KR100959073B1 - Radio frequency filter and?tuning structure therein - Google Patents

Abstract

A tuning structure of a high frequency filter having a receiving space and a resonator is provided with a tuning adjusting screw which is fastened to a screw hole of a cover at a corresponding position of an upper portion of the resonator, A first tuning adjusting screw in the form of a tube having a structure and having a female screw or a full contact structure inside the screw hole of the cover and a male screw or a pin structure fastened to the female screw or contact structure inside the first tuning adjusting screw The sprocket consists of a second tuning adjustment screw in the form of a rod.

RF, filter, tuning, resonance, cavity, temperature

Description

[0001] DESCRIPTION [0002] RADIO FREQUENCY FILTER AND TUNING STRUCTURE THEREIN [0003]

The present invention relates to a radio frequency (RF) filter, and more particularly to a frequency tuning structure in a high frequency filter.

High-frequency filters (DR filter, cavity filter, waveguide filter, etc.) have a structure of a kind of circuit box for resonating high frequency, especially very high frequency. Generally, a resonant circuit by a coil and a capacitor is not suitable for forming a very high frequency because of a large radiation loss. The RF filter has a resonance cavity formed of a DR (Dielectric Resonator) or a metal resonator in a cavity of a metallic cylinder or a rectangular parallelepiped surrounded by a conductor, so that only an electromagnetic field having a natural frequency exists, And has a structure that enables resonance of a very high frequency.

The RF filter using such a DR or metal resonator rod is disclosed in Korean Patent Application No. 2002-84938 (name: radio frequency filter having a dielectric with a high dielectric constant and a high selectivity value, Applicant: (Filed on December 27, 2002) and Patent Application No. 2002-52351 (name: Radio Frequency Filter with Spring Nut, Applicant: K.M. W. Co., Inc., inventor: Jong-Kyu Park, filed 2002 August 31, 2008), and the like.

Since the RF filter using the DR or metal resonator rods has a small insertion loss and is advantageous in high output, it is applied to almost all the transmission / reception communication equipment such as a mobile communication base station, a repeater, a broadcasting repeater and a satellite communication system. They are also used for bandpass filters and various shapes and structures are being developed depending on the required filtering characteristics.

Such an RF filter is a cover that divides a space in a housing into a plurality of accommodating spaces, a resonator of DR or a metal resonator rod is provided in each of the divided accommodating spaces, and a tuning adjusting screw provided at a position corresponding to the resonator And the housing is sealed. The RF filter having such a configuration is inductive and capacitive coupled by the interaction between the respective components, thereby transmitting a signal of a specific frequency band. At this time, the capacitance between the resonator and the tuning adjusting screw is adjusted by precisely adjusting the distance between the resonator and the tuning adjusting screw, thereby performing precise frequency tuning.

However, when the ambient temperature at which the RF filter is used changes, the receiving space, the resonator, and the tuning adjusting screw are subject to heat shrinkage and expansion. In particular, when used as a high-power transmission filter, a significant amount of heat is generated due to insertion loss And the heat shrinkage and swelling are caused by the temperature change caused by the generated heat. And adjusting a capacitance value between the resonator and the tuning adjusting screw to cause resonance to occur at a desired frequency. The RF filter structure includes a capacitance value due to a change in interval of each component, and a change in inductance value due to a change in length of the resonator The characteristic of the filter is changed according to the change of the characteristic of the filter.

In order to solve this problem, it is necessary to determine the interval between the resonator and the tuning adjusting screw or cover so that the inductance value and the capacitance value due to the expansion and contraction of each component at a specific frequency can complement each other. There is a disadvantage in that it takes a lot of time and costs, and it is fundamentally impossible to fabricate an RF filter which can be variably applied to a plurality of channels (frequency bands).

Therefore, a material such as Invar or the like having a very small coefficient of thermal expansion was used for the conventional RF filter. However, since the material of the invar is difficult to process as compared with other materials (Al, Fe, Bs, etc.) and the material cost is high, it is difficult to process the RF filter using the RF filter. there was.

Accordingly, it is an object of the present invention to provide a tunable filter that facilitates the process of fabricating a filter, thereby reducing process time and cost, enabling adaptive tuning and efficient tuning according to temperature conditions, Frequency filter and a tuning structure thereof.

In order to accomplish the above object, the present invention provides a tuning structure for a high-frequency filter having a receiving space and a resonator, the tuning adjusting screw including a tuning adjusting screw which is fastened to a screw hole of the cover at a corresponding position of the resonator ,

Wherein the tuning adjusting screw has a tubular first tuning adjusting screw having an externally threaded structure and fastened to a screw hole of the cover and having a female screw structure therein and a male screw structure fastened to a female screw structure inside the first tuning adjusting screw And a second tuning adjusting screw in the form of a rod having a first end and a second end.

As described above, since the tuning structure of the high-frequency filter according to the present invention does not use a conventional invar material, it is possible to simplify the manufacturing process and reduce the processing time and cost. In addition, the tuning structure of the high-frequency filter according to the present invention enables adaptive tuning and efficient tuning according to temperature conditions, and enables easy tuning even when the frequency band of the corresponding filter is shifted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be appreciated that those skilled in the art will readily observe that certain changes in form and detail may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. To those of ordinary skill in the art.

FIG. 1 is a tuning structure of a high-frequency (RF) filter according to an embodiment of the present invention. FIG. 2 shows a structure of one accommodation space among a plurality of accommodation spaces of a filter, A filter structure having, for example, four cells is shown as a structure of an RF filter employing a tuning structure according to an embodiment of the present invention. As shown in FIGS. 1 and 2, each cell of the RF filter may be provided with a resonator 12 using, for example, a metal resonator rod in which a hollow portion is formed to resonate and pass a desired frequency. At this time, a tuning adjusting screw 10 having a structure according to a feature of the present invention is fastened to the screw hole of the cover 16 at a corresponding position on the upper part of the resonator 12. [ In addition, the RF filter includes a plurality of coupling adjusting screws 10, which are respectively provided at positions corresponding to the windows formed in the diaphragm between the cells.

The tuning adjusting screw 10 is not a general screw type but a double structure. That is, the tuning adjusting screw 10 has a tubular first tuning adjusting screw 102 having a male thread structure on at least a part of the outside and fastened to a corresponding screw hole of the cover 16, And a second tuning adjusting screw 104 in the form of a rod having a male screw structure which is fastened to a female screw structure inside the first tuning adjusting screw 102. That is, the rod-shaped second tuning adjusting screw 104 has a structure to be fitted in the inner hole of the first tuning adjusting screw 102 in the form of a tube.

At this time, the end of the first tuning adjusting screw 102 facing the resonator 12 is formed in a disk shape so as to have a larger area facing the resonator 12, and the resonator 12 12 are inserted into the hollow portion of the resonator 12. [0050] The first tuning adjusting screw 102 is fixed on the cover 16 through the first nut 103 and the second tuning adjusting screw 104 is fixed to the cover 16 through the second nut 105, (I.e., on the opposite end of the resonator 12 opposite to the resonator 12).

In the RF filter structure according to the present invention, the resonator 12 may be made of various materials such as iron (Fe) instead of Invar, and the tuning adjusting screw 10 may be made of brass Bs) and various other materials.

In the temperature environment, the capacitance value between the tuning adjusting screw 10 and the resonator 12 and the inductance value due to the change of the length of the resonator are greatly influenced, and in the frequency band, It is possible to experimentally determine the capacitance value between the adjusting screw 10 and the resonator 12. At this time, it is possible to adjust the RF filter to a desired frequency band using the second tuning adjusting screw.

 In the present invention, the first tuning adjusting screw 102 and the second tuning adjusting screw 104 are appropriately adjusted so as to be complementary to each other individually through a temperature test as described later. Thus, by adjusting the capacitance value thereof, .

More specifically, first, tuning of the RF filter is performed by adjusting the tuning adjusting screw 10 at room temperature, and then the temperature of the RF filter is increased by applying heat to the RF filter through a separate heating device , The housing including the cover 16 of the RF filter, and the resonator 12 and the tuning adjusting screw 10 are expanded to perform a temperature test to observe the frequency variation.

During the temperature test, the volume of each component of the RF filter expands when the temperature rises. The distance between the first tuning adjusting screw 102 and the resonator 12 is made to be longer than the distance between the first tuning adjusting screw 102 and the resonator 12, Which causes a phenomenon in which the frequency is increased. Conversely, the amount by which the tuning adjusting screw 10 and the resonator 12 are stretched by themselves increases the inductance value of the resonator 12 and causes a phenomenon of decreasing the frequency because the gap between the resonator and the tuning adjusting screw 10 is reduced .

If the frequency is increased at a high temperature as a result of observing the frequency variation at the time of the temperature test, the capacitance value between the resonator 12 and the first tuning adjusting screw 102 increases as the accommodation space 14 increases. It can be seen that the amount of reduction is larger than that of the resonator 12 and the tuning adjusting screw 10, which is larger than that of the resonator 12 and the tuning adjusting screw 10, so that the capacitance value becomes smaller when viewed as a whole.

In order to compensate for this, the gap between the resonator 12 and the first tuning adjusting screw 102 is made more distant so that the sensitivity of the capacitance value formed between them is reduced. At this time, the second tuning adjusting screw 104 is tuned so that the end portion thereof is further inserted into the hollow portion of the resonator 12, so that the resonance frequency is adjusted to a desired band.

When the frequency is lowered at a high temperature as a result of observing the frequency variation during the temperature test, the capacitance between the resonator 12 and the first tuning adjusting screw 102 increases as the accommodation space 14 increases. It can be seen that the resonator 12 and the tuning adjusting screw 10 are larger and larger than the decreasing amount, which is due to the capacitance increase when viewed as a whole.

In order to compensate for this, the gap between the resonator 12 and the first tuning adjusting screw 102 is made to be closer to each other so that the sensitivity of the capacitance value formed therebetween is tuned. At this time, the second tuning adjusting screw 104 is tuned so that the end portion of the second tuning adjusting screw 104 is further projected to the hollow portion of the resonator 12, so that the resonance frequency is adjusted to a desired band.

At this time, in the case of the second tuning adjusting screw 104, there is no change in the interval between the resonator and the tuning adjusting screw at the time of the temperature change, and therefore the internal capacitance of the resonator 12 is not greatly affected.

As described above, the tuning structure of the RF filter according to the present invention uses a structural characteristic of each other to move a desired frequency band with the first and second tuning adjusting screws 102 and 104, and at the same time to adjust the gap with the resonator 12 So that the temperature stable point can be found at a frequency determined by the length ratio.

At this time, in the RF filter structure according to the present invention, the tuning adjusting screw 10 can be used in combination with two or more different materials (Fe, Bs, Al, etc.).

As described above, the RF filter and its tuning structure according to an embodiment of the present invention can be performed. While the present invention has been described with reference to the exemplary embodiments, it is to be understood that various changes may be made without departing from the scope of the present invention. . For example, in the above description, it is explained that the resonator is formed in the shape of a hollow and the end of the second tuning adjusting screw is inserted therebetween, so that the mutual coupling is performed. However, Various types of coupling structures may be employed. In the above description, the first and second tuning adjusting screws are coupled to each other in such a manner that the first and second tuning adjusting screws are coupled to each other. However, the second tuning adjusting screw can be simply slidably moved The first tuning adjusting screw of the first tuning adjusting screw. In this case, a separate mechanism may be further provided on the outside in order to fix the position of the second tuning adjusting screw.

Thus, various modifications of the present invention can be made, and thus the scope of the present invention should not be limited by the illustrated embodiments but should be determined by equivalents of the claims and the claims.

1 is a diagram illustrating a tuning structure of a high-frequency filter according to an embodiment of the present invention.

2 is a structural view of a high-frequency filter employing a tuning structure according to an embodiment of the present invention

Claims (9)

In a tuning structure of a high-frequency filter having a receiving space and a resonator, And a tuning adjusting screw for tuning a resonance frequency installed in a structure corresponding to a screw hole formed in a housing opposed to an upper portion of the resonator at a corresponding position of the resonator, A first tuning adjusting screw in the form of a tube having a male thread structure on the outside and fastened to the screw hole and having a female screw structure therein and being capacitively coupled to the resonator at an end opposite to the resonator; And a second tuning adjusting screw in the form of a rod having a male screw structure which is fastened to a female screw structure inside the first tuning adjusting screw and which is capacitively coupled to the resonator at an end opposite to the resonator. Tuning structure. The tuning structure of a high-frequency filter according to claim 1, wherein an end portion of the first tuning adjusting screw opposed to the resonator is formed in a disk shape so as to have a larger area opposite to the resonator. The tuning structure of a high-frequency filter according to claim 1, wherein an end portion of the second tuning adjusting screw, which is opposite to the resonator, is inserted into a hollow portion formed in the upper portion of the resonator. The tuning structure of a high-frequency filter according to claim 1, wherein the tuning adjusting screw is made of at least one of iron (Fe), brass (Bs), and aluminum (Al). In a high frequency filter formed of a plurality of accommodating spaces, A resonator provided in the accommodation space and having a hollow portion for allowing a predetermined frequency to resonate, And a tuning adjusting screw for tuning a resonance frequency installed in a structure corresponding to a screw hole formed in a housing opposed to an upper portion of the resonator at a corresponding position of the resonator, A first tuning adjusting screw in the form of a tube having a male thread structure on the outside and fastened to the screw hole and having a female screw structure therein and being capacitively coupled to the resonator at an end opposite to the resonator; And a second tuning adjusting screw in the form of a rod having a male screw structure which is fastened to a female screw structure inside the first tuning adjusting screw and which is capacitively coupled to the resonator at an end opposite to the resonator. . The high-frequency filter according to claim 5, wherein an end of the first tuning adjusting screw opposite to the resonator is formed in a disk shape so as to have a larger area opposite to the resonator. 6. The high-frequency filter according to claim 5, wherein an end of the second tuning adjusting screw opposite to the resonator is inserted into a hollow portion formed in the upper portion of the resonator. The high-frequency filter according to any one of claims 5 to 7, wherein the tuning adjusting screw and the resonator are made of at least one of iron (Fe), brass (Bs) and aluminum (Al). The high-frequency filter according to any one of claims 5 to 7, wherein the resonator is a structure using a metal resonator rod.

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