KR20000014851A - High frequency filter - Google Patents

Abstract

PURPOSE: A high frequency filter of a cylindrical cavity type is provided to have an excellent an attenuation characteristic at a low band. CONSTITUTION: A high frequency filter of a cylindrical cavity type comprises an upper block(100), a lower block(200), and a plurality of resonators. The upper block(100) has a plurality of cylindrical openings(110), and the lower block(200) has a plurality of cylindrical grooves(220). The plurality of resonators are formed by inserting a dielectric into the cylindrical openings of the plurality and into the cylindrical grooves of the plurality. The high frequency filter comprises a coupling path(240) and a coupling waveguide(230). The coupling path(240) connects two ones of the resonators to an input terminal and to an output terminal, respectively, and the coupling waveguide(230) connects remaining resonators adjacent to each other.

Description

Cylindrical Cavity High Frequency Filter

The present invention relates to a cylindrical cavity type high frequency filter used in a high frequency circuit located next to an antenna of a wireless communication system such as mobile communication, personal communication, satellite communication, and next-generation mobile communication (International Mobile Telecommunication-2000). It is possible to correct error by adjusting the fine characteristic of the resonator and the amount of coupling between the resonator and the resonator, and to manufacture the cylindrical cavity type high frequency filter that can be used for the base station filter of mobile communication which requires simple output due to the simple manufacturing process. It is about.

In the recent wireless communication systems, the transmission and reception frequency bands which are close to each other are used for efficient use of the frequency. Therefore, the filter used in the high frequency circuit of the communication system has excellent attenuation characteristics at the stop band of higher or lower frequency than the pass band. In addition, in accordance with the trend of smaller and lighter communication systems, filters are also required to be smaller and lighter. In addition, error correction due to manufacturing tolerances is required because the frequency used is high.

Next, a filter having a disc-shaped resonator axially symmetric with a conventional comb-line filter will be briefly described with reference to FIGS. 1 to 3.

As shown in FIGS. 1 and 2, the former nonlinear filter has a housing 11 formed of a metal material and acts as a ground, and is screwed upright with a bottom surface of the housing 11. A plurality of resonators 12 having a metal rod shape are provided. Here, since the bottom surface of the resonator 12 is shorted to ground and the top surface is open, the resonator 12 operates as a quarter-wave resonator with one end shorted. Such a resonator 12 has the strongest electric field in its open face and the strongest magnetic field in its shorted face.

In addition, a plurality of metal plates 13 are welded to both side walls of the housing 11 so as to be positioned between the resonators 12, and the metal plates 13 form a coupling window near an open surface or a shorting surface of the resonator 12. Form. Accordingly, the coupling amount between the resonators 12 may be adjusted such that the resonators 12 are coupled to each other by an electric field or a magnetic field.

In addition, the upper surface of the housing 11 is mounted so that the characteristic adjusting screw 14 corresponds to each resonator 12, the screw 14 is the open surface of the resonator 12 and the ground, that is, of the housing 11 A capacitance is formed between the upper surfaces, the capacitance value of which is adjusted according to the insertion depth in the housing 11 of the screw 14.

In the drawings, reference numerals 15 and 16 denote input and output terminals of signals connected to the outside.

In the conventional nonlinear filter, when a high frequency signal is input to the input terminal 15, the signal is transmitted to a resonator adjacent to the input terminal 15, and the signal transmitted to the resonator is capacitively coupled thereto. Transferred to another resonator. The signal transmission between the resonators is continued until the signal is transmitted to the last resonator adjacent to the output terminal 16, and finally the signal transmitted to the last resonator is output through the output terminal 16.

At this time, the signal of the unwanted frequency band is transmitted to the ground through the resonator 12, the capacitance value formed between the upper surface of the housing 11 and the open surface of the resonator 12 is adjusted by turning the screw (14) Done.

On the other hand, in the filter having a disk-shaped resonator of the latter axially symmetrical in the conventional filter, as shown in Figure 3, the cylindrical metal housing 21, and the inner plate and both ends of the housing 21, the disc A plurality of resonators 22a and 22b having a shape are provided. Here, a plurality of resonators 22a each having a metal film 23 formed therein is mounted in the housing 21, and a coupling window between the resonator and the resonator is formed in the metal film 23. A dielectric constant having a large dielectric constant is inserted between the resonators 22a to reduce its size. In addition, an input / output coupling window 25 is formed in the resonator 22b mounted at both ends of the housing 21, and the input / output coupling window 25 is connected to input and output waveguides 26 and 27 connected to the outside. do.

However, although the electronic nonlinear filter can be miniaturized, it is difficult to fix the resonator metal rod so as to stand upright with respect to the bottom surface of the housing, and it is difficult to weld the metal plate to the inner wall surface of the housing. there was.

In addition, the latter axially symmetrical disc-shaped resonator makes it easy to distinguish the TE ₁ mode from other higher-order modes, so that an excellent frequency response can be obtained, but since the dielectric is inserted only in a part of the housing, the overall size of the filter It is difficult to miniaturize, and since all the components of the filter are symmetrical with respect to the axial direction of the housing, it is difficult to physically support and fix the resonator.

Accordingly, the present invention has been made in view of the above-described problems, and has excellent attenuation characteristics in the stopband, low insertion loss, and spurious at a wide frequency for output power efficiency of a base station. The object is to provide a cylindrical cavity type high frequency filter with good characteristics.

1 is a block diagram of a diagonal filter according to the prior art.

Figure 2 is a cross-sectional view taken along the line a-a in Figure 1;

Figure 3 is a block diagram showing a filter having a disk-shaped resonator axially symmetrical according to the prior art.

4 is a configuration diagram of an embodiment of a cylindrical cavity type high frequency filter according to the present invention;

5 is a cross-sectional view taken along the line b-b in FIG.

* Explanation of symbols for the main parts of the drawings

100: upper block 110: cylindrical hole

120: fastening screw 130: metal cover

140: coupling amount adjusting screw 200: lower block

210: cylindrical groove 220: screw hole

230: coupling waveguide 240: coupling passage

In order to achieve the above object, the present invention, a plurality of cylindrical holes formed upper block; A lower block coupled to the upper block and having a plurality of cylindrical grooves communicating with a plurality of cylindrical holes formed in the upper block; A plurality of resonators formed by inserting a dielectric into the cylindrical hole of the upper block and the cylindrical groove of the lower block; A coupling passage formed on an upper surface of the lower block and connecting two of the resonators to input and output terminals of a signal, respectively; And a coupling waveguide formed on an upper surface of the lower block, the coupling waveguide connecting adjacent resonators among the remaining resonators except for the resonators connected to the input and output terminals.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 4 and 5.

In the cylindrical cavity type high frequency filter according to the present invention, the transmission characteristic at a frequency close to the pass band is "0", so that the characteristic at the stop band can be improved, and the insertion loss is small and small. Implemented to easily adjust the error, in the present embodiment, a plurality of cylindrical holes 110 having a thread formed on the inner circumferential surface of the upper block 100 and the upper block 100 of the metal material formed so as to penetrate the upper and lower surfaces; Combined and divided into a lower block 200 of a metallic material formed with a plurality of cylindrical grooves 210 corresponding to the cylindrical hole 110. Here, a dielectric is inserted into the cylindrical hole 110 of the upper block 100 and the cylindrical groove 210 of the lower block 200 to operate as a cylindrical resonator, and two of the resonators are input and output of signals. It is connected to the terminal.

As shown in Figure 4 and 5, the outer side of the upper block 100 is mounted with a plurality of fastening screws 120 for coupling the upper block 100 and the lower block 200. The metal cover 130 is fastened to the cylindrical hole 110 of the upper block 100 so as to be engaged with the screw thread formed on the inner circumferential surface thereof. In the filter of the present embodiment, the resonant frequency and the passband characteristics of the resonator are finely adjusted according to the insertion depth of the cylindrical hole 110 of the metal cover 130, and the user can use the The error that occurs can be adjusted.

In addition, the screw 140 is fastened to penetrate the upper block 100 between the cylindrical holes 110 except for the cylindrical holes 110 located at the input / output terminal side, and the screws 140 are disposed between adjacent resonators. The amount of binding is controlled.

In addition, the outer side of the lower block 200 is formed with a plurality of screw holes 220 to which the fastening screw 120 can be engaged. In addition, a plurality of coupling waveguides 230 connecting adjacent resonators are formed at a predetermined angle on the upper surface of the lower block 200, and dielectrics are inserted into the coupling waveguides 230 so that adjacent resonators are respectively inserted. Combine with each other. In this case, the coupling waveguide 230 is not formed between the resonators connected to the input / output terminals.

On the other hand, the respective coupling waveguide 230 is inserted into the lower end of the screw 140 penetrating the upper block 100, the coupling between each resonator by the user adjusts the insertion depth to the waveguide 230 of the screw 140 The amount can be adjusted.

In addition, an input / output coupling passage 240 is formed on an upper surface of the lower block 200 to connect an input / output terminal and each resonator opposite thereto, and the input / output coupling passage 240 has a dielectric inserted therein so that an external input is formed. It provides a signal and a path of a signal output to the outside.

On the other hand, the speed of light (3 × 10 ⁸ ㎧) is c, the dielectric constant of the dielectric material is ε _r , and the radius and height of the resonator are a and d, J _n (x) in the Bessel function for TM [TE] mode. When the m th root of [J _n '(x)] is represented by x _nm , the resonant frequency f _nm1 of the resonator is calculated by the following equation (1).

In the above equation, it can be seen that the smaller the order of the mode, the filter can be implemented with a resonator having a small radius for the same resonant frequency.

In the present embodiment, in order to obtain excellent attenuation characteristics in the stop band, a sudden attenuation at the transition point of the frequency band can be obtained by placing the attenuation pole frequency at which the transmission characteristic becomes "0" near the resonance frequency of the TE ₁₁ mode. have. In addition, in the cylindrical resonator, the attenuation pole in which the TE ₂₁₁ and the TE ₃₁₁ cancel each other and the transmission characteristic is "0" can be obtained. Therefore, when manufacturing the filter of the present embodiment, the shape ratio of the resonator is appropriately selected so that the coupling waveguide ( By adjusting the angle between 230), the mode adjacent to the TE ₁₁ mode can be TE ₂₁₁ and TE ₃₁₁ .

On the other hand, TE, if the _first mode is to be twice the resonator diameter, the length of the Q value is twice as large, the cavity than the mode of the other low order, the cylindrical resonator can be obtained the greatest quality factor (Q) value, wherein The insertion loss of the filter is the smallest. Therefore, the manufacturer of the filter selects the appearance ratio (2a / d) of the resonator in consideration of the size and quality factor of the resonator, and accordingly inserts a dielectric having a high dielectric constant into the resonator to reduce the size of the filter. Is approximately It can be made inversely proportional to.

If the contour ratio of the resonator is 1.6 with respect to the resonant frequency 2 Hz in the TE ₁₁ mode, the diameter and length of the resonator according to the dielectric constant of the dielectric inserted into the cylindrical resonator are shown in Table 1 below.

ε _r = 1 ε _r = 20 ε _r = 40 ε _r = 75 Diameter (cm) 21.8 4.8 3.5 2.5 Length (cm) 13.6 3 2.19 1.56

As described above, the filter of the present embodiment can adjust the attenuation characteristics of the filter, the ripple in the pass band, and the like by using the ratio of the coupling waveguide 230 between the resonators, the length, and the diameter to the length of the resonator. Response characteristics can be obtained.

On the other hand, with respect to the positional change of the coupling waveguide 230 formed between the resonators, the resonant frequency of the TE ₁₁ mode is hardly affected, while the resonant frequencies of the TE ₂₁₁ and TE ₃₁₁ depend on the positional change of the coupling waveguide 230. Done. Therefore, the attenuation poles existing between the resonance modes also depend on the positional change of the coupling waveguide, so that the attenuation poles are placed near the resonant frequency of the TE ₁₁ mode by adjusting the angle between the coupling waveguides, thereby providing a sharp attenuation at the transition point of the frequency band. You will get it.

The present invention described above is not limited to the above-described embodiments and drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have

In the cylindrical cavity type high frequency filter according to the present invention as described above, it is possible to eliminate unnecessary frequency response by adjusting the angle of the coupling waveguide, to obtain a rapid attenuation at the transition point of the frequency band, and to control the resonator by controlling the metal cover and screw. Since it is possible to control the amount of coupling between the resonator and the micro-property control, it is easy to correct the error generated in the manufacturing process of the filter.

In addition, since the dielectric having excellent dielectric constant is inserted, the filter can be miniaturized, and since a separate means for supporting and fixing the dielectric is unnecessary, the manufacturing is simple, but there are other effects.

In addition, the filter of the present invention has a low insertion loss characteristic because the structure of the resonator is simple and the quality factor is large.

Claims (3)

An upper block having a plurality of cylindrical holes formed therein; A lower block coupled to the upper block and having a plurality of cylindrical grooves communicating with a plurality of cylindrical holes formed in the upper block; A plurality of resonators formed by inserting a dielectric into the cylindrical hole of the upper block and the cylindrical groove of the lower block; A coupling passage formed on an upper surface of the lower block and connecting two of the resonators to input and output terminals of a signal, respectively; And A coupling waveguide formed on an upper surface of the lower block and connecting adjacent resonators among remaining resonators except for resonators connected to the input and output terminals; Cylindrical cavity type high frequency filter comprising a. The method of claim 1, And a metal cover inserted into each cylindrical hole of the upper block so as to be movable in order to adjust the resonant frequency and passband characteristics of the resonator. The method of claim 1, And a conductive member penetrating between the cylindrical holes of the upper block so as to correspond to the coupling waveguide of the lower block to adjust the coupling amount between the resonators, and fastened to be movable.