KR100976251B1 - Non-contacting cavity filter using for matching tuning bar - Google Patents

Abstract

PURPOSE: A non-contact cavity filter is provided to improve an IM(intermodulation) property by forming a disk on one end of an antenna port. CONSTITUTION: A matching tuning bar(230) comprises first to third matching tuning bars(230a-230c). The first matching tuning bar is applied to a receiving port(102). The second tuning bar is applied to the first transmission port(103). The third matching tuning bar is applied to a second transmission port(104). The first matching tuning bar is positioned between the cavity resonator connected to the receiving port and the cavity resonator connected to the first transmission port. The second matching tuning bar is positioned on the rear of the cavity resonator connected to the first transmission port. The third matching tuning bar is positioned between the cavity resonator connected to the first transmission port and the cavity resonator connected to the second transmission port.

Description

Non-contacting cavity filter using for matching tunneling bar

The present invention provides a tuning rod (incomplete screw) or a Y contact formed inside an antenna port, an ANT port, a Tx port, and a Rx port of a body constituting a cavity filter. The present invention relates to a contactless cavity filter using a matching tuning rod that can increase the efficiency of the production process and attenuate intermodulation distortion (IMD) by adjusting the strength of the coupling by a tuning screw.

In this case, the cavity filter includes a duplexer and a triplexer in which a cavity resonator into which a tuning screw is inserted is formed.

In general, a filter is a kind of electronic circuit that passes only a signal waveform of a desired shape and filters out an unwanted waveform, and is composed of a combination of inductance L and capacitance C.

In addition, when multiple signals are sent through one line and collected or distributed again, a multiplexer is called a multiplexer, and a duplexer is a device in which one path is shared by two transmission signals (Tx) and one reception signal (Rx). (Duplexer), a device shared by three signals is called a triplexer, and the duplexer and triplexer are eventually combined circuit elements based on a filter.

In the frequency domain duplex (FDD) method applied to general RF mobile communication (for example, CDMA or AMPS), since one antenna uses a different transmission frequency and a reception frequency, signals of a transmission port, a reception port, and an antenna port are used. You use a duplexer that organizes the flows just as you want them to, without mixing them together.

The duplexer is composed of a BPF (Bandpass Filter) which passes only the transmitter frequency and a BPF that passes only the receiver frequency, and then properly matches the middle with the antenna. The shape and S parameters are shown as follows. .

First, S21 and S13, which means power transfer between the antenna (port 1), the reception (port 2), and the transmission (port 3), have a high pass through at each BPF pass frequency due to the filter characteristics, but 0dB in the pass band. There is an insertion loss that has a slightly smaller value. On the other hand, S23, which means power transfer between the transmitter and the receiver, is suppressed to the lowest in both the transmit and receive frequency bands and is isolated to minimize interference and noise.

The duplexer may be implemented by a combination of LC filters, but since the frequency selectivity is poor, in most cases, the duplexer is made by using a resonator, and a coaxial dielectric resonator (Coaxial Ceramic Resonator or Bar Dielectric Resonator) has a high Q value. Because it is mainly used.

The monoblock duplexer, which is a monoblock and connects L and C circuits through one side pattern, is more difficult to design and tune than the classical resonator combination type. In mass production, it is applied to most duplexers due to the advantages of low process variables, low cost, and good insertion loss because there is no metal film between resonators.

Also, in the field of high frequency filters, a cavity resonator, which is a microwave resonator using a resonance phenomenon of a cavity (cylindrical, cuboid, donut, etc.) surrounded by a conductor wall, is used.

On the other hand, a triplexer is a passive filter element that separates three frequency bands, and integrates a low pass, band pass, and high pass filter into three frequencies at once. Can be passed separately, the basic structure and principle is similar to the duplexer.

In a conventional filter (a duplexer will be described as an example) using a resonator, as shown in FIGS. 1 and 2, the antenna port 13, the transmit port 12, and the receive port 14 are electrically connected. The connecting pin 13a of the antenna port 13 is connected to the first transmitting resonator 11a and the first receiving resonator 11b by a wire, soldered, and replated to improve performance. Done.

In this case, passive intermodulation distortion (PIMD) caused by passive elements causes severe signal interference problems in the frequency domain of the receiver receiving the information, where IM (InterModulation) is most affected by the Y contact point. (Wire connected to ANT Port Pin)

Therefore, as shown in FIG. 2, there is a need for repeated connection position change by measurement to specify a region where the resonator and the wire are soldered in order to adjust the strength of the coupling and improve the IM characteristic.

The present invention uses a plurality of matching tuning bars for a Y-contact having a triangular structure formed inside an antenna port (ANT port), a reception port (Rx port), and a transmission port (Tx port) of a body. It is an object of the present invention to provide a contactless cavity filter using a matching tuning rod that adjusts the coupling strength by a contactless contact.

In addition, the present invention can reduce the work of soldering (wire) to the resonator (Reoldator) and the silver plating cost after soldering, and can improve the intermodulation distortion (PIMD) generated by the Y contact Another object is to provide a contactless cavity filter using a matching tuning rod.

The solid-state cavity filter using the matching tuning rod according to the present invention is provided with an antenna port and a transmitting / receiving port, a body having a cavity resonator therein, and a cover coupled to an upper side of the body and provided with a resonance tuning screw. In the filter configured, a triangular Y contact formed in the antenna port (ANT port), the reception port (Rx port) and the transmission port (Tx port) of the body to a plurality of matching tuning bar (Matching Tuning Bar) It is a technical feature to adjust the strength of coupling by a contactless state.

The contactless cavity filter using the matching tuning rod according to the present invention includes an antenna port (ANT port) 101, a reception port (Rx port) 102, and a transmission port (Tx port) 103 of the body 100 ( 104) By adjusting the strength of the coupling by adjusting the Y-contact point formed inside, the productivity is improved by simplifying the production process, increasing efficiency, and reducing silver plating cost and time after soldering. In addition, the excellent IM characteristic improved by more than 20 ~ 30dBc has the effect of attenuating intermodulation distortion (IMD).

Preferred embodiments of the present invention will be described in detail by the accompanying drawings.

3 is a perspective view of the contactless cavity filter using a matching tuning rod according to the present invention, Figure 4 is a cross-sectional view schematically showing that the tuning screw and the tuning rod is aligned by combining the body and the case of Figure 3, Figure 5 In the present invention is a schematic diagram showing the adjustment of the position of the tuning screw and the tuning rod with a network analyzer for impedance matching.

As shown in FIG. 3, the contactless cavity filter using the matching tuning rod according to the present invention includes an antenna port 101 and a transmission / reception port 102, 103, 104 and a cavity resonator 110 inside. A body 100 provided with; It is coupled to the upper side of the body 100 is composed of a cover 200 provided with a resonance tuning screw 210 and a matching tuning rod 230, the body 100 and the cover 200, respectively, a plurality of Coupling holes 120 and 220 are formed and tightly screwed together.

At this time, an antenna port (ANT port) 101 and a receiving port (Rx port) 102 of the body 100 so that the signal input from the antenna port 101 can exchange signals with the transmission and reception ports without signal distortion. And adjusting the strength of the coupling by contactless contacting the Y-contact having a triangular structure formed inside the Tx port 103 and 104 with a plurality of matching tuning bars 230 and matching impedance. It is a technical feature of the present invention.

As shown in FIG. 4, the resonance tuning screw 210 is inserted into the resonator 110, and the matching tuning rod 230 has one side fixed to the cover 200 and the other side the body 100. It is located in a specific area with a predetermined distance from the lower surface of the.

At this time, the matter for the tuning screw is already known technology, detailed description thereof will be omitted below.

In the present invention, for the convenience of understanding, the thread is formed on the whole, the tuning screw, the thread is formed only on a portion of the tuning rod (incomplete screw), and divided into the resonance tuning screw 210 and the matching tuning rod according to the frequency band used The diameter, length, and number of 230 are changed

Of course, the tuning rod and the tuning screw are similar because the basic hardware characteristics, it is possible to use a mixture of both.

Since the present invention is a contactless method using a matching tuning rod 230 to replace the conventional wire type Y contact, the matching tuning rod 230 is a first matching tuning rod 230a applied to the receiving port 102. And a second matching tuning rod 230b applied to the transmission port 1 103 and a third matching tuning rod 230c applied to the transmission port 2 104.

That is, the first matching tuning rod 230a is positioned between the cavity resonator connected to the reception port 102 and the cavity resonator connected to the transmission port 1 103, and the second matching tuning rod 230b transmits. Located in the rear side of the cavity resonator connected to the port 1 (103), the third matching tuning rod 230c is a cavity resonator connected to the transmission port 1 (103) and the cavity resonator connected to the transmission port 2 (104) It is located in between.

An installation position of the matching tuning rod 230 in the state in which the body 100 and the cover 200 are coupled is indicated by reference numeral 130 in FIG. 3.

In this case, as shown in FIG. 5, the matching tuning rod 230 manually adjusts the length projecting to the lower side of the cover 200 while impedance matching in the network analyzer 300. This greatly improves IM characteristics.

That is, the conventional wire method has an IM value of 140 to 150 dBc, but the contactless method according to the present invention exhibits excellent IM characteristics improved to about 20 to 30 dBc and more than 170 dBc.

In addition, the matching tuning rod 230 may be formed of any one of the tuning screw shape of the thread is formed as a whole, or an incomplete screw thread formed on one side to be coupled to the cover 200 by the nut.

The length of the matching tuning rod 230 protruding to the lower side of the cover 200 is determined by the frequency band in which the filter is used, which can be determined by a repeated test by the network analyzer 300, Depending on the environment, the tuning rods are M6, M3, M4, M5, M8, M16 and so on.

For example, when using a tuning rod of the M6 standard, within the reception path of the WCDMA, PCS, and DCS bands (Rx Path), the matching tuning rod 230 protrudes below the cover 200 within a range of 2 to 5 mm in length. In the path (Tx Path) it is determined within the range of 1 to 20mm.

In addition, in the reception path (Rx Path) of the GSM, CDMA, LTE bands, the length of the matching tuning rod 230 protruding to the lower side of the cover 200 is within a range of 10 to 18 mm, and in the transmission path (Tx Path), 18 to It is determined within the range of 22mm.

At this time, the length of the matching tuning rod 230 protrudes to the lower side of the cover 200 is changed by the material (iron, brass) or diameter, of course.

On the other hand, the antenna port 101, as shown in Figure 2, is formed with a straight connection pin 13a, the connection pin 13a is easy to solder (soldering), but radio waves in a wireless manner Loss occurs.

In order to improve this, in the present invention, as shown in FIG. 3, the disc 101a having a disc or polygonal plate shape protrudes at one end of the antenna port 101 inserted into the body 100, thereby causing an IM (InterModulation). ) To improve the characteristics.

The present invention as described above is not limited to the above-described specific embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various changes without departing from the gist of the present invention as claimed in the claims. will be.

1 is a plan view schematically showing a body of a conventional cavity filter,

FIG. 2 is a perspective view schematically showing that the antenna port and the cavity resonator of FIG. 1 are connected by wires;

3 is an internal perspective view of a contactless cavity filter using a matching tuning rod according to the present invention;

4 is a cross-sectional view schematically showing that the body and the case of FIG. 3 are combined to align the resonance tuning screw and the matching tuning rod.

Figure 5 is a schematic diagram showing the adjustment of the position of the resonance tuning screw and the matching tuning rod with a network analyzer for impedance matching in the present invention.

<Explanation of symbols for the main parts of the drawings>

100: body 101: antenna port

101a: Disk 102: Receive (Rx) port

103: Tx port 1 103: Tx port 2

110: cavity resonator 120, 220: coupling hole

130: matching position

200: cover 210: resonant tuning screw (Tuning Screw)

230: matching tuning rod 230a: first matching tuning rod

230b: second matching tuning rod 230c: third matching tuning rod

300: Network Analyzer

Claims (6)

In the filter is provided by the antenna port and the receiving port, the body is provided with a cavity resonator inside, and a cover coupled to the upper side of the body and provided with a resonance tuning screw, A plurality of Y contacts having a triangular structure formed inside the antenna port (ANT port) 101, the reception port (Rx port) 102, and the transmission port (Tx port) 103, 104 of the body 100 A solid state cavity filter using a matching tuning rod, characterized in that the strength of the coupling (Coupling) is adjusted by a contactless with a matching tuning bar (230). The method of claim 1, The matching tuning rods 230 may include a first matching tuning rod 230a applied to the reception port 102, a second matching tuning rod 230b applied to the transmission port 1 103, and a transmission port 2 104. ) Made of a third matching tuning rod (230c), The first matching tuning rod 230a is positioned between the cavity resonator connected to the reception port 102 and the cavity resonator connected to the transmission port 1 103, and the second matching tuning rod 230b is the transmission port 1. Located at the rear side of the cavity resonator connected to 103, the third matching tuning rod 230c is located between the cavity resonator connected to the transmission port 2 (104) and the cavity resonator connected to the transmission port 1 (103) Solid-state cavity filter using a matching tuning rod, characterized in that located. The method according to claim 1 or 2, The matching tuning rod 230 is a contactless using a matching tuning rod, characterized in that formed by any one of the tuning screw shape or the incomplete screw thread formed on one side of the screw thread is formed as a whole to be coupled to the cover 200 by the nut Cavity Filter. The method of claim 1, The matching tuning rod 230 is a contactless using a matching tuning rod, characterized in that manually adjusting the length of the projecting to the lower side of the cover 200 through the impedance matching process in the network analyzer (Network Analyzer) 300 Cavity Filter. The method of claim 4, wherein The length of the matching tuning rods 230 is a contactless cavity filter using a matching tuning rods, characterized in that determined within the range of 0.5 ~ 50mm according to the frequency band used. The method of claim 1, One end of the antenna port 101 is a solid-state cavity filter using a matching tuning rod, characterized in that the disk (101a) of the disc or polygonal plate-shaped protruding to improve the IM (InterModulation) characteristics.

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