KR200263615Y1 - Dielectric Filters with Attenuation Poles - Google Patents

Abstract

The present invention relates to a ceramic dielectric filter for forming a plurality of holes penetrating the upper and lower surfaces in one dielectric block and selectively plating the outer surface of the dielectric block to transmit a signal of a specific frequency, in particular, the upper surface of the dielectric filter At least one input / output electrode is placed between the resonator and the resonator on the resonator opening side of the resonator, so that it is easy to control the characteristics of the filter and provides an excellent filter that can reduce the size of the filter.

Description

Dielectric Filters with Attenuation Poles

The present invention relates to a bandpass filter used in a high frequency circuit next to an antenna of a wireless communication system to pass a signal of a desired frequency and to remove a signal of an undesired frequency, and in particular, by providing a filter having a plurality of attenuation poles. A ceramic dielectric filter having attenuation characteristics.

In the conventional ceramic dielectric filter, an integrated filter using a quarter wave resonator having one end shorted is frequently used. The integrated filter forms a resonator by drilling a plurality of holes penetrating the upper and lower surfaces of the dielectric block in one dielectric block, and plating the inner wall of the lower surface, side surfaces, and holes of the dielectric block except the upper surface of the dielectric block with a highly conductive material. The upper surface of the dielectric block is formed by selectively plating a metal pattern and a metal pattern for an input electrode and an output electrode to facilitate electric field coupling or magnetic field coupling between the resonator and the resonance period. Has

In general, a large number of resonators penetrating through the dielectric block can provide a filter having excellent attenuation characteristics, but the size of the filter is large and the insertion loss of the filter is large.

The dielectric filter according to the prior art is shown in FIG. 1 is a high frequency filter using four resonators. The dielectric filter 100 of FIG. 1 drills four holes 103 to 106 penetrating from the upper surface 101 to the lower surface 102 of one dielectric block, and the lower surface 102 and the side surface 110 except for the upper surface 101. ) To form a ground plane and plate the inner wall of the hole with a conductive metal to form a resonator. On the upper surface of the dielectric block, a metal pattern 113 for coupling the input / output electrodes 107 and 108 with the resonator and the resonator period 116) was optionally plated. In particular, the input electrode 107 and the output electrode 108 are dielectric filters that can be directly mounted on the PCB substrate by extending the transmission line to the side of the dielectric block to facilitate mounting on the PCB substrate. There is a simple feature. Since the hole formed in FIG. 1 operates as a quarter-wave resonator with one end shorted, a hole and a resonator will be used below.

The operation principle of FIG. 1 will be described using the equivalent circuit of FIG. 2 as follows. Resonators 103 to 106 of FIG. 1 are shown as resonators 203 to 206 of equivalent circuits in FIG. 2. The microwave signal transmitted to the input electrode 107 is propagated to the first resonator by the capacitance C201 formed between the input electrode 107 and the coupling pattern 113 of the first resonator 103. The high frequency signal propagated to the first resonator is the capacitance between the electromagnetic coupling between the first resonator 103 and the second resonator 104 and the coupling metal pattern 113 around the first resonator and the coupling metal pattern 114 around the second resonator. Propagated to the second resonator 104 by C212. The microwave signal propagated in this manner is propagated to the fourth resonator 106 and propagated to the output terminal by the capacitance C240 between the coupling metal pattern 116 and the output electrode 108 around the fourth resonator. The attenuation characteristic of this resonator shows the attenuation characteristic curve of the four stage resonator. The attenuation pole for improving the attenuation characteristic at a specific frequency is determined by the coupling capacitance between the resonators (C212 ~ C234) and the amount of electromagnetic coupling between each resonator, and occurs at a frequency lower than the pass band. Dielectric filters used in mobile communication terminals are small in size and require high attenuation characteristics. However, when the number of resonators is reduced, the attenuation characteristic is worsened. When the number of resonators is large, the attenuation characteristic is improved but the size is increased. Therefore, in order to improve the attenuation characteristic without increasing the number of resonators, the dielectric filter improves the attenuation characteristic by placing an attenuation pole whose transmission characteristic becomes zero at a desired frequency. However, the filter having the structure as shown in FIG. 1 exhibits attenuation characteristic of the filter by coupling of the resonant period electromagnetic field, and there is no attenuation pole between the input electrode and the first resonator. In addition, there is a problem in that the size of the filter increases in order not to increase the capacitance between the input and output electrodes and the ground plane.

Another embodiment according to the prior art is shown in FIG. 3. It is a high frequency filter structure composed of band pass filter using three resonators and one band stop filter. The equivalent circuit for the high frequency filter of FIG. 3 is shown in FIG. The operation principle of FIG. 3 is described using the equivalent circuit of FIG. 4 as follows. The high frequency signal entering the input electrode 307 is capacitively coupled to the first resonator 303 and the second resonator 304 to form capacitances C401 and C402, respectively. The incident high frequency signal is propagated to the second resonator by the capacitance C402 and propagated to the fourth resonator by the electromagnetic field coupling in the resonant period and then to the output. At this time, the high frequency signal propagates to the first resonator 303 by the capacitance C401 between the input electrode 307 and the first resonator 303, and the undesired high frequency signal flows to the ground terminal by the first resonator 303 and is output. An attenuation pole with zero transmission characteristics with no signal transmitted to it occurs. This attenuation pole frequency occurs at frequencies lower than the passband. The high frequency filter is composed of a band pass filter using three resonators and one stop band filter. The filter of this structure can move the attenuation pole frequency of the stop band independently of the band pass filter, thereby increasing the attenuation characteristic at the desired frequency. However, since the coupling between the bandpass filter and the stopband filter should not occur, the size of the filter is increased, and the attenuation pole frequency has a problem that occurs only at a frequency lower than the passband.

In the present invention, in the integrated filter using a dielectric, at least one input / output electrode is formed between the resonator and the resonator to increase the number of resonators by having attenuation poles whose transmission characteristics are zero at frequencies lower or higher than the pass band. It is an object of the present invention to provide a filter having improved attenuation characteristics.

Therefore, the present invention is provided to solve the problems of the prior art as described above, by placing at least one input and output electrode between the resonator and the resonator to adjust the coupling amount between the resonator, or the input and output electrode and the adjacent resonator according to the present invention By adjusting the coupling capacitance between them, it is possible to place the attenuation pole whose transmission characteristic becomes zero at higher or lower frequencies than the pass band, thereby providing a compact filter that can improve the attenuation characteristics in the stop band without increasing the number of resonators. Its purpose is to.

1 is a structural diagram of an integrated filter using a ceramic dielectric according to the prior art,

2 is an equivalent circuit diagram of the dielectric filter of FIG.

3 is a structural diagram of an integrated filter using another ceramic dielectric according to the prior art,

4 is an equivalent circuit diagram of the dielectric filter of FIG.

5 is a structural diagram of a dielectric filter according to a first embodiment of the present invention,

6 is an equivalent circuit diagram of a dielectric filter according to a first embodiment of the present invention,

7 is another equivalent circuit diagram of a dielectric filter according to a first embodiment of the present invention,

8 is a structural diagram of a dielectric filter according to a second embodiment of the present invention,

9 is an equivalent circuit diagram of a dielectric filter according to a second embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

500: dielectric filter 501: top surface

502: when 510: side

503, 504, 505, 506: resonator 513, 514, 515, 516: coupling pattern around the resonator

507: input electrode 508: output electrode

According to the present invention for achieving the above object, to form a resonator by drilling a plurality of holes through the upper and lower surfaces of the dielectric block, and to form a ground plane by plating the lower and side surfaces of the dielectric block with a conductive metal, The inner wall of the hole is plated with a conductive metal to be connected to the conductive metal formed on the lower surface of the dielectric block to form a short end to operate as a quarter-wave resonator with one end shorted, and an electric field coupling between the resonators or When forming an input / output electrode with a metal pattern that facilitates magnetic field coupling, at least one input / output electrode may be placed between the resonator and the resonator so that attenuation poles having zero transmission characteristics may be provided at frequencies higher or lower than the pass band. The attenuation characteristic of the high frequency filter can be improved without increasing the number.

In the following, with reference to Figures 5, 6 and 7 attached to a preferred embodiment of the dielectric filter according to the present invention will be described in detail.

5 is a structural diagram of a dielectric filter according to a first embodiment of the present invention, as shown in FIGS. 1 and 3, the ceramic dielectric filter 500 of the present invention has an upper surface 501, a lower surface 502, and a side surface thereof. With a 510, the bottom and side surfaces comprise one dielectric block formed of parallelepipeds that are plated with a conductive metal to form a ground plane. The dielectric block is formed with four holes 503 to 506 penetrating through the upper surface 501 and the lower surface 502 of the dielectric block, and the inner wall of the hole is plated with a conductive metal to form the lower surface 502 of the dielectric block. It is connected with the formed conductive metal to form a short end. The metal patterns 513 to 516 formed around the holes 503 to 506 located on the top surface 501 of the dielectric block allow electric field coupling between adjacent resonators. The input electrode 507 is positioned between the resonator 503 and the resonator 504, and electric field coupling is performed between the input electrode 507 and the resonators 503 and 504, respectively. An equivalent circuit thereof is shown in FIG. 6. The input electrode 507 generates capacitance C601 by electric field coupling with the first resonator 503, and generates another capacitance C602 by electric field coupling with the second resonator 502. Electromagnetic coupling is made between the first resonator 503 and the second resonator 502. Therefore, the high frequency signal entering the input electrode is incident to the first resonator 603 by the coupling capacitance C601 and then the signal transmission method and the input electrode propagated by the electromagnetic field coupling between the first resonator 603 and the second resonator 604. There is a transmission path of the signal propagated directly to the second resonator 604 by the coupling capacitance (C602). The high frequency signals propagated to the second resonator 604 through the other paths are combined, and propagated to the fourth resonator 606 by the electromagnetic coupling between the resonators as shown in FIGS. 1 and 3, and then to the output electrode 608. Is delivered and output. In the equivalent circuit of FIG. 6, the coupling capacitances C601 and C602 and the electromagnetic coupling portion between the first resonator 603 and the second resonator 604 are converted into a Y-type equivalent circuit as shown in FIG. 7. In the circuit as shown in FIG. 7, resonance is determined by the first resonator 703 and the admittance Y703. Therefore, in the equivalent circuit of FIG. 7, the attenuation pole frequency at which the transmission characteristic becomes zero is determined by the admittance Y703 on the first resonator 703. Therefore, if the admittance component Y703 is the capacitance component, the attenuation pole frequency is lower than the pass band. When the admittance (Y703) component is an inductance component, the attenuation pole frequency is located at a frequency higher than the pass band.

8 is a structural diagram of a dielectric filter 800 according to a second embodiment of the present invention, in which an input electrode 807 is positioned at a first resonator 803 and a second resonator 804, and an output electrode 808 is a third resonator ( 805 and the fourth resonator 806. The dielectric block 800, the resonators 803 to 806, and the coupling patterns 813 to 816 on the resonators are illustrated in FIG. 5. The filter having such a structure has two paths through which an input signal propagates, two paths of an output signal, and the equivalent circuit is shown in FIG. 9. In this filter, the frequency of the first attenuation pole is determined by the value of the admittance (Y903) located above the first resonator (903), and the frequency of the second iron pole is determined by the value of the admittance (Y906) located above the fourth resonator (906). The frequency is determined. The filter having such a structure can place the attenuation pole at a lower frequency or a higher frequency than the pass band, thereby improving the attenuation characteristics without increasing the size of the filter.

As described in detail above, the present invention can provide a filter having a plurality of attenuation poles at a frequency higher or lower than a passband without increasing the number of resonators in a high frequency filter used in a mobile communication terminal. In addition, since the number of resonators is small, it is possible to provide a high frequency filter having excellent insertion loss characteristics.

Claims (2)

A plurality of holes penetrating the upper and lower surfaces of the dielectric block are formed, and the lower and side surfaces of the dielectric block are plated with a conductive metal to form a ground plane, and the inner wall of the hole is plated with a conductive metal to form a lower surface of the dielectric block. By forming a short end by connecting the formed conductive metal to operate the hole as a quarter-wave resonator short-circuited at one end, by selectively plating a metal pattern to facilitate the field coupling or magnetic field coupling between the resonators In the dielectric filter, at least one input / output metal pattern is formed between the resonator and the resonator to facilitate electric field coupling with not only adjacent resonators but also adjacent ones. A plurality of holes penetrating the upper and lower surfaces of the dielectric block are formed, and the lower and side surfaces of the dielectric block are plated with a conductive metal to form a ground plane, and the inner wall of the hole is plated with a conductive metal to form a lower surface of the dielectric block. By forming a short end by connecting the formed conductive metal to operate the hole as a quarter-wave resonator short-circuited at one end, by selectively plating a metal pattern to facilitate the field coupling or magnetic field coupling between the resonators In the dielectric filter, at least one input / output metal pattern is formed between the resonator and the resonator to facilitate electric field coupling not only with the adjacent resonator but also with the non-adjacent resonator, and the electromagnetic coupling amount of the resonator is adjusted to lower frequency than the pass band. Or attenuation pole with zero transmission at high frequency. Dielectric filter characterized in that