KR100814457B1 - Dual-band feedforward linear power amplifier - Google Patents

Abstract

A dual-band feedforward linear power amplifier is provided to perform a dual-band linear power amplification for two communication frequency bands separated over a certain frequency according to a band width of a wide band directional combiner and a diplexer. In a dual-band feedforward linear power amplifier, a wide band Wilkinson power divider(10) distributes a dual-band signal to two paths. A dual-band power amplifier(20) diverges the dual-band signal in a main path to two different paths, amplifies, and combines the diverged signal to one path, again. A wide band directional coupler(30) receives the dual-band signal and outputs the signal distributively. A dual-band main signal canceller(40) combines the amplified dual-band signal and the dual-band signal in a supplementary path from the wide band Wilkinson power divider, destructively. A dual-band intermodulation power amplifier(50) diverges the dual-band intermodulation distortion signal to two different paths according to a frequency component, amplifies, and combines the signal to one path, again. A dual-band intermodulation distortion signal canceller(60) outputs a pure main signal finally.

Description

Dual-band Feedforward Linear Power Amplifier

1 is a block diagram illustrating a typical single band feedforward linear power amplifier,

2 is a block diagram showing the overall configuration of a dual band feedforward linear power amplifier according to the present invention;

3A and 3B are block diagrams illustrating a dual band main signal removing loop according to the present invention, and a diagram illustrating an operation principle of the dual band main signal removing loop;

4A and 4B are block diagrams illustrating a dual band intermodulation distortion signal removal loop according to the present invention, and a diagram illustrating an operation principle of the dual band intermodulation distortion signal removal loop.

5A and 5B are block diagrams illustrating a single band equal group speed delay main signal canceller and a single band equal group speed delay intermodulation distortion signal canceller according to the present invention;

6A and 6B are block diagrams showing the same group speed delay double band main signal canceller according to the present invention;

7 is a schematic diagram illustrating a measuring method of a dual band feedforward linear power amplifier according to the present invention;

8A and 8B are graphs illustrating a measurement result of a dual band main signal cancellation loop and a graph of a dual band intermodulation distortion signal cancellation loop measurement result according to the present invention;

9A and 9B are graphs showing ACLR characteristics according to output power levels of digital cellular bands for CDMA IS-95-A 4FA signals according to the present invention, and graphs showing output spectrums of digital cellular bands at an average output power of 41.5 dBm. ,

10A and 10B are graphs showing ACLR characteristics according to the output power level of the IMT-2000 band for the WCDMA 4FA signal according to the present invention, and an output spectrum of the IMT-2000 band at an average output power of 40 dBm.

The present invention relates to a dual band feedforward linear power amplifier, and more particularly, a dual band feedforward capable of performing a dual band linear power amplification for two communication frequency bands separated by 1 GHz or more depending on the bandwidth of the diplexer and the wideband directional coupler. A linear power amplifier.

In general, mobile communication in the past was mainly limited to low-volume data exchange such as voice and text. However, in order to satisfy various demands of users, various functions such as digital cameras, MP3s, and TV receivers of high pixels have been added to the terminal, and a situation in which high-capacity data has to be transmitted and received.

As a result, in order to provide a service including multimedia information in addition to the existing communication, a case in which another service band is used in addition to a frequency already used by one service provider has occurred.

At this time, since the development of equipment for each application case involves a lot of cost and effort, the research on multi-band equipment that can cover more than one frequency band is being actively conducted recently. However, despite the need for multiband equipment, most of the research so far has been limited to terminals due to the strict linearity requirements of the base stations.

In order to overcome this linearity problem, there are various linearization methods, but in terms of improvement effect and operating bandwidth, the practical linearization techniques are predistortion technique, feedforward technique, negative feedback technique, and digital transposition. There are methods such as distortion and envelope elimination and retention.

First, the RF predistortion technique is widely used in terms of small size and light weight, but the nonlinearity improvement effect is less than the feedforward technique, and it is not easy to have the linearity improvement effect in a wide frequency band.

Negative feedback techniques have limited application range due to the limitation of operating bandwidth and possibility of oscillation. Digital predistortion techniques compensate for nonlinearity in RF circuits by predistorting baseband signals. Due to the memory effect of the RF power amplifier, a good linearization effect is obtained only in a relatively narrow band.

In addition, the feedforward technique is practically the most widely used for the excellent linearity improvement effect, and the most active research is being conducted. However, research to date has focused mainly on linearization and efficiency improvement within one operating frequency.

The present invention has been made to solve the conventional problems as described above,

It is an object of the present invention to provide a dual band feed forward linear power amplifier capable of dual band linear power amplification for two communication frequency bands separated by a predetermined frequency or more depending on the bandwidth of the diplexer and the wideband directional coupler.

Another object of the present invention is to provide a dual band feedforward linear power amplifier capable of simultaneously performing dual band operation and wideband signal cancellation within each band by using the same group speed delay dual band signal canceller.

A dual band feedforward linear power amplifier of the present invention for achieving the above object,

The dual-sided Wilkinson power divider 10 for splitting the dual-band signals of frequency bands 1 and 2 into two paths and the dual-band signal delivered to the main path connected to the wideband Wilkinson power divider 10 according to frequency components A dual band power amplifier 20 for branching and amplifying the other two paths and synthesized in one path again, an amplified double band connected to the dual band power amplifier 20 and delivered through the dual band power amplifier 20 A wideband directional coupler 30 receiving and distributing a signal, connected to a group delay line connected to an auxiliary path of the input side wide Wilkinson power divider 10 and a wideband directional coupler 30, and transmitted through the wideband directional coupler 30. A double band signal that cancels the amplified double band signal and the double band signal transmitted to the auxiliary path through the wide band Wilkinson power divider 10. A dual band intermodulation distortion signal connected to an inverse main signal canceller 40, the wideband directional coupler 30, and the double coarse main signal phase strength 40 and transmitted through its output is provided in two different paths according to frequency components. A double band intermodulation amplifier 50 for branching, amplifying and synthesizing into one path, a group delay line connected to the main path of the wideband directional coupler 30, and the double band intermodulation amplifier 50, and the wide band A dual band intermodulation distortion signal that finally outputs only the pure main signal by destructively synthesizing the amplified double band signal transmitted through the directional coupler 30 and the dual band intermodulation distortion signal transmitted through the double band intermodulation amplifier. It is characterized by including the offset device (60).

Hereinafter, an embodiment of a dual band feedforward linear power amplifier of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a general structure of a single band feed forward linear power amplifier. The circuits of the conventional single band feed forward linear power amplifier perform only the amplification, distribution, and synthesis functions of a single frequency band signal.

Figure 2 is a block diagram showing the overall configuration of a dual-band feedforward linear power amplifier according to the present invention, Figure 3a is a block diagram showing a dual-band main signal cancellation loop, Figure 4a is a dual-band intermodulation distortion signal cancellation loop The block diagram shown.

As shown, the dual band feedforward linear power amplifier of the present invention consists of a dual band main signal cancellation loop and a dual band intermodulation distortion signal cancellation loop.

The dual band main signal removal loop,

An input side wide Wilkinson power divider 10, a dual band power amplifier 20 connected to the wide band Wilkinson power divider 10, a wideband directional coupler 30 connected to the dual band power amplifier 20, and And a group delay line connected to the main path of the input wide-band Wilkinson power divider 10 and the same group speed delay double band main signal canceller 40 connected to the wideband directional coupler 30.

The dual band intermodulation distortion signal cancellation loop

A dual band intermodulation amplifier (50) connected to the wideband directional coupler (30) and the dual band main signal phase strength (40), a group delay line connected to the main path of the wideband directional coupler (30), and the double band intermodulation; And a same group speed delay double band intermodulation distortion signal canceller 60 connected to the amplifier 50.

The same group speed delay dual band main signal canceller 40 is composed of a dual band hybrid circuit using a wide band Wilkinson combiner and vertically mounted planar circuits, as shown in FIG. 6A. It is connected by an open line, and a coupling and transmission terminal of a dual band hybrid circuit of another path has a configuration connected by a short line.

In addition, the same group speed delay dual band main signal canceller 40 is composed of a broadband coupler and a dual band hybrid circuit, the dual band hybrid circuit coupling and transmission terminals of one path are connected by an open line, The coupling and transmission terminals of the band hybrid circuit have a configuration connected by a short circuit.

The same group speed delay dual band intermodulation distortion signal canceller 60 is composed of a dual band hybrid circuit using a wideband directional coupler and vertically mounted planar circuits, as shown in FIG. The transmission terminals are connected by an open line, and the coupling and transmission terminals of a dual band hybrid circuit of another path are connected by a short line.

In addition, the same group speed delay dual band intermodulation distortion signal canceller 60 is composed of a wideband directional coupler and a dual band hybrid circuit, the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line, The coupling and transmission terminals of the dual band hybrid circuit of one path have a configuration connected by a short circuit.

The dual band power amplifier 20 installed between the input broadband Wilkinson power divider 10 and the wideband directional coupler 30 includes an input diplexer 21 branching into two different paths according to frequency components, and the input die. Power amplifiers (PAs) 24 and 25 parallel to two paths branched through the flexure 21 and amplified signals, and amplified through the two power amplifiers 24 and 25. It consists of an output diplexer 26 which combines the dual band signal back into one path.

In more detail, the dual band power amplifier 20 is parallel to the input diplexer 21 and the two paths branched through the input diplexer 21 according to the frequency component, Variable amplitude / phase regulators 22 and 23 for controlling the amplitude and phase of the signal, power amplifiers 24 and 25 for amplifying the signal, and amplification delivered through the two power amplifiers 24 and 25. And an output diplexer 26 for synthesizing the combined dual band signal into one path.

The dual band intermodulation amplifier 50 provided between the wideband directional coupler 30 and the dual band intermodulation distortion signal canceller 60 includes an input diplexer 51 branching into two different paths according to frequency components. An intermodulation power amplifier (IPA) 54, 55 arranged in two paths branched through the input diplexer 51 and amplifying a signal; and the two intermodulation amplifiers 54, 55. It consists of an output diplexer 56 which combines the amplified double band signal transmitted through the back path into one path.

More specifically, the dual band intermodulation amplifier 50 is parallel to the input diplexer 51 and the two paths branched through the input diplexer 51 according to the frequency component. Variable amplitude / phase regulators 52, 53 for controlling the amplitude and phase of the signal, intermodulation amplifiers 54, 55 for amplifying the signal, and two intermodulation amplifiers 54, 55 for amplifying the signal. It consists of an output diplexer 56 which combines the amplified double band signal to be transmitted back into one path.

In general, since a mobile communication system adopts a frequency division transmission / reception scheme, a diplexer for transmission / reception frequency division is already used. Therefore, the transmission filter used in the existing diplexer is applied to the output diplexer of the dual band PA, and the remaining diplexer handles the small signal so that it can be easily implemented by using low Q elements. In addition, single-band combiners and single-band signal cancellers have been replaced by double-band signal cancellers.

As shown in FIG. 2, when two operating bands are expressed as frequency band 1 and frequency band 2, in FIG. 2, a solid line means a band 1 and a dotted line means a frequency signal of band 2. In the section where the solid line and the dotted line exist together, two band signals are simultaneously transmitted by the broadband passive element, and the section where only one solid line or the dotted line exists is the section where only the signal of the single band branched by the frequency branching operation of the diplexer is transmitted. to be.

3A and 3B illustrate a main signal cancellation loop and an operation principle of a dual band feedforward linear power amplifier according to the present invention. Referring to FIGS. 3A and 3B, the linearization operation principle is described. The dual-band input signal ( A in FIG. 3b) of and frequency band 2 is divided into two paths (main path and auxiliary path) by an input wideband Wilkinson power divider.

The dual band signal transmitted from the dual to the main path is branched into two different paths according to frequency components by the input diplexer 21 i which is a frequency selection element. The signals of each branched band are amplified by the PAs 24 and 25 and have intermodulation distortion signals in addition to the main signals due to the nonlinearity of the PAs 24 and 25, and are output by the output diplexer 26. The signal of each band can be adjusted in magnitude and phase by the variable amplitude / phase controllers 22 and 23 of the corresponding band.

A portion of the amplified dual band signal is extracted ( G in FIG. 3B) and applied to the input of the dual band main signal canceller 40, branched to the auxiliary path by the input wideband Wilkinson power divider 10, to the group delay line path. The two bands ( H of FIG. 3b) transmitted through the signal are canceled with each other, leaving only the dual band intermodulation distortion signal ( I of FIG. 3b).

4A and 4B illustrate a dual band intermodulation distortion signal cancellation loop and an operation principle according to the present invention, and the dual band intermodulation distortion signal obtained at the output of the dual band main signal canceller 40 ( I in FIG. 4B). Is branched into two paths of frequency band 1 and frequency band 2 by input diplexer 51, and linearly amplified by intermodulation amplifiers 54 and 55 of each band.

The intermodulated distortion signal of each amplified band is synthesized in one path by the output diplexer 56 again ( M in FIG. 4B) and applied to the input of the dual band intermodulation distortion signal canceller 60. Comparing with the output signal ( L in FIG. 4B) via the dual band PA 20 and the wideband directional coupler 30 including the modulated distortion signal, only the pure main signal is delivered to the final output ( N in FIG. 4B). .

On the other hand, in the feedforward linearization scheme, the amplitude, reverse phase, and group speed delay must be simultaneously matched for an even signal cancellation of the signal of the entire band with respect to an input signal having a predetermined frequency band. However, the same group speed delay canceller is proposed to cancel the wideband signal because the signal canceller of the general structure cannot satisfy both the reverse phase match and the group speed delay match.

5A and 5B are block diagrams of a typical single-band co-group delay signal canceller, as shown in FIG. 5A, 5B, based on the fact that the reflection coefficients of the short-circuit and open transmission lines are out of phase with each other as shown. .

6A and 6B, on the other hand, are block diagrams of the same group speed delay dual band signal canceller that extends the signal canceller of FIGS. 5A and 5B. As shown in FIG. 6A, the dual band main signal canceller 40 is a wideband Wilkinson combiner. And a dual band hybrid circuit (VIP broadband 90 ° hybrid) using a vertically mounted planar circuit, and the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line, and the dual band hybrid of the other path. The coupling and transmission terminals of the circuit are connected by short circuit lines.

The dual band intermodulation distortion signal canceller 60 is composed of a dual band hybrid circuit (VIP broadband 90 ° hybrid) using a wideband directional coupler and vertically mounted planar circuits, as shown in FIG. 6B. The coupling and transmission terminals are connected by an open line, and the coupling and transmission terminals of a dual band hybrid circuit of another path are connected by a short circuit.

As shown in FIG. 6A, when a dual band signal is applied to two input terminals G and H of the dual band main signal canceller 40, a coupling port and a through port are shorted and opened, respectively. It passes through the VIP broadband 90 ° hybrid to the isolation port. When total reflection occurs in open and short stubs, the output signals due to in-phase and 180 ° phase reversal meet the simultaneous matching conditions of amplitude, reverse phase, and group speed delay. Applying the output signals to a wideband (in-phase) Wilkinson coupler completely cancels the input dual-band signal at the output stage I.

Similarly, as shown in FIG. 6B, the dual band input signals having a phase difference of 90 ° with an amplitude difference by the difference between the coupling coefficient and the insertion loss of the wideband directional coupler are VIP broadband 90 ° hybrid having the coupling end and the transmission end shorted and open, respectively. It is applied to the two input terminals L and M of the circuit. The applied signal is passed to the isolation stage, where the output signals are applied to the mutual isolation stage of the broadband directional coupler again. The output signals of the wideband directional coupler satisfy the simultaneous matching conditions of amplitude, inverse phase and group speed delay so that the input signal is completely canceled at the output stage N.

Meanwhile, in the present invention, in order to verify the effectiveness of the design method, a dual band feedforward for a digital cellular band (f0 = 880 MHz) and an IMT-2000 (f0 = 2.14 GHz) band base station spaced apart from 1.26 GHz based on the center frequency of the operating band. A linearization system was implemented and its performance was checked by applying it to a large power amplifier for commercial base stations with a maximum output power of 120W.

7 shows a method for measuring the degree of linearization improvement of a dual band feedforward linear power amplifier. In order to confirm the dual band operation, two signal generators were used to apply the CDMA IS-95A 4FA signal and the WCDMA 4FA signal, respectively, and measured using two spectrum analyzers. In this case, since the dual-band feedforward linear power amplifier is a two-terminal circuit, a wideband Wilkinson synthesizer / divider is used for the input and output terminals.

8A and 8B are loop elimination measurement results measured using a network analyzer. 8A shows a measurement result of the dual band main signal cancellation loop, which has a main signal rejection characteristic of 36.9 dB or more in the 869 to 894 MHz band and 32.1 dB or more in the 2.14 to 2.17 GHz band. FIG. 8B is a measurement result of the dual band intermodulation distortion signal cancellation loop, and has 20dB and 30.6dB rejection characteristics at 100MHz operating bandwidth including the digital cellular and IMT-2000 bands, respectively. In particular, it can be seen that the bandwidth for signal cancellation of 20 dB or more is 113.27 MHz in the digital cellular band and 173.85 MHz in the IMT-2000 band.

9A and 9B show output spectral characteristics of a dual band feedforward linear power amplifier measured by the measuring method mentioned in FIG. 7, and FIG. 9A shows an output at a point 3.125 MHz and 4.375 MHz separated from the center frequency of the digital cellular band. ACLR characteristics before and after the improvement according to the power level are shown. 9B shows an output spectrum with an average output power of 41.5 dBm, indicating that when the average output power is 41.5 dBm, the ACLR is improved by 16.52 dB from -32.96 dBc to -49.48 dBc at 3.125 MHz from the center frequency. It also shows that it maintains good linearity in the output dynamic range.

FIG. 10A illustrates ACLR characteristics before and after improvement according to output power levels at points separated from 5 MHz and 10 MHz at the center frequency of the IMT-2000 band, and FIG. 10B is an output spectrum at an average output power of 40 dBm. It shows even improvement over 5MHz and 10MHz spaced at full output power level, and shows very good linearity after improvement. At an average output power of 40 dBm, the ACLR improved by 18.59 dB from -33.09 dBc to -51.68 dBc at 5 MHz from the center frequency. Good linearity is maintained in the output dynamic range.

On the other hand, this embodiment of the present invention is only to describe a preferred example, the scope of the present invention is not limited to such, and can be changed as appropriate within the scope of the same idea.

As described above, the present invention enables dual-band linear power amplification for two communication frequency bands separated by a predetermined frequency or more according to the bandwidth of the diplexer and the wideband directional coupler. In addition, by using the same group speed delay dual band signal canceller, it is possible to cancel the wide band signal in each band at the same time as the dual band operation, which has the effect of showing excellent performance as a large power amplifier system for base stations in today's broadband multimedia communication field. .

In addition, the dual-band feedforward linear power amplifier of the present invention can reduce the number of outdoor antennas and the incoming cable, if the development of the dual-band base station antenna, it is also possible to improve the ease of operation and urban aesthetics. .

Claims (9)

An input wideband Wilkinson power divider for distributing dual band signals in frequency bands 1 and 2 in two paths; A dual band power amplifier 20 connected to the wide band Wilkinson power divider 10 for branching and amplifying a dual band signal delivered to a main path into two different paths according to frequency components and amplifying the dual band signals into one path; A broadband directional coupler (30) connected to the dual band power amplifier (20) for receiving and amplifying and outputting the amplified dual band signal transmitted through the dual band power amplifier (20); The amplified dual band signal and the broadband Wilkinson power divider are connected to a group delay line and a broadband directional coupler 30 connected to the auxiliary path of the input side wide Wilkinson power divider 10. A dual band main signal canceller 40 which cancels and couples the dual band signals transmitted to the auxiliary path through 10; It is connected to the wideband directional coupler 30 and the dual band main signal canceller 40 and branches and amplifies the dual band intermodulation distortion signal transmitted through the output into two different paths according to frequency components, and then returns one path. A dual band intermodulation amplifier 50 synthesized with; The amplified double band signal of the main path transmitted through the wideband directional coupler 30 and connected to the group delay line connected to the main path of the wideband directional coupler 30 and the dual band intermodulation amplifier 50. A dual-band intermodulation distortion signal canceller 60 for compulsively synthesizing the dual-band intermodulation distortion signal transmitted through the dual-band intermodulation amplifier and finally outputting only the pure main signal; Dual band feedforward linear power amplifier, characterized in that consisting of. The method of claim 1, The dual band main signal canceller 40 is composed of a dual band hybrid circuit using a wide band Wilkinson combiner and vertically mounted planar circuits, and the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line. A dual band feed forward linear power amplifier, characterized in that the coupling and transfer terminals of a dual band hybrid circuit of another path are connected by a short circuit. The method of claim 1, The dual band main signal canceller 40 is composed of a broadband combiner and a dual band hybrid circuit, and the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line and the dual band hybrid of the other path. A dual band feedforward linear power amplifier, characterized in that the coupling and transfer terminals of the circuit are connected by short circuits. The method of claim 1, The dual band intermodulation distortion signal canceller 60 is composed of a dual band hybrid circuit using a wideband directional coupler and vertically mounted planar circuits, and the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line. And a coupling and forwarding terminal of the dual band hybrid circuit of the other path is connected by a short line to the dual band feed forward linear power amplifier. The method of claim 1, The dual band intermodulation distortion signal canceller 60 is composed of a wideband directional coupler and a dual band hybrid circuit, and the coupling and transmission terminals of the dual band hybrid circuit of one path are connected by an open line, A dual band feed forward linear power amplifier, characterized in that the coupling and transfer terminals of a dual band hybrid circuit are connected by a short line. The dual band power amplifier 20 of claim 1, wherein the dual band power amplifier 20 is provided between an input broadband Wilkinson power divider 10 and a wideband directional coupler 30. An input diplexer 21 branching into two different paths according to frequency components, power amplifiers 24 and 25 parallel to two paths branching through the input diplexer 21 and amplifying a signal; And an output diplexer (26) for combining the amplified double band signals transmitted through the two power amplifiers (24, 25) into one path again. 2. The dual band power amplifier 20 of claim 1, wherein the dual band power amplifier 20 is provided between an input broadband Wilkinson power divider 10 and a wideband directional coupler 30. A variable amplitude / phase adjuster, which is parallel to the input diplexer 21 branching into two different paths according to the frequency components and the two paths branching through the input diplexer 21 to control the amplitude and phase of the signal. (22) (23), an output for synthesizing the amplified dual band signals transmitted through the two power amplifiers 24 and 25, and the power amplifiers 24 and 25 for amplifying the signals into one path. A dual band feedforward linear power amplifier characterized by consisting of a diplexer (26). 2. The dual band intermodulation amplifier 50 of claim 1 is provided between the wideband directional coupler 30 and the double band intermodulation distortion signal canceller 60. Intermodulation amplifiers 54 and 55 that are amplified in parallel with the input diplexer 51 branching into two different paths according to the frequency components and the two paths branching through the input diplexer 51. And an output diplexer 56 for synthesizing the amplified double band signals transmitted through the two intermodulation amplifiers 54 and 55 into one path. . 2. The dual band intermodulation amplifier 50 of claim 1 is provided between the wideband directional coupler 30 and the double band intermodulation distortion signal canceller 60. A variable amplitude / phase adjuster that is parallel to the input diplexer 51 branching into two different paths according to the frequency components and the two paths branching through the input diplexer 51 to control the amplitude and phase of the signal. (52) and (53), intermodulation amplifiers 54 and 55 for amplifying the signal, and amplified double band signals transmitted through the two intermodulation amplifiers 54 and 55 in one path. Dual band feed forward linear power amplifier, characterized in that consisting of an output diplexer (56).

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