KR20000041041A - Incorporated dielectric filter - Google Patents

Abstract

PURPOSE: An incorporated dielectric filter is provided to adjust the attenuation characteristics simply according to the bent number of a coil pattern by providing the coil pattern bent consecutively in a rectangular shape. CONSTITUTION: A dielectric block(10) is formed in a rectangular shape and the entire surface of the block(10) is formed with a conductive electrode except for one side. two consonant holes(17, 18) pass through from an open surface(15) without a conductive electrode of the dielectric block(10) to a surface opposite to the open surface(15), and have conductive electrodes in the inner surfaces thereof. An input electrode(16a) and an output electrode(16b) connect the ground electrode(13) on an external electrode of the dielectric block(10). Conductive electrodes(17a, 18a) are connected between the holes(17, 18).

Description

Integral Dielectric Filter

The present invention relates to an integrated dielectric filter used as a band pass filter in a high frequency region in a wireless communication device, and more particularly, to attenuate out-of-band signals in a frequency region higher than a pass band, The present invention relates to an integrated dielectric filter that is easy to predict the adjustment value.

In general, the dielectric filter is to achieve a desired passband characteristics by connecting a plurality of dielectric blocks having a coaxial resonator, the integrated dielectric filter is one step from the dielectric filter, a plurality of coaxial in one dielectric block The structure is simplified by forming a type resonator.

The dielectric filter is used as a bandpass filter to obtain a signal of a desired channel band only in a mobile communication device such as a car phone or a mobile phone using a high frequency band as a communication band. Therefore, the dielectric filter has a small size, light weight, and high impact resistance. This is required and a bandpass characteristic of 20 to 30 MHz is required.

Various structures of an integrated dielectric filter have been proposed in order to obtain such characteristics, and FIG. 1 is a perspective view showing a configuration of an example of a conventional integrated dielectric filter. As shown in FIG. 1, a conventional integrated dielectric filter has a rectangular shape and includes a dielectric block 1 having a conductor electrode formed on an entire surface except one surface thereof, and a conductor electrode of the dielectric block 1 not formed. Two resonant holes 7 and 8 formed to penetrate from the surface 5 to the opposite surface and have conductor electrodes formed on the inner surface thereof, and short-circuit with the ground electrode 3 on the external electrode of the dielectric block 1; An input electrode 6a and an output electrode 6b formed in an A-shape, conductor electrodes 7a and 8a formed on the open surface 5 in connection with internal electrodes of the two resonance holes 7 and 8, and A ground pattern 9 is formed between the two resonance holes 7 and 8 of the open surface 5 to extend from the ground electrode 3 to face each other.

In this configuration, the mutual capacitance and mutual inductance between the two resonance holes 7 and 8 are distorted due to the ground pattern 9 in the electric field between the two resonance holes. As a result, the mutual capacitance and the mutual inductance can be adjusted by adjusting the line width, the length of the ground pattern 9 and the gap between the two patterns. That is, as the shape of the ground pattern 9 is changed, the position of the attenuation poles in the pass band can be moved by adjusting mutual capacitance and mutual inductance.

In other words, in the conventional integrated dielectric filter, the ground pattern extending from the ground electrode is formed at the portion where the electric field of the open surface is the strongest and distorts the electric field, thereby reducing mutual capacitance and increasing self capacitance. As a result, mutual capacitance between the two resonant holes decreases, while mutual inductance increases to form an attenuation pole in the high frequency region based on the pass band.

However, in the structure of the conventional integrated dielectric filter, there is a problem that it is difficult to predict the attenuation characteristics for the bandpass for the transmitter filter from the deformation of the shape of the ground electrode in the design stage of the dielectric filter. That is, through the two-dimensional simulation, there was a problem that it is impossible to predict the proper shape for the ground pattern.

In addition, even when the tuning operation for adjusting the attenuation characteristic by the ground electrode is performed, since the amount of change in mutual capacitance and mutual inductance with respect to the shape change of the ground electrode cannot be calculated numerically in relation to the shape change, an appropriate attenuation characteristic Since the tuning operation to obtain a number of times repeatedly performed has a problem that the work is complicated and the time required to increase.

Therefore, the present invention has been made to solve the above-mentioned conventional problems, and its object is to provide an integrated dielectric filter for the transmitter stage, and to easily change the amount of change in mutual inductance and mutual capacitance between resonance holes in the open surface of the dielectric block. An object of the present invention is to provide an integrated dielectric filter having a ground pattern formed in a predetermined pattern so as to be predictable.

1 is a perspective view showing a configuration according to an example of a conventional integrated dielectric filter.

Figure 2 is a perspective view showing the configuration of an integrated dielectric filter in accordance with an embodiment of the present invention.

3 is a perspective view showing the configuration of an integrated dielectric filter according to another exemplary embodiment of the present invention.

4 is an equivalent circuit diagram of an integrated dielectric filter in accordance with an embodiment of the present invention.

5 is a graph showing the characteristics of the integrated dielectric filter of the present invention.

Explanation of symbols on the main parts of the drawings

10 Dielectric block 13 Grounding electrode

15.Open 16a ... Input electrode

16b ... Output electrode 17,18 ... Resonance hole

17a, 18a ... Conductor electrode 19, 19 '... Coil electrode

In order to achieve the above object, the integrated dielectric filter according to the present invention includes a dielectric block, a plurality of resonant holes formed through the front and rear surfaces of the dielectric block and having electrodes formed therein, and the front surface of the dielectric block. Ground electrodes formed on all outer surfaces except the input and output electrodes formed by short-circuiting a portion of the ground electrodes with other portions, and open electrodes on which no electrodes of the dielectric block are formed are connected to the inner electrodes of the resonance holes, respectively. It characterized in that it comprises a coil pattern between the conductor electrode and the conductor electrode in the form of a successive bent in a square shape, both ends thereof are connected to the conductor electrode, respectively.

In addition, in the integrated dielectric filter according to the present invention, the coil pattern is bent up and down successively to connect the conductor electrode.

In addition, in the integrated dielectric filter according to the present invention, the coil pattern is bent from side to side to connect the conductor electrode.

Figure 2 is a perspective view showing the configuration of an integrated dielectric filter in accordance with an embodiment of the present invention. As shown in FIG. 2, the integrated dielectric filter according to the exemplary embodiment of the present invention includes a dielectric block 10 having a rectangular shape and having conductor electrodes formed on the entire surface except one surface thereof, and a conductor of the dielectric block 10. Two resonant holes 17 and 18 formed through the open surface 15 where the electrode is not formed to the opposite surface and having a conductive electrode formed therein, and grounded on the outer electrode of the dielectric block 10. A conductor electrode formed on the open surface 15 connected to the input electrode 16a and the output electrode 16b formed in an L-shape by shorting with the electrode 13 and the internal electrodes of the two resonance holes 17 and 18. The coil electrode pattern 19 formed in a predetermined pattern is connected by connecting the conductor electrodes 17a and 18a between the 17a and 18a and the two resonance holes 17 and 18 of the open surface 15. It is made.

In the above-described configuration, the coil electrode pattern 10 is formed to have a predetermined width, one end of the coil pattern 19 is connected to the conductor electrode 17a connected to the internal electrode of the resonance hole 17, The other end of the coil pattern 19 is connected to the conductor electrode 18a connected to the internal electrode of the resonance hole 18. In this case, the coil pattern 19 is formed of a conductive material having an inductance component, and is formed of a concave-convex pattern formed by successively bending a rectangular shape between two conductor electrodes.

At this time, the number of times the coil pattern 19 is bent may vary depending on the mutual capacitance component value to be adjusted. That is, as the number of bending of the coil pattern 19 increases, the mutual capacitance decreases, and the mutual inductance increases, so that the attenuation characteristic of the pass band for the high frequency band can be adjusted.

On the other hand, Figure 3 is a perspective view showing the configuration of an integrated dielectric filter according to another embodiment of the present invention. As shown in FIG. 3, in the integrated dielectric filter according to another embodiment of the present invention, the coil pattern 19 ′ is left and right unlike the bending direction of the coil pattern 19 is bent up and down in one embodiment of FIG. 2. It is formed to be bent so that the traveling direction is formed up and down. Also in the integrated dielectric filter according to this configuration, as in the integrated dielectric filter shown in FIG. 2, the mutual capacitance and mutual inductance between the two resonance holes 17 and 18 are adjusted by adjusting the number of bendings of the coil pattern 19 '. The attenuation characteristic can be changed by adjusting.

Since the operation of the integrated dielectric filter according to each structure illustrated in FIGS. 2 and 3 is the same, the operation of the integrated dielectric filter according to the present invention will be described below with reference to FIG. 2.

4 shows an equivalent circuit diagram of an integrated dielectric filter in accordance with the present invention. 4 to 22 show a coaxial resonator formed by a resonance hole 17 having a conductor electrode 17a formed therein. L1 and C1 are determined by a transmission line and ground by the resonance hole 17. It is self inductance and self capacitance.

Reference numeral 23 denotes a coaxial resonator formed by another resonance hole 18 having an internal electrode 18a, and L2 and C2 denote magnetic inductances formed between the transmission line and ground by the other resonance hole 18, and C2 It is magnetic capacitance. In addition, 21 is a coil pattern 19 having one end connected to each of the two conductive electrodes 17a and 18a connected to the internal electrodes of the two resonance holes 17 and 18 on the open surface 15 and bent more than a predetermined number of times. As the resonator circuit shown by, Lm and Cm represent mutual inductance and mutual capacitance formed between two transmission lines, that is, two resonance holes 17 and 18.

In addition, CO1 denotes a capacitance between the input electrode 16a and the conductor electrode inside the resonance hole 17, and CO3 denotes a capacitance between the resonance hole 18 and the output electrode 16b on the output terminal side.

Therefore, the attenuation ratio at the desired frequency can be adjusted by adjusting the mutual capacitance Cm and the mutual inductance Lm formed between the two coaxial resonators 17 and 18. That is, the frequency at which the attenuation poles are formed can be adjusted by adjusting the number of bendings of the coil pattern 19.

In other words, when the number of bending of the coil pattern 19 is increased, the mutual capacitance Cm between the two resonance holes 17 and 18 decreases and the mutual inductance Lm increases, so that the attenuation poles in the high frequency region based on the pass band are increased. Is formed. On the contrary, when the number of bending of the coil pattern 19 is reduced, the mutual capacitance Cm between the two resonance holes 17 and 18 increases and the mutual inductance Lm decreases, so that the attenuation poles in the pass band can be adjusted. .

At this time, by implementing the inductance component between the two resonant holes 17, 18 in a visible coil pattern, it is easy to predict the change in the mutual capacitance value. The change amount of mutual inductance Lm according to the number of bending of the coil pattern 19 can be easily calculated by the capacitance value being inversely proportional to the separation distance between the two electrodes and proportional to the electrode area. That is, as the number of bending of the coil pattern 19 increases, the distance between the electrodes forming the coil pattern 19 decreases, so that the magnetic capacitance increases, thereby increasing the mutual inductance Lm.

Figure 5 is a graph showing the filter characteristics of the integrated dielectric filter according to the present invention as described above, the dotted line is a graph showing the gain with respect to the frequency of the conventional dielectric filter, the solid line shows the gain with respect to the frequency of the dielectric filter according to the present invention As shown in the graph, as shown, a high attenuation ratio can be obtained in the high frequency region (point 5) based on the pass band. In addition, the attenuation electrode may be moved according to a desired characteristic by adjusting a bending frequency of the coil pattern 19.

The integrated dielectric filter according to the present invention is not limited to the above-described embodiments, and may be variously modified and implemented within the range permitted by the technical idea of the present invention.

As described above, the integrated dielectric filter according to the present invention includes a coil pattern having both ends connected to the conductive electrode connected to the internal electrode of the resonance hole and being bent in succession in a square shape, thereby adjusting the number of bending of the coil pattern. It is possible to provide an integrated dielectric filter that can easily adjust the damping characteristics.

In addition, by converting the number of bending of the coil pattern in the design step it can provide an advantage that the prediction of the mutual inductance component between the resonance holes can be easily. That is, by implementing the inductance components between the resonance holes in a visible coil pattern, it is possible to obtain an effect of easily predicting an appropriate mutual inductance value.

Claims (3)

Dielectric blocks, A plurality of resonance holes formed through the front and rear surfaces of the dielectric block and having electrodes formed therein; A ground electrode formed on all outer surfaces except the front surface of the dielectric block; An input / output electrode formed by shorting a portion of the ground electrode with another portion; A conductor electrode connected to an internal electrode of the resonance hole on an open surface on which the electrode of the dielectric block is not formed; And a coil pattern connected to the conductor electrodes in a quadrangular shape and continuously connected to the conductor electrodes. The method of claim 1, And the coil pattern is bent up and down successively to connect the conductor electrodes. The method of claim 1, The coil pattern is formed to be bent to the left and right in order to connect the conductor electrode.