KR20150000966A - Asymmetric Doherty Amplifier - Google Patents

Abstract

The present invention relates to an asymmetric Doherty power amplifier, and more particularly, to an asymmetric Doherty power amplifier capable of maximizing power efficiency by implementing a carrier amplifier and a FET of a peaking amplifier in the same device. A carrier signal amplifying means for amplifying a carrier signal of an RF signal distributed asymmetrically from the distributing means and a peak signal of an RF signal distributed asymmetrically and input from the distributing means, And a power combining means for combining the RF power signals amplified and outputted from the carrier signal amplifying means and the peak signal amplifying means, respectively, wherein the carrier signal amplifying means and the peak signal amplifying means are connected to each other with a maximum output capacity The same is true of the present invention.

Description

Asymmetric Doherty Amplifier < RTI ID = 0.0 >

The present invention relates to an asymmetric Doherty power amplifier, and more particularly, to an asymmetric Doherty power amplifier capable of maximizing power efficiency by implementing a carrier amplifier and a FET of a peaking amplifier in the same device.

Modern mobile communication systems use digital modulation communication methods to use limited frequency resources more efficiently. The digitally modulated signal is power amplified to a certain level and radiated through the antenna of the base station or repeater. At this time, in order to amplify the input power of the baseband signal to a desired power, the linear characteristic of the power amplifier should be good. Therefore, in order to satisfy the high linearity characteristic, the power amplifier is generally operated in the A or AB mode.

On the other hand, recently, there is a demand for a power amplifier having excellent linear characteristics and high efficiency. As a method for achieving high efficiency, it can be considered to enhance the efficiency of the amplifier itself and to increase the efficiency of the additional linearization circuit. In the former case, there are methods such as Doherty, LINC (LINA amplification using nonlinear components), Envelope Elimination and Restoration (EER), and bias adaptive control.

In the case of Doherty, asymmetric amplifiers are used according to the ratio according to the PAR (Peak-to-Average Ratio) of the input signal in order to improve the power consumption efficiency of the high output power amplifier of the transmission base station and the repeater. When two FETs are used, FETs having different output capacitances are used. The input power signals are divided at a certain ratio at the input side of the Doherty structure amplifier, and the electric power is amplified by each FET. At this time, if the electric characteristics such as path gain, phase, and delay of each FET are equal to each other, maximum performance can be obtained. However, since each FET used in the asymmetric Doherty has different output capacities, the characteristics of the FET itself such as gain, delay, and phase are different from each other, There is a difficult problem.

According to the prior art, Korean Patent Registration No. 10-1107827 (entitled "3-way Doherty Amplifier Including a Minimum Output Network"), when implementing the carrier amplifier and the picking amplifier in a three-way manner as in the conventional Doherty amplifier, To an invention using an FET device having other electrical characteristics.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an N-way Doherty amplifier using FET devices having different electrical characteristics for carrier amplifiers and peaking amplifiers, -way Doherty amplifier.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

The above-mentioned object of the present invention can be achieved by a radio communication apparatus comprising: distributing means for distributing an RF input signal; carrier signal amplifying means for amplifying a carrier signal of an RF signal distributed asymmetrically inputted from the distributing means; A peak signal amplifying means for amplifying a peak signal of an RF signal, and a power combining means for combining an RF power signal amplified and outputted from the carrier signal amplifying means and the peak signal amplifying means, respectively, wherein the carrier signal amplifying means and the peak signal amplifying means The means can be achieved by providing an asymmetric Doherty power amplifier characterized in that the elements use the same maximum output capacity.

The carrier signal amplifying means and the peak signal amplifying means are provided in parallel with each other, and the respective output powers are coupled by the power combining means.

The RF signal inputted to the peak signal amplifying means is characterized in that the magnitude of the power of the input signal is relatively larger than that of the RF signal inputted to the carrier signal amplifying means.

The output capacitance of the carrier signal amplifying means and the peak signal amplifying means is determined according to the peak-to-average ratio (PAR) of the RF input signal. The drain voltage supplied to the carrier signal amplifying means is a predetermined reference voltage And the drain voltage supplied to the peak signal amplifying means is supplied with a voltage corresponding to the output capacitance determined according to the PAR of the RF input signal.

The output capacitance of the carrier signal amplifying means and the peak signal amplifying means is determined according to the peak-to-average ratio (PAR) of the RF input signal. The drain voltage supplied to the carrier signal amplifying means is a predetermined reference voltage And the drain voltage supplied to the peak signal amplifying means is supplied with a voltage obtained by multiplying the reference voltage by a predetermined multiple according to the comparison between the envelope signal of the detected RF input signal and the predetermined threshold voltage.

The drain voltage supplied to the peak signal amplification means includes envelope detection means for detecting an envelope of the RF input signal, comparison means for comparing the detected envelope signal with a predetermined threshold voltage, and comparison means for comparing the detected envelope signal with a predetermined threshold voltage A drain voltage obtained by multiplying the reference voltage by a predetermined multiple is supplied, and if not, the drain voltage is determined by a drain voltage supply means for supplying the reference voltage.

As described above, according to the present invention, since the same FET device is used, the electric characteristics are the same, so that the Doherty amplifier can be easily implemented and the power efficiency can be improved.

According to the present invention, since the conventional N-way Doherty amplifier is implemented as a 2-way Doherty amplifier, the size and the number of the amplifiers can be reduced, thereby reducing the size of the product and reducing the price of the product.

Further, according to the present invention, since the same FET device is used, the tuning time of the amplifier in the production process can be greatly reduced.

According to the present invention, even if the drain voltage of the FET is changed due to the use of the same FET device, the electric characteristics are different from each other, so that the electric power efficiency is improved more than when using the FET device having completely different electrical characteristics, .

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, It should not be construed as limited.
1 is a diagram showing a configuration of a conventional N-way Doherty amplifier,
FIG. 2 is a diagram illustrating the efficiency of a conventional N-way Doherty amplifier,
3 is a diagram illustrating a configuration of an asymmetric Doherty power amplifier according to the present invention,
Fig. 4 is a graph showing the characteristic of the FET MRFE6V25L of Freescale Co.,
FIG. 5 is a diagram illustrating the configuration of an asymmetric Doherty amplifier using envelope tracking means according to the present invention,
6 is a diagram showing an output waveform of a voltage input to a drain terminal of a picking amplifier according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings. In addition, the embodiment described below does not unduly limit the content of the present invention described in the claims, and the entire structure described in this embodiment is not necessarily essential as the solution means of the present invention.

<Asymmetry Doherty  Configuration and function of power amplifier>

A conventional Doherty amplifier is a high efficiency modulation amplifier for a large power transmitter configured to synthesize a main amplifier (carrier amplifier) for amplifying a basic signal (carrier signal) and an auxiliary amplifier (a peaking amplifier) for amplifying a peak signal . In order to achieve high efficiency, only the carrier amplifier operates at low output and the carrier amplifier and peaking amplifier operate at high output simultaneously. At this time, the carrier amplifier and the peaking amplifier use FET devices having different output capacities. Typically, the carrier amplifier is in Class B, the picking amplifier is in Class C, and the picking amplifier starts operating when the carrier amplifier saturates.

Meanwhile, the N-way Doherty amplifier is composed of one carrier amplifier 210 and a plurality of picking amplifiers 220 as shown in FIG. The number of the peaking amplifiers 220 may be appropriately selected according to the N-way to be implemented.

The power divider 100 distributes the input RF signal according to the number of the carrier amplifiers and the number of the peaking amplifiers. For example, in a 3-way case, one carrier amplifier and two peaking amplifiers are electrically coupled in parallel to each other, and the power divider 100 divides the RF input signal into three parts and inputs them to the carrier amplifier and the peaking amplifier, respectively.

One of the signals distributed in the power divider 100 is input to the carrier amplifier 210, and the remaining signals are input to the peaking amplifier 220, respectively. The delay line 10 having the characteristic impedance of Ro oh is electrically coupled between the power divider 100 and the peaking amplifier 220 in order to compensate for the phase difference of the amplifier output terminal before being input to the peaking amplifier 220. [ do.

The signal input from the power divider 100 to the carrier amplifier 210 is amplified and output according to the set gain of the carrier amplifier 210 and is supplied from the power divider 100 to the plurality of picking amplifiers 220 Is amplified and output according to the set gain of the peaking amplifier at a specific point in time (usually at the point when the carrier amplifier saturates).

Offset lines 20 having predetermined lengths? C and? P are provided at the rear ends of the carrier amplifier 210 and the peaking amplifier 220, respectively. The offset line 20 causes the output matching of the carrier amplifier 210 to take place in the situation where the load impedance Ro is modulated and causes the open output impedance to be achieved when the peaking amplifier 220 is disconnected. This offset line 20 allows proper load impedance modulation to achieve asymmetrical output coupling and minimize power leakage.

FIG. 2 shows the efficiency of the conventional N-way Doherty amplifier. It can be seen that the maximum efficiency can be realized in a 3-way case at about -12 dB of output back-off. At this time, the back-off generally means that the amplifier is operated at a point of 3 to 5 dB lower than the maximum available power point, thereby securing the linearity.

That is, when a power signal of -12 dB of the input PAR is input to the 4-way Doherty amplifier as shown in FIG. 2, when the average power is output at the point where the output capacity of the amplifier is backed -12 dB, Can be obtained. The output capacity of the amplifier refers to the primary P1dB or Psat, and the maximum output capacity of 4way is the sum of the four FET outputs.

Meanwhile, among the conventional N-way Doherty amplifiers shown in FIG. 1, the carrier amplifier 210 is always fixed to one, and the peaking amplifier 220 increases according to the N-way. Therefore, in the case of the conventional 3-way Doherty amplifier, one carrier amplifier and two picking amplifiers are used.

In contrast, the asymmetric Doherty power amplifier according to the present invention implements a picking amplifier using one carrier amplifier and one FET having twice the capacity of the conventional two picking amplifiers. Therefore, unlike the conventional N-way Doherty amplifier, the asymmetric Doherty amplifier according to the present invention uses FETs having the same output capacity so that the electric characteristics (for example, gain, delay, phase) of the carrier amplifier and the peaking amplifier are the same.

At this time, if the power distributor 100 is replaced by a directional coupler of 2: 1 (-5dB) at 3way, the same effect as the conventional 3way can be realized. The asymmetric Doherty power amplifier according to the present invention can be constructed by selecting the FETs such that the capacities of the carrier amplifier and the peaking amplifier are equal to each other and by varying the amount of power of the input signal distributed to the carrier amplifier and the peaking amplifier.

FIG. 3 shows an asymmetric Doherty power amplifier according to the present invention. In FIG. 3, one carrier amplifier 330 and one peaking amplifier 330 are used to perform the same performance as a conventional 3-way amplifier (composed of one carrier amplifier and two picking amplifiers) (340). At this time, the carrier amplifier 330 and the peaking amplifier 340 use FETs having the same output capacity.

First, the RF input signal is primarily amplified by the driver amplifier 310 and output to the distributing means 320. At this time, the distributing means 320 may be embodied by a -5dB directional coupler. If the conventional 4-way Doherty amplifier is implemented as 2-way as in the present invention, the distributing means 320 may be embodied by a -6 dB directional coupler.

The RF signal output from the driver amplifier is distributed asymmetrically by the distributing means 320 to the carrier amplifier 330 and the peaking amplifier 340. [ The RF signal input from the distributing means 320 to the carrier amplifier 330 is coupled to the gate of the carrier amplifier 330 and the RF signal input from the distributing means 320 to the picking amplifier 330 is supplied to the peaking amplifier 340, Lt; / RTI &gt;

The capacity of the FET used in the carrier amplifier 330 and the peaking amplifier 340 is determined according to the PAR of the RF input signal. The output capacity of the FET to be determined at this time uses an FET having the same output capacity as both the carrier amplifier 330 and the peaking amplifier 340.

The drain of the carrier amplifier 330 and the drain of the peaking amplifier 340 are coupled to the matching circuit 350, respectively. In addition, the source of the carrier amplifier 330 and the source of the peaking amplifier 340 are respectively grounded. The drain terminal of the carrier amplifier 330 is applied with a voltage of about 26 to 38 volts provided by an external system and a voltage corresponding to a predetermined FET output capacitance is applied to the drain terminal of the peaking amplifier 340.

An example of the voltage supplied to the drain terminal of the picking amplifier 340 will be described with reference to FIG. Fig. 4 shows the relationship between the output power capacity of Freescale's MRFE6V25L FET and the input voltage at the drain terminal. 4, when the output capacity of the peaking amplifier 340 is determined, the corresponding drain voltage is supplied to the DC-DC converter 360 through the DC-DC converter 360 Supply.

As described above, by implementing the asymmetric 2-way Doherty amplifier 3 having the performance of the conventional N-way Doherty amplifier 1 in a very small size, excellent power efficiency characteristics can be realized.

On the other hand, the DC-DC converter 360 of FIG. 3 can be changed to the envelope tracking means 460 of FIG. Hereinafter, an example in which the envelope tracking means 460 is used will be described. However, descriptions of the same functions and configurations as those of Fig. 3 will be omitted.

5, in order to use the envelope tracking means 460, the coupler 410 samples the RF input signal. The envelope signal 510 is detected by the envelope detection means as shown in FIG. 6 for the sampled RF input signal. The comparing means compares the detected envelope signal 510 with a threshold voltage 530, V _t . When the envelope signal 510 is smaller than the threshold voltage, Vds is directly applied to the peaking amplifier 440, and when the envelope signal 510 is larger than the threshold voltage, Vds * 2 is output. The output waveform 520 of the voltage input to the drain terminal of the peaking amplifier is shown in FIG. 6 by comparison with the threshold voltage. For example, when Vds is DC 28 [v], 28 [v] is input to the drain terminal of the peaking amplifier when the detected envelope signal is smaller than the threshold voltage, and when the detected envelope signal is larger than the threshold voltage, v] is inputted to the drain terminal of the peaking amplifier, it is possible to realize better efficiency than the amplifier which fixes 56 [v] to the drain terminal.

Although the present invention has been described with reference to the embodiment thereof, the present invention is not limited thereto, and various modifications and applications are possible. In other words, those skilled in the art can easily understand that many variations are possible without departing from the gist of the present invention.

1: conventional n-way Doherty amplifier
3: Asymmetric Doherty amplifier according to the present invention
10: Delay line
20: offset line
100: N-way power splitter
210: Carrier amplifier
220: Picking amplifier
310: Driver Amplifier
320: directional coupler
330: Carrier amplifier
340: Picking amplifier
350: matching circuit
360: DC-DC Converter
410: Coupler
420: Delay line
425: directional coupler
430: Carrier amplifier
440: Picking amplifier
450: matching circuit
460: Envelope tracking means
510: envelope signal
520: Output waveform
530: threshold voltage

Claims (5)

A distributing means for distributing the RF input signal,
Carrier signal amplifying means for amplifying a carrier signal of an RF signal distributed asymmetrically from the distributing means,
A peak signal amplifying means for amplifying a peak signal of an RF signal distributed asymmetrically from the distributing means and inputted,
And power combining means for combining the RF power signals amplified and output from the carrier signal amplifying means and the peak signal amplifying means, respectively,
Wherein said carrier signal amplifying means and said peak signal amplifying means have mutually equal maximum output capacities.
The method according to claim 1,
Wherein the carrier signal amplifying means and the peak signal amplifying means comprise:
And each output power is coupled by the power coupling means. &Lt; Desc / Clms Page number 13 &gt;
The method according to claim 1,
Wherein the RF signal input to the peak signal amplifying means comprises:
And the power of the input signal is relatively larger than that of the RF signal input to the carrier signal amplifying means.
The method according to claim 1,
And the output capacity of the carrier signal amplifying means and the peak signal amplifying means are set so that,
Is determined by the peak-to-average ratio (PAR) of the RF input signal,
Wherein the drain voltage supplied to the carrier signal amplifying means is supplied with a predetermined reference voltage,
Wherein the drain voltage supplied to the peak signal amplifying means is supplied with a voltage corresponding to the output capacitance determined according to the PAR of the RF input signal.
The method according to claim 1,
And the output capacity of the carrier signal amplifying means and the peak signal amplifying means are set so that,
Is determined by the peak-to-average ratio (PAR) of the RF input signal,
Wherein the drain voltage supplied to the carrier signal amplifying means is supplied with a predetermined reference voltage,
Wherein the drain voltage supplied to the peak signal amplifying means is a voltage obtained by multiplying the reference voltage by a predetermined multiple according to a comparison between an envelope signal of the detected RF input signal and a predetermined threshold voltage.

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