KR100504798B1 - Diplexer circuit for dual band communication device - Google Patents

Abstract

The present invention relates to a diplexer circuit of a dual band communication terminal, and a diplexer implemented with a single chip realizes performance in a chip in a process in which an input frequency is divided into dual bands by an internal selection terminal. Because of this, there is a problem that the coupling phenomenon and the better isolation (Isolation) generated here can not be obtained. Accordingly, the present invention provides a resonant circuit comprising a capacitor C1 and an inductor L1 reflecting a frequency other than the cellular frequency band from a high frequency signal received through an antenna Ant, and a capacitor having one side grounded to the resonant circuit. A cellular frequency path configured to separate cellular frequency bands by connecting C3 in parallel; Selectivity in a short resonator comprising a capacitor C2 and an inductor L2 reflecting a frequency other than the PCS frequency band from a high frequency signal received through the antenna Ant and a frequency band output through the short resonator An open resonator unit for improving the circuit width is connected to the PCS frequency path configured to separate the PCS frequency band, thereby improving the coupling phenomenon and the separation degree.

Description

DIPLEXER CIRCUIT FOR DUAL BAND COMMUNICATION DEVICE}

The present invention relates to a diplexer circuit of a dual band communication terminal, and more particularly to a diplexer circuit of a dual band communication terminal for optimizing the performance of the diplexer circuit in a communication terminal configured to be used in a dual band. will be.

Conventionally used diplexers are mainly used four methods (Band Splitters, Wide Bandpass Diplexer & Triplexers, Narrow Bandpass Diplexer, Quadrature Diplexer).

Currently, the diplexer used in a tri-mode communication terminal is almost implemented with a chip.

In this case, the frequency band used in the diplexer is a frequency band of 824MHz ~ 894MHz (AMPS) (hereinafter referred to as cellular) and a frequency band of 1850MHz ~ 1990MHz (PCS) (hereinafter referred to as PCS) is used, cellular It is used to separate the duplexer and PCS duplexer and for the medium frequency mixer.

In this case, the duplexer is connected to the antenna to pass only the signal required for the call, and refers to the main components of the mobile communication terminal that serves to remove unnecessary signals and noise.

1 is a block diagram showing a configuration for explaining a function of a conventional diplexer as described above.

As shown therein, the diplexer 10 is configured to display the cellular duplexer 20 and the PCS duplexer 30 at frequencies of 824 MHz to 894 MHz (AMPS) and 1850 MHz to 1990 MHz (PCS) in a high frequency signal received through an antenna. It acts as a separation.

The diplexer 10 is mostly composed of chips, and the characteristics of the diplexer 10 are 0.7 dB (0.4 dB Typ) of maximum band pass frequency and 15 dB of isolation (Isolation).

For reference, the insertion loss IL gives a result generated by inserting a transducer into a transmission system, and the power P ₂ given to a place after the transducer and the power given to the same place when the transducer is removed. The ratio of (P ₁ ) is expressed in decibels (dB).

In addition, the isolation (Isolation) refers to the amount of power transfer from one antenna to the other antenna, the separation between the antenna is expressed in decibels as a ratio of the other antenna reception power to the input power to one antenna, In RF, the received power ratio from Rx to Rx is also a concept of separation.

2A and 2B are exemplary views for explaining characteristics such as insertion loss and separation of a conventional diplexer chip.

As shown, the insertion loss of the PCS (0.4dB Typ) and cellular (0.3dB Typ) band frequencies is designed to be about 0.7dB Max (0.4dB Typ).

Therefore, as shown in FIG. 1, since the diplexer implemented as a single chip realizes performance in the chip in the process of dividing the input frequency into a double band by an internal selection terminal, the diplexer is further coupled with the coupling phenomenon generated here. There is a problem that good isolation cannot be obtained.

Accordingly, the present invention was created to solve the above-mentioned conventional problems, and the die of the dual band communication terminal for dividing the diplexer circuit into discrete to improve the coupling phenomenon and the separation degree. The purpose is to provide a flexure circuit.

In order to achieve the above object, the present invention provides a resonant circuit including a capacitor C1 and an inductor L1 and a resonant circuit for reflecting a frequency other than the cellular frequency band from a high frequency signal received through an antenna. A cellular frequency path configured to separate a cellular frequency band by parallelly connecting a capacitor C3 having one side grounded thereto; A short resonator 200 formed of a capacitor C2 and an inductor L2 reflecting a frequency other than the PCS frequency band from the high frequency signal received through the antenna; An open resonator 100 for improving selectivity in the frequency band output through the short resonator 200 is connected to the PCS frequency path configured to separate the PCS frequency band.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 3 is a circuit diagram showing the configuration of the diplexer circuit according to the present invention. As shown in the drawing, the antenna Ant converts the power high frequency energy of the transmitter into radio wave energy at the time of transmission and radiates it into the space, A band required for an antenna may be received and transmitted through an energy converter (not shown) that receives radio wave energy of a space and converts it into electric power to supply the receiver.

Accordingly, the frequency band received through the antenna is divided into a cellular frequency band (824MHz to 894MHz) and a PCS frequency band (1850MHz to 1900MHz).

The configuration of the PCS path in the circuit of FIG. 3 will now be described in detail.

First, the PCS path is largely composed of an open resonator 100 and a short resonator 200, and the open resonator 100 performs band selection and short resonance. The unit 200 serves as a band rejection.

Open resonance serves to select the desired frequency by reducing the loss to a minimum, and further minimizes the loss of the PCS band by its inductor (L3), and by the value of C4 (2pF), high frequency band like the PCS band. It can play a role of compensating for insertion loss (Insertion Loss).

That is, the capacitor C4 and the inductor L3 connected in parallel to each other form an open resonance shape, and thus, a desired band can be selected in the high frequency band.

Next, in the short resonance, a structure for rejecting a band other than the PCS band is formed.

Therefore, the discrete diplexer circuit as described above is characterized in that a better isolation and less insertion loss can be obtained by using a tuning circuit (not shown).

4A and 4B are exemplary views for explaining characteristics such as insertion loss and separation of a diplexer configured to be discrete according to the present invention, and an insertion loss of the conventional diplexer chip shown in FIG. In comparison, the insertion loss of the cellular band is -0.015 to -0.088, indicating that the insertion loss of the cellular band is significantly improved.

However, the PCS band is in a similar state because the specification is high in frequency.

Next, in the case of the separation characteristic of FIG. 4B, it can be seen that the separation between the cellular band and the PCS band is further improved at a 15 dB Min value of the conventional specification of FIG. 2B.

That is, the bones of m1, m2, and m3, m4 are not very deep in FIG. 2b, but the bones of m9, m10, and m11, m12 are deep in FIG. 4b.

The larger the valley between the bands, the better the separation.

For reference, if the concept of the diplexer resonance at this time is expressed mathematically it can be expressed as the following equation (1).

Where Q is relative bandwidth of through response,

        f_o is the center frequency of diplexer (Hz)

        BW_3dB is 3dB bandwidth of desired though response (Hz)

As described above, in the diplexer circuit of the dual band communication terminal of the present invention, the insertion loss of the cellular band is -0.015 to -0.088, which is smaller than that of other diplexers. Insertion loss is also -0.249 ~ -0.582 has the effect of further improving the insertion loss.

In addition, the return loss in the present invention has a margin of much more than 15 dB, and the attenuation also satisfies the typical 25 dB, and in the case of isolation, the performance is realized with a good margin of 15 dB Min or more. It is effective.

1 is a block diagram showing a configuration for explaining the function of a conventional diplexer.

2A and 2B are exemplary views for explaining characteristics such as insertion loss and separation of a conventional diplexer chip.

3 is a circuit diagram showing the configuration of a diplexer circuit according to the present invention.

4A and 4B are exemplary views for explaining characteristics such as insertion loss and separation of a diplexer configured to be discrete according to the present invention.

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

100: open resonator 200: short resonator

C1 to C4: Capacitors L1 to L3: Inductor

Claims (2)

A resonant circuit composed of a capacitor C1 and an inductor L1 reflecting a frequency other than the cellular frequency band from a high frequency signal received through an antenna Ant and a capacitor C3 having one side grounded to the resonant circuit in parallel. A cellular frequency path configured to couple to separate cellular frequency bands; Selectivity in a short resonator comprising a capacitor C2 and an inductor L2 reflecting a frequency other than the PCS frequency band from a high frequency signal received through the antenna Ant and a frequency band output through the short resonator A diplexer circuit of a dual band communication terminal, comprising: a PCS frequency path configured to separate an PCS frequency band by connecting an open resonator unit for improving the frequency response. The diplexer circuit according to claim 1, wherein the open resonator comprises a 2pF capacitor (C4) and a 2nH inductor (L3) connected in parallel on one side thereof.