SE519812C2 - Methods and apparatus for linear power amplification - Google Patents

Abstract

An arrangement for linearizing an amplifier by a combination of two methods is described. In the first a predistorter 213 supplies harmonics to the main amplifier 214 in such a way as to counteract the distortion. In the second a feedforward arrangement subtracts in 219 a signal derived from the input of the main amplifier from a signal derived from the output to produce a distortion signal which is then subtracted from the main amplifier output to remove remaining distortion. The arrangement may be used in multi-carrier amplification.

Description

25 30 b) Uï - n. . f n n 519 812 - | . , <. Fig. 1, generates a control signal, connects the generated signal to an input signal, detects the control signal in an output terminal and controls the phase and gain of an error amplifier, the intermodulation distortion can be suppressed accordingly. The linear power amplifier thus uses the control signal to continuously suppress the phase and gain of the error amplifier regardless of the variable factors of the circumstances in order to remove the intermodulation distortion.

If the linear power amplifier, which uses the control signal shown in Fig. 1, does not take into account the varying factors of the circumstances, it is difficult to set the conditions for automatic adjustment of the amplifier's linear gain. Due to the fact that the linear power amplifier also includes a control generator and a control detection, etc., the design and control operation of the linear power amplifier can also be very sophisticated.

A pre-distortion system for generating pre-distortion as above in the input signal and improving the intermodulation suppression properties of the main amplifier is a negative feedback system for feedback of the distortion and suppression of the distortion included in the amplifier output and a feed-off system is provided for distortion, which produces back phase, and suppression of the extracted distortion is an example of a method of linear power amplification for eliminating intermodulation distortion without the use of the pilot system.

SUMMARY OF THE INVENTION An object of the present invention is therefore to provide a linear power amplifier device and a method for dividing and removing intermodulation distortion with the pre-distortion system and the feed system.

Another object of the present invention is to provide a linear power amplifier device and a method for suppressing intermodulation distortion, 1992-432-- Zfíšï? z 55,323: \ PT ~ .T: \ _ E2 * i '\ A? JS \, _ PI-íêï' 3 O92l Åë-CBC »u» u u 10 15 20 25 30 35 519 812. ,, ~,. 3 generated in the main amplifier, with the pre-distortion system and suppression of the intermodulation distortion, which is included in a finally output amplified signal.

A further object of the present invention is to provide a linear power amplifying device and method which installs a pre-scrambler in a front terminal before intermodulation distortion is expected to be generated in the main amplifier, generates a pre-distortion signal and feeds the generated pre-distortion amplifier signal to the main amplifier. to thereby first suppress the intermodulation distortion generated in the main amplifier.

A further object of the invention is to provide a linear power amplifier device and a method for extracting the remainder of the intermodulation distortion, which is included in the output of the main amplifier, where the intermodulation distortion is first suppressed and the extracted intermodulation distortion is connected to the final signal. by the intermodulation distortion is suppressed a second time in the finally output amplification signal.

To achieve the above objects of the present invention, the invention can be realized with a linear power amplifier device having a main power amplifier for eliminating an intermodulation signal, comprising a predistortion device for first suppressing the intermodulation signal generated after amplification. of an RF signal in the main power amplifier, by generating overcones corresponding to the input RF signal, and a pre-distortion signal coupling the RF signal to the harmonics and a feeder for a second suppression of the intermodulation signal by canceling the input RF signal and the output signal from the main power amplifier, extraction of an intermodulation signal distortion, error amplification of the extracted intermodulation signal distortion and cup - C320: \ F'T = -. Ti \ _EI ~ í '\ I -: = * ISX PÚÉ- "Vlíläläl, 23043 ø - ; «1 n 10 15 20 25 30 35 519 812 ---- -« - - «m 4 ling of the amplified intermodulation signal t ill main power amplifier output.

The invention can be further realized by means of a method for eliminating an intermodulation signal in a linear power amplifier device, which includes a main power amplifier, comprising (a) firstly suppressing the intermodulation signal, which is generated after amplifying an RF signal in the main power amplifier, by generating harmonics corresponding to the input RF signal and a pre-distortion signal coupling the RF signal to the harmonics and (b) secondly suppressing the intermodulation signal by canceling the input RF signal and the output signal from the main power amplifier, extracting of an intermodulation signal distortion, error amplification of the extracted intermodulation signal distortion and coupling of the amplified intermodulation signal to the output power of the main power amplifier.

Brief description of the drawings The invention will be described in more detail below and the advantages thereof are indicated with reference to the accompanying drawings, in which like reference symbols indicate the same or similar components.

Fig. 1 is a block diagram showing the construction of a prior art linear power amplifier.

Fig. 2 is a block diagram illustrating the construction of a linear power amplifier according to a first embodiment of the present invention.

Fig. 3 shows the construction of a pre-distortion device in Fig. 2.

Fig. 4 shows the construction of an automatic level controller in Fig. 3.

Fig. 5 illustrates the construction of a signal detector in Fig. 4.

Figs. 6A to 6G are views showing the characteristics of the signal spectrum for explaining the operation of the. : ik-CBC 10 15 20 25 30 35 519 812. ». ; The linear power amplifier according to the first embodiment of the present invention shown in Fig. 2.

Fig. 7 is a view showing the construction of a signal detector in Fig. 2.

Fig. 8 is a view showing the construction of a regulator in Fig. 2.

Fig. 9 is a flow chart illustrating the operation of the attenuation and phase control functions of the controller according to an embodiment of the present invention.

Fig. 10 is a flow chart showing the operation of controlling a variable attenuator and a variable phase shifter in Fig. 2 by means of the controller according to an embodiment of the present invention.

Figs. 11A to 11C are flow charts showing the characteristics of the setting of a frequency for controlling the attenuation and phase of the signal shown in Fig. 10.

Fig. 12 is a block diagram illustrating the construction of a linear power amplifier according to a second embodiment of the present invention, and Fig. 13 is a block diagram showing the construction of a linear power amplifier according to a third embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The following description sets forth a large number of specific details, such as components and frequencies of the specific circuit, to provide a better understanding of the invention. However, those skilled in the art will appreciate that the invention may be practiced without these specific details. A detailed description of known functions and constructions, which complicate the understanding of the invention, will be avoided.

Fig. 2 is a block diagram showing the construction of a linear power amplifier according to a first embodiment of the present invention. In Fig. 2, a first variable attenuator 211 controls the attenuation of the gain of the input RF signal by means of an attenuation control signal 1e§a ~ oz ~ 2av: sca = \ pAT1ßx \ nns \ P2 @ 7o921, noc 1 »Q. fo I. ~. | | .u 10 15 20 25 30 - ~. . vu. . »-. u 519 812 «». ~ u n 6 ATT1. A first variable phase shifter 212 inputs the output signal from the first variable attenuator 211 and controls the phase of the input RF signal by means of a phase control signal PIC1.

A pre-distortion device 213 inputs the RF signal and expects in advance generation of a harmonic as intermodulation distortion in the main power amplifier 214 of the terminal terminal and generates the distortion signal. The main power amplifier 214 amplifies the RF signal output in the pre-distortion device 213 and outputs the power amplified signal. A second delay unit 215 inputs the RF signal output in the main power amplifier 214, delays and outputs the input RF signal during the time during which the intermodulation signal is exerted. The above construction is considered as the main path in the linear power amplifier according to a preferred embodiment of the present invention.

A power divider 216 divides the RF signal applied to the main path and outputs the split RF signal. It is also possible to use a directional switch as a power divider 216. A first delay 217 compensates for the delay time of the RF signal in the main path pre-distortion and amplification process. A power divider 218 is located in the output terminal of the main power amplifier 214 and divides the output signal of the main power amplifier 214, which is then to be output. Like the power divider 216, the directional switch can be used as a power divider 218. A signal canceler 219 inputs the RF signal output in the first delay 217 and the amplified RF signal output in the power amplifier 214. The signal canceler 219 cancels the RF signal output from the output of the main power amplifier 217 from the first delay 217, thereby detecting the intermodulation signal. In the embodiment of the present invention, the signal canceler 219 is designed as a subtractor.

A second variable attenuator 220 inputs the intermodulation signal output from the signal canceler 219 and controls the gain of the intermodulation signal, which - z 593: . . u 10 15 20 25 30 35 »| In the attenuator control signal ATT2, which is output in a controller 237. A second variable phase shifter 221 inputs the intermodulation signal output in the second variable attenuator 220 and controls the phase of the intermodulation signal which is input by a phase control signal PIC2, which is output in the controller 237. An error amplifier 222 amplifies the intermodulation signal, which is output to the second variable phase shifter 221, and outputs the amplified intermodulation signal. A signal coupler 223 connects the output signal from the error amplifier 222 to the terminal of the second delay 215. The directional coupler can be used as a signal coupler 223.

The construction according to the above corresponds to the sub-track for suppressing the intermodulation signal of the main track in the preferred embodiment of the present invention.

A power divider 231 divides the input RF signal applied to the terminal and outputs a first signal SF1. A power divider 232 is located in the terminal of the main power amplifier 214 and divides the amplified RF signal and outputs a second signal SF2. A power divider 233 is located in the output of the signal canceler 219 and divides the intermodulation signal, where the RF signal is canceled, and outputs a third signal SF3. A power divider 234 is provided in the output terminal and divides the finally output RF signal and outputs a fourth signal SF4. The power parts 231 to 234 can be replaced with a directional coupler. A signal selector 235 inputs the above signals SF1 to SF4, which are output in the power parts 231 to 234, and selectively outputs the signal SF, which is correspondingly controlled by means of switching control data SWC, which is output in the controller 237.

A signal detector 236 detects a received signal strength indicator (hereinafter referred to as RSSI) of signal sF, PCD (PLL control data), which is output in the controller, and output in the signal selector 235 by the control data then feeds the RSSI signal, which is converted till lik- ~~ 2íz ^ zï7 z 555: \ PT '= TX_EZ ~ i “\ A? ISQPÉÉEVNJQIZl. ÜÜÜ = - = = -n 10 15 20 25 30 35 519 812 8 ström. The controller 237 generates the switching control signal SWC for selecting the signal SF, which refers to the signal selector 235 and thus the control data PCD for determining the frequency for detecting the SF RSSI of the signal selected in the signal detector 236.

In addition, the controller 237 analyzes the value of the RSSI signal output in the signal detector 236 and generates attenuation control signals ATT1 to ATT3 and phase control signals PIC1 to PIC3, and the variable which signals controls the variable attenuator phase shifter in order to adjust the pre-phase of the signal SF to In case the input signal output in the power divider 231 is selected, the gain and the analyzed result are controlled by the controller 237. usually the controller 237 detects the signal detector 236, detects the RSSI of the input RF signal and judges the magnitude of the RSSI component. accordingly can be recognized. In the case of the output of the main power amplifier 214 output in the power divider 232, the controller 237 selects the signal detector 236, detects the RSSI of the amplified RF signal of the amplified RF signal, and judges the magnitude of the RSSI to thereby generate an attenuation control signal. the signal for adjusting the attenuation and the phase of the intermodulation signal output in the pre-distortion device 213. Second, when the output of the signal canceler 219 is selected, the controller 237 controls the signal detector 236, detects the RSSI of the RF signal recorded in the canceled intermodulation signal, and judges the magnitude of the RSSI to thereby generate the attenuation control signal ATT1 and the phase control signal PIC1 and are arranged for adjusting the attenuation and phase of the RF signal input in the connection of the linear power amplifier. Third, when the finally output gain signal is selected, the controller 237 controls the signal detector 236, detects the RSSI of the intermodulation signals in the finally output signal, and judges the magnitude of the RSSI to "" 13 z 553: \ PT «. A '\ EMXA? ÄS _ \ _ Pišêïïüïšläl .Zßßšï - v: »vn 10 15 20 25 30 35 519 812 | @. . f. 9 thereby generates the attenuation control signal ATT2 and the phase control signal PIC2, each the signal for adjusting the attenuation and phase of the intermodulation signal output in the signal canceler 219.

According to a preferred embodiment of the present invention according to the above, the linear power amplifier eliminates the intermodulation signal, which may occur in the amplifier stage, by using the pre-distortion system and the feed system. In the above embodiment of the present invention, the pre-distortion device 213 first has the function of removing the intermodulation signal output to the main power amplifier 214. To perform this function, the preamplifier 213 previously expected generation of harmonics which can be generated after amplification in the main amplifier. pure 214 to then adjust their phase so that they have a back phase with harmonics, which can be generated in the main power amplifier so as to be output when the harmonics are applied to the power transistor of the main power amplifier 214.

When using the pre-distortion system, it is impossible to completely eliminate the intermodulation signal caused in the linear power amplifier.

As a result, the linear power amplifier according to the embodiment of the present invention first suppresses the intermodulation signal in the pre-distortion device 213 and finally suppresses the intermodulation signal with adaptation of the feed system. The linear power amplifier using the feed system cancels the pure RF signal distortion at the output of the main power amplifier 214, extracts the intermodulation signal and connects the extracted intermodulation signal to the signal switch 223 to thereby cancel the intermodulation distortion. When using the feed system, the amplified signal of the intermodulation signal distortion recorded in the final output terminal of the linear power amplifier can be suppressed, so that the pure, amplified RF signal can be output. 'z' \ PT ^ .T'X> E2 * É “\ ÅÉISI \, _ PIÉ97092l JFBÛ a u ~. vu. . . . In the above-explained embodiment of the present invention, the intermodulation signal generated at the gain of the main power amplifier 214 is suppressed only during use of the predistortion system, and the intermodulation signal relating to the output of the main power amplifier 214 is suppressed other times during use. of the feed system. To clarify the explanation, it can be stated that after the suppression of the intermodulation signal by means of the pre-distortion system, the intention here is that the finding that the operation for suppression of the intermodulation signal by means of the feed system can be followed.

Figs. 6A to 6G show the characteristic of the signal spectrum for explaining the operation of the linear power amplifier according to a first embodiment of the present invention, which is shown in Figs. 2, Figs. 6A to 6G illustrating the assumption of two tones. That is, Fig. 6A shows the input RF signal, Fig. 6B shows the harmonic signal of the RF signal generated in a harmonic generator 314, Fig. 6C shows a signal which can adjust the magnitude of the harmonics by means of a variable attenuator 315 in the predistortion device 213 and has a adjusted phase, which can be input with back phase in the main power amplifier 214 by means of a variable phase shift 316, and Fig. 6D shows the amplified RF signal, which contains the intermodulation signal by amplifying the pre-distortion signal input in the main power amplifier 214, as shown in Fig. 6C. . Fig. 6E shows the intermodulation signal extracted by canceling the signal distortion in the amplification signal RF in the signal canceller 219, as shown in Fig. 6A, Fig. 6F shows the signal, which adjusts the magnitude of the intermodulation signal shown in Fig. 6E and adjusts the output signal from the the main power amplifier 215 and Fig. 6G show the finally output signal, which suppresses the intermodulation signal by coupling the intermodulation signal extracted according to Fig. 6D and the one according to l99 fi ~ Û2 "Z: JS 7: 5ü3: \ PÅTXB fi \ ANSÅP297Ü92l - uÜ | | «| N. 10 15 20 25 30 35» ~ ».. V |» A... Ll Fig. 6D amplified the RF signal to each other with late back phase.

Fig. 3 shows the construction of the pre-distortion device 213 in Fig. 2. According to Fig. 3, the power divider 312 divides the RF signal present in the connection and outputs the divided RF signal. An automatic level controller (hereinafter referred to as ALC) constantly maintains the level of the input RF signal for the generation of constant harmonics regardless of the variation of the level of the input RF signal. the harmonic generator 314 inputs the RF signal, which adjusts the level thereof in the automatic level controller 313 and generates third, fifth, seventh and higher harmonics of the RF signal. A variable attenuator 315 inputs the harmonic signal output in the harmonic generator 314 and controls the amplification of the harmonic distortion by the attenuation control signal ATT3 output in the controller 237. The variable phase shifter 316 inputs the harmonic signal output in the harmonic output tower 237. A second delay 311 delays the RF signal input over the main path during the period of time during which the distortion signal occurs. A signal coupler 317 is located between the terminal of the second delay 311 and the terminal of the main power amplifier 214, whereby the pre-distortion signal is coupled to the delayed RF signal.

According to Fig. 3, the harmonic generator 314 is constructed with a signal coupler and a shot key diode. After the RF signal is applied to the shot key diode, the shot key diode generates the high harmonics according to the level of the input RF signal. Accordingly, the level of the RF signal supplied to the shot key diode must be set as the level which can perform the most desirable suppression of the intermodulation signal included in the output of the main power amplifier 214. To do this, the automatic level controller 313 is located in 1998M32 "Zf / 'fj-'í z \ PT ~ .TA' * ._ EM“ \ E:? JSXPZÉWÛÉÉZl Åê-QÛ «ø. .O u -« »|» 10 15 20 25 30 35 @ u e. V: v n ~ | »n u 519 812.; ~ -. - 12 front connection of the harmonic generator 314, so that the RF signal can always be input at a given level.

The automatic level controller 313 controls and outputs the RF signal at the set, given level independent of the variation of the level of the RF signal input to the linear power amplifier. Fig. 4 shows the construction of the automatic level controller 313 in Fig. 3, where a variable attenuator 412 is connected between the power divider 312 and the harmonic generator 314. Thus, when the power divider 414 is located in the socket of the harmonic generator 314, which finally divides and outputs the RF signal, which has the adjusted level and is applied to the harmonic generator 314. In this case, a power detector 415 converts the RF signal to DC voltage and thus outputs the converted signal to a level controller 416. The level controller 416 controls the variable attenuator 412 according to the DC voltage output. to the power detector 415, so that the RF signal, which always has the given level, can be fed to the harmonic generator 314.

The power detector 415 according to Fig. 4 is to detect multi-carrier wave. Namely, the power detector 415 is to supply the RF signal for the multi-carrier and converts the input RF signal to direct voltage. Fig. 5 shows the construction of the power detector 415 in Fig. 4, where an RF transformer 451 supplies the RF signal and generates two signals which have a phase difference of 180 ° relative to each other, which two signals are output from the RF transformer 451, is transmitted from the transmission lines 452 and 453 via the shot diodes 454 and 455 to the DC level, whereby the converted signal is synthetically filtered via a capacitor 456 and a resistor 457 and the filtered signal is output as a DC voltage.

Figs. 3 and 4 show the operation for controlling the level of the input RF signal, wherein the RF transformer 451 for generating the signals with the phase difference 180 ° in the power detector 415 generates two signals by separating the input RF signal by means of a unit with 1eäß ~ ø: ~ 2äv; 5øe: \ PATïßM \ ANs1P2 @ vo921, moc @ ~ - - -v 10 15 20 25 30. v ~ v v- uvvvv v v .v vv: v v v vv A v: vv. v v «v v v r a v v v vv v .. v vw v v 1 a v ~. .vv .av v v .. v .v vv v n vv v v uu v, lv m v »m v 13 half diameter. The shot key diodes 454 and 455 further convert the two signals input via the transmission lines 452 and 453 to DC level. Thus, the average power of the multicarrier can be sensed without error, so that the level of the RF signal applied to the harmonic generator 314 can be accurately converted to direct voltage.

At this time, the level controller 416 generates the control signal independent of the level of the DC voltage of the RF signal output from the power detector 415, and applies the variable attenuator 412 to the generated control signal. The level controller 314 can be realized by means of OP amplifiers. At this time, the control signal supplied to the level controller 416 is generated to enable the attenuation control to be performed more after the voltage has increased in accordance with the DC voltage of the detected RF signal and to enable attenuation control less after the voltage therein has decreased. The variable attenuator 412 variably attenuates the RF signal to its given level independent of the level of the input RF signal and supplies the attenuated signal to the harmonic generator 314.

When the variation of the level of the input RF signal is 10 dB, the operating area of the automatic level controller 313 must be designed so that it minimally controls its level above 10 dB. The output level of the RF signal from the automatic level controller 313 should be set to optimally suppress the intermodulation signal generated by the harmonic generator 314 in the main power amplifier 214 as the pre-distortion signal. Therefore, since the harmonic generator 314, which supplies the output signal from the automatic level controller 313, supplies the RF signal at a given level, harmonics may be stable. When the harmonics output in the harmonic generator 314 are supplied to the main power amplifier 214, which is coupled to the RF signal, the main power amplifier 214 can prevent the generation of the intermodulation signal in steps when amplifying the RF signal. l fl šäßwfllš ~ - Zíñ-'ï z r \ PT ~ .T> '\ EEQÅNS X PLFJZCYBIZ l. ZS-QBCI v v v v vv 10 15 20 25 30 35 x; »N 1 v 519 812 14 In the same way, the input of the harmonics generated according to the above to the main power amplifier 214, the size and the back phase of the harmonics, which can be generated during the amplification, must be adjusted. The variable attenuator 315 and the variable phase shifter 316 shown in Fig. 3 adjust the magnitude of the harmonics generated when the magnitude of the intermodulation signal which can be generated at the gain, and the phase of input harmonics having the adjusted magnitude with bakfas.

The controller 237 controls the signal selector 235 and selects the output signal from the main power amplifier 214, which is output in the power divider 232, and the signal detector 236 detects the RSSI of the intermodulation signal in the output of the main power amplifier 214, as shown in Fig. 6D. After comparing and analyzing the RSSI value in the intermodulation signal output in the signal detector 236 with the previous state RSSI value, the attenuation control signal ATT3 and the phase control signal PIC3 are generated to control the suppression of the intermodulation signal so that it is performed evenly by the main effect 21. .

The variable attenuator 315 then adjusts the magnitude of the pre-distortion signal generated in the harmonic generator 315 by the attenuation control signal ATT3 and the variable phase shifter 315 adjusts its phase so that the pre-distortion signal can be input with reverse phase to the main power amplifier. 6D, which signal is generated by the harmonic generator 314, its size and phase, and the signal switch 317 connects the intermodulation signal to the input of the main power amplifier 214. At this time, as shown in Fig. 6A, the second delay 311 for delaying the input RF signal delays the RF signal until the predistortion signal is connected to the main power amplifier 214 terminal. It will be appreciated that the pre-distortion signal is then coupled to the terminal of the main power amplifier 214. Preferably, the position in which the RF signal cup- "Zíx fi i-'š z 503:" gPf -. The intermodulation signal as shown in Fig. 6C is adjusted with the reverse phase as a connection to the power transistor of the main power amplifier 214.

As noted above, the pre-distortion device 213 expects in advance that the intermodulation signal is generated in the main power amplifier 214 to thereby generate the pre-distortion signal and controls the phase and attenuation of the harmonics to prevent the intermodulation signal from being generated at the maximum value. to the main power amplifier 214. In this case, the pre-distortion device 213 substantially eliminates the third harmonics, which are generated with the highest level among the harmonics that can be generated in the main power amplifier 214. The intermodulation signal elimination power of the pre-distortion system can greatly reduce the load through the use of the feed system.

Because the adjustment of the feed system is very fine and varied, the pre-distortion system is advantageous with respect to the improvement of the number of dB.

After the first suppression of the intermodulation signal, which is generated in the main power amplifier 214 by the pre-distortion system, as pointed out above, the intermodulation signal, which is impossible to suppress, is suppressed by the feed system. At the top of the feed system, the steps for reducing the intermodulation signal of the main power amplifier 214 are broadly divided into two steps. One is to extract the pure intermodulation signal distortion by canceling the input RF signal and the output of the main power amplifier 214. The other is to cancel the intermodulation signal distortion in the output of the main power amplifier 214 and correct the magnitude and phase of the her. the intermodulation signal in order to reduce the intermodulation signal which is included in the signal which is finally output in the main power amplifier in a perfect manner. ~ - 252117 z 593: \ PT \ .T "\ _ BÉ ~ í“ \ ¿'-1? JSXPIEÉWÛÉZl. EDC | - ~. .V 10 15 20 25 30 35. |.. »N |.. | 1» The first steps of the feed system will be explained in more detail below: The power splitter 216 on the subway divides the RF signal input according to Fig. 6A into the subway and the first delay unit 217 delays the RF signal divided in the power splitter 216 during pre-distortion and RF amplification. whereby the delayed signal is applied to the signal canceler 219. The RF signal distortion shown in Fig. 6A, which is output from the first delay 217, is mutually canceled with the signal distortion of the amplification signal shown in Fig. 6D, which signal is divided into the power divider 218 for extraction. and outputting the pure intermodulation signal distortion.

As previously pointed out, the signal canceler 219 as well as the core structure of the feed system should detect only the intermodulation signal distortion in the main power amplifier 214. The signal canceler 219 may be constructed as a subtractor or an adder. When designing the signal canceler 219 as a subtractor, two RF signals intended for input must be adjusted so that they obtain the same phase. When designing the signal canceler 219 as an adder, the two RF signals intended for input must be adjusted so that they have a back phase. In a preferred embodiment of the present invention, the signal canceler is not designed as a subtractor but as an adder. In this case, the subtractor has a signal coupler inside, feeds one of the two RF signals for input to the signal coupler but has the same phase with the other signal and converts the other signal so that it obtains a back phase with one signal and thus inputs the converted signal to the signal coupler. When the RF signal shown in Fig. 6A and the amplified RF signal shown in Fig. 6D are fed to the signal canceler 219, which is designed as a subtractor, the distortion of the two RF signals having the same phases is converted so that they receives baking phases in the interior. Then the RF signal is canceled while passing the signal coupler (here a Wilkinson combi- "Z-ffi-Ü 'z 551%: \ PT \ .T" * ._} ÉZZ \ í \ A -. * JS' \ ' 35392 l. EDC - - «ne: 10 15 20 25 30 35 -. | | Vu... V .- 17 ners are used), whereby the intermodulation signal distortion is kept clean.

At this time, the levels and phases of the two signal cancelers 219 applied to the RF signals may be exactly equal to each other. To achieve this, in the main power amplifier 214 the main path and the RF signal intended for input via the subway must be exactly in accordance with the group delay, and likewise the flatness characteristic of the delay must be positive. Preferably, a generation of this phase distortion of the RF signal intended for cancellation should be prevented as much as possible.

When, as described above, the level and phase of the RF signal supplied to the first delay 17 and the output of the main power amplifier 214 do not exactly match, the RF signal is not exactly canceled in the signal canceler 219. To remove the foregoing, the variable attenuator adjusts 211 according to Fig. 2, the level of the RF signal input by the attenuation control signal ATT1, which is fed to the controller 237, and the second variable phase shifter 212 adjusts the phase of the RF signal input by the phase control signal PIC1, which is fed to the controller 237. Thus, the first variable attenuator 211 and the second variable phase shifter 212 adjust to match the phase and level of the RF signal of the subway and those of the RF signal of the main path.

The signal canceller 219 thus cancels two input RF signals while maintaining the same level and phase.

As previously pointed out, for controlling the phases and levels of the two RF signals, the controller 237 supplies the switch control signal SWC for selecting a third signal SF3 to the signal selector 235 and supplies the control data PCD for detecting RSSI in the RF signal distortion in the third signal of the signal detector 236. SF3. As a consequence, the signal selector 235 selectively supplies the third signal SF3 as an output signal from the signal canceller 219, the output signal from the signal selector 219 being divided into the power divider 233 and the signal detector 236 generating RSSI, which converts RF signal 19 ° 38 PT ~ .T "\ _ BPí \ Å-NS \, _ P2É7 ~ '243921, EÉi-IDC 10 15 20 25 30 35 519 812 18 nal distortion in the third signal SF3 to DC voltage. The controller 237 then generates the attenuation control signal ATT1 and the phase control signal PIC1 for attenuating the RF signal distortion in the signal canceler 219.

The first variable attenuator 211 then attenuates the input RF signal by determining the attenuation ratio by means of the attenuation control signal ATT1 and the first phase variable phase shifter 212 adjusts the phase of the RF signal input by the phase control signal PIC1. Since the attenuation control signal ATT1 and the phase control signal PIC1 are generated after comparing and analyzing the RSSI in the RF signal to be fed to the signal canceler 219, and the RSSI of the previous RSSI together control the first variable attenuator 211 and the first variable phase shifter 212. the two RF signals, as shown in Figs. 6D and 6A, so that the above RF signals may finally have the same phases and levels.

The reason for the cancellation of the RF signal distortion in the signal canceler 219 as above is that the error amplifier 222, which is located in the rear connection, is not to be affected by a greater suppression of the RF signal but only an extraction of the intermodulation signal distortion . If the output of the signal canceler 219 changes and the RF signal is not effectively eliminated, the relatively high level RF signal is input to the error amplifier 222, thereby damaging the error amplifier 222.

The second step of the feed system will now be explained in more detail. The intermodulation signal output in the signal canceler 219 according to the above adjusts its phase and level over the second variable attenuator 220, the second variable phase shifter 221 and the error amplifier 222 and the intermodulation signal distortion included in the output signal from the main power amplifier is removed. . In this case, the intermodulation signal coupled 1eae ~ o: ~ 2av = scæf \ PAT1ßx \ AmsgPz @ vo921, noc I ~ - «.u 10 15 20 25 30 35 v - 1. now " - . - .- v 519 812 19 by means of the signal coupler 223, have the reverse phase of the amplified and output signal.

The controller 237 here generates the switch control signal SWC for selecting the fourth signal SF4 as the final output signal, which is divided into a power divider 234 and outputs the control data PCD for detecting the RSSI of the harmonics as the intermodulation signal of the fourth signal SF4.

The signal selector 235 thus outputs the fourth signal SF4, which is fed to the power divider 234 by means of the switch control signal SWC, and the signal detector 236 is connected to the controller 237 by detecting RSSI of the harmonics of the fourth signal SF4 by means of the control data PCD. The controller 237 then compares and analyzes the RSSI of the intermodulation signal, which is included in the finally output signal, with the RSSI of the previous intermodulation signal, so that the attenuation control signal ATT2 and the phase control signal PIC2 for suppressing it in the the end output signal including the intermodulation signal can be generated, depending on the analysis result.

Therefore, the second variable attenuator 220 for input of the signal canceler 219 outputs adjusts the level of the intermodulation signal input by the attenuation control signal ATT2 and the second variable phase shifter 221 for inputting the signal output from the second variable attenuator 220 adjusts the phase of the intermodulation which is input by means of the phase control signal PIC2.

At this time, the second variable phase shifter 221 controls the phase of the intermodulation signal to have the reverse phase of the signal coupler 223 by means of the phase control signal PIC2. The error amplifier 222, which is coupled between the second variable phase shifter 221 and the signal switch 223, thus amplifies and outputs the intermodulation signal, which has the level and phase adjusted according to the above.

As discussed above, according to an embodiment of the present invention, the linear power amplifier uses the feed system and the pre-distortion system to suppress the intermodulation signal belonging to "C253 zr \ PT: TA '\ I-ÉIVÅÅNS \ If * 2f;?' 7¿392l. HBL? 10 15 20 25 30 35 ~ ».« »U 519 812 | v |..-20 amplification signal. the intermodulation signal, which is included in the output signal of the main power amplifier 214, of the feed step and thereby connects the above detected signal to the finally output signal and reduces the intermodulation signal in a sequential manner. due to the difficulty in designing and designing the main power amplifier 214 and failing the 222, the intermodulation signal of a given magnitude is previously suppressed using the predistortion device 213 and the remainder of the intermodulation signals is eliminated by the feed system. Due to this, the design and construction of the linear power amplifier can be facilitated.

The suppression of the intermodulation signal by means of the feed system and the pre-distortion system, which is centered on the controller 237, will be described in more detail below.

Fig. 7 shows the construction of the signal detector 236 illustrated in Fig. 2.

According to Fig. 7, an attenuator 711 attenuates and outputs an SF signal output from the signal selector 235. A filter 712 is a broadband filter which filters the signal of the transmission band. A phase locked loop (hereinafter PLL) 713 and an oscillator 714 generate a corresponding local frequency LF1 by means of the control data PCD, which is output to the controller 237. This local frequency LF1 determines the frequency for detecting the RSSI of the selected SF signal. A mixer 715 mixes the signal fed to the filter 712 with the local frequency LF1 and thus generates an intermediate frequency IF. A filter 716 filters as an intermediate frequency filter a subtracted signal SF-LF1 of two frequencies at the output of the mixer 715 and thereby generates lšüë- "ïlš - ~ Zííiï * z 553: \ PT ~ _T ° \ _ Eb fi l-ïålßï, P2 E ? 7 53921, ïë-DC 10 15 20 25 30 b) UI »1. | .- nu nu '. N v.« »- I v.

L - v »v». - -. -. r. | _. -. .vl i .U. - -.

«. .U. .. | u u .. .v -. p u nu ~ H n n. 21 the filtered signal as an intermediate frequency LF1. An oscillator 719 generates the fixed local frequency LF2.

The mixer 718 mixes the intermediate frequency LF1, which is fed to the intermediate frequency amplifier 717, and an intermediate frequency IF2 and then generates the intermediate frequency IF2.

A filter 720 filters a subtracted signal IF1-LF2 of two frequencies at the output of the mixer 718 and outputs the filtered signal as the local frequency LF2. A log amplifier 712 converts the intermediate frequency IF2 for supply to the filter 720 to the DC voltage and generates the converted voltage as an RSSI signal.

According to the operation shown in Fig. 7, the signal selector 235 selectively outputs the corresponding RF signal of the first signal SFI to the fourth signal SF4 by means of the switching control signal SWC of the controller 237. The filter 712 of the signal detector 236 thus filters the RF signal and applies the mixer 715 to the filtered signal RF.

The PLL 713 and the oscillator 714 then generate the local frequency LF1 for selecting the RF signal or the harmonics of the signal in accordance with the selection of the control data PCD1 of the controller 237.

Accordingly, the mixer 715 outputs mixed SF signals and the local frequency and the filter 716 filters the frequency corresponding to the subtraction between the two signals and outputs the filtered frequency as intermediate frequency IF1. The design described above determines the frequency for detecting RSSI in the selected SF signal and performs frequency conversion in the first step simultaneously.

The mixer 118 then mixes the local frequency LF2 and the intermediate frequency IF1, which is fed to the oscillator 718 and the filter 720 filters the frequency corresponding to the subtraction between the intermediate frequency IF1 and the mixed frequency local frequency LF2, whereby the filtered frequency is output as intermediate frequency IF2. The frequency conversion in the second stage is performed via the above construction. The logic amplifier 721 inputs the intermediate frequency IF2 and converts the input intermediate frequency 1e @ e ~ ø; ~ 2% ¶: sd;: \ PATgßx \ ANs1P29vo921, moc ». «| -4 10 15 20 25 30 35 I - x. pp. 519 812. . - v s w 22 IF2 to DC voltage for output. Here, the output signal becomes RSSI.

Fig. 8 shows the construction of the regulator 237 in Fig. 2 according to the present invention. In Fig. 8, an analog-to-digital converter 814 (hereinafter referred to as the ADC) converts the RSSI output in the signal selector 236 into digital data for output. A read only memory 812 (hereinafter referred to as ROM) stores the attenuation and phase control program in accordance with an embodiment of the present invention. A central unit 811 (hereinafter referred to as CPU) generates control data PCD for selecting the frequency in and for selecting the desired RSSI in the selected SF signal and the switching control signal SWC for selecting RF signal, depending on the program in ROM 812, and generates attenuation after equal- A direct- temporary control control signals ATT and phase control signals PIC movement and analysis of RSSI input in ADC 814. memory 813 (hereinafter referred to as RAM) stores all kinds of data, which are generated in the execution of the program following DAC) converts attenuation control data and phase control data, as met. A digital-to-analog converter 815 (i) is fed to the controller 811, to analog data and outputs the converted data as attenuation control signals ATT and phase control signals PIC. A transmitter 816 transmits the state information of the linear power amplifier under control by CPU 816.

Fig. 9 is a flow chart showing the operation of adjusting the level and phase with control of the above attenuators and variable phase shifters by the controller 237 according to an embodiment of the present invention. As shown in Fig. 9, "X" denotes an attenuation value and "Y" a phase variation value. According to Fig. 9, after changing the value of the variable attenuator, it changes from Pa to Pb at the time when RSSI is input, if the size of the detected signal decreases the phase variation value from Pb to Pc. In the event that the value of the variable attenuator changes from Pc to Pd at the time the RSSI is input, it changes if the detected signal increases again fas- lüäß fl- fllš - 212317 1 503: \ PF ~ .T ° \ _I-ÉM ” \ ANSÅPZÉF 743921, Eë-IBC 10 15 20 25 30; v v q e. 519 812 «» ~ @ u 23 the variation value in the direction of Pc. Pc is used herein to denote the point at which the magnitude of the attenuation value is temporary. Thus, after the phase variation value has changed from Pc to Pe and the size of detected RSSI has decreased, the variable phase shifter shifts the phase variation value in the direction of Pf.

When the attenuation and phase operations are repeatedly checked as above, the value of the variable attenuator and the variable phase shifter can be found, at which the magnitude of the detected SF signal is minimized. Fig. 10 is a flow chart showing the operations of the variable attenuator and the variable phase shifter in the controller 237 according to an embodiment of the present invention. As shown in Fig. 10, after the phase of the detected signal is first checked, the attenuation of the signal is performed. However, it is possible to control the phase of the signal after the attenuation of the signal.

According to Fig. 10, the steps for eliminating the intermodulation distortion are broadly divided into four. With respect to this in particular, the SF1 RSSI of the first signal is detected, a channel in which the RF signal is detected in the set transmission band, whereby the service channels are determined.

Second, the SF2 RSSI of the second signal is detected, and the main power amplifier 214 suppresses the intermodulation signal to amplify the received RF signal, thereby generating the pre-distortion signal. Third, the RS3I of the third signal SF3 is detected, and thus the intermodulation signal for canceling the RF signal distortion in the signal canceler 219 is detected. on the main track, can be controlled for suppression.

Figs. 11A to 11C are flow charts showing the characteristics of the frequency setting for controlling the attenuation and the phase of a signal in Fig. 10, Fig. 11A being represented as the second signal SF2 as output signal 1998-4133. z 'yPf-.TIXßbfviaïlåiPlâíïïíššlå l .ZI- * Üiï 10 15 20 25 30 b) Ul | n | «u» 519 812 | v. xm 24 from the main power amplifier 214, the output signal being divided into the signal coupler 232, Fig. 11B is shown as the third the signal SF3 when the output signal is divided in the signal coupler 232 and Fig. 11C is shown as the fourth signal SF4 as the finally output signal in the signal coupler 224.

When first driven, according to Figs. 10 and 11, the controller 237 performs initialization operation of the linear power amplifier in step 1000. After the initialization, the CPU 811 reads the voltage values of the attenuation control signals ATT1 to ATT3 and the phase control signals PIC1 to PIC3 with the specific power and the specific frequency. reads the voltage values in the corresponding area of RAM 813 and initializes the corresponding areas of RAM 813 to store the RSSI value corresponding to the number of transmission channels and the service channel information.

The initialization operation as above is performed only after the linear power amplifier has first been activated. Once the linear power amplifier is actuated, the initialization operation is not performed.

When the initialization operation is completed, the CPU 811 outputs the switching control signal SWC for selecting the first output to the power divider 231 to determine the service channel in step 1001 and outputs signal SF1, the control data PCD for selecting the first channel for the transmission band in step 1013. In this case, the signal selector 235 selectively outputs the first signal SF1 by means of the switching control signal SWC and the signal detector 236 detects the RSSI of the first channel frequency by means of the control data PCD. Thereafter, the controller 237 stores the RSSI received in the set channel in the corresponding channel area of RAM 813 in step 1015 and increases the channel number for detecting RSSI for the next channel in step 1017.

The channel scanning operation as above is performed to the last channel in the transmission band during a repeated execution of steps 1011 to 1019.

In the channel scan operation according to the above, the controller 237 detects the 3 "CEO z z" yPfaTï Eší '~, ÅNS \ I- "2 7092 l, ÜDLT | u Q - »- 10 15 20 25 30. s. of 519,812 RSSI and stores the detected RSSI in its interior during sequential increase of the channel number from the first channel to the end channel with respect to the total number of channels of the transmission band. In the case where the mobile communication system is a code division multiplexing access system (hereinafter referred to as CDMA), the transmission band is 869.640 MHz to 893.19 MHz and the channel interval is 1.23 MHz. In the case of a CDMA system, the SF1 band of the first signal is 869.640 MHz to 893.19 MHz, the control data PCD being arranged to designate the first signal SF1 from the first channel frequency 869.640 MHz as the twentieth channel frequency 893.10 MHz in a range of 1.23 MHz sequentially. In the aforementioned CDMA system, the controller 237 detects the RSSI of the designated channel and stores the detected RSSI in RAM 813, and in order, the transmission band designates each channel frequency of 869.640 MHz to 893.19 MHz in the channel scan operations.

When the channel scan operation is completed, the controller 237 sums the RSSI for the total number of channels stored in RAM 813 in step 1021 and calculates the average value by dividing the summed value for RSSI in all channels by the number of channels in step 1023. During execution of step 1015 to 1035, the controller 237 then determines the service channels. As for the steps for determining the service channel, the controller 237 takes the RSSI values for each channel stored in RAM 823 in order and compares the value obtained with the average value. If, after checking in step 1027, the RSSI of the channel exceeds the average value, the controller 237 checks in step 1029 whether or not the RSSI value of the corresponding channel exceeds a reference value + d. It is assumed here that d = 3 dB. Thus, if the RSSI value of the current channel exceeds the average value and the reference value in the above steps 1027 and 1029, the controller 237 checks in step 1029 whether or not the RSSI value of the corresponding channel is greater than 30 dB than the reference value + a. The purpose of this is to set channels, which have the safe signal distortion, as "2ííšï7 z \ PT ~ .T" \ _ šäbíïxšßšß fl Pišíïïijš fl lål Jil-BC u o: »v: - 10 15 20 25 30 35. n. . J ».1: H 519 812 a" = a "= z_¿ = 26 service channel even if the detected RSSI value exceeds the average value. When the RSSI value of the current channel exceeds the mean value and the reference value + a, the controller 237 sets the corresponding channel as the service channel in step 1031. During repetition of steps 1025 to 1035, the controller 237 checks the size of all channels' RSSI and sets the service channels.

After selecting the first signal SF1 according to the above, the controller 237 detects and analyzes the RSSI value for the total number of channels in the first signal SF1 band and sets and stores the channel to be transmitted and served. Thereafter, the controller 237 amplifies and outputs the signals of the set service channels.

In order to simplify the explanation, however, two successive channels are served in the embodiment according to the present invention. At this time, the frequency of each channel RF signal is assumed to be f1 and f2 and the intermodulation signal is assumed to be IM1 to IM2.

The controller 237 controls according to Fig. 10 in steps 1111 to 1163 the intermodulation signal, which is included in the output of the main power amplifier 214, and controls the variable attenuator 315 and the variable phase shifter 316. The pre-distortion device 213 generates the pre-distortion signal for suppression, which can be generated in the main power amplifier 214 after amplification, and the controller 237 detects RSSI in the intermodulation signal, which is included in the output of the main power amplifier 214, and controls variably so that the inter- in the main power amplifier 214. evenly suppressed, it is assumed that after detecting RSSI in the intermodulation signal output in the main power amplifier 214, the controller 237 compares the detected value with RSSI in the intermodulation signal in the previous state and performs three-step control operations. in accordance with the compared results. It is assumed here that ADC lší-iší- "fš f:" C253 z \ P? ~ .T "\ _ El \ í“ \ š & ï * š $ \ P22? 743921 .ZWBC eu un. 10 15 20 25 30 u CH 519 812; »-. .- 27 814 and DAC 815 are 16 bit converters, the first step being set as three steps and the second step being set as ten steps and the third step being set as twenty steps.The step becomes a quantization step after A / D At that time, when the initial level and phase are controlled, the controller 237 then increases the phase and attenuation control signal by one step and the RSSI of the IM signal is detected from the second control operation to the Xth control operation.The controller 237 controls it in the first step in case the comparison difference is below ten steps, it controls in the second step in case the comparison difference is below twenty steps and controls it in the third step in case the comparison difference is over twenty steps. with the control of the level and phase of the pre-distortion signal in sequence X times.

The controller 237 outputs the switch control signal SWC for selecting the second signal SF2 in step 1011. The signal selector 235 thus selects the signal shown in Fig. 11A, which is supplied to the main power amplifier 214 and thereby outputs the selected signal to the signal detector 236. To meet this the controller 237 checks in step 1013 whether or not the value of the set HG count is 0. At this time, the HG count counts the suppressed number of the intermodulation signal, which occurs in the main power amplifier 214. When here the value of the HG count is set to The controller 237 outputs the phase control signal PIC3 as phase control signal PPPIC3 + 1 step value of the previous state (initial state) in step 1015 and converts the phase control signal PIC3 to the analog signal by means of DAC6 in DAC 815 for later application to the variable attenuator 316. in the pre-distortion device 213 adjusts the phase of the pre-distortion signal fed to the upper the tone generator 314 by means of the phase control signal PIC3 and presses on the connection of the main power amplifier 214 the adjusted level. In step 1017, the controller stores 237 phase- 1998--432 "ZL-'flz 593: \ ON" \ E2 \ š "\ ŧ ° š-S§ '7 13921 Äi - IBC | Q I «» n u - v - f »10 15 20 25 30 35 519 812 ---- -. - -, .- 28 control signal PIC3 as well as the previous phase control signal PPIC3 for the next state. In step 1019, the controller 237 supplies the attenuation control signal ATT3 as attenuation control signal PATT3 + 1 of the previous state and converts the attenuation control signal ATT3 to the analog signal by means of DAC5 for supply to the variable attenuator 315. At this time, the variable of the variable - tone generator 314 supplied with the pre-distortion signal by means of the attenuation control signal ATT3 and connects the adjusted level to the connection of the main power amplifier 214. Then, the controller 237 stores the attenuation control signal ATT3 as well as the previous attenuation control signal PATT3 in step 1121.

It can be seen that the first phase and level control of the pre-distortion signal according to the above is achieved by adding a step to the control signal in the previous state. However, the corresponding control signal can occur with a comparison of the difference between the currently detected control signal and the control signal in the previous state. After controlling the phase and level of the pre-distortion signal as above, the controller 237 increases the HG count in step 1161.

After controlling the phase and level of the pre-distortion signal according to the above, the controller 237 again performs steps 1123 to 1135, detects the intermodulation signals IM1 to IM4 RSSI present at the output of the main power amplifier 214 and selects the intermodulation IM which has the largest RSSI value in the step. 1139

To do this, the controller 237 sequentially outputs the control data PCD for designating the signals IM1 to IM4, when the intermodulation signals in the output of the main power amplifier 214 are output in the signal detector 236, as shown in Fig. 11A, and receives and stores the RSSI value of the corresponding intermodulation signal to IM4.

Then, in step 1141, the controller compares the RSSI of the selected IM signal with the phase control signal PPIC3 in the preceding 1% 9e ~ o3 ~ 2ä7; saa: \ PAT \ ßx \ aNsyP2@vo921.noc. - | | .- 10 15 20 25 30 35. - - - uu 519 812 »- - A 1 i 29 condition. At this time, if the IM signal exceeds the phase control signal PPIC3, the controller 237 sets the phase control value to be reduced in step 1143 and, if the IM signal is less than the phase control signal PPIC3, the controller 237 sets the phase control value to increase in step 1145. After setting the the increase / decrease of the phase control, the controller 237 occupies the subtraction between the value of the IM signal and the phase control signal PPIC3 for the previous state in step 1147, whereby the phase control signal PIC3 is generated in dependence on the above subtraction. The phase control signal PIC3 is applied to the variable phase shifter 316 over the DAC 815.

Thereafter, the controller 237 stores the phase control signal PIC3 as the previous phase control signal PPIC3, which is to be used in the next state.

After generating the phase control signal PIC3 according to the above, the controller 237 also compares the RSSI of the IM signal, which is selected with the attenuation control signal PATT3 in the previous state in step 1151. If in this case the IM signal is larger than the attenuation control signal PATT3, the controller 237 sets the attenuation control value. in step 1153. If in contrast the IM signal is less than the attenuation control signal PATT3, the controller 237 sets the attenuation control value to be increased in step 1155. After setting the attenuation control increase / decrease according to the above, the controller 237 occupies the subtraction value between the value of the IM the signal and the attenuation control signal PATT3 in the previous state in step 1157 and thereby generate the attenuation control signal ATT3 in accordance with the above subtraction.

The attenuation control signal ATT3 is applied to the variable attenuator 315 over DAC 815. Thereafter, the controller 237 stores the attenuation control signal ATT3 as the previous attenuation control signal PATT3 in step 1159.

In step 1161, the controller 237 then increments the HG count by one and thus checks whether or not the HG count becomes the X value. If then the HG count does not become the X value, the controller 237 returns to the above steps .N39 "2fíšï'í 'z Büš: \ PP.T>' \ I-} 2 * í“ \ kïIS2212237092 l. ~ u 10 15 20 25 30 35. - ». u 519 812 1 -» V - v 30 1071 and repeats the above steps. the level of the pre-distortion signal by comparison with the phase and attenuation control signals PIC and ATT and determines the control direction and the control magnitude. level, the controller 237 prevents the generation of the intermodulation signal and, if the HG count becomes X, the operation ends with the adjustment of the predistortion signal.

After adjusting the phase and level of the pre-distortion signal, the controller 237 performs the operation of suppressing the RF signal distortion present in the output of the signal canceler 219.

In Fig. 10, in steps 1211 to 1255, the controller 237 detects the RF signal distortion present in the signal canceler 219 and controls the first variable attenuator 211 and the first variable phase shifter 212. The signal canceler 219 cancels the output of the main power amplifier 214, as shown in Figs. 11A, and the RF signal for input, and detects only the intermodulation signal generated after amplification. In this case, the controller 237 detects the RSSI of the RF signal included in the output of the signal canceler 219, as shown in Fig. 11B, and variably controls the level and phase of the RF signal so as to evenly suppress the RF signal in the signal canceler 219. According to the embodiment of the present invention, after detecting the RSSI of the signal signal 219 supplied to the signal canceler 219, the controller 237 compares the detected value with the RSSI of the RF signal in the previous state and performs the control operation in three steps, depending on the comparison difference. Assuming that ADC 814 is a 16-bit converter, the first step is set as three steps, the second step as ten steps and the third 15%) "Zïíí-'ß z 553: \ PT: TA '\ _ I-IZ ~ É ”\ Ä? IS2121297092 l, ÉP-DC 10 15 20 25 30 35« - ~ «in 519 812 31 step as twenty steps. The step becomes the quantization step after A / D conversion. When then at the point in which phase and level is initially checked, the controller 237 controls the phase and the level as the first step, independent of detected RSSI, controls it as the first step in case the comparison difference is below ten steps, it controls as the second step in case the comparison difference is below twenty steps and controls it as the third step in case the comparison difference is over twenty steps.As pointed out above, the control of the level and phase of the predistortion signal is performed in sequence X times.

The controller 237 outputs the switching control signal SWC for selecting the third signal SF3 in step 1211. The signal selector 235 thus selects the signal shown in Fig. 11A, which is supplied to the signal canceler 219, whereby the selected signal is output to the signal detector 236. Thereafter, controller 237 and analyzes the RSSI of the intermodulation signal included in the signal canceler 219, controls the first variable attenuator 211 and the first variable phase shifter 212, and adjusts the level and phase of the RF signal.

To accomplish this, in step 1212, the controller 237 checks whether or not the count is set to 0. The count here counts the number for canceling the RF signal included in the signal canceler 219.

After the count value is set to 0, the controller 237 outputs the phase control signal PIC1 as phase control signal PPIC1 + 1 step of the previous signal intended for storage in step 215 and converts the phase control signal PIC1 to the analog signal by means of DAC2 in DAC 815 for supply to the first variable phase shifter. 212. The first variable phase shifter 212 thus adjusts the phase of the RF signal input by the phase control signal PIC1 and outputs the adjusted phase to the main power amplifier 214. In step 1217, the controller 237 stores the phase control signal PIC1 as the previous phase control signal PPIC1 for the next state. The controller 237 further outputs lgggmøš fl üëüzüüš: \ PåTXEM \ ANS \ P297092l.§0C 10 15 20 25 30 35 u; .lv 1 519 812 .M .H 32 attenuation control signal ATT1 as attenuation control signal PATT1 + 1 step of previous state in step 1219 and converts the attenuation control signal ATT1 to the analog signal by means of DAC1 for later supply to the variable attenuator 315. The first variable adjusts attenuator 315 the level of the RF signal input from the attenuation control signal ATT1 and supplies the adjusted level to the main power amplifier 214.

The first phase and level of the RF signal are controlled as above by adding a step to the control signal of the previous state. However, the corresponding control signal may occur with the comparison of the difference between the now detected control signal and the control signal of the previous state. After controlling the phase and level of the RF signal as above, the controller 237 increases the SUB count in step 1253.

In contrast, at a check in step 1211, the SUB count is set to 0, the controller 237 sequentially outputs the control data PCD for designating the signals f1 to f2 in the output of the signal canceler 219, output as shown in Fig. 11B, and receives and stores the RSSI value. of the corresponding signal f1 to f2. The controller 237 selects the f-signal having the largest RSSI value among the f1 to f2 signals in step 1231.

Then, the controller 237 compares the RSSI of the f-signal selected with the phase control signal PPIC1 in the previous state in step 233. If at this time the f-signal is larger than the phase control signal PPIC1, the controller 237 sets the phase control value to be described in step 1235, and , if the f-signal is less than the phase control signal PPIC1, the controller 237 sets the phase control value for increase in step 1237. After setting the phase control increase / decrease, the controller 237 occupies the subtraction between the value of the f-signal and the phase control signal PPIC3 of the previous state in step 1239 and thereby generates the phase control signal PIC1 in accordance with the above subtraction.

The phase control signal PIC1 is applied to the first variable phase- 19 '-3 šš- "fl 3 - C221 * z“ yPäT fl I-ÉÄQANS IXLFIšÉ-ï 7092 l, BBC s | v. Ss u 10 15 20 25 30 35 519 812. ~ «- .- 33 the shifter 212 over DAC 815. Thereafter, the controller 237 stores the phase control signal PIC1 as the previous phase control signal PPIC1 for use in the next state.

After the generation of the phase control signal PIC1 in step 1243, the controller 237 further compares the RSSI of the f-signal selected with the value of the attenuation control signal PATT1 in the previous state. If at this time the f-signal is greater than the attenuation control signal PATT1, the controller 237 sets the attenuation control value PATT1, which is to be reduced in step 1245, and if the f-signal is less than the attenuation control signal PATT1, the controller 237 sets the attenuation control value PATT1 to increase step 1247. After the increase / decrease position of the attenuation control, the controller 237 occupies the subtraction between the value of the f-signal and the attenuation control signal PPIC1 in the previous state in step 1249 and thereby generates the attenuation control signal ATT1 in accordance with the above subtraction. The attenuation control signal ATT1 is applied to the first variable attenuator 211 over DAC 815. Thereafter, in step 1251, the controller 237 stores the attenuation control signal ATT1 as the previous attenuation control signal PATT1.

After increasing the SUB count by one step in step 1253, the controller 237 in step 1253 checks whether or not the SUB count gets Y value. If the SUB count does not get a Y value, the controller 237 returns to step 1223 to thereby perform the above steps again. During repetition of the above steps, the controller 237 detects the RSSI of the RF signal recorded in the signal canceler 219 and thus adjusts the phase and level of the RF signal by comparing the RSSI of the RF signal output from the signal canceler 219 in the previous phase and determining the control direction and control size. During the adjustment of the phase and level of the RF signal input as above, the controller 237 prevents the generation of the RF signal relating to said signal if the SUB count becomes Y, and terminates the operation by suppressing the RF included in the signal canceler 219. signals. - 242117 z Säll: ïtPfaTï I ~}} í “~, kNS" =, _ F2É-V7f_) 92 l. Ei- »ZIJC - -, = .v: v - - .- 10 15 20 25 30 35 519 812 According to Fig. 10, in steps 1311 to 1363, the controller 237 detects the intermodulation signal IM included in the RF signal, which RF signal is finally output in the main power amplifier 214, and controls the second variable attenuator 220 and the second the variable phase shifter 221. The RF signal output to the main power amplifier 214 is compensated over the second delay 215 while the intermodulation signal detected in the sub-path is suppressed and the intermodulation signal distortion included in the RF signal which is finally output by coupling the back phase of the intermodulation distortion treated in the subway by the signal coupler 223. can be suppressed, in which case the intermodulation signal distortion can be included in the RF signal, which is finally output, and the included intermodulation distortion can not contribute to the is suppressed.

At this time, the controller 237 detects the RSSI of the intermodulation signals IM1 to IM4 included in the output of the main power amplifier 214, as shown in Fig. 11C, and variably controls the phase and level of the IM1 to IM4 intermodulation signals to the intermodulation signal distortion finally output from the signal coupler 223 can be suppressed evenly in the main power amplifier 214. In the embodiment of the present invention it is assumed that after the detection of the intermodulation signals IM1 to IM4 RSSI recorded in the RF signal is amplified and finally output, the controller 237 compares the detected value with RSSI of the intermodulation signals IM1 to IM4 in the previous state and performs the control operation in three steps according to the compared results. It is assumed here that ADC 814 is a 16-bit converter, the first step being set as three steps, the second step being set as ten steps and the third step being set as twenty steps. The step becomes quantization step after A / D conversion. At the time when the initial level and phase are checked, the controller 237 then increases the phase and attenuation control signal one step 1% @ 2wø: ~ 2av; sas: \ PATäßM \ æNs: P2@vos21.§oc v ~ f ».u - - | - n 10 15 20 25 30 35 519 812; | . , u 35 and the RSSI of the IM signal are detected from the second control operation to the Xzte control operation. The controller 237 controls it as the first step in case the comparison difference is below ten steps, controls it as the second step in case the comparison difference is below twenty steps and controls it as the third step in case the comparison difference is over twenty steps. As previously pointed out, the operation is performed by controlling the level and phase of the pre-distortion signal in sequence Z times.

As shown in Fig. 10, steps 1311 to 1363 are performed in the same order as the above-mentioned steps 1111 to 1163 for adjusting the level and phase of the pre-distortion signal. The controller 237 thus controls the signal selector 235, selects the fourth signal SF4, controls the signal detector 236 and sequentially selects the intermodulation signals IM1 to IM4.

The controller 237 here sequentially receives RSSI for the intermodulation signals IM1 to IM4, which is detected in the signal detector 236. After selecting the intermodulation signal IM, which has the largest RSSI of the received intermodulation signals IM1 to IM4, the controller 237 compares the one now detected the intermodulation signal IM RSSI with the corresponding intermodulation signal IM in the previous state.

The controller 237 controls the second variable phase shifter 221 and the second variable attenuator 220 by receiving the phase control signal PIC2 and the attenuation control signal ATT2, corresponding to the comparative difference between the above intermodulation signal distortions. At this time, the controller 239 controls the second variable attenuator 220 and the second variable phase shifter 221 Z times.

As shown in Fig. 10, the linear power amplifier according to this embodiment of the present invention sets the service channels and adjusts the level and phase of the predistortion signal to suppress the intermodulation signal included in the main power amplifier 214 in a sequential manner. The above amplifiers also adjust the phase and level of the RF signal applied to the main path to suppress it in the signal 50%: \ FTQTÄBšT ~ ANSX PZÉÉVZOÉZI. 25-1312 R _ \. f u u - »n« - - æ | u 10 15 20 25 30 35 519 812 ~ -. The RF signal received by the canceler 219 and the level and phase of the intermodulation signal output to the signal canceler 129, so that the intermodulation signal, which relates to the amplified and finally output RF signal, can be suppressed.

An example of the present invention can be achieved by first selecting service channels, then controlling the phase and level of the pre-distortion signal and thirdly controlling the phase and level of the input RF signal and fourthly controlling the phase and level of the intermodulation signal distortion output in the signal canceler 219. .

According to another embodiment, the selection of service channels can be performed in an interval between given times by means of timer interruptions. Using the above control method, the controller 237 performs service channel search operation whenever the timer interrupt is generated and controls the variable attenuators and the variable phase shifts, as noted above, for the remainder of the periods. After the timer interrupt is generated in the state when an arbitrarily variable attenuator and arbitrarily variable phase shifter is controlled, at this time the controller 237 interrupts the operation and performs the timer interrupt service routine and thereby returns to the main routine and performs the currently processed operation.

While according to Fig. 10 the number, i.e. X, Y and Z, which control the variable attenuators and the variable phase shifters, can further be set as a number, which can effectively control the level and phase of the signal input to the corresponding variable attenuators and variable phase shifters. more specifically this number of 5 for all.

Fig. 12 is a block diagram showing the construction of a linear power amplifier according to a second embodiment of the present invention. The linear power amplifier according to the second embodiment of the present invention is of the same construction as the one according to the first embodiment thereof, as shown in Fig. 1, with the exception of 199æ «o3 ~ c20: ccæ: \ PATäßxxAms: P2 @ vo921. aoc | ø | - now . . . «N 10 15 20 25 30 35 519 812 = | . ». 37 that the first variable damper 211 and the first variable phase shifter 212 are located in the subway.

According to Fig. 12, the pre-distortion device 213 in the main path is of the same construction as that shown in Figs. the controlled signals to the input RF signal, converts the coupled signals to the RF signal subjected to pre-distortion, and outputs the converted signals to the main power amplifier 214. The main power amplifier 214 supplies the output signal of the pre-distortion device 213 to the RF amplifier 213. , which has been pre-distorted, and outputs the RF signal when the intermodulation signal distortion is suppressed.

The remaining construction of the linear power amplifier corresponds to that of the first embodiment of the present invention, shown in Fig. 2, with the exception of the above construction. The reference numerals in the second embodiment of the present invention are thus the same as in the first embodiment thereof. The controller 237 further selectively selects input of the first signal SF1 to the fourth signal SF4 in the same manner as in Fig. 10 and generates attenuation signals ATT1 to ATT3 and phase control signals PIC1 to PIC3 with detection of RSSI of the RF signal or intermodulation signal in it. selected SF signal. After setting the service channels, the controller 237 adjusts in order the phase and level of the pre-distortion signal for suppression of the intermodulation signal, which relates to the main power amplifier 214, adjusts the level and phase of the sub-signal supplied RF signal in order to suppress the RF included in the signal canceler 219. signal distortion and finally adjusts the level and phase of the intermodulation signal distortion applied to the signal canceller 129 in order to suppress the "Zíåïl: BÖIZ: \ PT« .T "\ E} \ '; \ la? I-SXFIZÉYÉÜQZl, EIÜIL '»<> = v.« »| «.- 10 15 20 25 30 35 519 812 v s o v v - 38 intermodulation signal distortion, which relates to the amplified and finally output RF signal.

Fig. 13 is a block diagram showing the construction of a linear amplifier according to a third embodiment of the present invention. The linear amplifier according to the third embodiment of the present invention is of the same construction as that of the second embodiment thereof, as shown in Fig. 13, except that the first variable attenuator 211 and the first variable phase shifter 212 are located between the main course and the subway.

According to Fig. 12, the predistortion device 213 in the main path is of the same construction as that shown in Figs. 3 and 5 and generates harmonics corresponding to the input RF signal, controls the level and phase of the harmonics depending on the attenuation control signal ATT3 controlled signals to the input RF signal, converts the coupled signals to the predistortion signal, and finally outputs the converted signal to the main power amplifier 214. The main power amplifier 214 inputs the output signal to the predistortion device 213 and outputs the RF signal modulator signal is suppressed by amplifying the RF signal, which has been subjected to pre-distortion.

The first delay 217, which is located in the sub-path, feeds the RF signal, which is divided into the main path by the power divider 216, delays the RF signal while the RF signal is processed in the predistortion device 213 and the main power amplifier 214, and outputs the delayed RF signal. to the signal canceller 219.

The first variable attenuator 211 and the first variable phase shifter 212 are connected between the power divider 218 and the signal canceler 219, which control the level and phase of the RF signal input by the attenuation control signal ATT1 and the phase control signal PIC1, which are output in the controller 237. and outputs the controlled level and phase to the signal canceler 219. The first variable attenuator l * 3 '<38 --- fJE - 2%? z 5522: \ PT ~ .TV '\ _ EÅ \ í \ Ä? ISXÉZÉW 53921. Zê-IDC »» ». .o ~. | - .- 10 15 20 25 30 35 519 812 »» Q E -. 211 and the first variable phase shifter 212 are thus located between the main path and the sub-path and the phase and level of the RF signal amplified and output to the main power amplifier 214 in the main path are controlled to thereby be output to the signal canceler 219.

The remaining construction of the linear power amplifier corresponds to that of the first embodiment of the present invention, as shown in Fig. 2, with the exception of the above construction. The reference numerals in the second embodiment of the present invention thus correspond to those in the first embodiment thereof.

The controller 237 further selectively supplies the first signal SF1 to the fourth signal SF4 in the same manner as in Fig. 10 and generates attenuation signals ATT1 to ATT3 and phase control signals PIC1 to PIC3 with detection of the RF signal RSSI or the intermodulation signal in the selected SF signal. After setting the service channels, the controller 237 adjusts in order the phase and level of the pre-distortion signal for suppression of the intermodulation signal, which relates to the main power amplifier 214, adjusts the level and phase of the sub-signal supplied RF signal so as to suppress the distortion of the RF signal, the signal canceller 219, and finally adjusts the level and phase of the intermodulation signal output in the signal canceller 129 so as to suppress the intermodulation signal distortion associated with the amplified and finally output RF signal.

Like the linear power amplifier according to the first embodiment of the present invention, the linear power amplifiers according to the second and third embodiments of the present invention select for the first service channel, control for the second pre-distortion signal phase and control for the third the input RF signal. The phase and level of the lens and fourthly controls the phase and level of the intermodulation signal output in the signal canceller 219. According to another embodiment thereof, the selection of "?; 5ü;: \ PaTïßMïANs \? 2970921, §oc | -». .- ~ - - »n 10 15 20 25 30 35 519 812. |..,« 40 service channel is performed In a range of given times by means of timer interruptions.Using the above control method, the controller 237 performs the service channel search operation whenever the timer interrupt is generated and controls the variable attenuators and the variable phase shifts in the specified manner for the remainder of the periods. condition, in which an arbitrary, variable attenuator and a variable phase shifter are controlled, the controller 237 interrupts the operation and performs the timer interrupt service routine to thereby return to the main routine and perform the current operation.

While according to Fig. 10 the number, i.e. X, Y and Z, by which the variable attenuators and the variable phase shifters are controlled, can be set as the number which effectively controls the level and phase of the signal input in the corresponding variable attenuators and variable phase shifters are set to the same speech for all and more concretely at 5.

As can be seen from the above, the linear power amplifier according to the practice of the present invention efficiently divides and controls the intermodulation signal distortion with the pre-distortion system and the feed system. In other words, the linear power amplifier first suppresses the intermodulation signal distortion which can be generated in the main power amplifier using the predistortion system and secondly suppresses the intermodulation signal which relates to the output signal from the main power amplifier by using the feed system. In this way, it is easy to design and manufacture the main power amplifier 214 and the error amplifier 222. Since variable attenuators and variable phase shifters perform the linear function in the same way, they have their wide bandwidth with respect to the frequency characteristics and their relatively good flatness. good variable properties, the linear power amplifier of the present invention can be used for other purposes. 19ae ~ ø: ~ 2 fi v: seis: 3PATïßx3AmsgP29vo921.moc ~ ~ «. vn v. -; nu v- n. 4 ... u. . .. ..

. HRS .. . ,., l. ,. .... . ... It is therefore to be understood that the present invention is not limited to the specific embodiment described herein as the best mode for carrying out the invention, but that the invention is to be construed as set forth in the appended claims. »Ewa: \ 1> r« .- f1: = \ _ ': fc

Claims (15)

10 15 20 25 30 35 519 812 a. 1.. v 42 PATENT REQUIREMENTS A linear power amplifier device having a main power amplifier for eliminating an intermodulation signal, comprising a predistortion device for first suppressing the intermodulation signal generated after amplifying an RF signal in the main power amplifier by generating RF harmonics. signal, and a pre-distortion signal coupling the RF signal to the harmonics and a feeder for a second suppression of the intermodulation signal by canceling the input RF signal and the output signal from the main power amplifier, extracting an intermodulation signal distortion, the error amplifier extracted the intermodulation signal distortion and coupled the amplified intermodulation signal to the main power amplifier output. Device according to claim 1, wherein the pre-distortion device consists of a power divider for power division of the input RF signal, an automatic level controller for regulating and outputting the divided RF signal at a given level, a harmonic generator for generating harmonics corresponding to the level-controlled RF signal and a signal coupler for coupling the harmonics to the input RF signal and generating an RF signal with pre-distortion. Device according to claim 1 or 2, wherein the feeder comprises a power divider for dividing the RF signal input from the main path to a sub-path, a signal canceler for canceling the RF signal of the sub-path and the output signal of the main power amplifier and detecting the intermodulation signal, "fšš" C213 ir "yPï-zTi, E2 \ i \ ÅNSX? ZšÉY? ¿J§2 l. SBC - - <; n n -. - «- o 10 15 20 25 30 35 ~ Q | . nu I. . . . n 519 812. v. an error amplifier for amplifying the intermodulation signal distortion output from the signal canceler and a signal coupler for coupling the output signal from the error amplifier to the output power of the main power amplifier on the main path and suppressing said intermodulation output output to distortion, RF signal. A linear power amplifier device, comprising a first variable attenuator and phase shifter, located in the main path, for adjusting the level and phase of the input RF signal, a predistortion device for generating harmonics corresponding to the RF signal output to it. first variable attenuator and phase shifter and thereby generating the RF signal with pre-distortion coupled to the RF signal, a main power amplifier for amplifying and outputting the RF signal with pre-distortion, a first delay device which is located in a sub-path, for delaying the split RF signal to the main path, a signal canceler located in the sub-path, for canceling the output signal separated from the main path from the main power amplifier and the output signal from the first delay device, whereby the one included in the amplified RF signal the intermodulation signal is extracted, a second variable attenuator and phase shifter for adjusting the d a level and phase of the intermodulation signal output to the signal canceler, an error amplifier for amplifying the intermodulation signal output to the second variable attenuator and the phase shifter, a second delay device for delaying the output of the main power amplifier and a signal switching switch for the till den 'ß * s ~ nf ~ "% 7« søs: \ PAT @ mx \ rs: fl evrw ".won av -im * k \ _ \ <. ~, _e. , - 10 15 20 25 30 35 u - ~ f -n 519 812 - «. »A» 44 the second signal of the delay so as to suppress the intermodulation signal relating to the finally output RF signal. An apparatus according to claim 4, wherein the predistortion device comprises a power divider for power division of the input RF signal, an automatic level controller for regulating and outputting the divided RF signal at a given level, a harmonic generator for generating harmonics. corresponding to the level-controlled RF signal, a third variable attenuator and phase shifter for adjusting the level and phase of the harmonics output from the harmonic generator, a delay device for delaying the input RF signal and a signal coupler for switching the harmonics output in the third variable attenuator and phase shifter, to the output device of the delay device and generation of an RF signal with pre-distortion. Linear power amplifier device, comprising a pre-distortion device placed in a main path for generating harmonics corresponding to an input RF signal, coupling the generated harmonics to the RF signal and generating an RF signal with predistortion, a main power amplifier for amplification and output feeding the RF signal with pre-distortion, a first variable attenuator and phase shifter, which is placed in a sub-path, for adjusting the level and phase of said RF signal to the main path, a first delay device for delaying the to the first variable attenuator and the phase shifter output the RF signal, a signal canceler, which is located in the main path for canceling the output signal from the output signal of the main power amplifier divided to the main path and the output signal lGÜB- "fJL-š - ~ 2 = 'å7: 5013:' ïPfaT fl B§í \ A ? I-S_ \ LPIÉÉYÉ¿JÉJZI. ÛÛÛ ~ - = - »n 10 15 20 25 30 35» -. »Fo 519 812. | |. U 45 from the first delay device, whereby in the first the correct RF signal including the intermodulation signal is extracted, a second variable attenuator and phase shifter for adjusting the level and phase of the intermodulation signal output in the signal canceler, an error amplifier for amplifying the intermodulation signal output in the second variable attenuator and phase shifter. a second delay device for delaying the output signal from the main power amplifier and a signal coupler for coupling the intermodulation signal output in the error amplifier to the output signal from the second delay device, whereby the intermodulation signal relating to the finally output RF signal is output. The apparatus of claim 6, wherein the predistortion device comprises a power divider for power division of the input RF signal, an automatic level controller for regulating and outputting the divided RF signal at a given level, a harmonic generator for generating harmonics. corresponding to the level-controlled RF signal, a third variable attenuator and phase shifter for adjusting the level and phase of the harmonics output in the harmonic generator, a delay device for delaying the input RF signal and a signal coupler for coupling the the third variable attenuator and the phase shifter output the harmonics to the delay device output and generate an RF signal with predistortion. Linear power amplifier device, comprising a distortion device, located in a main path, for generating harmonics corresponding to an input RF signal, coupling the generated harmonics v = sü; = \ PaTxßM \ nNs1P2 @ vo921, §oc 10 15 20 25 30 35 ««: | m 519 812 46 to the RF signal and generating an RF signal with pre-distortion, a main power amplifier for amplifying and outputting the RF signal with pre-distortion, a first delay device, which is placed in a sub-path, for delaying the the RF signal divided into the main path, a first variable attenuator and phase shifter, which is located between the sub-path and the main path, for adjusting the level and the phase of the output signal from the output signal of the main power amplifier divided to the main path, canceling the RF signal output from the first variable attenuator and the phase shifter and the output signal from the first delay device, whereby an intermodulation signal included in the amplified RF signal is extracted, a second variable attenuator and phase shifter for adjusting the output of the signal canceler the level and phase of the intermodulation signal, an error amplifier for amplifying it in the second variable the attenuator and the phase shifter output the intermodulation signal, a second delay device for delaying the output signal from the main power amplifier and a signal coupler for coupling the intermodulation signal output in the error amplifier to the output signal from the second delay device, whereby the intermodal means output RF signal, is suppressed. Apparatus according to claim 8, wherein the pre-distortion device comprises a power divider for power division of the input RF signal, an automatic level controller for regulating and outputting the divided RF signal at a given level, - 2119: 17: 51332 \ PÅTÅ '\ _ I ~ E} É ”\ E> ÅIS i F23” I ”' D92 l. ZHBC ~ | «1 .v 10 15 20 25 30 35 519 812 47 a harmonic generator for generating harmonics corresponding to the level-controlled RF signal, a third variable attenuator and phase shifter for adjusting the level and phase of the harmonics output in the harmonic generator, a delay device for delaying the input RF signal and a signal coupler for coupling harmonics output in the third variable attenuator and phase shifter to the output signal of the delay device and generating an RF signal with predistortion. A linear power amplifier device, comprising a first variable attenuator and phase shifter, located in a main path, for adjusting the level and phase of an RF signal input by means of a first attenuator control signal and a first phase control signal, a pre-distortion device for generating harmonics corresponding to the RF signal output in the first variable attenuator and phase shifter, adjusting the level and phase of the harmonics by means of a third attenuation control signal and a third phase control signal and thus generating the RF signal with predistortion coupled to the RF the signal, a main power amplifier for amplifying and outputting the RF signal with predistortion, a first delay device placed in a sub-path for delaying the divided RF signal in a main path, a signal canceler, which is placed in the sub-path, for canceling the output of the output of the main power amplifier divided to the main path and the output of the first delay the second device, whereby the intermodulation signal included in the amplified RF signal is extracted, a second variable attenuator and phase shifter for inputting an intermodulation signal output in the signal canceler and adjusting the level and phase of the intermodula. gPäTiyï-Zšíïjiïl-SXÉZÉÉWÜÉZl, ÜÜÜ 10 15 20 25 30 35 vn »- en u | »| The 48 signal by means of a second attenuation control signal and a second phase control signal, an error amplifier for amplifying the intermodulation signal output in the second variable attenuator and the phase shifter, a second delay device for delaying the main power amplifier amplifier signal for a signal amplifier output. the output output of the intermodulation signal to the output of the second delay device, whereby the intermodulation signal relating to the finally output RF signal is suppressed, a signal selector comprising power dividers dividing the output of the main power amplifier, the output of the output terminator and the signal selective output of a corresponding split signal by means of switching control signals, a signal detector for inputting the output signal from the signal selector, synchronizing frequencies of RF signals and intermodulation signals by means of control data and detecting the RSS of the signal I, a controller for generating the switching control signals for sequential control of the signal selector, outputting the output data for synchronizing the intermodulation signals relating to the main power amplifier, after selecting the output signal from the main power amplifier, comparing the RSSI of the output in the signal the thermodulation signal with RSSI of an intermodulation signal in a previous state, generating the third attenuation control signal and the third phase control signal corresponding to the compared result, output of the control data for synchronizing the RF signals, which relate to the output signal from the signal canceller after selecting the output signal from the signal canceller, comparing the RSSI of the RF signals output in the signal detector with the RSSI of the RF signal in the previous state, generating the first attenuation control signal and the first 3 - z \ PP ~, T "\ _BÉ * 'S \ Ä = * ISXPZÉTNJQZl, ÉëÜC uuu »I y 10 15 20 25 30 35« a | . »O 519 812 1«. = u 49 phase control signal in accordance with the comparison result, output of the control data for synchronization of the intermodulation signals recorded in the RF signal, after selecting the finally output RF signal, comparison of RSSI of the intermodulation signals output in the signal detector, with RSSI of the intermodulation signal in the previous state and generation of the second attenuation control signal and the second phase control signal in accordance with the comparison result. The apparatus of claim 10, wherein the pre-distortion device comprises a power divider for power division of the input RF signal, an automatic level controller for regulating and outputting the divided RF signal at a given level, a harmonic generator for generating harmonics. corresponding to the level-controlled RF signal, a third variable attenuator and phase shifter for adjusting the level and phase of the harmonics output in the harmonic generator, a delay of delay of the input RF signal and a signal coupler for switching the ones in the third variable attenuator and the phase shifter output the harmonics to the output of the delay device and generate an RF signal with predistortion. An apparatus according to claim 10 or 11, wherein the signal detector comprises a phase locked loop for inputting the control data and generating a local frequency corresponding to the input control data, a mixer for mixing a signal output in the signal selector with the output signal from the phase-locked loop, a filter for performing frequency conversion of a frequency output in the mixer and 19äs ~ 0z ~ 2æ7: 5d;: \ PAT1ßxxANs; P29vo921.mßc «. . - f: 10 15 20 25 30 35 u - | - .n 519 812 »- -. «U 50 a log amplifier for converting the output signal from the filter to a direct voltage and outputting the converted voltage as RSSI. A method of eliminating an intermodulation signal in a linear power amplifier device, which includes a main power amplifier, comprising (a) first, suppressing the intermodulation signal generated after amplifying an RF signal in the main power amplifier, by generating harmonics in the main power amplifier. corresponding to the input RF signal and a pre-distortion signal coupling the RF signal to the harmonics and (b) secondly suppressing the intermodulation signal by canceling the input RF signal and the output signal from the main power amplifier, extracting a intermodulation signal distortion, error amplification of the extracted intermodulation signal distortion and coupling of the amplified intermodulation signal to the main power amplifier output signal. A method according to claim 13, wherein step (a) comprises dividing the input RF signal and a constant maintenance of the level of the divided RF signal, generating a harmonic signal corresponding to the RF signal, coupling the harmonic signal to the RF signal and the generation of an RF signal with pre-distortion and suppression first by an intermodulation signal, which is generated after amplification and output of the pre-distortion signal. A method according to claim 13 or 14, wherein step (b) comprises canceling the first suppressed power amplifier signal and the input RF signal and extracting the intermodulation signal, amplifying the extracted intermodulation signal and 1993-43 3 - ~ CEO rr ïRPT-: Tïx Išêíljäïšš XPÉ 'I 5392 l. ÜÜÜ - | . «V: O ... .... . .. .. .. .... O I II I) i i Ib I I I _. -. . . . . . . . . . . . . . 51 suppressing for the second time the intermodulation signal, which is recorded in the finally output RF signal, after coupling the amplified intermodulation signal to said first suppressed power amplification signal. §-- xC (Q.- í IC f) - '3 ~~: \ PP ~, T ° * .EZ * í “\ LNSXPÉÅÉF'I'¿J * B2 l JÉHBLT