KR200321637Y1 - Extraction Apparatus of Phase and Amplitude Error in Linear Power Amplifier - Google Patents

Abstract

The present invention relates to a phase, magnitude error extraction device in a linear power amplifier, and more particularly, a pre-amplifier for amplifying a weak RF input signal; A first directional coupler for distributing the signal output from the pre-amplifier to the main amplifier and the delay line; First and second main amplifiers for amplifying the input signal to a desired output level; A second directional coupler for distributing a signal output from the first main amplifier to a second delay line and a second vector modulator; First and second delay lines for compensating time delays for signals output from the pre-amplifier and the first main amplifier, respectively; A first divider for distributing a signal past the first delay line in phase; A second divider for combining the signal distributed in the first divider with the signal distributed in the first main amplifier; A third divider for combining the signal distributed in the first divider with a signal past the first vector modulator; First to third vector modulators simultaneously controlling the magnitude and phase of a signal input to each under control of a control board; 90 ° which receives the signals output from the second delay line and the second main amplifier, respectively, and outputs only the main signal to one port and only the error signal to the other output port by using the phase relationship between the ports. A hybrid bonder; An isolator for preventing a signal output from the 90 ° hybrid coupler from flowing into the LPA; Receives an error signal output from one port of the 90 ° hybrid coupler and consists of a control board for generating a control voltage to the first to third vector modulator respectively to maintain a constant output characteristics irrespective of environmental changes of the LPA In addition, the linearization performance can be improved, the control signals for several vector modulators can be easily implemented, the overall LPA efficiency can be increased, and the size of the entire amplifier can be reduced, thereby miniaturizing, high efficiency, and low-cost amplifiers desired by consumers. To make it.

Description

Extraction Apparatus of Phase and Amplitude Error in Linear Power Amplifier

The present invention relates to a phase and amplitude error extractor in a linear power amplifier (LPA), and more particularly, to linearization of a power amplifier which is a core module of a mobile communication system. It solves some of the problems of the most widely used linearization method, Feedforward, and is designed to greatly improve the amplifier performance and efficiency with a simple circuit configuration.

In general, a liner power amplifier employing a well-known feedforward method (hereinafter referred to as LPA) is a pre-amplifier for amplifying a weak RF input signal to an appropriate level as shown in FIG. )Wow;

A directional coupler (21) for distributing various signals outputted through the pre-amplifier (18);

A vector modulator (22, 38) for adjusting a phase and a magnitude of a signal output through the directional couplers (21, 37);

A main amplifier (24) for amplifying the signal output through the directional coupler (23) from the vector modulator (22) to a desired output;

Delay lines 27 and 32 for compensating for time delays caused by the main amplifier 24 and the error amplifier 39;

A directional coupler 26 for distributing a signal including an error signal; A directional coupler 36 for canceling the main signal;

An error amplifier 39 for amplifying the error signal from which the main signal is canceled to an appropriate level;

A directional coupler 28 which combines the main signal 25 including the error signal and the extracted error signal 40 to cancel the error signal of the output port;

An isolator 31 for preventing a signal reflected at the output port from flowing into the LPA;

Directional couplers 17 and 23 for inputting pilot signals;

Directional couplers 20 and 29 for distributing signals to control boards 41 and 42 for generating control signals to the vector modulators 22 and 38, respectively;

Control boards 41 and 42 which generate appropriate control signals to the vector modulators 22 and 38.

However, the LPA of the general feedforward method having such a configuration has some problems as follows.

First, in addition to the main amplifier 24 for amplifying the main signal, there should be an error amplifier 39 for amplifying the error signal to an appropriate level. This added error amplifier acts as a problem of lowering the overall efficiency of the LPA. have.

Second, the conventional feedforward LPA cannot separate the main signal and the error signal from the output port, and thus requires a separate signal, a pilot signal (17) 23, the pilot signal is provided separately In addition to lowering the overall efficiency of the LPA, the circuit becomes complicated, the overall size of the LPA is increased, and the cost of production rises, causing a burden on the consumer.

The present invention has been devised to solve such a conventional problem, and the phase shift function of the 90 ° hybrid coupler is completely separated from the main signal and the error signal without the pilot signal required by the conventional feedforward LPA. It is possible to improve the linearization performance, to simply implement control signals for several vector modulators, and to increase the overall LPA efficiency by eliminating the error amplifier required in the conventional feedforward method. The objective is to provide a phase and magnitude error extraction device in a linear power amplifier that can reduce the size of the entire amplifier to create the miniaturized, high efficiency, low cost amplifier that consumers want.

The object of the present invention is a pre-amplifier for amplifying a weak RF input signal to an appropriate level; A first directional coupler for distributing the output signal amplified to a proper level through the pre-amplifier to a main amplifier and a delay line; First and second main amplifiers for amplifying the input signal to a desired output level; A second directional coupler for distributing the signal amplified to the proper level through the first main amplifier to a second delay line and a second vector modulator; First and second delay lines for compensating time delays for the signals output from the pre-amplifier and the first main amplifier, respectively; A first divider for distributing a signal past the first delay line in phase; A second divider for combining the signal distributed in the first divider with the signal distributed in the first main amplifier; A third divider for combining the signal distributed in the first divider with a signal past the first vector modulator; First to third vector modulators simultaneously controlling the magnitude and phase of a signal input to each under control of a control board; 90 ° which receives the signals output from the second delay line and the second main amplifier, respectively, and outputs only the main signal to one port and only the error signal to the other output port by using the phase relationship between the ports. A hybrid bonder; An isolator for preventing a signal output from the output port of the 90 ° hybrid coupler from flowing into the LPA; The control board receives the error signal output from one port of the 90 ° hybrid coupler and generates a control voltage to the first to third vector modulators to maintain a constant output characteristic regardless of the environmental change of the LPA. Can be achieved.

Therefore, it is possible to completely separate the main signal and the error signal without the pilot signal to improve the linearization performance, and to simply implement the control signal for several vector modulators, which was required in the conventional feedforward method. The elimination of error amplifiers not only improves the overall LPA efficiency, but also reduces the size of the entire amplifier, making it the smallest, most efficient, low-cost amplifiers consumers demand.

1 is a block diagram of a conventional feedforward (Feedforward) LPA block configuration.

Figure 2 is a block diagram of the device of the present invention.

3 is a phase relationship waveform diagram of a 90 ° hybrid coupler for explaining the operating state of the device.

Explanation of symbols on the main parts of the drawings

1: pre-amplifier

2, 4: first and second directional couplers

3, 15: main amplifier

5, 8: first and second delay lines

6: 90 ° hybrid coupler

7: isolator

9, 12, 14: first to third vector modulator

10, 11, 13: first to third dispenser

16: control board

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

Figure 2 shows a block diagram of the device of the present invention, Figure 3 shows a phase relationship waveform diagram of a 90 ° Hybrid Coupler for explaining the operating state of the device of the present invention.

According to the present invention, there is provided a device comprising: a pre-amplifier 1 for amplifying a weak RF input signal to an appropriate level;

A first directional coupler (2) for distributing the signal amplified and outputted through the pre-amplifier (1) to a first main amplifier (3) and a delay line (8);

First and second main amplifiers (3) (15) for amplifying the signals respectively input through the first directional coupler (2) and the third vector modulator (14) to a desired output level;

A second directional coupler (4) for distributing the signal amplified to the appropriate level through the first main amplifier (3) to the second delay line (5) and the second vector modulator (9);

First and second delay lines (8) (5) for respectively compensating time delays for the signals output from the pre-amplifier (1) and the first main amplifier (3), respectively;

A first divider (10) for distributing a signal past the first delay line (8) in phase;

A second divider that combines the signal distributed by the first divider 10 with the signal input through the second directional combiner 4 and the second vector modulator 9 distributed by the first main amplifier 3 ( 11);

A third divider (13) for combining the signal divided by the first divider (10) with the output signal of the second divider (11) past the first vector modulator (12);

First to third vector modulators (12) (9) (14) for simultaneously controlling the magnitude and phase of a signal input to each under control of the control board (16);

Receives the signals output from the second delay line 5 and the second main amplifier 15, respectively, and outputs only the main signal to one port using the phase relationship between the ports, and only the error signal to the other output port. A 90 ° hybrid coupler 6 for outputting the same;

An isolator (7) which prevents a signal output from the output port of the 90 ° hybrid coupler 5 from flowing into the LPA;

First to third vector modulators 12 and 9 for receiving a control signal output from the other port of the 90 ° hybrid coupler 5 and maintaining a constant output characteristic regardless of the environmental change of the LPA. It is characterized by consisting of the control board 16 to generate each to (14).

Referring to Figure 3 the operation and effect of the device of the present invention configured as described above are as follows.

First, the weak input signal S, which does not include the LPA input error signal, is amplified into a signal 43 having a predetermined level through the pre-amplifier 1 and then the first delay through the first directional coupler 2. It is distributed to line 8 and main amplifier 3.

At this time, the output signal of the first main amplifier 3, which amplifies the signals 43 respectively input through the first directional coupler 2 to a desired output level, receives an error signal because of the nonlinear characteristics of the first main amplifier element. It becomes the included signal 44.

As such, the output signal of the first main amplifier 3 including the error signal is distributed through the second directional coupler 4 and input to the second delay line 5 and the second vector modulator 9. The signal input to the 2 delay line 5 is converted into a signal 45 in which the time delay of the second main amplifier 15 is compensated and then the port 1 of the 90 ° hybrid coupler 6 (45 in FIG. 3). Form).

On the other hand, the first delay line 8 is to compensate for the time delay of the first main amplifier 3, the signal 50 past the first delay line 8 is distributed in the first divider 10. .

This divided signal is passed through the first main amplifier 3 to the first echo combiner 4 and the signal 47 and the second divider 11 whose magnitude and phase are changed in the second vector modulator 9. Are combined in.

The signal combined in the second divider 2 can produce only an error signal from which the main signal has been removed by appropriately adjusting the phase and magnitude in the second vector modulator 9.

The error signal from which the above-mentioned main signal is removed is output in a phase-adjusted manner in the first vector modulator 12 to be out of phase with one signal 52 distributed in the first divider 10 (i.e., FIG. 2 of 51).

Accordingly, the third divider 13 couples the signal 52 distributed by the first divider 10 and the signal 51 output from the first vector modulator 12 to each other. The final signal combined and output from the divider 13 has a form of a signal 53 in which phases of the main signal and the error signal are reversed.

The output signal 53 of the third divider 13 is controlled by the second vector modulator 14 in its magnitude and phase (i.e., 90 ° phase inversion) and then through the second main amplifier 15. After being amplified to a predetermined level, it is input to port 3 of the 90 ° hybrid coupler 6 in the form of a predetermined signal (ie, signal 48).

At this time, the phase relationship of the 90 ° hybrid coupler 6 is as shown in FIG.

That is, as mentioned above, the signal 45 input to port 1 of the 90 ° hybrid coupler 6 should have the form of signal 48 and the signal input to the port 3 should be 48.

The signal input from port 1 is delayed by 90 ° in port 2 to form the signal 55, and is delayed by 180 ° in port 4 to form 59.

In addition, when a signal is input to port 1, port 3 becomes an isolation port so that no signal appears.

The signal input to port 3 of the 90 ° hybrid coupler 6 is in the form of 48, which becomes the signal of 56 which is delayed by 180 ° out of port 2, and the delay of 90 ° out of port 4 results in 60 It becomes a signal.

At this time, when a signal is input to port 3, port 1 becomes an isolation port and no signal appears.

As a result, the signal input from the port 1 of the 90 ° hybrid coupler 6 and the signal input to the port 3 are combined with each other to form a form of 57 in which the error signal is removed from the port 2, and is output to the LPA output port. The main signal is removed and becomes the signal form of 61 so as to enter the control board 16 to produce control signals for the first to third vector modulators 12, 9, 14.

At this time, it is necessary to control so that the magnitude of the error signal is always maximized at the port 4 of the 90 ° hybrid coupler 6 so that the output at the port 2 has the smallest error signal to obtain the maximum linearization characteristic.

This type of LPA eliminates the need for the error amplifier required by the general feedforward method, and eliminates the need for the pilot signal used to extract the error signal adjacent to the main signal. LPA linearization performance and efficiency can be improved, production costs can be reduced to low cost, and the circuit is not complicated, and the overall LPA size can be miniaturized.

As described above, according to the present invention, since an error amplifier is not included in the circuit and only an error signal can be extracted using a 90 ° hybrid coupler, an error signal, which is a disadvantage of the general-purpose feedforward LPA, can be extracted. It is possible to solve the problems of amplifier efficiency and circuit complexity caused by the addition of pilot, and also to compensate for the error signal, which is a disadvantage of the conventional method, but an error amplifier is added but it is not applied in this configuration. The complexity problem of the doubler circuit can be solved.

In addition, the coupling loss of the 90 ° hybrid coupler is smaller than the coupling loss of the directional coupler used in the conventional output stage, which improves the overall LPA efficiency, thereby providing an amplifier suitable for the low cost, high efficiency, and miniaturization trend of the current LPA market. .

Claims (1)

A known pre-amplifier 1 for amplifying the weak RF input signal to an appropriate level; A known first directional coupler (2) for distributing the signal amplified and output to the appropriate level through the pre-amplifier (1) to the first main amplifier (3) and the delay line (8); First and second main amplifiers (3) (15) for amplifying the signals respectively input through the first directional coupler (2) and the third vector modulator (14) to a desired output level; A known second directional coupler (4) for distributing the signal amplified to the appropriate level through the first main amplifier (3) to the second delay line (5) and the second vector modulator (9); Known first and second delay lines (8) (5) for compensating time delays for signals output from the pre-amplifier (1) and the first main amplifier (3), respectively; A first divider (10) for distributing a signal past the first delay line (8) in phase; A second divider for combining the signal distributed in the first divider 10 with the signal input through the second directional coupler 4 and the second vector modulator 9 after being distributed in the first main amplifier 3. (11); A third divider (13) for combining the signal divided by the first divider (10) with the output signal of the second divider (11) past the first vector modulator (12); First to third vector modulators (12) (9) (14) for simultaneously controlling the magnitude and phase of a signal input to each under control of the control board (16); Receives the signals output from the second delay line 5 and the second main amplifier 15, respectively, and outputs only the main signal to one port using the phase relationship between the ports, and only the error signal to the other output port. A 90 ° hybrid coupler 6 for outputting the same; A known isolator (7) for preventing a signal output to the output port of the 90 ° hybrid coupler 5 from flowing into the LPA; First to third vector modulators 12 and 9 for receiving a control signal output from the other port of the 90 ° hybrid coupler 5 and maintaining a constant output characteristic regardless of the environmental change of the LPA. A phase and magnitude error extracting apparatus in a linear power amplifier, characterized by comprising a known control board (16) which is generated in (14), respectively.