EP2102981A2

EP2102981A2 - Reconfigurable power amplifier and use of such amplifier for making a multistandard amplification stage for mobile phone communications

Info

Publication number: EP2102981A2
Application number: EP08761931A
Authority: EP
Inventors: Didier Belot; Yann Deval; Nathalie Deltimple; Eric Kerherve; Pierre Jarry
Original assignee: Centre National de la Recherche Scientifique CNRS
Current assignee: Centre National de la Recherche Scientifique CNRS
Priority date: 2007-01-16
Filing date: 2008-01-14
Publication date: 2009-09-23
Also published as: WO2008099113A3; FR2911447B1; US20100109770A1; WO2008099113A2; JP2010516214A; FR2911447A1; JP5095755B2; US8115547B2

Abstract

The reconfigurable power amplifier of the present invention includes at least one amplification circuit (E1, E2) and control means (6) of said amplification circuit for adapting the operation thereof depending on an input signal (RF in) applied thereto. The control means include means (4, 5) for modifying the compression point of said amplification circuit and for adapting the gain of the circuit in order to increase the efficient added power of the circuit for the modified compression point.

Description

Reconfigurable power amplifier and use of such an amplifier for producing a multistandard amplification stage for mobile telephony

The invention relates to high frequency power amplifiers and more particularly relates to reconfigurable power amplifiers.

A particularly interesting application of such amplifiers relates to the development of an amplification stage for a mobile telephone station and, more particularly, the design of multistandard reconfigurable power amplifiers, that is to say capable of adapting to the specifications of different telecommunication standards.

Thus, for example, such a reconfigurable power amplifier must be able to operate as well according to UMTS standards (WCDMA) and according to GSM, DCS or PCS standards.

The concept of reconfigurability indicates that these amplifiers must be able to dynamically modify their properties according to the standard used at a given moment but also the power level of an incident signal applied to it so that it works at a power level. optimum.

Indeed, according to certain standards, in particular the GSM and GSM 1800 (DCS) standards, because of the type of modulation used, the power of the signals is relatively high, which implies a particular constraint for RF applications.

It is thus the object of the invention to propose a reconfigurable power amplifier, in particular power, in order to respond dynamically to the specific constraints imposed on it.

The object of the invention is therefore, according to a first aspect, a reconfigurable power amplifier, comprising at least one amplification circuit and means for controlling said circuit. amplifier for adapting its operation according to an input signal applied to it.

According to a general characteristic of this amplifier, the control means comprise means for modifying the compression point of said amplification circuit and for adapting the gain of the circuit in such a way as to increase the power-added efficiency (PAE). English) of the circuit for the modified compression point.

Thus, the compression point is varied so as to adapt the linearity of the amplifier according to the operating conditions and the PAE is dynamically modified so as to obtain a maximum PAE at the modified compression point. It has indeed been found that the output of the amplifier is maximum for the maximum power output, the efficiency being lower for lower power output levels.

Setting the maximum PAE at the modified compression point thus improves the performance of the amplifier at low power.

According to another characteristic of the invention, the control means comprise means for adapting the level of a bias current applied to said circuit.

Preferably, the power amplifier is a two - stage amplifier and has a first amplification stage and a second amplification stage. The control means then comprise first and second control means for respectively adapting the operation of the first and second amplification stages.

Thus, for example, the first control means comprise means for adapting the compression point of the first stage.

As regards the second control means, these advantageously comprise means for adapting the gain of the second stage. According to another characteristic of the invention, the amplifier further comprises means for modifying the amplification class of said amplification circuit.

In one embodiment, these means comprise means for modifying the equivalent impedance of an output network of the circuit.

For example, the amplifier thus comprises switching means for selectively connecting a capacitance and an inductance connected in parallel with the output of the circuit. As regards the means for adapting the level of the bias current, these advantageously comprise, in one embodiment, a set of current sources selectively connectable in parallel to each other.

Other objects, features and advantages of the invention will become apparent on reading the following description, given solely by way of nonlimiting example, and with reference to the appended drawings in which:

- Figure 1 is a table illustrating the specifications of different telecommunication standards (GSM, DCS and UMTS);

FIG. 2 is a block diagram illustrating the general structure of a reconfigurable power amplifier according to the invention;

FIG. 3 illustrates the general principle of the dynamic compensation implemented within the amplifier of FIG. 1;

FIG. 4 is a block diagram illustrating the development of the bias current of the amplification circuits of the amplifier of FIG. 2; FIGS. 5 and 6 illustrate the variation of the compression point of the first amplification stage of the amplifier of FIG. 2; and

FIGS. 7 and 8 illustrate the evolution of the effective combined power of the amplifier of FIG. 2. Referring first to FIG. 1, a reconfigurable power amplifier must satisfy several requirements specific to each telecommunication standard according to which it is intended to operate. Current standards indeed use different types of modulation that imply differences in the forms of the RF signals conveyed.

For example, the GSM and GSM 1800 (DCS) standards use a Gaussian Minimum Shift Keying (GMSK) type modulation, whereas the UMTS standard uses QPSK ("Quaternary Phase Shift Keying" modulation, in English).

As far as the UMTS standard is concerned, the transmitted signals have a non-constant envelope, which means that the envelope of the RF signal varies as a function of time. But it must be preserved in order to prevent the information contained in it from being altered. It is therefore necessary that the RF amplifiers used for signal processing have good linearity in order to avoid distortion of the envelope during amplification. But the demands in terms of power output are less restrictive. On the contrary, with regard to GSM and GSM standards

1800 (DCS), according to the GMSK modulation used, the envelope is relatively constant so that it is not necessary to provide an amplification having a very high linearity. On the other hand, as indicated by the visible table as in FIG. 1, the power output must be relatively high. In order to reduce the consumption, which is a relatively restrictive criterion when it comes to realizing a reconfigurable power amplifier for a mobile telephone station, the efficiency of the amplifier and its efficiency must be sufficient. This is why sinusoidal operating classes, in particular class A or class AB power amplifiers, are generally used for the realization of telecommunication station power stages designed to operate according to the UMTS standard, because of their good linearity, whereas Class F power amplifiers are used instead for the development of power stages for telecommunications equipment intended to operate according to the GSM, DCS or PCS standards. FIG. 2 shows a reconfigurable power amplifier capable of responding to the specific constraints of each standard and, in particular, of privileging either the linearity criterion or the efficiency criterion, depending on the standard used.

As will be detailed hereinafter, this high frequency power amplifier is adapted to dynamically modify the compression point (CP) of the amplifier stage (s) that it comprises and to modify the amplification class. of these stages in order either to improve the linearity of the amplifier or to improve the efficiency. In the exemplary embodiment shown in FIG. 2, the amplifier comprises two amplification stages E 1 and E 2 constituting one a driving stage (E 1) and the other a power stage (E 2).

As is conventional, each stage comprises a transistor Qd and _Qp, respectively. As can be seen in the figure, the transistor Qd of the first stage E1 is associated with two inductors LI1 and L12 connected to a DC voltage source Vcc and the other to ground.

Similarly, the transistor Q _p is associated with two inductors L21 and L22 connected to the voltage Vcc and the other to ground.

The first stage transistor Qd control electrode receives a high frequency RF signal _1n through an input matching network 1.

The common node between the inductance LI 1 and the transistor Qd is connected to the control electrode of the transistor Q _p of the second stage 2 via a conventional interstage matching network 2. The common node between the inductor L21 and the transistor Q _p provides an amplified signal S via an output network 3 essentially comprising an RLC network.

Furthermore, each stage is provided with a bias circuit, respectively 4 and 5, for biasing the transistor Qd

The amplifier is provided by a processing unit 6 receives, as input, the RF signal _1n and controlling the bias circuits 4 and 5 for biasing the transistors Qd and _Qp of the amplification stages E l and E 2 depending on the signal input involved in the amplifier.

More particularly, the first bias circuit 4 of the first stage E 1 is adapted to develop a bias current Ibiasd for the control electrode of the transistor Qd in order to vary its compression point (CP).

The second bias circuit 5 of the second stage E2 is, meanwhile, for developing a bias current Ibiasp for the second transistor Q _p . In addition, the processing unit 6 acts on the output network 3 in order to modify the operating class of the power stage by modifying the equivalent impedance of this output network 3.

Thus, according to the amplifier visible in FIG. 2, it is essentially a question of modifying the compression point of the amplifier and the class of operation in order either to improve the linearity or to improve the efficiency with added power ( EAP).

This PAE operating parameter is in fact constituted by the ratio between the added power, that is to say the linear difference between the output power and the input power, at a frequency

RF wanted on the product of the sum of the currents flowing through each stage and the DC voltage Vcc-

In other words, the PAE is given, for a two - stage amplifier, by the following relation: p - pl RF (out) ¹ RF (In)

PAE = O)

(I ₁ + I ₂ ) - Vcce

in which :

- P _{RF (0Ut)} designates the output power of the amplifier at the RF frequency;

- P _{RF (M)} denotes the power of the RF input signal _1n ; and

Ii and I ₂ denote currents flowing through transistors Qd and As previously indicated, sinusoidal class amplifiers, such as class A, B, AB and C amplifiers exhibit good linearity but relatively low efficiency.

In contrast, the switching transistors, of class D, E and F, in which the transistors operate in switching mode, have a lower linearity but a higher output.

This is why a class A amplifier is usually used as UMTS standard to realize the control stage and a class AB amplifier to realize the power stage, while it is preferable to use an amplifier. class AB to realize the control stage and a high - efficiency amplifier (class F) to realize the power stage as standard GSM, DCS or PCS.

In order to be able to operate the amplifier in multistandard, it is desirable to be able to pass the class A / class AB configuration class AB / class F.

In the following description, it will be considered that it is essentially to be able to dynamically pass the configuration of a two-stage amplifier class A / AB class AB / F. But the invention also applies "mutatis mutandis" to the reconfiguration of power amplifiers operating according to other telecommunications standards. The architectures of transistors of classes AB and F are relatively close. They differ essentially only by their point of polarization and their output impedance.

Thus, by acting on the bias current and Ibiasd Ibiasp and by modifying the configuration of the output stage, it is possible to change the class of operation of each transistor Qd and _Qp.

Referring to FIG. 3, in which the curve I designates the evolution of the output power P _or t as a function of the input power P _1n and the curve II designates the evolution of the PAE as a function of the input power, the amplifier, and in particular the bias circuit 4 of the first stage E 1, modifies the polarization current

Ibiasd of transistor Qd so as to lower the compression point

CP l corresponding to an operating point (P _or t, a; P _1n , a) to the operating point CP 1 ', corresponding to the operating point (P _or t, b; P _1n , b) as illustrated by FIG. arrow F.

But, as is known per se, the PAE is maximum for the maximum power output, while for the lower power levels, the efficiency is lower.

Also, the modification of the compression point is combined with a gain compensation in order to adjust the PAE curve so as to obtain a maximum PAE at the compression point CP 1 thus modified.

Referring to FIGS. 4 and 5 and FIG.

OCP 1 and ICP 1 denote respectively the output power and the input power at the 1 dB compression point, as previously indicated, the variation of the compression point is obtained by modifying the polarization current Itπasd-

For example, the bias circuit 4 may consist of a succession of current sources II, 12, ... I _n arranged in parallel and each associated with a switch C 1, C 2, C 3,... CN, driven by the central unit 6 as a function of the RF signal _1n so as to develop the bias current Ib _ias d applied to the transistor Qd.

For this purpose, the processing unit 6 is provided with a detector providing detection of the power level of the RF input signal _1n for example, to lower the compression point when the input power decreases. Referring to FIG. 5, this can be done by increasing or lowering the bias current Ibiasd as a function of the input power level. Similarly, referring to FIGS. 7 and 8, the PAE can be modified by increasing or lowering the bias current

Abiasd-

Referring again to FIG. 2, the amplification class modification of the amplifier, and in particular of the second stage E2, is performed by modifying the equivalent impedance of the output network 3.

Thus, as shown in FIG. 2, the output network 3 of the second stage E2 is provided with a resonator formed by the parallel association of an inductance L 'and a capacitance C at the output of the associated second stage E2 two switches 7 and 8 interposed one, namely the switch designated by the reference 7 between the second stage E2, with interposition of a decoupling capacitor C "and the resonator L 'C, and the other between the resonator The C and output impedance RLC of the output network 3. The switches 7 and 8 are controlled by the central unit 6 so as to bypass the LC resonator via a branch line 9. The output network 3 can thus be selectively configured, under the control of the central unit 6 so as to configure the power stage 2 either in the form of a class AB transistor, or in the form of a transistor class F, for example depending on the power level detected nce of the RF input signal _1n .

Claims

Reconfigurable power amplifier, comprising at least one amplification circuit (E 1, E 2), and control means (6) of said amplification circuit for adapting its operation according to an input signal (RF _1n ) which it is applied, characterized in that the control means comprise means (4) for modifying the compression point (CP 1, CP 1 ') of said amplification circuit and for adjusting the gain of the circuit so as to increase the efficiency added power (PAE) circuit for the modified compression point.

2. Amplifier according to claim 1, characterized in that the control means comprise means for adapting the level of a bias current (I _BIA S _D ) applied to said circuit.

3. Amplifier according to one of claims 1 and 2, characterized in that it comprises a first amplification stage (E l) and a second amplification stage (E2), the control means comprising first and second means (4, 5) for respectively adapting the operation of the first and second stages (E1, E2) of amplification.

4. Amplifier according to claim 3, characterized in that the first control means comprise means for adapting the compression point of the first stage (E l).

5. Amplifier according to one of claims 3 and 4, characterized in that the second control means comprise means (5) for adjusting the gain of the second stage.

6. Amplifier according to any one of claims 1 to 5, characterized in that it further comprises means for modifying the operating class of said amplification circuit.

7. An amplifier according to claim 6, characterized in that the means for modifying the operating class of the amplification circuit comprise means for modifying the equivalent impedance of an output network (3) of the circuit.

8. Amplifier according to claim 7, characterized in that it comprises switching means (7, 8) for selectively connecting a capacitor (C) and an inductor (L ') connected in parallel to the output of said circuit.

An amplifier according to any one of claims 2 to

8, characterized in that the means for adjusting the level of the bias current comprise a set of current sources (II, 12, ... I _n ) selectively connectable in parallel to each other.

10. Use of a power amplifier according to any one of claims 1 to 9, for the production of a multistandard amplification stage for mobile telephone.