, one side of the strip line is shorted to ground through a via hole (Via-Hole), and the other side has a predetermined shape through the via hole (Via-Hole). It is connected to a planar pattern, which forms a capacitance of the ground plane. And this is called loading capacitance (Loading capacitance) capacitance, since the load capacitance propagation delay effect (Slow-wave effect) a can be obtained, based on the resonance frequency of the resonator (Fundamental resonant frequency, f ₀₎ and a spurious resonance frequency (Spurious resonant frequency, f ₁ ) occurs at a lower frequency than a conventional resonator composed of strip lines only.

 The first spurious resonant frequency has the greatest influence on the spurious characteristics of the entire system, and the ratio is 3 for the existing resonant frequency. This means that a frequency three times the reference resonance frequency is passed without being blocked.

5 shows a simulation result of resonance characteristics of a multilayer quarter-wave resonator loaded with a capacitor according to the present invention.

This is achieved by varying the loading capacitance using the equivalent circuit shown in FIGS. 3b and 4b according to the present invention, while the ratio of the reference frequency (f ₀ ) and the first spurious resonance frequency (f ₁ ) to the ratio (f) of the two frequencies (f). ₁ / f ₀ ) to investigate the resonance characteristics.

Hereinafter, a change in the resonance frequency, a change in the spurious resonance frequency, and a change in the ratio of the spurious frequency to the reference resonance frequency will be described in detail with respect to the loading capacitance value of FIG. 5.

As shown in FIG. 5, when the capacitance value of the loading capacitance is 0 pF, a resonator composed of a conventional strip line is shown. In this case, it can be seen that the ratio f ₁ / f ₀ of the reference resonance frequency f ₀ and the first spurious resonance frequency f ₁ is three. As the capacitance value of the loading capacitance increases, the ratio (f ₁ / f ₀ ) of the reference resonant frequency (f ₀ ) and the first spurious resonant frequency (f ₁ ) gradually increases, and the ratio is 4 pF. It can be seen that the increase to about 4.5.

From the simulation results of FIG. 5, when the filter is designed using the multilayer quarter-wave resonator loaded with the capacitor according to the present invention, the design of a compact filter having a wider up-stop band than the filter designed by the conventional method It can be seen that.

The resonance characteristics of the multilayer quarter-wave resonator loaded with the capacitor with the strip line according to the present invention are affected by the length and width of the strip line, the distance between the ground planes, and the like. You can choose the structure according to the.

The present invention is preferably applicable to all filter structures and filter applications such as duplexers, diplexers, tunable filters, in particular filters using laminated PCBs, filters using LTCC technology, and other laminated structures using other materials. .

The above embodiment of the present invention is not limited to the specific matters described in the above specification, and those skilled in the art to which the present invention pertains can easily implement many other modified embodiments.

Therefore, the multilayer quarter-wave resonator loaded with the capacitor of the present invention has a strip line formed of a pair of conductor thin films on both sides with a dielectric substrate interposed therebetween, and a first connection portion capable of connecting a capacitor to one end of the strip line. And a second connection part for connecting a capacitor to the other end of the strip line, thereby reducing the size of the resonator by a desired size, thereby basically reducing the size of the circuit, and reducing the size of the resonator with a reference resonant frequency. Since the frequency difference from the first spurious resonant frequency is much larger than that of a conventional half-wave transmission line, it is possible not only to design a filter with a wide upper stopband. Because of its ability to control spurious signals, There is the technical advantages and effects that can be designed.

Claims (8)

In a quarter wave strip line resonator using a laminated structure, Bi-connected or uni-connected strip lines each having a set of conductor thin films on both sides with a dielectric substrate interposed therebetween; A first connection part connected to one side of the strip line through a via hole with a capacitor; And Second connection portion for connecting the other end of the strip line to the ground plane through the via hole Multilayer quarter-wave resonator loaded with a capacitor comprising a. The method of claim 1, And the strip line is a bidirectionally connected open first strip line (100). The method of claim 2, Having a first equivalent capacitor circuit 130 synthesized by connecting the first capacitor CP1 and the second capacitor CP2 in parallel to the first connection unit 110 of the bidirectionally connected open first strip line 100. A multi-layer quarter wave resonator loaded with capacitors. The method of claim 3, wherein When the required capacitance value is smaller than the reference capacitance value, only the first capacitor CP1 is connected to the first connection portion 110 of the two-connected open first strip line 100. Multilayer quarter-wave resonator. The method of claim 2, The second connection portion 120 of the two-connected open first strip line 100 is a capacitor-loaded multilayer quarter-wave resonator, characterized in that directly connected to the ground plane via a via-hole (Via-Hole). The method of claim 1, And the strip line is a one-sided open second strip line (200). The method of claim 5, A capacitor loaded multi-layer quarter-wave resonator, characterized in that the first capacitor (CP) is connected to the first connection portion 210 of the one-connection open second strip line (200). The method of claim 5, The capacitor-loaded multilayer quarter-wave resonator, characterized in that directly connected to the ground plane via the via-hole (Via-Hole) of the second connection portion 220 of the one-way open second strip line (200).

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