KR20050109889A - Rf front-end apparatus in tdd wireless communication system - Google Patents

Abstract

The present invention relates to a high frequency front-end device of a time division duplex (TDD) wireless communication system, and transmits a signal from the power amplifier to an antenna feed line, and transmits a signal from the antenna feed line. An open stub having a predetermined length to load the transmission line line according to a control signal, and a circulator for transmitting the transmission line line, the transmission line line installed on the reception path for receiving side isolation in transmission mode, and a control signal. And a low noise amplifier for low noise amplifying and outputting a signal from the high frequency switch, and a high frequency switch connected to a low noise amplifier or a low noise amplifier, wherein the transmission line, the high frequency switch, and the open stub are connected to each other. The line is characterized by having a length of? / 2. As described above, the present invention not only protects the output stage of the power amplifier PA, but also has the advantage of attenuating the transmission power flowing into the low noise amplifier in the transmission mode to protect the low noise amplifier.

Description

RF FRONT-END APPARATUS IN TDD WIRELESS COMMUNICATION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency (RF) front-end device in a time division duplex (TDD) type wireless communication system, particularly to a low noise amplifier (LNA). An apparatus for protecting a low noise amplifier by attenuating transmission power.

In general, an RF front-end device performing a TDD function in the TDD wireless communication system mainly uses an RF switch or a circulator.

1 shows an RF shear apparatus using an RF switch.

As shown, a power amplifier 102 is connected to an output terminal of the transmitter 101, and a receiver 103 is connected to an output terminal of a low noise amplifier 104 (LNA). Is connected. Here, the single pole double through switch 105 is switched so that the transmission signal from the power amplifier 102 is connected to the filter 106 when it is transmitting, and the reception signal from the filter 106 when it is receiving. Is switched to couple to the low noise amplifier 104. The filter 106 performs a band filtering function on the transmission signal and the reception signal. Meanwhile, a directional coupler (D / C) 107 is connected between the filter 106 and the antenna and performs a function of coupling a transmission signal and a reception signal. The coupled signal is used to monitor the transmission signal and the reception signal for abnormalities. The structure shown in FIG. 1 is a method in which a transmission / reception path is switched in the RF switch 105 by a control signal. This structure is mainly applied to systems with transmit power of less than 1W.

2 shows an RF shear apparatus using a circulator.

As shown, the power amplifier 202 is connected to the output terminal of the transmitter 201, and the receiver 203 is connected to the output terminal of the low noise amplifier 204. Here, the circulator 205 connects the transmission signal from the power amplifier 202 to the filter 206, and connects the signal from the filter 206 to the low noise amplifier. The filter 206 performs a band filtering function on the transmission signal and the reception signal. Meanwhile, the directional coupler 207 is connected between the filter 206 and the antenna and performs a function of coupling a transmission signal and a reception signal. The coupled signal is used to monitor the transmission signal and the reception signal for abnormalities. The structure as shown in FIG. 2 is a method of separating transmission / reception using a characteristic in which the signal attenuation is transmitted little in the forward direction and the signal transmission loss is large in the reverse direction. This architecture applies to systems with transmit power less than a few W (about 7-8 W).

As described above, the RF front-end structure can be applied to a TDD system using a low power high frequency signal. However, in a system using a high power signal of about 10W or more, Power rating, break down, and unrealistic price in circuit implementation are not applicable. In particular, when the RF front-end is implemented to handle the large power in the same manner as in FIG. 1, the cost becomes unrealistic amount (about $ 1,500), and the method as shown in FIG. When a problem occurs in the antenna feed line, the reflected power of the transmission power is introduced into the low noise amplifier (LNA) input terminal, which may cause permanent damage to the low noise amplifier (LNA) input circuit.

Accordingly, an object of the present invention to solve the above problems is to provide an RF front-end device capable of processing a high-frequency signal of high power in a time division duplex (TDD) wireless communication system.

It is another object of the present invention to provide an apparatus for protecting the terminating circuit of a power amplifier in a time-division duplex (TDD) type wireless communication system using high power and attenuating the transmission power introduced into a receiver low noise amplifier in a transmission mode. .

According to an embodiment of the present invention for achieving the above object, a high-frequency front-end device of a time division duplex (TDD) wireless communication system, to transmit a signal from the power amplifier to the antenna feed line And a circulator for transmitting a signal from the antenna feed line to the quarter wave transmission line, the quarter wave transmission line installed on the reception path for receiving side isolation in a transmission mode, and a control signal. And a high frequency switch for shorting the load of the quarterwave transmission line to ground or connecting to a low noise amplifier, and the low noise amplifier for low noise amplifying and outputting a signal from the high frequency switch. do.

According to another embodiment of the present invention, a high frequency front-end device of a time division duplex (TDD) wireless communication system transmits a signal from the power amplifier to an antenna feed line, and the antenna feed line A circulator for transmitting a signal from the transmission line to the transmission line, the transmission line provided on the reception path for isolation on the receiving side in transmission mode, and the load of the transmission line line according to a control signal The high frequency switch connected to an open stub or a low noise amplifier, and the low noise amplifier for low noise amplifying and outputting a signal from the high frequency switch, wherein the transmission line line, the high frequency switch, and the open stub are connected to each other. And the length of the transmission line to be formed is lambda / 2 length.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, an RF front-end device for protecting an output terminal of a power amplifier and an input terminal of a low noise amplifier in a time division duplex (TDD) type wireless communication system using high power will be described.

3 illustrates a configuration of an RF shearing apparatus of a time division duplex system according to an embodiment of the present invention.

As shown, the RF shearing apparatus according to an embodiment of the present invention, the transmitter 301, the power amplifier 302, the isolator 303, the circulator 304, the receiver 305, the low noise amplifier 306 And a switch 307, a quarter wave (λ / 4) transmission line line 308, a filter 309, a directional coupler 310, and an antenna 311. Here, the quarter wave (λ / 4) indicates the length between the circulator 304 and the ground when the switch 307 is connected to ground.

Referring to FIG. 3, the power amplifier 302 first amplifies and outputs a transmission signal from the transmitter 301. The isolator 303 is connected to the output terminal of the power amplifier 302 and functions to protect the termination circuit of the power amplifier 302. In addition, in the transmission mode, it serves as termination for a signal reflected and returned when an abnormality occurs in an antenna feed line path. The isolator 303 may generally use the isolator configured at the output terminal of the power amplifier 302 as it is.

The circulator 304 is a signal isolation of about 20 dB between the transmitting side (power amplifier 302 and isolator 303) and the receiving side (λ / 4 transmission line line 308 and low noise amplifier 306). To provide. In addition, a path loss of about 0.3 dB is provided between the antenna side (filter 309 and the directional coupler 310) and each transmitting / receiving side. The circulator 304 transmits a signal from the isolator 303 to the filter 309 and a signal from the filter 309 to the quarterwave transmission line line 308 according to the illustrated directionality. .

The filter 309 is connected between the circulator 304 and the directional coupler 310, and performs the function of band filtering the transmission signal and the reception signal. The directional coupler 310 is connected between the filter 309 and the antenna 311 and performs a function of coupling a transmission signal and a reception signal. The coupled signal is used to monitor the transmission signal and the reception signal for abnormalities.

The quarterwave transmission line 308 is connected between the circulator 304 and the SPDT switch 307. According to the state of the load of the quarterwave transmission line 308 (connected state of the SPDT switch 307), the impedance viewed from the circulator 304 side is open (the state of the SPDT switch 307 is connected to ground). Or 50Ω (with SPDT switch 037 connected to low noise amplifier 306). In fact, when the SPDT switch 307 is connected to ground (when the control signal TX on), the λ / 4 transmission line line 308 is connected between the circulator 304 and the SPDT switch 307 by about 20 dB. It provides a degree of isolation.

The SPDT switch 307 functions to short-circuit the load of the λ / 4 transmission line line 307 to ground or to the input terminal of the low noise amplifier 306 according to the TX on / off control signal. On the other hand, when the control signal TX on, the signal isolation of about 26 dB is provided between the λ / 4 transmission line line 308 and the input terminal of the low noise amplifier 306, and the signal of about 0.3 to 0.4 dB when the control signal TX off Provide a loss. Here, a pin diode (PIN) switch may be used instead of the SDPT switch 307.

The low noise amplifier 306 low noise amplifies the signal from the SPDT switch 307 and outputs it to the receiver 305.

Next, a detailed operation based on the configuration of FIG. 3 will be described below.

4 is a view for explaining the normal transmission signal flow and circuit operation in the configuration of FIG. In the transmission mode, it is very important that the high power transmission signal does not cause electrical damage to the input terminal of the receiving low noise amplifier 306.

Referring to FIG. 4, first, a 60 W transmission signal output from the power amplifier 302 isolator 303-> circulator 304-> filter 309-> directional coupler 310-> antenna ( 311) radiates through the path ⓐ. At this time, the SPDT switch 307 is connected to the ground by the TX on control signal. Therefore, the impedance seen from the other side of the λ / 4 transmission line line (e.g. 1/4 of the effective wavelength length at 2.35 GHz) 308 with one side shorted is the transmission line theory (∞ = jZo tan). [beta] l, l = [lambda] / 4) becomes an open impedance to prevent the transmission of a large power transmission signal to the receiving end. Indeed, in this state the λ / 4 transmission line line 308 provides a transmit signal isolation of at least 20 dB. The SPDT switch 307 also provides transmit signal isolation of about 26dB (neg uPG2009 use example). Finally, the transmission side power (path ⓑ) induced at the input of the receiving low noise amplifier 306 through the leakage of the circulator 304 is calculated as follows.

-18.5 dBm = +47.8 dBm (power amplifier output, 60 W)-0.3 dB (isolator loss)-20 dB (circulator isolation)-20 dB (λ / 4 transmission line isolation)-26 dB (SPDT switch isolation) )

From the above equation, the transmit (TX) power induced at the input of the low noise amplifier 306 becomes about -18 dBm. This value is much smaller than Input IP3 (+12 dBm) at the input of the low noise amplifier (Agilent's MGA72543), and does not cause any electrical damage to the input of the receiving low noise amplifier 306 in transmit mode.

FIG. 5 is a diagram for describing a transmission signal flow and a circuit operation when an unexpected problem occurs such as truncation or short circuit on a transmission path in the configuration of FIG. 3. As described above with reference to FIG. 4, it is very important that the high power transmission signal reflected from the antenna stage © does not cause electrical damage to the input terminal of the receiving side low noise amplifier 306. The difference from FIG. 4 is that the reflected wave power of the reflected and returned transmission signal is transmitted along the receiving path, thereby eliminating the transmission / reception isolation provided by the circulator 304, which is an input terminal of the receiving low noise amplifier 306. It can have a significant adverse effect on

Referring to FIG. 5, first, a 60 W transmission signal output from the power amplifier 302 isolator 303-> circulator 304-> filter 309-> directional coupler 310-> ⓒ point. Reflected in-> Directional Coupler 310-> Filter 309-> Circulator 304-> Reflected in λ / 4 transmission line line 308 with open impedance-> Through isolator 303 path (ⓗ) Termination at end isolator 303.

At this time, the SPDT switch 307 is connected to the ground by the TX on control signal, and the λ / 4 transmission line line 308 is in an open impedance state as described with reference to FIG. 4. Thus, more than 20 dB of transmit signal isolation is provided between the circulator 304 and the SPDT switch 307. In this state, when the transmission side reflected power (path ⓓ) induced at the input terminal of the reception side low noise amplifier 306 is calculated as follows.

-1.5 dBm = +47.8 dBm (power amplifier output, 60W)-0.3 dB (isolator loss)-0.3 dB (circulator loss)-0.9 dB (filter insertion loss)-0.6 dB (directional coupler traveling loss) -0.9 dB (filter insertion loss)-0.3 dB (circulator loss)-20 dB (λ / 4 transmission line line isolation)-26 dB (SPDT switch isolation)

From the above equation, the reflected power reflected at the input of the noise amplifier 306 is about -1.5 dBm. This value is 13.5 dB less than the input IP3 (+12 dBm) at the input of the low noise amplifier (Agilent's MGA72543). As mentioned above, unlike the expectation that the transmit / receive isolation provided by the circulator 304 may be lost, the transmit side high power signal may have a significant adverse effect on the input of the low noise amplifier 306 on the receiving side. Still does not cause any electrical damage to the input of the low noise amplifier 306 on the receiving side. This structure also has the advantage of protecting the expensive power amplifier 302 output stage since the reflected transmit power is terminated in the isolator 303.

FIG. 6 is a diagram for describing a flow of a received signal and a noise signal induced from a power amplifier in the configuration of FIG. 3. In the receive mode, the loss between the noise power induced from the power amplifier 302 and the input of the antenna 311 and the low noise amplifier 306 directly affecting the system noise figure (NF) is important.

Referring to FIG. 6, first, the SPDT switch 307 is connected to the input terminal of the low noise amplifier 306 by a terminal shorted to the ground by the TX off control signal. At this time, the impedance seen from the other side of the lambda / 4 transmission line line 308 is 50Ω by the transmission line theory (50Ω = Zo ² / ZL, ZL = 50) to be in the lambda / 4 transmission line line 308 There is almost no loss of received signal. The loss (path ⓖ) between the antenna 311 and the input terminal of the low noise amplifier 306 is calculated as follows.

-1.9 dB =-0.3 (directional coupler loss)-0.9 dB (filter insertion loss)-0.3 (circulator loss)-0.4 (SPDT switch loss)

From the above equation, the loss between the antenna 311 and the low noise amplifier 306 input is about -1.9 dB. This loss value is typical of the value obtained from other systems. Therefore, there is little deterioration of noise figure (NF).

Meanwhile, in the reception mode, the bias control signal of the power amplifier 302 is turned off to minimize the influence of the reception impedance from the power amplifier 302. The circulator 304 provides about 20 dB of output noise isolation of the power amplifier 302. When power (path ⓕ) derived from the power amplifier 302 in which the bias control signal is in an off state at the input terminal of the low noise amplifier 306 is calculated as follows.

-104.7 dBm / 10 MHz =-84 dBm / 10 MHz (power amplifier power)-0.3 dB (isolator loss)-20 dB (circulator isolation)-0.4 (SPDT switch loss)

From the above equation, the power drawn from the power amplifier 302 at the input of the low noise amplifier 306 is about -104.7 dBm / 10 MHz. This value is a thermal noise level that does not affect receiver performance. That is, the structure of FIG. 3 can receive an input signal in an optimal state even in a reception mode.

7 shows the configuration of an RF shearing apparatus of a time division duplex (TDD) system according to another embodiment of the present invention. The difference from the above-described embodiment of the present invention is that a transmission line is connected between the circulator and the SPDT switch, and an open stub having a predetermined length instead of ground to a predetermined terminal of the SPDT switch. ), The transmission line for the isolation of the receiver in transmission mode is λ / 2 long. At this time, the length of (transmission line + switch + open stub) is λ / 2, and the switch is located at the center of the λ / 2 length. In this regard, the following description will collectively refer to (transmission line line + switch + open stub) as "λ / 2 transmission line line 713".

As shown, the RF shearing apparatus according to another embodiment of the present invention, the transmitter 701, the power amplifier 702, the isolator 703, the circulator 704, the receiver 705, the low noise amplifier 706 , Switch 707, transmission line 708, filter 709, directional coupler 710, antenna 711, and open stub 712. As described above, the switch 707 may use an SPDT switch or a pin diode switch. Meanwhile, in the following description of FIG. 7, detailed descriptions of the above-described components will be omitted, and the main components will be described below.

Referring to FIG. 7, the circulator 704 is about 20 dB between the transmitting side (power amplifier 702 and isolator 703) and the receiving side (λ / 2 transmission line line 713 and low noise amplifier 706). It provides signal isolation of. In addition, a path loss of about 0.3 dB is provided between the antenna side (filter 709 and the directional coupler 710) and each transmitting / receiving side.

The λ / 2 transmission line line 713 has an open impedance (switch 707 connected to the open stub 712) viewed from the circulator 704 side according to the load state (connected state of the switch 707). ) Or 50 kHz (with the switch 707 connected to the low noise amplifier 706). Indeed, when the switch 707 is connected to the open stub 712 (control signal Tx on), 20 dB of signal isolation is provided between the circulator 704 and the switch 707.

The switch 707 connects the transmission line 708 to the open stub 712 or the input terminal of the low noise amplifier 706 according to the Tx on / off control signal. Here, in the transmission mode (Tx on) provides about 26dB signal isolation between the transmission line line 708 and the low noise amplifier 706, and in the receive mode (Tx off), 0.3 ~ 0.4dB insertion loss (insertion) loss). In detail, when the switch 707 is switched to the open stub 712, as shown in FIGS. 8 and 9, λ from a point shorted by the switch 707 (a point of zero amplitude). Since the amplitude at the point separated by 4 is maximized, the impedance of the λ / 2 transmission line line 713 becomes open.

On the other hand, the isolation 703 is a function of terminating the transmission signal reflected back beyond the antenna feed line in the transmission mode (Tx on) and protect the termination circuit of the power amplifier 702 at the same time Do this.

Next, a detailed operation of the configuration of FIG. 7 will be described below.

8 is a diagram for explaining a normal transmission signal flow and circuit operation. In the transmission mode, it is very important that the high power transmission signal does not cause electrical damage to the input terminal of the receiving low noise amplifier 706.

Referring to FIG. 8, a transmission signal of about 60 W output from the power amplifier 702 is first used as an isolator 703-> circulator 704-> filter 709-> directional coupler 710-> antenna ( 711) is emitted through the path ⓐ. At this time, the terminal of the SPDT switch 707 is connected to the open stub 712 by the TX on control signal. In this case, the impedance seen from the other side of the λ / 2 transmission line line (eg, 1/2 of the effective wavelength length at 2.35 GHz) 713 with one side open is the transmission line theory (∞ = − jZo cot βl, β = 2π / λ, ℓ = λ / 2) to open impedance, thereby preventing transmission of a large power transmission signal to the receiving end.

On the other hand, when the transmission side power (path ⓑ) induced at the input terminal of the reception side low noise amplifier 706 through the leakage of the circulator 704 is calculated, it becomes -18.5 dBm as in the embodiment of the present invention. This value is much smaller than Input IP3 (+12 dBm) at the input of the low noise amplifier (Agilent's MGA72543), and does not cause any electrical damage to the input of the receiving low noise amplifier 706 in transmit mode.

FIG. 9 is a diagram for describing a transmission signal flow and a circuit operation when an unexpected problem occurs such as truncation or short circuit on a transmission path. As described above, it is very important that the high power transmission signal reflected and returned from the antenna stage ⓒ does not cause electrical damage to the input terminal of the reception low noise amplifier 706. The difference from FIG. 8 is that the reflected wave power of the reflected and returned transmission signal is transmitted along the receiving path, thereby eliminating the transmission / reception isolation provided by the circulator 704, which is an input terminal of the receiving low noise amplifier 706. It can have a significant adverse effect on

Referring to FIG. 9, first, a 60 W transmission signal output from the power amplifier 702 isolator 703-> circulator 704-> filter 709-> directional coupler 710-> ⓒ point. Reflected from-> Directional Coupler 710-> Filter 709-> Circulator 704-> Reflected at λ / 2 transmission line line 713 with open impedance-> Through isolator 703 path (ⓗ) Termination at end isolator 703.

At this time, the SPDT switch 707 makes the load of the λ / 2 transmission line line 708 open by a TX on control signal. This provides more than 20 dB transmission signal isolation between the circulator 704 and the SPDT switch 707. In this state, when the transmission side reflected power (path ⓓ) induced at the input terminal of the reception side low noise amplifier 706 is calculated, it becomes -1.5 dBm. This value is 13.5 dB less than the input IP3 (+12 dBm) at the input of the low noise amplifier (Agilent's MGA72543). As mentioned above, unlike the expectation that the transmit / receive isolation provided by the circulator 704 may have been lost, it may adversely affect the input of the low-noise amplifier 706 on the receiving side. Still does not cause any electrical damage to the input of the low noise amplifier 706 on the receiving side. This structure also has the advantage of protecting the expensive power amplifier 702 output stage since the reflected transmit power is terminated at the isolator 703.

FIG. 10 is a diagram illustrating a flow of a received signal and a noise signal flow induced from a power amplifier. In the receive mode, the loss between the noise power induced from the power amplifier 702 and the input of the antenna 711 and the low noise amplifier 706 directly affecting the system noise figure (NF) is important.

Referring to FIG. 10, first, the SPDT switch 707 has a terminal connected to an open stub by a TX off control signal to an input terminal of the low noise amplifier 706. At this time, the impedance seen from the other side of the λ / 2 transmission line line 713 is 50 에 by the transmission line theory (50 Ω = Zo ² / ZL, ZL = 50), so that the λ / 2 transmission line line 713 There is almost no loss of received signal. Here, the loss (path ⓖ) between the antenna 711 and the input terminal of the low noise amplifier 706 is -1.9 dB as in the embodiment of the present invention. This loss value is typical of the value obtained from other systems. Therefore, there is little deterioration of noise figure (NF).

In the reception mode, the bias control signal of the power amplifier 702 is turned off in order to minimize the influence of the reception side interference from the power amplifier 702. At this time, the circulator 704 isolates the output noise of the power amplifier 702 of about 20 dB. When the power (path ⓕ) derived from the power amplifier 702 in which the bias control signal is turned off at the input terminal of the low noise amplifier 706 is calculated, -104.7 dBm / 10 MHz as in the embodiment of the present invention. Becomes This value is a thermal noise level that does not affect receiver performance. That is, the structure of FIG. 7 can receive an input signal in an optimal state even in a reception mode.

In detail, the above-described embodiment of the present invention can be applied to a system having a use frequency of 2 to 3 GHz, and another embodiment of the present invention is preferably applied to a system having a use frequency of 3 GHz or more. The reason is that when the frequency used is 3 GHz or more, the length of the λ / 4 transmission line becomes too short, which makes it difficult to actually implement. For example, on a printed circuit board (PCB) with a frequency of 4 GHz and a substrate dielectric constant of 4.7, the λ / 4 effective wavelength length is about 8.6 mm, and the SPDT switch and its peripheral circuits alone can exceed this effective wavelength length. Therefore, when the frequency used is 3GHz or more, the circuit is designed using a transmission line line for receiving side isolation as λ / 2, as in another embodiment of the present invention.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

As described above, the present invention not only protects the output stage of the power amplifier (PA) in a TDD wireless communication system using high power, but also attenuates the transmission power introduced into the low noise amplifier in the transmission mode to reduce the low noise amplifier. There is an advantage to protect. In particular, when the structure according to the present invention is applied to the RF front-end of HPi (High sped Portable Internet) system, which is currently actively developed, it is possible to easily solve the technical difficulties caused by the TDD operation of the high power signal. On the other hand, since the (circulator + isolator + transmission line line + SPDT switch) part according to the present invention can be manufactured in a single module form, the transfer of technology and the income generation can be expected.

1 shows a high frequency shearing device using an RF switch.

2 shows a high frequency shearing device using an isolator.

Figure 3 is a view showing the configuration of the RF shear apparatus of the time division duplex system according to an embodiment of the present invention.

4 is a view for explaining the normal transmission signal flow and circuit operation in the configuration of FIG.

FIG. 5 is a view for explaining the transmission signal flow and the circuit operation when an unexpected problem occurs such as truncation or short circuit on the transmission path in the configuration of FIG. 3; FIG.

FIG. 6 is a view for explaining a flow of a received signal and a noise signal induced from a power amplifier in the configuration of FIG.

7 is a view showing the configuration of the RF shearing apparatus of a time division duplex (TDD) system according to another embodiment of the present invention.

8 is a view for explaining the normal transmission signal flow and circuit operation in the configuration of FIG.

FIG. 9 is a view for explaining the flow of a transmission signal and a circuit operation when an unexpected problem occurs such as truncation or short circuit on the transmission path in the configuration of FIG. 7; FIG.

FIG. 10 is a view for explaining a flow of a received signal and a noise signal induced from a power amplifier in the configuration of FIG. 7; FIG.

Claims (10)

In a high frequency front-end device of a time division duplex (TDD) wireless communication system, A circulator for transmitting a signal from the power amplifier to an antenna feed line and for transmitting a signal from the antenna feed line to a quarterwave transmission line; The quarterwave transmission line being installed on a reception path for reception side isolation in a transmission mode; The high frequency switch shorting the load of the quarterwave transmission line to ground or connecting to a low noise amplifier according to a control signal; And said low noise amplifier for low noise amplifying and outputting a signal from said high frequency switch. The method of claim 1, And an output terminal of the power amplifier includes an isolator, the isolator protecting the output terminal of the power amplifier and terminating a signal reflected back when an abnormality occurs in an antenna feed line. The method of claim 1, The quarter wave transmission line is an impedance open or 50 ohms viewed from the circulator side according to the connection state of the high frequency switch. The method of claim 1, And the high frequency switch is a single pole double through (SPDT) switch or a pin (PIN) diode switch. The method of claim 1, And turn off the bias control of the power amplifier in the receive mode. In a high frequency front-end device of a time division duplex (TDD) wireless communication system, A circulator for transmitting a signal from the power amplifier to an antenna feed line and for transmitting a signal from the antenna feed line to a transmission line line; The transmission line line installed on the reception path for reception side isolation in the transmission mode; The high frequency switch connecting the load of the transmission line to an open stub of a predetermined length or to a low noise amplifier according to a control signal; And a low noise amplifier for low noise amplifying and outputting a signal from the high frequency switch, And a transmission line line formed by connecting the transmission line line, the high frequency switch, and the open stub is λ / 2. The method of claim 6, And an output terminal of the power amplifier includes an isolator, the isolator protecting the output terminal of the power amplifier and terminating a signal reflected back when an abnormality occurs in an antenna feed line. The method of claim 6, The transmission line line is characterized in that the impedance seen from the circulator side is open or 50 ohms according to the connection state of the high frequency switch. The method of claim 6, And the high frequency switch is a single pole double through (SPDT) switch or a pin (PIN) diode switch. The method of claim 6, And turn off the bias control of the power amplifier in a receive mode.