KR100305581B1 - Dielectric duplexer having attenuation function of local oscillation frequency - Google Patents

Abstract

The present invention relates to an integrated dielectric duplexer having a local oscillation frequency attenuation function capable of attenuating a local oscillation frequency applied together with a transmission signal from a transmission circuit portion to improve noise characteristics at a receiver. When formed through the front and rear surfaces, the electrode is formed on the inner surface to form a plurality of resonant holes constituting the transmitting end and the receiving end, the ground electrode formed on the entire surface except the open surface formed with the resonance hole of the dielectric block, and the ground An integrated dielectric duplexer comprising an input / output electrode formed by shorting a part of an electrode with another electrode, the capacitance not being connected to another electrode pattern between one of the resonance holes and the ground electrode of the resonance holes constituting the transmitting end of the dielectric block. It is provided with the electrode pattern for sex coupling.

Description

Integrated dielectric duplexer with attenuation function of local oscillation frequency {DIELECTRIC DUPLEXER HAVING ATTENUATION FUNCTION OF LOCAL OSCILLATION FREQUENCY}

The present invention relates to an integrated dielectric duplexer used for a transmitting and receiving terminal in a mobile communication terminal of an ultra-high frequency band, and more particularly, to provide an attenuation characteristic for a local oscillating signal at a transmitting end so that an oscillating signal of the transmitting end is applied to the receiving end as noise. An integrated dielectric duplexer having a local oscillation frequency attenuation function that can be prevented.

In general, a duplexer is provided as an important part of a mobile communication device which is provided at an antenna terminal to apply a transmission signal from a transmission circuit unit to an antenna terminal and applies a reception signal received at the antenna terminal to the reception circuit unit. As described above, the duplexer 11 is provided between one antenna 10 and the transmission / reception circuit units 12 and 13 to provide a function of simultaneously receiving and transmitting signals.

The duplexer 11 is composed of a receiver filter and a transmitter filter, and the receiver filter has a pass characteristic with respect to the reception frequency and a stop characteristic with respect to the transmission frequency, while the transmitter filter has a pass characteristic with respect to the transmission frequency and a reception frequency. It is implemented to have a blocking property for.

Miniaturization is a prerequisite for a duplexer that satisfies these characteristics to be applied to a mobile communication device that is currently used. To satisfy this requirement, an integrated dielectric duplexer in which a transmitting end filter and a receiving end filter are formed in one dielectric block is required. to be.

The basic structure of the integrated dielectric duplexer is composed of a receiving end (RX) and a transmitting end (TX), as shown in Figure 6, which is constant so as to be parallel to each other through the two facing surfaces of the dielectric block 60 of the rectangular parallelepiped. A plurality of resonant holes 66 are formed at intervals, and internal electrodes are formed in the resonant holes 66, and ground electrodes 62 are formed on all surfaces except the one surface 61 on which the resonant holes 66 are formed. The electrode 67 is formed on the open surface 61 in which the electrode is not formed and extends with the electrode in the resonance hole 66. Then, a transmitting electrode 65 to be connected to the output end of the transmitting circuit part and a receiving electrode 63 connected to the input end of the receiving circuit part are formed on both sides of the open surface 61, respectively, and an antenna electrode 64 to be connected to the antenna end at the center thereof. ), A portion from the transmission electrode 65 to the antenna electrode 64 constitutes a transmission filter, and a portion from the antenna electrode 64 to the reception electrode 63 constitutes a reception filter.

These duplexers are mutually spaced to determine coupling capacitances formed between the plurality of resonance holes 66 and loading capacitances formed between the ground electrode 62 and each resonance hole 66. Should be maintained properly.

In addition, since the pass bands of the transmission filter and the reception filter are adjacent to each other side by side, the attenuation poles must be provided to each adjacent side to increase the signal separation characteristics, and the formation of such attenuation poles is performed by coupling between the resonance holes 66. By adjusting the capacitance.

In addition, the next generation mobile communication system (IMT-2000: International Mobile Telecommunication-2000) that realizes high-speed wireless communication of up to 2Mbits / sec, which is being developed nowadays, is not currently internationally unified. Since it is developed independently by the manufacturer, the specifications of the parts are very variable, and it is very important to respond appropriately and promptly to the needs of users.

In the development of such an IMT, in the duplexer, which is a core component of the RF stage, the attenuation characteristic of the local oscillation frequency of the transmitter acts as an important variable.The local oscillation frequency is a development method of a base station and a terminal separately from a transmission and reception frequency. It can vary depending on.

That is, as shown in Fig. 2, in the transmitting circuit section, the transmission signal fw is mixed with the local oscillation frequency fl generated by the local oscillator 21b and the mixer 21. In this case, the mixer 21 The sum frequency f1 + fw and the difference frequency fl-fw of the transmission signal fw and the local oscillation frequency f1 are output. Only the signal of the sum frequency fl + fw set according to the transmission frequency is passed through the band pass filter 22 and output, and this signal is applied to the transmission signal input terminal of the duplexer 11. In this case, the local oscillator 21b may be transmitted to the duplexer 11 without being filtered. If the local oscillation signal is passed as it is, the local oscillator 21b may be transmitted to the receiving circuit unit 12 through the duplexer 11 to deteriorate the signal characteristics. Can be.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described various problems, and an object thereof is to attenuate a local oscillation frequency that attenuates a local oscillation frequency applied together with a transmission signal from a transmission circuit unit to improve noise characteristics at a receiver. It is to provide an integrated dielectric duplexer having a.

1 is a block diagram illustrating a configuration example of a duplexer generally provided in a mobile communication device.

2 is a block diagram showing a partial configuration of a transmitting end in a mobile communication device used for a duplexer or the like.

3 is a perspective view of one embodiment of an integrated dielectric duplexer constructed in accordance with the present invention.

4 is a perspective view showing another embodiment of an integrated dielectric duplexer according to the present invention.

5 is a perspective view showing another embodiment of an integrated dielectric duplexer according to the present invention.

6 is a perspective view showing an example of a conventional integrated dielectric duplexer.

7A is a characteristic graph of a conventional integrated dielectric duplexer, and FIG. 7B is a characteristic graph of an integrated dielectric duplexer according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: antenna

11: duplexer

12: receiving circuit

13: transmitting circuit

g (TX): Characteristic graph of transmitter

g (RX): Characteristic graph of receiver

As a construction means for achieving the above object of the present invention, the present invention is formed through the front and rear of the dielectric block, the electrode is formed on the inner surface of the plurality of resonant holes constituting the transmitting end and the receiving end, and the dielectric block In an integrated dielectric duplexer comprising a ground electrode formed on the entire surface except the open surface formed with a resonance hole of the first electrode, and an input / output electrode formed by shorting a part of the ground electrode with another electrode.

And a capacitive coupling electrode pattern which is not connected to another electrode pattern between one of the resonance holes constituting the transmitting end of the dielectric block and the ground electrode.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention. In the accompanying drawings, the same reference numerals are used for the same constituent means, and redundant descriptions thereof are omitted.

3 is a perspective view showing an embodiment of the present invention applied to an integrated dielectric duplexer having the most common structure. The coupling electrode pattern C1 is disposed between a plurality of resonant holes 30a to 30c of the transmitting end TX and a ground electrode. It is formed.

The coupling electrode pattern C1 enhances the capacitance component of the transmission end TX, thereby improving attenuation characteristics at frequencies lower than the pass band of the transmission filter.

3 shows an example of a basic integral dielectric duplexer without inductance coupling or capacitance formed to form an attenuation pole at a specific desired point. Next, in FIG. 4, attenuation pole is formed at the high end at the transmitting end and at the low end at the receiving end. As a perspective view showing an embodiment of the present invention applied to an integrated dielectric duplexer having a coupling pattern, the transmission end TX is connected to a ground electrode 102 between a plurality of resonant holes 30a to 30c for each resonance period. The first coupling electrode patterns L1, L1 ', L2, and L2' increasing the inductance value are formed, and the receiving end RX has a capacitance between the resonators between the plurality of resonance holes 30d to 30g and the ground electrode. In the integrated dielectric duplexer having the second coupling electrode pattern 40 which is not connected to the other ground pattern 102 to increase, the resonant hole 30b of the transmitting terminal TX and the ground conductor To configure to form a capacitive coupling rings third electrode pattern (C2) between.

The receiving end RX of the integrated dielectric duplexer forms an attenuation pole in a frequency band overlapping a transmission signal lower than the pass band, and the transmitting end TX forms an attenuation pole in a frequency band overlapping a reception signal higher than the pass band. At the same time, a third attenuation pole is formed at a predetermined frequency band lower than the pass band of the transmission signal by the third electrode pattern C2 formed at the transmission end TX, thereby attenuating the local oscillation frequency that can enter from the transmission circuit section. .

5 is a perspective view showing another embodiment of the integrated dielectric duplexer according to the present invention, in which the integrated dielectric duplexer is formed in accordance with the present invention in which the coupling pattern is complicated to obtain a desired attenuation characteristic at a desired point.

As illustrated, the integrated dielectric filter may include a dielectric block in which a plurality of through holes 310a to 310j are formed in parallel with each other and the electrode pattern 302 is coated on the front surface except for the first surface 301 having the through holes. In 300, a pattern is formed in the periphery of each of the through holes 310a to 310j on the first surface 301 to which the electrode is not applied, and the internal electrode is formed, and the resonance hole for the transmitter is located on the left side. The first coupling patterns 320a to 320c connected to the ground electrode 302 are printed between 310a to 310e, and the capacitive coupling is performed between the resonance holes 310f to 310i for the receiving end and the ground electrode 302. A second coupling pattern 330 is formed, and a capacitive coupling is formed between any of the resonance holes 310c and 210d of the resonance holes formed in the transmitting end and the first coupling pattern 320b connected to the ground. The third coupling pattern C3 is formed.

In the integrated dielectric filters shown in FIGS. 3 to 5, the input / output electrode and the antenna electrode are formed on the other invisible surface of the dielectric block.

As shown in the accompanying drawings, the present invention can improve the attenuation characteristics at a frequency lower than the transmission frequency by replacing one of the plurality of inductance coupling formed in the transmission stage (TX) with capacitance coupling. The attenuation pole point can be adjusted by appropriately adjusting the coupling coefficient by adjusting the shape and area of the coupling pattern. The attenuation pole can be improved at a lower frequency than the transmitting end because the duplexer is implemented as a quarter-wave resonator and has periodicity.

More specifically, the duplexer exhibiting the filter characteristic at the resonance frequency f0 has the filter characteristic even in the frequency band of 3 * f0. Therefore, the structure having the attenuation pole in the frequency band slightly lower than the resonance frequency f0 means that the attenuation pole is also in the frequency band slightly lower than 3 * f0, which contributes to improving the attenuation characteristics even in the frequency band higher than f0.

In addition, since the local oscillation frequency is formed at a frequency lower than the transmitting end frequency or higher than the receiving end frequency, the duplexer having the structure according to the present invention has an advantage of improving attenuation characteristics at the local oscillation frequency.

7 is a characteristic graph showing an improved effect in an integrated dielectric duplexer implemented in accordance with the present invention.

FIG. 7A is a characteristic graph of a conventional duplexer. As shown in the drawing, attenuation of 40 db or more occurs at a point p1 at which the transmitter end frequency characteristic graph g (TX) is slightly higher than the transmission frequency overlapping the reception frequency band. In the frequency band lower than the oscillation band such as the oscillation band (p2), the attenuation characteristic is very low, and it may adversely affect the reception circuit side through the duplexer from the local oscillation frequency transmission circuit side.

On the contrary, according to the characteristic graph of the duplexer according to the present invention shown in Fig. 7B, the characteristic graph of the duplexer transmitting end has attenuation characteristic of a predetermined dB or more in the reception frequency band p1 higher than the transmission frequency band, It can be seen that the attenuation pole is formed even in the lower local oscillation frequency band p2. In addition, it can be seen that the attenuation effect of a predetermined dB or more appears in the band p3 higher than the reception frequency. From this, it can be seen that the local oscillation frequency set lower than the transmission frequency or higher than the reception frequency is reliably prevented.

In fact, in the case of IMT, the next-generation mobile communication device, the transmitter frequency is 1.92GHz ~ 1.98GH and the receiver frequency is 2.11GHz ~ 2.17GHz.In addition to the pass characteristics for the set band and the attenuation characteristics for the adjacent band, the local oscillation of the transmitter is In the frequency band of 2.3 GHz to 2.25 GHz, attenuation characteristics of more than a predetermined level (65 dB) are required. In this case, therefore, the blocking characteristic with respect to the local oscillation frequency can be obtained by replacing one of the inductive coupling patterns of the transmitter with a capacitive coupling pattern as in the present invention.

As described above, the attenuation characteristic for the local oscillation frequency lower than the transmission frequency or higher than the reception frequency can be obtained by forming one capacitive coupling pattern with a plurality of inductive coupling patterns in the transmitting end. As a result, there is an excellent effect of simply manufacturing a duplexer that can meet the needs of various users.

Claims (3)

When formed through the front and rear of the dielectric block, the electrode is formed on the inner surface of the plurality of resonant holes constituting the transmitting end and the receiving end, and the ground electrode formed on the entire surface except the open surface formed with the resonance hole of the dielectric block; In an integrated dielectric duplexer comprising an input and output electrode formed by shorting a portion of the ground electrode with another electrode, An integrated dielectric having attenuation function of a local oscillation frequency, comprising an electrode pattern for capacitive coupling which is not connected to another electrode pattern between one of the resonance holes constituting the transmitting end of the dielectric block and the ground electrode; Duplexer. The method of claim 1, wherein the integrated dielectric duplexer Forming at least one ground pattern connected to the ground electrode between each resonance hole constituting the transmitting end of the dielectric block, and forming the electrode pattern for the capacitive coupling between the at least one ground pattern, And a linear electrode extending in the formation direction of each resonance hole constituting the receiving end of the dielectric block, the linear electrode being not connected to the ground electrode. The method according to claim 1 and 2, And the capacitive coupling electrode pattern formed at the transmitting end extends between the resonance hole and the ground electrode in a direction in which at least two transmitting end resonating holes are formed, the integrated dielectric duplexer having attenuation function of the local oscillation frequency.