KR200404256Y1 - Notch Tunable Radio Frequency Filter - Google Patents

Abstract

The present invention relates to a high frequency filter capable of adjusting the notch, the main body portion having a partition and a window portion formed in the partition so that a plurality of internal spaces are formed, a resonator portion mounted in the inner space of the main body portion, the frequency of the resonator portion A predetermined coupling capacitance inside the high frequency filter including a resonance adjusting unit for adjusting, a window adjusting unit formed in the window unit for adjusting the frequency bandwidth of the resonating unit, and a cover unit penetrating through the resonance unit and the window adjusting unit and coupled to the main body unit. The notch generating unit and the notch adjusting unit formed on the notch generating unit are formed to adjust a predetermined coupling capacity formed in the notch generating unit, thereby adjusting the notch characteristic formed in the filter to realize a steep skirt characteristic. The present invention relates to an adjustable high frequency filter.

Description

Notch Tunable Radio Frequency Filter

The present invention relates to a high frequency filter capable of notch adjustment, and more particularly, a notch adjusting part having a notch generating part inside the filter to adjust a coupling capacity, thereby adjusting notch characteristics formed on the filter to improve attenuation characteristics. This relates to a possible high frequency filter.

In general, the bandpass filter increases the insertion loss as the frequency moves away from the passband, and the slope of the slope is called a skirt characteristic. The slope of the skirt exhibits a frequency selective characteristic which is one of the important functions of the bandpass filter.

1 is an exploded perspective view of a conventional dielectric resonator notch filter.

As shown in FIG. 1, the conventional dielectric resonator notch filter 100 partitions a plurality of cavities 100a to be formed therein, and windows 105-1 to 105-7 for adjusting inductance and capacitance therein. Is provided with a plurality of partitions 101 formed thereon, a metal housing 102 having input and output connectors 103 and 104 on one side thereof, and a dielectric resonator 106 mounted in each cavity of the housing 102. -1 to 106-8, and one side is mounted to the input and output connectors 103 and 104 of the housing 102, respectively, and the other side is an outer surface of the resonator located in the vicinity of the input and output connectors 103 and 104. A notch generating means mounted at a predetermined position on the partition 101 of the housing 102 and the first end couplings 107 and 108 which form a loop as the current flows through the section 102 of the housing 102. 109 and the cover 110 is located on the upper side of the housing 102.

The notch generating means 109 includes a notch generating plate 112 for generating the notch, a metal connecting rod 113 mounted through the notch generating plate 112, and a central portion of the metal connecting rod 113. It is fixed to the notch generating plate 112 and the metal connecting rod 113 is composed of a Teflon (111) to prevent the short circuit to the partition (101).

In addition, a resonator support screw (not shown) for fixing the resonators 106-1 to 106-8 to the housing 102, and tuning for adjusting the resonant frequency mounted on the upper surface through the cover part 110, respectively. Screws 114-1 to 114-7 are provided. Here, eight resonators are provided in the housing 102 in two rows.

When a high frequency is input to the input connector 103, a current flows through the very short coupling dynamics to form a loop and an electromagnetic field is formed and transmitted to each resonator by inductive coupling through a window, and finally to the output connector 104. Is output. At this time, frequencies other than the specific frequency band are reflected through the input connector 103 terminal without resonating, and the resonant frequencies are tuned by the tuning screws 114-1 to 114-17.

Therefore, such a structure has a problem that it is difficult to output uniform notch characteristics as well as the productivity is reduced by the coupling capacity is changed by the processing tolerance generated when manufacturing the metal connecting rod 113.

The present invention is to improve the above problems, in order to improve the damping characteristics of the filter is provided with a notch generating portion inside the filter notch adjustment unit is rotated in the upper and lower directions at the top of the notch generating portion is a predetermined coupling By adjusting the capacity, the notch characteristic formed in the filter is adjusted so that the attenuation characteristic is improved, and the object thereof is to improve productivity and reliability.

One embodiment of the present invention for achieving the above object is a main body portion having a partition and a window portion formed in the partition so that a plurality of internal spaces are formed, a resonance portion mounted in the internal space of the body portion, the frequency of the resonance portion A high frequency filter comprising a resonance adjusting unit for adjusting, a window adjusting unit formed in the window unit for adjusting the frequency bandwidth of the resonating unit, and a cover unit penetrating through the resonance unit and the window adjusting unit and coupled to the main body unit, wherein one side of the partition It is characterized in that the notch generating portion is fixed to the notch generating portion and a predetermined coupling capacity is formed on the notch adjusting portion.

According to one embodiment according to the present invention, the notch generating portion is formed in the notch bar in which the coupling groove is formed in the central portion of the cylindrical metal, the groove formed in the lower surface of the rectangular dielectric to assemble the coupling groove and the upper surface of the dielectric. The notch adjustment unit is characterized in that consisting of the assembly hole is rotated and assembled.

According to one embodiment according to the present invention, the notch adjusting unit is rotated upward and downward through the cover part to the assembly hole of the notch generating unit to adjust a predetermined coupling capacity.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2a is an internal perspective view of a high frequency filter capable of notch adjustment according to an embodiment of the present invention, Figure 2b is a perspective view of a high frequency filter capable of notch adjustment according to an embodiment of the present invention.

As shown in FIGS. 2A and 2B, the notch-adjustable high frequency filter 200 includes input and output connectors 210 and 220 through which signals are transmitted and received, and partitions to form a plurality of internal spaces 230. 260 and a main body 240 provided with a window 270 formed in the partition 260, resonators 251 to 256 to be mounted in the internal space 230 of the main body 240, Resonance adjusting units 331 to 336 for adjusting the frequencies of the resonating units 251 to 256, and window adjusting units 340 to 344 formed in the window unit 270 for adjusting the frequency bandwidth of the resonating units 251 to 256. ), The resonator and the window adjusting unit (331 to 336, 340 to 344) through a high frequency filter comprising a cover portion 310 coupled to the main body portion 240, fixed to one side of the partition 260 And a notch generating unit 280 and a predetermined coupling capacitance formed thereon, rotated and adjusted on an upper portion of the notch generating unit 280. It composed of a value adjusting section 290.

The signal input to the input connector 210 is transmitted to the resonator through a feeder connected between the input connector 210 and the first resonator 251.

The main body 240 has a rectangular shape, and two columns are formed in the longitudinal direction by the partition 260, and three inner spaces 230 are formed in each row, and the center of each inner space 230 Resonators 251 to 256 formed in a cylindrical shape are coupled to the main body 240. The partition 260 of the main body 240 is formed with a window 270 for adjusting the coupling capacitance between the resonator 251 ~ 256.

The main body 240 of the main body 240 so that the window adjusting portion 340 made of an adjustment bolt for adjusting the inductive and capacitive coupling amount of the window portion 270 penetrates the cover portion 310 and is located in the window portion 270. It is assembled in the upper predetermined position.

The resonator parts 251 to 256 are formed of a cylindrical metal, and circular grooves are formed in each of them to accommodate the resonance adjusting part 330. Each of the six metal resonator parts 251 to 256 includes a first resonator part 251. ), The second resonator 252, and the like. In addition, a groove forming a quadrangular shape is formed at one side of the partition 260 between the second resonator 252 and the fifth resonator 255, and a predetermined coupling capacitance is formed in the groove. 280 is fixed.

The cover part 310 is formed with twelve through holes to penetrate the adjusting bolt and is coupled to the main body part 240.

The resonance adjusting units 331 to 336 are formed of six adjusting bolts penetrating through the cover part 310 and inserted into the respective resonance parts 251 to 256 mounted in the internal space 230 of the main body part 240. 6 protruding parts corresponding to the resonance adjusting parts 331 to 336 are formed on the outer surface of the cover part 270, and the protruding parts are rotated in the up and down directions to be formed by the resonating parts 251 to 256. The passband frequency is adjusted. In addition, window adjustment units 340 to 344 made of control bolts are inserted into each window unit 270 in parallel with the resonance adjustment units 331 to 336, and a window adjustment unit 340 is formed on an outer surface of the cover unit 270. Five protrusions corresponding to ˜344) are rotated in the up and down directions to adjust the coupling capacitance between the resonator parts 251 to 256, thereby changing the pass band width to be fixed on the outer surface of the cover part 310. Supported by nuts.

Figure 2c is an exploded perspective view of the notch generating unit according to an embodiment of the present invention.

As shown in FIG. 2C, the notch generating unit 280 is fitted into a groove of the partition 260, and is a quadrangular teflon 281 that is fixed to the bottom surface of the teflon 281. Is formed and assembled with the grooves 284 formed in the central portion of the notch bar 283 made of cylindrical metal.

In addition, a circular assembly hole is formed on an upper surface of the Teflon 281 so that the notch adjusting unit 290 made of a control bolt is assembled to the assembly hole by passing through the cover part 310 and the notch generating unit 280. Rotation in the upper and lower directions at the top of the), the predetermined coupling capacitance is finely adjusted, thereby adjusting the notch characteristics formed in the filter 200.

On the other hand, the signal through the resonator 251 ~ 256 is transmitted to the output connector 220 through a feeder connected between the resonator 256 and the output connector 220 at the end and is output to the outside.

3 is a graph of a frequency characteristic of a high frequency filter capable of notch adjustment according to an embodiment of the present invention.

As shown in FIG. 3, the notch adjustable high frequency filter 200 exhibits frequency characteristics having upper and lower notches 400 and 401 in upper and lower stop bands, and as a result, the notch characteristics are changed by the notch adjusting unit. Adjusted to improve steep skirt characteristics.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be determined by the scope of the utility model claims.

The present invention made as described above is provided with a notch generating portion inside the filter in order to improve the damping characteristics of the filter, the notch adjustment unit is rotated in the upper and lower directions at the top of the notch generating portion to adjust a predetermined coupling capacity, The notch characteristic formed in the filter is adjusted to implement a steep skirt characteristic, and has an effect of improving productivity and reliability.

1 is an exploded perspective view of a conventional dielectric resonator notch filter

Figure 2a is an internal perspective view of a high frequency filter capable of adjusting the notch according to an embodiment of the present invention

Figure 2b is a perspective view of a high frequency filter capable of adjusting the notch according to an embodiment of the present invention

Figure 2c is an exploded perspective view of the notch generating unit according to an embodiment of the present invention

Figure 3 is a graph of the frequency characteristics of the high frequency filter capable of notch adjustment according to an embodiment of the present invention

* Description of the main drawing codes *

100: notch filter 100a: cavity

101: partition 102: housing

103: input connector 104: output connector

105-1 ~ 105-5: Window 106-1 ~ 106-8: Resonator

107, 108: ultra-short coupling 109: notch generating means

110: cover 111: Teflon

112: notch generating plate 113: metal connecting rod

114-1 ~ 114-17: Tuning screw for resonant frequency adjustment

200: filter 210: input connector

220: output connector 230: internal space

240: main body 251 ~ 256: resonator

260: partition 270: window

280: notch generating unit 281: teflon

282: coupling groove 283: notch bar

284 groove 285 assemblyman

290: notch adjusting portion 310: cover portion

331 to 336: resonance adjustment unit 340 to 344: window adjustment unit

400: upper notch 410: lower notch

Claims (3)

Adjusting the frequency bandwidth of the resonator, the main body portion including the partition and the window portion formed in the partition, the resonator mounted in the inner space of the body portion, the resonance adjusting unit for adjusting the frequency of the resonator unit to form a plurality of internal spaces In the high frequency filter comprising a window adjusting portion formed in the window portion, the resonating portion and the window adjusting portion formed through the cover portion coupled to the main body portion, A notch generator fixed to one side of the partition to form a predetermined coupling capacity; And The notch adjustment high frequency filter, characterized in that the notch adjustment portion is formed on the notch generating portion. The notch generating unit of claim 1, wherein the notch generating unit comprises: a notch bar having a groove formed in a central portion of the cylindrical metal; Coupling grooves formed on a lower surface of a rectangular dielectric to assemble the grooves; And High frequency filter capable of adjusting the notch, characterized in that the notch adjustment portion is formed by rotating the assembly on the upper surface of the dielectric. The notch adjustment high frequency filter according to claim 1 or 2, wherein the notch adjustment unit is assembled to the assembling hole of the notch generation unit through the cover part to adjust a predetermined coupling capacity in the up and down directions.