WO2006032616A1 - Power amplifier unit, mobile telecommunications terminal and associated operating method - Google Patents

Abstract

The invention relates to a power amplifier unit (LVE), comprising a first and at least one additional power amplifier (LV1, LV2, ..., LVW) each being supplied with an operating voltage and being connected in series. A phase-modulated input signal can be supplied from a first signal source (SQ1) to the first power amplifier (LV1) via a first signal line (SL1), and this input signal can be supplied in a manner that enables it to be amplified/attenuated by the first power amplifier (LV1) to the additional power amplifier (LVW). In order to minimize a distortion of the phase of the phase-modulated input signal by impressing the amplitude modulation in the power amplifier unit (LVE), an additional signal can be supplied from a second signal source (SQ2) exclusively to the at least one additional power amplifier (LVW) via a second signal line (SL2). This additional signal leads to the impression of an amplitude modulation upon the phase-modulated input signal in the at least one additional power amplifier (LVW), this amplitude- and phase-modulated signal being able to be amplified/attenuated by the at least one additional power amplifier (LVW), and the amplified/attenuated amplitude- and phase-modulated signal can be output to a transmitting unit (SE) via a third signal line (SL3). The inventive power amplifier unit (LVE) can be advantageously used in a mobile telecommunications terminal that operates according to the EDGE standard.

Description

description

Power amplifier unit, mobile telecommunication terminal and associated operating method

The invention relates to a power amplifier unit to ^¬ collectively a first and at least one further supplied respectively to an operating voltage, series-connected power amplifier, a mobile telecommunication terminal, comprising a power amplifier unit and a method for amplification / attenuation and modulation of a phasenmodulier¬ th input signal in a Power amplifier unit ^{¬ to} a first and at least one further each supplied with an operating voltage, connected in series power amplifier.

It is known that power amplifier units, comprising a first and at least one further each supplied with an operating voltage, serially connected Leistungs¬ amplifier, for example, be used in mobile Telekommunikationsend ^¬ devices.

Usually has a power amplifier unit, which is used in mobile telecommunication terminals, which operate according to the EDGE standard or EGPRS standard, via three series-connected power amplifier. These are based on the one hand, component-specific properties of the Leis ^¬ tung amplifier and on the other hand to fulfilling requirements with regard to the power amplification or attenuation which are specified by the EDGE standard or EGPRS standard.

Using the example of the required dynamic range of the gain or loss from that in the EDGE standard or EGPRS standard be used ^¬ carrier wave of 1800 MHz to

Power amplifier unit supplied input signals ver¬ be clarified. The high frequency carrier oscillation must for Compliance with the maximum power values can be ver ^¬ strength to up to 26 dBm, with a gain of 4 dB is still to be considered for an amplitude modulation aufzuprägende. The input power is typically 5 dBm. This results in a maximum amplification of the input signal of 25 dB. On the other hand, minimum output values have the high frequency carrier wave of 2 dBm be with regard to reach, where denmodulation still an attenuation of -20 dB for a Amplitu be impressed ^¬ be considered. This results in a maximum attenuation of -23 dB.

The input signal of the power amplifier unit must therefore be amplifiable or attenuatable over a dynamic range of 48 dB by the power amplifier unit.

Due to component-specific properties of the power amplifiers, this dynamic range for use in mobile telecommunication terminals can nowadays only be achieved by a power amplifier unit comprising three power amplifiers connected in series. Each power amplifier amplifies the input signal supplied to it by 10 dB or attenuates it by -10 dB. By three series-connected power amplifiers of this type, a maximum amplification of the supplied input signal of 30 dB or a maximum attenuation of the supplied input signal of -30 dB can thus be achieved.

When using power amplifiers connected in series, a distortion of the phase of a phase-modulated input signal occurs due to component-specific properties, eg of limiting effects or transit time effects, if a signal applied to the power amplifiers imposes an amplitude modulation on the phase-modulated signal Input signal is to be effected. This is referred to as so-called amplitude modulation / phase modulation conversion. This is a parasitic influence on the phase of the phase mo dulierten input signal when changing the amplitude. These phase distortions accumulate in the individual series-connected power amplifiers to a total phase error of the high-frequency signal output by the power amplifier unit.

The distortion caused by amplitude modulation / phase modulation conversion of the high-frequency signal output by the power amplifier unit or the high-frequency carrier oscillation appears as a widening in the modulation spectrum. The modulation spectrum mask is a specification-relevant parameter in the mobile radio standards which is used to check the conformity of mobile Telekommunika¬ tion terminals must be tested and adhered to.

In mobile telecommunication terminals, which operate according to the EDGE standard (Enhanced Data Rate for GSM Evolution), a modulation method (8-phase shift keying) is used, which leads to a threefold higher bit transmission rate compared to GSM or GPRS. Eight different symbols are transmitted via the air interface, whereby the individual symbols differ from each other by a phase shift of only 45 degrees. Each symbol to be transmitted, a bit sequence is assigned to one of 3 bits, whereby the higher bit transfer rate over GSM or GPRS data per ^¬ transmission channel or user results.

Tion process, the exact function of the concentration used in EDGE Modula ^¬ is extensively described in the literature and, therefore, the skilled artisan will thoroughly known, so omitted here a more detailed representation of the Mo¬ used in EDGE dulationsverfahrens.

It is only important with respect to the invention that it is unquestionably obvious to the person skilled in the art that phase distortions of the radio-frequency signal to be transmitted via the air interface have the immediate effect that the transmitting side present bitstream after transmission over the air interface on the receiving side can only be incorrectly decoded and thus can not be converted back into the correct Bitström. The above-described amplitude modulation / phase modulation conversion therefore has a drastic effect on a modulation method in which 8 different, over the air interface to über ^¬ bearing symbols must be displayed in the available phase space of 360 degrees (EDGE), as in a modulation method in which only 2 different, to be transmitted via the air interface symbols in the phase space must be displayed (eg GSM, GPRS).

It is therefore an object of the present invention to provide a technical solution for a power amplifier unit and a method of the type mentioned, wherein a distortion of the phase of a phase-modulated input signal is minimized by impressing the amplitude modulation in the Leistungs¬ amplifier unit.

The object is kereinheit according to the invention by a Leistungsverstär ^¬ comprising a first and at least one white ^¬ direct each having an operating voltage supplied dissolved in series-connected power amplifier, wherein the first power amplifier from a first signal source via a first signal line, a phase-modulated input signal to ^¬ is feasible which can be amplified / attenuated by the first power amplifier and can be fed to the further power amplifier, wherein a further signal can be fed to the at least one further power amplifier via a second signal line from a second signal source, which signal is used to impress an amplitude modulation on the phase-modulated input signal in which at least performs a white ^¬ direct power amplifier, wherein the amplitude and phase modulated signal can be amplified / damped by the at least one further power amplifier and a third signal line, the amplified / attenuated amplitude and phase modulated signal can be output to a transmitting unit.

The object is further achieved according to the invention by a method for gain / attenuation and modulation of a phase-modulated input signal in a Leistungsverstärkerein¬ unit comprising a first and at least one further each supplied with an operating voltage, in series ge switched power amplifier, A phase-modulated input signal is fed to the first power amplifier from a first signal source via a first signal line, which is amplified / attenuated in the first power amplifier and fed to the further power amplifier, and wherein only the at least one of the further power amplifiers is connected via a second signal line from a second signal source, a further signal is supplied, which leads to the imposition of an amplitude modulation on the phase-modulated input signal in the at least one further power amplifier, wherein the amplitude and phase modu The amplified / attenuated amplitude and phase modulated signal is then output via a third signal line to a transmitting unit.

This has the advantage of minimizing phase distortion in imposing the amplitude modulation on the phase modulated input signal in the power amplifier unit. Further developments of the invention will become apparent from the dependent claims.

Advantageously, a first voltage regulator is interposed between a voltage source and the further power amplifier, to which the further signal can be fed to the signal source. As a result, the further power amplifier can be operated at an operating voltage which is optimal for it and deviates from the battery voltage. Advantageously, between the voltage source and the first power amplifier, a second voltage regulator is interposed, which is switchable by a signal control source via a switch. In this way, the first power amplifier is also operable with an operating voltage which is optimal for it and deviates from the battery voltage.

A further advantageous embodiment of the invention is that the second voltage regulator is switchable into two discrete Zu¬ states, wherein in a first state Ver ^¬ strengthening of the phase modulated input signal through the ers th th power amplifier and in a second state attenuation of the phase modulated input signal can be effected by the first power amplifier. Thus, on the one hand, a more complicated continuous amplification / attenuation control of the first power amplifier zuge¬ led phase-modulated input signal can be waived, while at the same time from the mobile radio standards resulting ^¬ binding mandatory specifications with respect to the ampli kung / attenuation of the phase modulated input signal through the entire power amplifier unit are met can.

In a refinement of the invention described in the preceding paragraph, the operating voltage supply of the first power amplifier can be effected by the second voltage regulator with the resistor connected in series between the second voltage regulator and the first power amplifier first power amplifier is limited. Thus, one obtains an easily implemented circuit for carrying out the invention in a mode with low amplification or attenuation of the phase-modulated input signal.

In an alternative development of the embodiment of the invention described in the preceding paragraph, when switched switch causes the operating voltage supply of the first power amplifier without Stromflußbegrenzung to the first power amplifier through the resistor. Thus one obtains an easily implemented circuit for carrying out the invention in a high-gain mode of the phase-modulated input signal.

Advantageously, ker between the first Leistungsverstär¬ and the further power amplifier interposed a second-supplied with egg ner operating voltage power amplifiers in series, in addition to the second power ^¬ via the second signal line that derived from the second signal source further signal amplifier is supplied. This makes it possible to achieve greater amplifications or attenuations of the phase-modulated input signal, taking into account the minimization of phase distortions in the power amplifier unit.

In a further advantageous manner, the further power amplifier and / or the second power amplifier can be operated with a continuous degree of amplification / attenuation. As can ^¬ by different mobile standards resulting ver ^¬ binding standards of the gain / attenuation to the phase-modulated input signal processing amplifier unit satisfied by the entire performance in terms.

Advantageously, a mobile telecommunications terminal comprises a power amplifier according to the invention. This modulation method can be applied to these terminals, in which transmitted over the air interface Hochfre ^¬ frequency signals in terms of their decoding on the Empfän¬ gerseite differ only by small phase differences.

Such a mobile telecommunication terminal is advantageously designed as an EDGE radio module. This can be the binding in the EDGE standard set 8 PSK Modu ^¬ lationsverfahren technically feasible. Further advantages of the invention will become apparent from the following description which, in conjunction with the accompanying Zeich¬ calculations, the invention with reference to three exemplary embodiments.

It shows in a schematic representation of the

1 shows a power amplifier unit known to the applicant from the internal prior art,

2 shows an embodiment of the invention Leis ^¬ tung amplifier unit with two series-connected power amplifiers,

3 shows an embodiment of the invention Lei ^¬ tion amplifier unit with three series-connected power amplifiers.

Figure 1 shows a power amplifier unit as known to the applicant from the internal prior art.

The power amplifier unit LVE comprises a first, a second and a further power amplifier LV1, LV2, LVW. The three power amplifiers LVL, LV2, LVW are connected in series and, via a second signal line SL2 with a voltage regulator SPRL, which is also part of the Leis ^¬ tung amplifier unit connected LVE. The Spannungsreg ^¬ ler SPRl is in turn connected to a voltage source SPQ. Via the second signal line SL2, the voltage regulator SPR1 supplies the three power amplifiers LV1, LV2, LVW with a uniform operating voltage. This operating voltage can deviate from the output voltage of the voltage source SPQ.

The first power amplifier LV1 is connected via a first signal line SL1 to a first signal source SQ1. Of the Voltage regulator SPRl is connected to a second signal source SQ2. The further power amplifier LVW is connected to a transmission unit SE via a third signal line SL3.

The first power amplifier LV1 receives a phase-modulated input signal from the first signal source SQ1. This signal source SQ1 may, for example, be a frequency synthesizer in which a digital bit stream supplied by a baseband chip is already modulated onto a high-frequency carrier oscillation, whereby a phase-modulated input signal is produced (not illustrated).

The phase-modulated input signal is by means of the second signal line SL2 another originating from the second signal source SQ2 and supplied via the voltage regulator SPRL signal all three power amplifiers LVL, LV2, LVW zuge¬ leads, on the one hand an imprint of a Amplitudenmodu ^¬ lation to the phase-modulated input signal in all three power amplifiers LV1, LV2, LVW and, on the other hand, the signals in all three power amplifiers LV1,

LV2, LVW additionally strengthened or dampened. The resulting amplified or attenuated amplitude-modulated and ^phase- modulated signal is subsequently fed to the transmitting unit SE via the third signal line SL3.

The second signal source SQ2 is, for example, a digital / analogue converter which is controlled by the baseband chip. The transmitting unit SE is (provided is not ^¬) a further component in the radio part of a mobile telecommunication terminal, for example, a toggle switch or already an antenna itself.

The interaction of the individual components mentioned is known to the person skilled in the art, so that no further details are given here. Important for the invention, however, is the circumstance that in the exemplary embodiment of the state of the art all power amplifiers LV1, LV2, LVW have a further one Signal is supplied, which leads in all power amplifiers LVL, LV2, LVW to an impact of an amplitude modulation on the phase-modulated input signal and for gain / attenuation. Technically realized this is by the second signal line SL2 with all three Leistungsverstär¬ ker LVl, LV2, LVW are controlled in parallel. The amplification or damping itself is determined by the supply voltage regulated by the voltage regulator SPR1.

However, such a power amplifier unit LVE has the disadvantage that, due to component-specific properties, eg of limiting effects or delay effects, the phase of a phase-modulated input signal is distorted, if the signal supplied to the power amplifiers LV1, LV2, LVW via the second signal line SL2 Imprinting an amplitude modulation on the phase-modulated input signal is to be effected. This so-called Amplitu ^¬ denmodulations / Phase Modulation conversion (Phasenverzer- tion) already described above in detail described in the power amplifier unit LVE, the phase error is accumulated in the individual power amplifiers LVL, LV2, LVW to a total, however, the correct decoding affected by over the air interface transmitted data on the receiver side or the reconversion of the correct bit stream, so that this power amplifier unit LVE is not used for modulation method, which exact assignment of bits to symbols that are transmitted via the Luftschnitt¬ point and only by a small phase shift from each other distinguish, eg 8 phase shift keying, as it must be used in EDGE.

2 shows a power amplifier according to the invention ^¬ unit LVE, in which the phase distortions are described nimiert mi¬. In the power amplifier unit LVE are a first and another power amplifier LVL, LVW in

Series switched. The first power amplifier LV1 is connected via a first signal line SLl from a first signal source SQl fed a phase modulated input signal. The first power amplifier LV1 is supplied with an operating voltage by a second voltage regulator SPR2. This operating voltage can be adjustable in stages or infinitely variable. The adjustment is provided by a signal control source SSQ, which is connected to the second voltage regulator SPR2. The signal control source SSQ is in turn controlled by a base ^band chip (not shown). The second Spannungsreg ^¬ ler SPR2, which may be outside of the power amplifier unit LVE (not shown) is supplied from a voltage source Span¬ SPQ, such as a battery. The second voltage regulator SPR2 sets the voltage of the Spannungs¬ source SPQ in a suitable manner to, and to the first Leis ^¬ tung amplifier LVL a particular variable voltage to the gain / attenuation of the phasenmodu¬ profiled input signal is controlled in the first power amplifier LVL about the change.

The further power amplifier LVW is supplied with a suitable operating voltage by a first voltage regulator SPR1 via a second signal line SL2. The voltage regulator SPR1 also supplies the further power amplifier LVW with a controllable voltage, the variation of which controls the amplification / attenuation of the signal in the further power amplifier LVW. The first voltage regulator Sprl is connected to the voltage source SPQ, and sets the operation ^¬ voltage of the voltage source SPQ in an appropriate operation ^¬ voltage for the further power amplifier LVW order. The first voltage regulator SPR1 is also connected to a second signal source SQ2, which outputs a further signal which is fed via the first voltage regulator SPR1 and the second signal line SL2 to the further power amplifier LVW. This further signal is not supplied to the second voltage regulator SPR2.

The further power amplifier LVW is connected to a transmission unit SE via a third signal line SL3. In contrast to the embodiment of Figure 1, the phase-modulated input signal in the first power amplifier LVL is only amplified / attenuated during only the further power amplifier LVW another signal over the second signal line SL2 of the second signal source SQ2 zu¬ is guided, which tion for impressing a Amplitudenmodula ^¬ leads to the phase-modulated input signal in the further power amplifier LVW. In addition, the resulting amplitude and phase modulated signal will become more

Power amplifier amplified / attenuated. Subsequently, the amplified / attenuated amplitude and phase modulated signal via the third signal line SL3 to the transmitting unit SE from ^¬ given. The underside described is realized technically different to the embodiment according to the prior art in Figure 1, characterized that there is no connection between the zwei¬ th signal line SL2 and the first power amplifier LVL gives, via which a further signal from the second signal ^¬ source SQ2 can be supplied, which leads to an imprint of an amplitude modulation on the phase-modulated input ^¬ signal in the first power amplifier LVL.

3 shows another example of the invention ^shown SEN power amplifier unit LVE, comprising a first, a second and a further amplifier connected in series tung Leis¬ LVL, LV2, LVW, also the inscribed be¬ phase distortions are minimized in the.

2, both a second power amplifier LV2 and the further power amplifier LVW, but not the first power amplifier LV1, are connected in parallel to the first voltage regulator SPR1 via the second signal line SL2, so that the further signal of the second signal source SQ2 both in the second power amplifier LV2 and in the further power amplifier LVW to an impression of an amplitude modulation on the phase modulator supplied from the first power amplifier LVL. lated input signal leads. In addition, the signals are so ^¬ probably amplified / attenuated in the second power amplifier LV2 and in the other power amplifier LVW. As an extension of the exemplary embodiment from FIG. 2, a switch S, for example a transistor, is switched on or off by a signal of the signal control source SSQ. If the switch S is switched off, a current flow from the voltage source SPQ via the second voltage regulator SPR2, a resistor W to the first power amplifier LVL. The resistor W limits the current flow. The change in the current strength controls the amplification / attenuation in the first power receiver LV1. However, since the resistor allows only small current intensities, the power amplifier unit LVE is in a mode with low amplification or attenuation of the phase-modulated input signal. When the switch S is turned on by the control signal source SSQ so finds directly a current flow from the voltage source to the first SPQ Leis ^¬ tung LVL amplifier without current limitation by the resistor W instead. Again, the gain in the first power receiver LVl is controlled by changing the current. Now the power amplification unit LVE is in a high gain mode of the phase modulated input signal.

Of course, the first power amplifier can also be operated in a continuous mode. However, it is also important here that no further signal is fed to the first power amplifier LV1, which leads to the impressing of an amplitude modulation on the phase-modulated input signal.

So the solution according to the invention shares the control of the Sen ^¬ deleistung to all three power amplifiers LVL, LV2, LVW, while the amplitude modulation is effected only in the second power amplifier LV2 or in the further power amplifier LVW. If the mandatory specifications of the EDGE standard are to be complied with, the first power amplifier becomes LVW operated, for example in a discrete amplification / attenuation mode, so maximum Verstärkun ^¬ gene of the phase-modulated input signal by 10 dB or ma¬ ximum attenuations of - 10 dB can be achieved. If the second power amplifier LV2 and the further power amplifier LVW are operated in a continuous operating mode, maximum amplifications of the supplied signal of 10 dB or maximum attenuation of -7.5 dB respectively can be achieved. This results in a maximum gain of 10 dB (first power amplifier LV1), +10 dB (second power amplifier LV2) + 10 dB (further power amplifier LVW) = 30 dBm or maximum attenuation of -10 dB (first power amplifier LV1), -7.5 dB (second power amplifier LV2) -7.5 dB (further power amplifier LVW) = -25 dBm, resulting in a total dynamics of the power amplification unit LVE of 55 dB.

By dispensing with the imprinting of an amplitude modulation in the first power amplifier LV1, the transmission oscillator from which the high-frequency carrier oscillation is generated by means of frequency multipliers or mixers is additionally insulated. As a result, backward influences by the first power amplifier LV1, for example pulling the transmission oscillator frequency, the so-called pull through the fixed drive of this first power amplifier LV1, are minimized. Moreover, the regulated voltage supply of the first power amplifier ^¬ LVL beitspunktes leads to ensure a stabilized Ar¬ and to suppress noise and Störein¬ influences on the power supply.

In this embodiment, the output voltage of the second voltage regulator SPR2 in the low gain / attenuation mode of the phase modulated input signal is 2.8V. The resistor W is intended to limit the current to less than 10 mA. If, for example, a resistance W of 330 ohms is selected, then the current supplied to the first power amplifier LV1 is 8 mA and the operating voltage is on The first power amplifier LV1 is 0.18 V. The output power can thus be regulated at the antenna reference point between +2 dBm and +15 dBm. The minimum operating voltage at the second power amplifier LV2 and at the further power amplifier LVW is 80 mV with an output power of +2 dBm at the antenna reference point.

In the high gain operation mode of the phase modulated input signal in which output powers of +15 dBm to +26 dBm are realized at the antenna reference point, the current in the first power amplifier LV1 is more than 50 mA. The minimum operating voltage applied to the second power amplifier LV2 and to the further power amplifier is 80 mV at an output power of +15 dBm at the antenna reference point.

The invention is not limited to the specific Ausführungsbei ^¬ play limited but also does not rule explicitly of ^¬ fenbarte modifications with one, as long as use is made of the core of the invention. This applies in particular since the person skilled in various circuits and components for Ausfüh¬ tion of the invention are known. In particular, further power amplifiers could be connected in series, of which, for example, two or three serve merely to amplify the phase-modulated input signal. Thus, no further signal is supplied to these power amplifiers, which leads to the phase-modulated signal in these power amplifiers for imparting an amplitude modulation.

However, it is also possible to connect further power amplifiers in parallel via the second signal line SL2 to the first voltage regulator SPR1, wherein in these power amplifiers, in addition to the signal amplification, the supply of a further signal leads to an impressing of an amplitude modulation on the phase-modulated input signal. However, a prerequisite for there ^¬ are component-specific properties of the Leis ^¬ processing amplifier through which in certain modes of operation a greater distortion of the phase in the imprint of Ampli¬ tudenmodulation not done.

Claims

claims

1) power amplifier unit (LVE), comprising a first and at least one in each case supplied with an operating voltage, series-connected power amplifier (LVL, LV2, ..., LVW), wherein the first power amplifier (LVL) from a first signal source ( SQl) via a first signal line (SLl) a phase-modulated input signal to ^¬ is feasible, which can be fed to be amplified by the first power amplifier (LVL) / damped and the further Leistungsverstär¬ ker (LVW), whereby exclusively the at least one further power amplifier (LV) via a second signal line (SL2) of a second signal source (SQ2), a further signal is fed, which leads to impressing an amplitude modulation on the phase modulated input signal in the at least one further power amplifier (LVW), wherein the amplitude and phase modulated signal by the at least amplify / attenuate another power amplifier (LVW) is bar and a third signal line (SL3), the amplified / attenuated amplitude and phase modulated ^¬ signal to a transmitting unit (SE) can be output.

2) power amplifier unit (LVE) according to claim 1, characterized in that between a voltage source (SPQ) and the further power amplifier (LVW) a first voltage regulator (SPRl) is interposed, the further signal of the second signal source (SQ2) can be fed.

3) power amplifier unit (LVE) according to claim 1 or 2, characterized in that between the voltage source (SPQ) and the first power amplifier (LVL), a second voltage regulator (SPR2) is interposed, which from a signal control source (SSQ) via a switch (S) is switchable. 4) power amplifier unit (LVE) according to claim 3, characterized in that the second voltage regulator (SPR2) is switchable into two discrete states, wherein in a first state amplification of the phase-modulated input signal through the first power amplifier (LVl) and in a second state, an attenuation the phase-modulated input signal by the first power amplifier (LVL) is effected.

5) power amplifier unit (LVE) according to claim 4, characterized in that by the second voltage regulator (SPR2) with switched off switch (S), the operating voltage supply of the first power amplifier (LVL) is effected, via one between the second voltage regulator (SPR2) and the first Power amplifier (LVL) in series resistor (W) is the current flow to the first power amplifier (LVL) is limited.

6) power amplifier unit (LVE) according to claim 4, d a d e r c h e c e n e c e s in that when the switch (S) is switched on

Operating voltage supply of the first power amplifier

(LVl) is effected without Stromflußbegrenzung to the first power amplifier (LVl) through the resistor (W).

7) power amplifier unit (LVE) according to one of vorste ^¬ henden claims, characterized in that between the first power amplifier (LVL) and the further power amplifier (LVW), a second with an operating voltage supplied power amplifier (LV2) is interposed in series, in addition to the second Power amplifier (LV2) via the second signal line (SL2) from the second signal source (SQ2) derived further signal can be fed. 8) Power amplifier unit (LVE) according to one of the preceding claims, characterized in that the further power amplifier (LVW) and / or the second power amplifier (LV2) are operable with a continuous gain / attenuation degree.

9) A mobile telecommunication terminal comprising a tentansprüche Leis ^¬ tung amplifier unit (LVE) according to one of the preceding patent.

10) Mobile telecommunication terminal according to claim 9, which is designed as an EDGE radio module.

11) Method for amplifying / attenuating and modulating a phase-modulated input signal in a power amplifier unit (LVE), comprising a first and at least one further power amplifier (LV1, LV2,..., LVW), each supplied with an operating voltage, connected in series. wherein the first power amplifier (LV1) is supplied with a phase-modulated input signal from a first signal source (SQ1) via a first signal line (SL1), which is amplified / attenuated in the first power amplifier (LV1) and supplied to the further power amplifier (LVW), and wherein at least one of the further Leis¬ tung amplifier (LV) is guided a further signal to ^¬ via a second signal line (SL2) from a second signal source (SQ2) exclusively, which tion for impressing a Amplitudenmodula ^¬ on the phase-modulated input signal in the Any artwork least another power amplifier (LVW) leads, the ampli tuden- and phase-modulated signal is attenuated by the Minim ^¬ least one further power amplifier (LV) ver¬ strengthens / and then the ver ^¬ strengthened / attenuated amplitude and phase modulated signal over a third signal line (SL3) to a transmitter unit (SE) is output ,