KR940001233Y1 - Protection circuit for high-frequency power amp - Google Patents

Abstract

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Description

High Frequency Power Amplifier Protection Circuit

1 is a conventional high frequency power amplifier protection circuit diagram.

2 is a high-frequency power amplifier protection circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

100: high frequency power amplifier 200: directional defect

300: forward power voltage converter 400: reflected wave power voltage converter

500: high frequency output control unit R11-Rl6: resistance

C11-C14: Capacitor OP11: Operational Amplifier

The present invention relates to a high frequency power amplifier protection circuit in a wireless transmission and reception system, and more particularly, to a high frequency power amplifier protection circuit for preventing the high frequency amplifier from being damaged by reflected wave power generated in an impedance mismatch state of an antenna.

In general, in order to protect the high frequency power amplifier when the impedance mismatch of the antenna in the wireless transmission and reception system, the isolator rate is used to transmit the high frequency output without attenuation for the forward power and attenuate the reflected wave power by a certain value.

FIG. 1 is a conventional high frequency power amplifier protection circuit diagram. When a high frequency signal is input through the input terminal Pl, the high frequency power amplifier 10 amplifies the high frequency signal by a high frequency output control voltage output from the high frequency output control unit 50. Will print.

The high frequency signal output from the high frequency power amplifier 10 is applied to the directional coupler 20. In this case, the directional coupler 20 detects and outputs the forward power and the reflected wave power, respectively. At this time, the forward power output from the directional coupler 20 is output through the line (a) is coupled by the capacitor (Cl), the forward power voltage conversion unit 40 consisting of a diode (Dl) and the capacitor (C2) It is rectified by) and output as DC voltage. The DC voltage output from the long-range power power converter 40 is divided by the resistors R1-R2 and applied to the inverting terminal (-) of the operational amplifier OP1 through the resistor R3. As a result, the operational amplifier OP1 receives the high frequency output control voltage of the high frequency power amplifier 10 when the voltage input through the resistor R3 is greater than the reference voltage input to the non-inverting terminal (+) through the input terminal P2. The output is almost at the reference voltage level. However, when the voltage input through the resistor R3 is lower than the reference voltage, the high frequency output control voltage applied to the high frequency power amplifier 10 is output higher than the reference voltage level. Here, the reference voltage input through the input terminal P2 is a reference voltage for adjusting the forward power to a predetermined level.

In addition, the high frequency signal output through the directional coupler 20 is transmitted through the antenna ANT1 via the isolator 30, and the isolator 30 does not attenuate the high frequency output when the impedance of the antenna ANT1 is matched. Will be sent.

However, when the antenna ANT1 is mismatched, the reflected wave power is generated. Since the isolator 30 attenuates the reflected wave power by a certain value, it prevents the high frequency power amplifier 10 from being damaged.

In the conventional circuit as shown in FIG. 1, although the reflected wave power is generated in the antenna ANT1 in the impedance mismatching state, the forward power detected by the directional coupler 20 is lowered and output from the forward power voltage converter 40. Since the DC voltage is lowered, the high frequency output control voltage, which is the output of the operational amplifier OP1, becomes higher than the reference voltage level, which not only damages the high frequency power amplifier 10 but also increases the power loss. There was a problem that the use time of the battery is shortened.

Accordingly, an object of the present invention is to provide a high frequency power amplifier protection circuit for preventing damage of a high frequency power amplifier by reflected wave power in an impedance mismatch state of an antenna in a wireless transmission and reception system.

Another object of the present invention is to detect the forward power and the reflected wave power at the same time by using the directional coupler in the wireless transmission and reception system, when the impedance matching state of the antenna to adjust the high frequency output control voltage by the forward power signal voltage In this case, the high frequency power amplifier protection circuit can be prevented from being damaged by adjusting the high frequency power control voltage according to the reflected wave power signal voltage.

Another object of the present invention is to provide a high frequency power amplifier protection circuit that can minimize the power loss of the antenna in a wireless transceiver system with a built-in battery, such as for portable use.

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

2 is a circuit diagram according to the present invention, a high frequency power amplifier 100 for inputting a high frequency signal and amplifying and outputting a high frequency signal by a predetermined high frequency output control voltage, and being amplified and output from the high frequency power amplifier 100. Outputs a high frequency signal, detects forward power in an impedance matching state, and detects and outputs reflected wave power in an impedance mismatch state, and transmits a high frequency signal output from the directional coupler 200. The antenna ANT2, the forward power voltage converter 300 for rectifying the forward power detected by the directional coupler 200 and outputting the direct current voltage, and the reflected wave power detected by the directional coupler 200 to rectify the direct current. Output voltage and reflected wave power of the reflected wave power voltage converter 400 and the forward power voltage converter 300 to output a voltage When the forward voltage or the reflected wave power is greater than the reference voltage Vr by inputting the output voltage of the piezoelectric converter 400, the amplification degree of the high frequency power amplifier 100 is further increased by adjusting the high frequency output control voltage to almost a reference voltage level. It consists of the high frequency output control part 500 which prevents abnormal abnormality.

In the configuration, the forward power voltage converting unit 300 is grounded by connecting a capacitor C11 and a resistor R10 to one side of the directional coupler 200 in series, and connecting the capacitor Cll and the resistor R10. An anode of the diode D11 is connected to the node, a capacitor C13 is connected and grounded to the cathode of the diode D11, and a cathode of the diode D11 is connected to one input of the high frequency output controller 500. The reflected wave power voltage conversion unit 400 is connected to the other end of the directional coupler 200 by the capacitor C12 and the resistor R11 in series, and is connected to the ground of the capacitor C12 and the resistor R11. An anode of the diode D12 is connected to the node, a capacitor C14 is connected to the cathode of the diode D12, and grounded, and a cathode of the diode D12 is connected to another input of the high frequency output controller 500. It is configured to be.

The high frequency output control unit 500 is the first voltage dividing means for dividing the DC voltage rectified from the forward power voltage converter 300, and outputs the rectified from the reflected wave power voltage converter 400 A second voltage dividing means for dividing a DC voltage and outputting the voltage; and a voltage level of the reference voltage when the divided voltage is greater than the reference voltage by receiving the divided voltage of the first voltage dividing means or the divided voltage of the second voltage dividing means. The operational amplifier OP11 outputs a high frequency output control voltage and outputs a high frequency output control voltage when the divided voltage becomes smaller than the reference voltage.

In addition, the high frequency power amplifier 100 may be implemented by the RF power module STM-1645-30 at the time of SGS-TOMSON.

An embodiment of the present invention based on the above configuration will be described with reference to FIG.

When the high frequency signal input through the input terminals P11 and 11 is input to the high frequency power amplifier 100 and the reference voltage input through the input terminal P12 is supplied to the non-inverting terminal (+) of the operational amplifier OP11, the The high frequency power amplifier 100 amplifies a high frequency signal according to a high frequency output control voltage output from the operational amplifier OP11 and transmits the high frequency signal through the directional coupler 200 and the antenna ANT2. At this time, if the impedance of the antenna ANT2 is in a matched state, the directional coupler 200 detects and outputs the forward power.

The forward power output from the directional coupler 200 is rectified by the forward power voltage converter 300 including the capacitors C11 and C13, the diode D11, and the resistor R10, and then converted into a DC voltage. That is, the tetragonal power output from the directional coupler 200 is coupled through the latching device C11 and terminated by the resistor R10 and through the first rectifier including the diode D11 and the latching device C13. The output is converted into DC voltage (V _F ). The DC voltage V _F rectified from the first rectifier is divided by the resistors R12 and R14 and output to the divided full arm V _FWD .

The divided voltage (V _FWD ) = Becomes

In addition, when the impedance of the antenna ANT2 is mismatched, the high frequency signal transmitted from the antenna ANT2 is returned to the high frequency power amplifier 100 through the directional coupler 200. This is called reflected wave power. In this case, the directional coupler 200 detects and outputs reflected wave power. The reflected wave power output from the directional coupler 200 is rectified by the reflected wave power voltage converter 400 including the capacitors C12 and C14, the diode D12, and the resistor R11, and is converted into a DC voltage. That is, the reflected wave power output from the directional coupler 200 is coupled through a capacitor C12 and terminated by a resistor R11 to direct current voltage through a second rectifier composed of a diode D12 and a capacitor C14. V _R ) is converted and output. The DC voltage V _R rectified from the second rectifier is divided by the resistors R13 and R14 and output as the divided voltage V _REFL . The divided voltage V _REFL = Becomes

Herein, when the impedance of the antenna ANT2 is matched

Therefore, the high frequency output control voltage of the high frequency power amplifier 100 is adjusted by the forward power. Therefore, the suppression voltage V _REFL divided by the resistors R12 and R14 is applied to the inverting terminal (−) of the operational amplifier OP11. In this case, the operational amplifier OP11 outputs the voltage Vo inverted and amplified by Equation (1) and applies it to the high frequency power amplifier 100.

Vo =

Here, V _r is a reference voltage input through the input terminal P12, and V _Fed is a voltage input through the resistor R15.

Thus, the operational amplifier OP11 controls the high frequency output through the output terminal when the voltage input through the resistor R15 becomes lower than the reference voltage V _r input to the non-inverting terminal (+) through the input terminal P12. When the voltage is high, the high frequency power amplifier 100 amplifies and outputs a high frequency signal to a predetermined level.

When the voltage V _Fed input through the resistor R15 becomes higher than the reference voltage V _r , the operational amplifier OP11 raises the high frequency output control voltage to the reference voltage V _r level through the output terminal. Adjust the output. When the high frequency output control voltage, which is the output of the operational amplifier OP11, is adjusted to the reference voltage V _r level, the high frequency power amplifier 100 lowers the high frequency signal to a predetermined level to amplify the output.

However, when the impedance of the antenna ANT2 is mismatched

Therefore, the high frequency output control voltage applied to the high frequency power amplifier 100 is adjusted by reflecting plate power. Therefore, the voltage V _REFL divided by the resistors R13 and R14 is applied to the inverting terminal (−) of the operational amplifier OP11. As a result, the operational amplifier OP11 passes through the output terminal when the voltage V _Fed input through the resistor R15 becomes lower than the reference voltage V _r input to the non-inverting terminal (+) through the input terminal P12. The high frequency output control voltage is output higher than the reference voltage (V _r ) level. When the high frequency output control voltage which is the output of the operational amplifier OP11 becomes higher than the reference voltage V _r level, the high frequency power amplifier 100 amplifies and outputs the high frequency signal to a predetermined level.

When the voltage V _Fed input through the resistor R15 is higher than the reference voltage V _r , the operational amplifier OP11 outputs a high frequency output control voltage at an almost reference voltage level through an output terminal. When the high frequency output control voltage, which is the output of the operational amplifier OP11, is lowered, the high frequency power amplifier 100 lowers the high frequency signal to a predetermined level and amplifies the output.

Therefore, when the reflected wave power detected by the directional coupler 200 is rectified and the divided voltage V _REFL generates the reflected wave power of a predetermined value or more, the high frequency output control voltage which is the output of the operational amplifier OP11 is referred to as a reference voltage. By preventing the output of the level or higher, the high frequency power amplifier 100 may not only prevent the high frequency power amplifier 100 from being damaged by the influence of the reflected wave power, but also when the reflected wave power is generated, the high frequency power amplifier 100 may overload. It prevents it from operating, and it does not cause unnecessary power loss, which can prolong the life of the battery when used as a portable.

As described above, when transmitting a high frequency signal using a directional coupler, the forward power and the reflected wave power are detected. When the antenna impedance is matched, the high frequency output control voltage of the high frequency power amplifier is adjusted according to the square power signal voltage. In the mismatching state, the control voltage of the high frequency power amplifier is prevented from being output beyond the reference voltage by using the reflected wave power signal voltage, thereby preventing damage of the high frequency power amplifier due to the reflected wave, and the built-in battery is used as for portable use. In an advanced system, the power loss can be reduced to extend the life of the battery.

Claims (2)

A high frequency power amplifier protection circuit of a radio telephone, comprising: a high frequency power amplifier (100) for amplifying and outputting a high frequency signal in response to a high frequency output control voltage supplied by inputting a high frequency signal and input from the high frequency power amplifier (100) Outputs a high frequency signal, detects the forward power in the impedance matching state, and detects the reflected wave power in the impedance mismatch state and outputs each of the directional coupler 200 and the reflected wave power detected by the directional coupler 200 to rectify the direct current When the reflected wave power voltage converting unit 400 outputting the voltage and the output voltage of the reflected wave power voltage converting unit 400 are input and the reflected wave power of the reference voltage V _r or more is detected, the high frequency power amplifier 10 is inputted. The high frequency output control unit 500 controls the supplied high frequency output control voltage not to exceed the reference voltage level. High-frequency power amplifier protection circuit characterized by a name. The method of claim 1, wherein the high frequency output control section 500, the second voltage dividing means for dividing and detecting the DC voltage rectified and output from the reflected wave power voltage converter 400, and the divided voltage of the second voltage dividing means; In comparison with the reference voltage, the high frequency output control voltage is output at the reference voltage level when the divided voltage is detected by the reflected wave power above the reference voltage, and the high frequency output control voltage when the divided voltage is detected by the reflected wave power below the reference voltage. A high-frequency power amplifier protection circuit comprising an operational amplifier (OP11) for outputting a higher than the reference voltage level.