KR100393535B1 - Signal detection circuit - Google Patents

Abstract

The present invention provides a signal detection circuit that does not cause mismatch of impedance by connection of a detection circuit.

To this end, in the present invention, the first circuit (1), the second circuit (3), the low pass filter (2) connected between the first circuit (1) and the second circuit (3), and the first circuit An inductance element having a detection circuit 5 for detecting a signal output from (1), wherein the low pass filter 2 is connected in series between at least the first circuit 1 and the second circuit 3; 2a) and a first splitting capacitor 2b having one end connected to one end of the inductance element 2a, and the other end of the first splitting capacitor 2b to the detection circuit 5 and connected to the first circuit. The signal was inputted into the detection circuit 5 via the classification capacitor 2b.

Description

Signal Detection Circuit {SIGNAL DETECTION CIRCUIT}

The present invention relates, for example, to a signal detection circuit for detecting a level of transmission power.

2 is a diagram illustrating a part of a transceiver for explaining a conventional signal detection circuit. The power amplifier 11 receives a 800 MH transmission signal output from a modulator (not shown). The power amplifier 11 amplifies the transmission signal to the required level and inputs it to the low pass filter 12. The low pass filter 12 is of a? Type to remove harmonics of the transmission signal. The nominal impedance is designed to be equal to the output impedance of the power amplifier 11.

On the output side of the low pass filter 12, a duplexer (antenna container) 13 and a detection circuit 14 are connected. The antenna 15 and the receiving circuit 16 are again connected to the duplexer 13. The duplexer 13 is for splitting the transmission signal and the reception signal, and inputs the transmission signal to the antenna 15 and the reception signal received at the antenna 15 to the reception circuit 16. In addition, the impedance of the input / output stage is equal to the nominal impedance of the low pass filter 12.

The detection circuit 14 is constituted by a double voltage rectifying circuit, and the charging capacitor 14a becomes a coupling capacitor with the low pass filter 12 to perform double voltage rectification by two diodes 14b and 14c. The voltage is detected in proportion to the level of the transmission signal, and the detected voltage is used for APC (automatic power control) and the like.

In a conventional signal detection circuit, input and output impedances of a power amplifier, a low pass filter, and a duplexer through which a transmission signal passes are made the same. This is to eliminate the loss caused by mismatch. In such a state, when a detection circuit is connected between the low pass filter and the duplexer, a mismatch of impedance occurs between the low pass filter and the duplexer, and a loss due to the mismatch occurs.

The present invention provides a signal detection circuit that does not cause mismatch of impedance by the connection of such a detection circuit.

1 is a partial configuration diagram of a transceiver for explaining a signal detection circuit of the present invention;

2 is a diagram illustrating a part of a transceiver for explaining a conventional signal detection circuit.

※ Explanation of code in main part of drawing

1: power amplifier 2: low pass filter

2a: inductance element 2b: first class capacitor

2c: second class capacitor 3: duplexer

4 antenna 5 detection circuit

5a, 5b: detector diode 6: receiving circuit

In order to solve the above problems, the signal detection circuit of the present invention comprises a first circuit, a second circuit, a low pass filter connected between the first circuit and the second circuit, and an output from the first circuit. A detection circuit for detecting a signal, wherein the low pass filter includes a first classification having one end connected to at least one end of the inductance element and the inductance element connected in series between at least the first circuit and the second circuit; The other end of the said 1st classification capacitor was connected to the said detection circuit, and the said signal was input into the said detection circuit via the said 1st classification capacitor.

The signal detection circuit of the present invention connects a second class capacitor between the other end of the inductance element and ground, and constitutes a π-type low pass filter by the inductance element and the first and second class capacitors. It was.

The signal detection circuit of the present invention will be described with reference to FIG. 1 is a diagram illustrating a part of a transceiver for explaining a signal detection circuit of the present invention. In the power amplifier 1 serving as the first circuit, a transmission signal of 800 MH band output from a modulator (not shown) is input. A low pass filter 2 is connected to the power amplifier 1, a duplexer 3 serving as a second circuit is connected to the low pass filter 2, and an antenna 4 is connected to the duplexer 3. . The transmission signal amplified to the required level by the power amplifier 1 is transmitted from the antenna 4 through the low pass filter 2 and the duplexer 3.

The low pass filter 2 removes harmonics of the transmission signal generated by the power amplifier 1, and includes an inductance element 2a and a first class capacitor 2b connected to both ends of the inductance element 2a. The second split capacitor 2c is configured in the form of?. The detection circuit 5 is connected via the first flow capacitor 2b.

The detection circuit 5 is composed of a double-voltage rectifier circuit, and the first class capacitor 2b constituting the low pass filter 2 is a charging capacitor and a coupling capacitor to detect the transmission signals 5a and 5b. Type in The detection circuit 5 detects a voltage in proportion to the level of the transmission signal, and the detected voltage is used, for example, in APC (automatic power control) or the like, whereby the power transmitted from the antenna 4 is controlled to be constant. .

The receiving circuit 6 is connected to the duplexer 3. The duplexer 3 is for splitting the transmission signal and the reception signal, and the reception signal received by the antenna 4 is input to the reception circuit 26.

Here, the output impedance of the power amplifier 1 and the input / output impedance of the duplexer 3 are designed to be the same. Therefore, the low pass filter 2 provided between the power amplifier 1 and the duplexer 3 is also designed to have a nominal impedance equal to these impedances. That is, since the detection circuit 5 is a DC circuit, the impedance is low, and when the detection circuit 5 is connected in series with the first classification capacitor 2b, the first classification capacitor 2b and the detection diodes 5a and 5b are connected. Since the connection point of ()) becomes an equivalent circuit to the grounded ground, the low pass filter 2 may be designed on the assumption that the connection point of the first branch capacitor 2b and the detection diodes 5a and 5b is the ground point. As a result, even when the detection circuit 5 is connected, the impedance of the low pass filter 2 and the impedance of the power amplifier 1 match, and the impedance of the low band pass filter 2 and the duplexer 3 are matched. Match the impedance of.

In addition, the detection circuit 5 can also be connected via the 2nd class | capacitance capacitor 2c. The configuration of the low pass filter 2 is not limited to the π type shown here, but may be a low pass filter that requires a classification capacitor.

As described above, the signal detection circuit of the present invention includes a first circuit, a second circuit, a low pass filter connected between the first circuit and the second circuit, and a detection circuit for detecting a signal output from the first circuit. And the low pass filter has at least one inductance element connected in series between the first circuit and the second circuit, and a first branch capacitor connected at one end of the inductance element to the other of the first branch capacitor. Since one end is connected to the detection circuit and a signal is inputted to the detection circuit via the first classification capacitor, there is no mismatch in impedance due to the connection of the detection circuit. In addition, since the first class capacitor also serves as a coupling capacitor for connecting the detection circuit, the number of parts to be used can be reduced.

In the signal detection circuit of the present invention, the second classification capacitor is connected between the other end of the inductance element and the ground, and the? Type low pass filter is formed by the inductance element and the first and second classification capacitors. Can be connected to either the input side or the output side of the low pass filter. Therefore, the degree of freedom in arrangement of circuit components is increased.

Claims (2)

A first circuit, a second circuit, a low pass filter connected between the first circuit and the second circuit, and a detection circuit for detecting a signal output from the first circuit, The low pass filter has an inductance element connected in series between at least the first circuit and the second circuit, and a first class capacitor having one end connected to one end of the inductance element, And the other end of the first classification capacitor is connected to the detection circuit, and the signal is input to the detection circuit via the first classification capacitor. The method of claim 1, A second branch capacitor is connected between the other end of the inductance element and the ground; And a? Type low pass filter formed by the inductance element and the first and second class capacitors.