KR101000207B1 - Dual Band Front End Module - Google Patents

Abstract

The present invention is a dual band front end module composed of a diplexer, an LPF, a phase shifter, a saw filter, and a choke coil.

Dual Band Front End Module

Description

Dual Band Front End Module             

1 is a view schematically showing the configuration of a conventional front-end module.

2 is a view schematically showing the configuration of a front-end module according to an embodiment of the present invention.

3A and 3B show the frequency response of a signal by a front end module according to one preferred embodiment of the present invention.

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

100, 200: Diplexer 110, 210: LPF

120, 220: phase shifter 130, 230: choke coil

140, 240: Saw filter 150, 250: Diode

160, 260 capacitors

The present invention relates to a dual band front end module that converts a choke coil from a distributed constant circuit to a concentrated constant circuit to reduce attenuation and insertion loss of harmonics.

With the recent development of mobile communication systems, mobile communication devices such as mobile phones and portable information terminals are rapidly spreading, and the frequencies used in these mobile communication systems are also different from each other in various directions such as 800 MHz-1 GHz and 1.5 GHz-2.0 GHz. A system for transmitting and receiving a signal of a band is provided.

Therefore, from the demand for miniaturization and high performance of these devices, miniaturization and high performance of components used in them are required, and efforts for miniaturization and cost reduction of portable electronic devices are inevitably concerned with the integration of passive elements constituting them. And research is active.

Conventionally, active devices are mostly integrated into high density integrated circuits based on silicon technology, and are implemented as only a few chip components. However, passive devices (resistance, capacitors, inductors, etc.) are hardly integrated. Individual elements were attached to the circuit board by soldering or the like.

Therefore, there is an increasing demand for an integrated technology of passive devices for miniaturizing electronic devices, improving performance and reliability of these passive devices, and an integrated technology using low temperature synchronous ceramics is currently actively being solved. Is being studied.

The LTCC technology has the advantage of using a conductive metal such as gold or silver that can be fired even in an oxidizing atmosphere, so that various passive elements such as resistors, capacitors, and inductors can be implemented in the front-end module of the mobile communication device. Apply.

Hereinafter, the front end module will be described with reference to the accompanying drawings.

1 is a view schematically showing the configuration of a conventional front-end module.

Referring to FIG. 1, the front end module may include a diplexer 100, a first LPF 110a, a second LPF 110b, a first phase shifter 120a, a second phase shifter 120b, and a choke coil ( 130a, 130b, a first saw filter 140a, a second saw filter 140b, diodes 150a, 150b, 150c, 150d, and capacitors 160a, 160b.

The diplexer 100 is connected to an antenna to separate a first frequency band (GSM) signal and a second frequency band (DCS) signal.

The first LPF 110a removes the high frequency noise of the signal transmitted from the GSM transmitter, and the second LPF 110b removes the high frequency noise of the signal transmitted from the DCS transmitter.

The first phase shifter 120a converts a phase of a frequency such that a signal of a first transmission band (GSM) transmission band is not received together with the first reception band (GSM) reception signal received by the diplexer 100. Let's do it.

The second phase shifter 120b converts the phase of the frequency such that the second frequency band DCS signal is not received together with the second frequency band DCS signal received by the diplexer 100.

Here, the received signals of the GSM and DCS are separated by the diplexer 100, but do not affect the signals respectively received by the first phase converter 120a and the second phase converter 120b.

The first saw filter 140a passes only signals in a predetermined range of frequencies desired by the GSM receiver for the signal passing through the first phase converter 120a, and removes signals outside the range, and removes the second saw filter. 140b passes only signals of a frequency band desired in the DCS receiver for a signal passing through the second phase shifter 120a and removes signals outside the range.

When the choke coils 130a and 130b are in the transmission mode, DC current flows through them and opens for the RF signal, and is embedded in the LTCC in a stripline form. At this time, the choke coils 130a and 130b are implemented as distributed constant circuits. That is, the choke coils 130a and 130b are composed of an inductor and a capacitor and embedded in the LTCC in a stripline form.

The choke coils 130a and 130b are composed of a first choke coil 130a and a second choke coil 130b, and the first choke coil 130a is installed at the front end of the GSM transmitter and thus the first LPF 110a. ), And the second choke coil (130b) is installed in front of the DCS transmitter to block the high frequency passed through the second LPF (110b).

The diodes 150a, 150b, 150c, and 150d include a first diode 150a, a second diode 150b, a third diode 150c, and a fourth diode 150d.

The first diode 150a and the second diode 150b change the transmission path and the reception path of the first frequency band (GSM) signal, and the third diode 150c and the fourth diode ( 150d) changes a transmission path and a reception path of the second frequency band (DCS) signal.

That is, the voltage is applied to V1 (V2 is off) in the GSM transmission mode, and the first diode 150a and the second diode 150b are turned on. In the DCS transmission mode, the voltage is applied to the power supply V2. (VC1 is in an off state) The third diode 150c and the fourth diode 150d are turned on.

 In the GSM reception mode, the power supply terminal V1 is turned off and the first diode 150a and the second diode 150b are turned off. In the DCS reception mode, the power supply V2 is turned off and reception is performed.

The capacitors 160a and 160b include a first capacitor 160a and a second capacitor 160b, and are DC blocking capacitors that prevent the DC signals of the power terminals V1 and V2 from flowing into the antenna.

However, when the choke coil is configured as a distributed constant circuit and embedded in the LTCC, the value causes coupling with the diplexer and the LPF, which lowers the harmonics of the front-end module, thereby lowering the insertion loss. There is this.

In addition, the width of the transmission band can be adjusted according to the value of the choke coil, but if a built-in distributed constant circuit and built in the LTCC there is a problem that can no longer be tuned.

Accordingly, an object of the present invention is to provide a dual band front end module capable of reducing attenuation and insertion loss of harmonics by converting a choke coil from a distributed constant circuit to a concentrated constant circuit.

According to an aspect of the present invention to achieve the above object, in the dual band front end module consisting of a diplexer, LPF, phase shifter, saw filter, choke coil, to configure the choke coil in a lumped constant circuit A dual band front end module is provided.

The choke coil is located on the LTCC as a lumped constant circuit.

The choke coil is an inductor and its value can be changed.

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

2 is a view schematically showing the configuration of the front-end module according to an embodiment of the present invention.

Referring to FIG. 2, the front end module may include a diplexer 200, a first LPF 210a, a second LPF 210b, a first phase shifter 220a, a second phase shifter 220b, and a choke coil ( 230a, 230b, first saw filter 240a, second saw filter 240b, diodes 250a, 250b, 250c, 250d, and capacitors 260a, 260b.                     

The diplexer 200 is connected to an antenna to separate a first frequency band (GSM) signal and a second frequency band (DCS) signal.

The first LPF 210a removes high frequency noise of the signal transmitted from the GSM transmitter, and the second LPF 210b removes high frequency noise of the signal transmitted from the DCS transmitter.

The first phase shifter 220a converts a phase of a frequency such that a signal of a first frequency band GSM transmission band is not received together with a first frequency band GSM signal received by the diplexer 200. Let's do it.

The second phase converter 220b converts the phase of the frequency such that the second frequency band DCS signal is not received together with the second frequency band DCS signal received by the diplexer 200.

Here, the received signals of the GSM and DCS are separated by the diplexer 200, but do not affect the signals respectively received by the first phase converter 220a and the second phase converter 220b.

The first saw filter 240a passes only signals of a predetermined range of frequency bands desired by the GSM receiver for the signal passing through the first phase converter 220a, and removes signals outside the range, and the second saw filter The signal 240b passes only signals in a frequency band desired by the DCS receiver for a signal passing through the second phase shifter 220b and removes signals outside the range.

When the choke coils 230a and 230b are in the transmission mode, DC current flows through them, and opens the RF signal, and is implemented as a lumped constant circuit. That is, the choke coils 230a and 230b have inductors positioned on the LTCC, and inductor values can be changed to adjust the width of the transmission band. Therefore, when the choke coils 230a and 230b are implemented as lumped constant circuits as described above, the inductor values can be changed, so that tuning after fabrication is possible, and attenuation and insertion loss of the harmonics are reduced.

The choke coils 230a and 230b are composed of a first choke coil 230a and a second choke coil 230b, and the first choke coil 230a is installed at the front end of the GSM transmitter to provide the first LPF 210a. ), And the second choke coil 230b is installed at the front end of the DCS transmitter to block the high frequency passed through the second LPF 210b.

The diodes 250a, 250b, 250c, and 250d include a first diode 250a, a second diode 250b, a third diode 250c, and a fourth diode 250d.

The first diode 250a and the second diode 250b change the transmission path and the reception path of the first frequency band (GSM) signal, and the third diode 250c and the fourth diode 250d. ) Changes the transmission path and the reception path of the second frequency band (DCS) signal.

That is, voltage is applied to V1 (V2 is off) in the GSM transmission mode, and the first diode 250a and the second diode 250b are turned on. In the DCS transmission mode, the voltage is applied to the power supply V2. (VC1 is in an off state) The third diode 250c and the fourth diode 250d are turned on.                     

 In the GSM reception mode, the power supply terminal V1 is turned off to turn off the first diode 250a and the second diode 250b. In the DCS reception mode, the power supply V2 is turned off to receive the reception signal.

The capacitors 260a and 260b include a first capacitor 260a and a second capacitor 260b, and are DC blocking capacitors that prevent the DC signals of the power terminals V1 and V2 from flowing into the antenna.

Hereinafter, the operation of the front end module configured as described above will be described.

The front-end module operates by separating transmission and reception signals of a digital cellular system (DCS) using a 1.8 GHz band and a global mobile communication system (GSM) using a 900 MHz.

First, when the power of V1 is turned on and the power of V2 is turned off, the GSM is converted into a transmission mode, and the GSM signal transmitted by the transmitter passes only the low frequency signal through the first LPF 210a. The antenna 250 propagates to the outside through the antenna 250a.

When the power of V1 is off and the power of V2 is on, the DCS is converted to a transmission mode, and the DCS signal transmitted by the transmitter passes only the low frequency signal through the second LPF 210b and the third diode. It propagates to the outside through the antenna 250c.

In addition, if the power of both V1 and V2 is off, both GSM and DCS are converted to a reception mode, and the GSM and DCS signals received by the diplexer 200 are separated. Here, when the GSM signal is received, the diplexer 200 receives the signal separated by the GSM receiver. However, in order to prevent the GSM transmission signal transmitted from the GSM transmitter is transmitted to the GSM receiver, the phase of the frequency is converted in the first phase converter 220a.

The first phase converter 220a serves to prevent the GSM transmission signal from being transmitted to the GSM receiver by bringing the impedance of the first saw filter 240a to the GSM transmission signal indefinitely.

On the other hand, when the DCS signal is received, the diplexer 200 separates and transmits the signal to the DCS receiver. The DCS signal received and transmitted by the diplexer 200 passes through the second saw filter 240b to attenuate the high frequency signal of the received signal.

Here, the choke coil 230 is to obtain an inductance, and passes the DC current of the DC power supply for operating the diode, and blocks the high frequency signal received through the antenna.

3A and 3B are diagrams showing frequency responses of signals by the front end module according to an exemplary embodiment of the present invention.

3A and 3B, it can be seen that the harmonic value of the front end module is attenuated by 10 db or more, and the insertion loss is also reduced. This harmonic attenuation is because the coupling value with the diplexer or phase shifter, which occurred when the choke coil is embedded in the LTCC board, is eliminated by implementing the lumped constant circuit. The attenuation of the harmonics affects the insertion loss characteristics of the band, thereby improving insertion loss.

In addition, when the distribution constant circuit is implemented to adjust the width of the GSM band, it is not possible to adjust the bandwidth according to the process deviation. Therefore, by implementing the choke coil as a lumped constant circuit, the optimum value can be found after the LTCC board is manufactured.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

According to the present invention as described above, it is possible to provide a dual band front end module in which the attenuation and insertion loss of the harmonics are reduced by converting the choke coil from the distributed constant circuit to the concentrated constant circuit.

In addition, according to the present invention, since the choke coil is implemented as a lumped constant circuit, the optimum value can be found after fabrication of the LTCC substrate, thereby providing a dual band front end module capable of improving yield in mass production.

Claims (3)

LPF located between the diplexer and the diplexer and the transmitter, a phase shifter and saw filter positioned between the diplexer and the receiver, and a choke coil connected to the common terminal of the LPF and the transmitter. To And a dual band front end module comprising the choke coil as a lumped constant circuit. The method of claim 1, And the choke coil is located on the LTCC. The method according to claim 1 or 2, The choke coil is an inductor, dual band front end module, characterized in that the value can be changed.

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