NL1006031C2 - Linear power amplification device and method. - Google Patents

Description

Short designation: Linear power amplification device and method.

The invention relates to a linear power amplifier comprising a main amplifier for eliminating intermodulation signals.

Generally, high power amplifiers 5 operate near the saturation region with non-linear operating characteristic to obtain maximum output power. However, in the case where multiple carriers are supplied to the power amplifier, intermodulation distortion occurs which significantly degrades the performance of the amplifier 10. This leads to the problem that the level of the input signal must be lowered by a few dB or that a power transistor with a larger capacity than generally used must be used to prevent deterioration in performance.

When a power transistor is not used but a normal transistor, intermodulation distortion can be prevented in a linear power amplifier by using its linear properties. If one wants to improve the quality of the RF signal transmitted with communication devices, it is necessary to use a linear power amplifier.

A block diagram of a linear power amplifier known per se as described in US patent 5 130 663 is shown in FIG. With this linear power amplifier, a control signal is generated, the generated signal is combined with an input signal, the control signal is detected at the output terminal, and this controls the phase and amplification of an error amplifier with which the intermodulation distortion can be suppressed accordingly. The linear power amplifier uses the control signal to continuously control the amplification factor of the error amplifier regardless of variable factors or conditions.

However, this makes it difficult to set the correct conditions for automatic adjustment of the linear amplifier as described above. Since the linear power amplifier additionally comprises the control generator and the control signal detection circuit, construction and operation of such a linear amplifier become more complicated.

The invention thus provides a linear power amplifier, characterized by: a pre-distortion circuit for suppressing an intermodulation signals generated by the amplification of the RF signal in the main amplifier by generating harmonics corresponding to the input RF signal and a pre-distortion signal by combining of the RF signal with these harmonics; and a feed-back circuit for further suppressing the intermodulation signal by neutralizing the input RF signal with the output signal of the main amplifier, extracting an intermodulation distortion signal, amplifying the extracted in-termodulation error signal and supplying the distorted signal. strength intermodulation error signal at the output of the main amplifier.

Preferred embodiments thereof are described in claims 2 and 3.

Furthermore, the invention provides such a linear power amplifier, characterized by: a first variable attenuator and phase shifter in the main signal path for adjusting level and phase of the input RF signal; a pre-distortion circuit for generating 35 harmonics corresponding to the RF signal supplied by the first variable attenuator and phase shifter 1006031 3 and thus generating the pre-distorted RF signal with the RF signal; a main amplifier for amplifying and outputting the preformed RF signal; 5 an in-way delay circuit for delaying the shared RF signal adapted to the delay in the main road; a down-way signal canceller for neutralizing the divided output voltage on the main-10 way and the output voltage of the first delay circuit, thereby obtaining intermodulation present in the amplified RF signal; a second variable attenuator and phase shifter for adjusting the level and phase of this intermodulation signal; an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter; a second delay circuit for delaying the output of the main amplifier; and a signal coupler for coupling the intermodulation signal supplied in the error amplifier to the output of the second delay circuit, thereby suppressing the intermodulation signal of the final RF signal.

A preferred embodiment thereof is described in claim 5.

Another embodiment of the invention is characterized by: a main circuit distortion circuit for generating harmonics corresponding to an input RF signal, combining these harmonics with the RF signal and generating a distorted RF signal; 35 a main power amplifier for amplifying and outputting the distorted RF signal; 1006031 4 a first attenuator and phase shifter in an under signal path for controlling level and phase of the divided RF signal taken from the main path; a first delay circuit for delaying the RF signal applied thereto from the first variable attenuator and phase shifter; a signal canceller included in the road to cancel the portion of the output signal extracted from the main road of the main amplifier by the delay signal output signal, thereby obtaining an intermodulation signal; a second variable attenuator and phase shifter for controlling the level and phase of this intermodulation signal; 15 an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter; a second delay circuit for delaying the output signal of the main amplifier and a signal coupler for combining the intermodulation signal at the output of the error amplifier with the output signal of the second delay chain, thereby suppressing intermodulation signals in the final output RF signal.

A preferred embodiment thereof is described in claim 7.

Furthermore, the invention provides a power amplifier having the features described in claims 8, 9 and 10, respectively.

The preforming circuit preferably includes: a divider for obtaining a portion of the input RF signal; an automatic level control for controlling and outputting the shared RF signal at a certain level; 1006031 5 a harmonic generator for generating harmonics corresponding to the level-controlled RF signal; a third variable attenuator and phase shifter 5 for adjusting the level and phase of the harmonics generated in this harmonic generator; a delay circuit for delaying the input RF signal; and a signal coupler for coupling a harmonic signal output in the third variable attenuator and phase shifter to the output signal of the delay circuit and thus generating a distorted RF signal.

The signal detector preferably includes: a phase lock loop to which the control data is input for generating a local frequency corresponding to the input control data; a mixer for mixing a signal supplied by the signal detector with the output of the phase-locked loop; a frequency down filter to a frequency supplied by the mixer; and a logarithmic amplifier for converting the output signal of the filter into a DC voltage 25 and supplying the converted voltage as the RSSI value.

The invention further provides a method for eliminating an intermodulation signal in a linear power amplifier device comprising a main power amplifier, characterized by the steps of: (a) first suppressing the intermodulation signal generated upon amplification of an RF signal in the main amplifier by generating harmonics corresponding to the input RF signal and a pre-distortion signal by coupling the RF signal with these harmonics; and 1006031 6 (b) thereafter suppressing the intermodulation signal by canceling the input RF signal with the output signal of the main power amplifier, extracting an intermodulation distortion signal, amplifying the extracted intermodulation distortion signal and combining the amplified intermodu -Lation signal with the output signal of the main amplifier.

In addition, step (a) consists of: dividing the input RF signal and keeping the level of the shared RF signal constant; generating a harmonic signal corresponding to the RF signal; combining the harmonic signal with the RF 15 signal and generating a pre-distorted RF signal; and suppressing an intermodulation signal generated upon amplifying the pre-distorted signal.

Step (b) then consists of neutralizing the suppressed power amplified signal and the input RF signal and extracting the intermodulation signal; amplifying the extracted intermodulation signal; and suppressing the intermodulation signal in the RF signal by coupling the amplified intermodulation signal with the suppressed power amplified signal.

The invention will be elucidated with reference to the drawing.

Fig. 1 is a block diagram of the linear power amplifier known per se; FIG. 2 is a block diagram of a first embodiment of the invention; Fig. 3 shows the pre-deformation circuit shown in Fig. 2; 1006031 7 FIG. 4 shows the automatic level control of FIG. 3; Fig. 5 shows the structure of the signal detector in Fig. 4; Fig. 6A to 6G show the characteristics of the signal spectrum obtained with the amplifier according to the invention. Fig. 7 shows the structure of the signal detector occurring in Fig. 2; Fig. 8 shows the construction of the control system occurring in Fig. 2; FIG. 9 is a flow chart for explaining the operation of the controller; FIG. 10 is a flow chart for explaining the operation of the variable attenuator and phase shifter occurring in FIG. 2; 11A through 11C show the frequency spectra used to control attenuation and phase; Figure 12 is a block diagram of a second embodiment of the amplifier according to the invention; Fig. 13 is a block diagram of a third embodiment of the amplifier according to the invention.

The block diagram of the linear power amplifier according to a first embodiment of the invention is given in Fig. 2. This figure shows the first variable attenuator 211 controlling the attenuation of the input RF signal via an attenuation control signal ATT1. A first variable phase shifter 212 receives the output of the first variable attenuator 211 and controls the phase of the input RF signal by means of a phase control signal PCI1 (PIC1; vert.).

A distortion circuit 213 receives the RF signal which may be expected to form 214 harmonics in the main power amplifier, due to the intermodulation distortion, and generates the distortion signal. The main power amplifier 214 amplifies the 1 0 0 6 0 3 1 8 RF signal output by the pre-distortion circuit 213 and supplies the power amplified signal. A second delay unit 215 is supplied with the RF signal from the main power amplifier 214, delayed and outputting the input RF signal when the intermodulation signal is supplied.

The above circuits form the main signal path of the linear power amplifier in this first embodiment.

A power divider 216 takes out part of the RF signal input into the main road and outputs this RF partial signal as output. It is also possible to use a directional coupler instead of the power divider 216. A first delay circuit 217 compensates for the delay time of the RF signal as it traverses the main road distortion and amplifier circuit. At the output terminal of the main power amplifier 214 there is a power divider 218 which takes part of the output signal of the main power amplifier 214 to be output. Here, too, a directional coupler can be used as power divider 218. A signal canceler 219 is supplied with the RF signal after traversing the first delay circuit 217 and the RF signal amplified in the power amplifier 214. The signal canceler 219 neutralizes the RF signal 25 output through the first delay circuit 217 with the output of the main power amplifier 214, thereby detecting the intermodulation signal. In this embodiment, the signal canceller 219 is configured as a subtractor.

A second variable attenuator 220 receives the intermodulation signal from the signal canceller 219 and the gain of the input intermodulation signal is controlled by an attenuation control signal ATT 2 output from a controller 237. A two-phase variable phase shifter 221 receives the input signal from the second variable attenuator 220 outputted intermodulation signal and controls the phase of the 1006031 9 input intermodulation signal through a phase control signal PIC2 supplied by the controller 237. An error amplifier 222 amplifies the intermodulation signal 5 outputted by the second variable phase shifter 221 and supplies it to a signal coupler 223 which couples it with the output signal of the error amplifier 222 to the output terminal of the second delay circuit 215. As the signal coupler 223, a direction coupler can be used.

The above forms a sub-signal path for suppressing the intermodulation signal in the main signal path in this preferred embodiment.

A signal power divider 231 takes part of the input RF signal at the input terminal 15 and supplies a first signal SF1. A divider 232 cooperates with the output terminal of the main power amplifier 214, extracts part of the amplified RF signal and provides a second signal SF2. A divider 233 at the output of the signal canceler 219 supplies a portion of the intermodulation signal from which the RF signal is removed and provides a third signal SF3. Finally, a divider 234 at the output terminal extracts part of the final output RF signal and supplies a fourth signal SF4. The dividers 231 to 25 with 234 can be replaced by a directional coupler. A signal selector 235 is input to the aforementioned signals SF1 to SF4 output in dividers 231 to 234 and selectively outputs the output signal SF controlled by the switch control data SWC output from the controller 237.

A signal detector 236 provides a signal indicative of the received signal strength (denoted as RSSI) of the signal SF outputted from the signal selector 235 as a DC signal applied to the controller 237 which provides a switching control signal SWC for selecting the signal SF of the signal selector 235 and thereby the control data PCD for determining the frequency for detecting the RSSI from the signal SF selected in the signal detector 236.

In addition, the controller 237 analyzes the RSSI 5 signal output from the signal detector 236 and generates the attenuation control signals ATT1 through ATT3 and the phase control signals PIC1 through PIC3; these signals control the variable attenuator and the variable phase shifter to control the variable attenuator and variable phase shifter in accordance with the analysis result of the controller 237. In addition, in the case where the signal output in the divider 231 is selected, the controller 237 controls the signal detector 236, detects the RSSI value of the input RF signal and judges the RSSI values so that the frequency component of the input RF signal is recognized. In the case where the output of the main power amplifier 214 supplied to the divider 232 is selected, the controller 237 controls the signal detector 236, detects the RSSI values of the harmonic signal of the amplified RF signal and evaluates the RSSI values, thereby attenuation control signal ATT3 and generating a phase control signal PIC3, for adjusting attenuation and phase of the intermodulation signal supplied by the pre-distortion circuit 213. When the signal canceller output 219 is selected, the controller 237 controls the signal detector 236, detects the RSSI values of the RF signal contained in the neutralized intermodulation signal, and judges the magnitude of the RSSI values, thereby the attenuation control signal ATT1 and the phase control signal PICl. exciting, intended for controlling attenuation and phase of the RF signal respectively input to the input terminal of the linear power amplifier. When the output amplified signal is selected, the controller 237 controls the signal detector 236, detects the RSSI values of the inter 10010031 11 simulation signals contained in the output final signal, and judges the sizes of the RSSI values, thereby the attenuation control signal ATT2 and the phase control signal PIC2 exciting, intended to control respective attenuation and phase of the intermodulation signal output in the signal canceller 219.

In the preferred embodiment as described above, the linear power amplifier eliminates the intermodulation signal that can occur during the amplification using the pre-distortion system and the pre-coupling. In the above-described embodiment, the preamp 213 primarily performs the function of removing the intermodulation signal output to the main power amplifier 214. To perform this function, the preamp 213 expects the harmonics that can be generated in the amplification in the main power amplifier. 214, and then adjusts its phase so that they have a phase opposite to that of the harmonics to be generated in the main power amplifier 214 when they reach the power transistor of the main amplifier 214.

When using the pre-distortion system, it is impossible to completely eliminate the intermodulation signal generated in the linear power amplifier. Accordingly, the linear power amplifier according to the described embodiment first suppresses the intermodulation signal in the pre-transformer 213 and finally suppresses the intermodulation signal using the feed-back system. The linear power amplifier used in the feed-back system eliminates pure RF signal distortion at the output of the main power amplifier, outputs the intermodulation signal and applies the extracted intermodulation signal 35 to the signal coupler 223, thereby eliminating the intermodulation distortion. Using the feed-back system, the intermodulation distortion 1006031 12 signal contained in the signal as finally amplified by the linear power amplifier can be suppressed so that a purely amplified RF signal can be output.

In the above-described embodiment, the intermodulation signal generated upon amplification in the main power amplifier 214 is first suppressed by the pre-distortion system, and then the intermodulation signal remaining at the output 10 of the high-power amplifier 214 is suppressed by the pre-coupling system. To simplify the explanation, first the suppression of the intermodulation signal in the pre-distortion system will be described and then the suppression of the intermodulation distortion by the pre-coupling system.

Fig. 6A to 6G show signal spectra explaining the operation of the linear power amplifier according to the invention, assuming the occurrence of two frequencies. Fig. 6A shows the input RF signal, FIG. 6B shows the harmonics of the RF signal generated in the harmonic generator 314, FIG. 6C shows the signal that can affect the harmonics through the variable attenuator 315 in the pre-distortion chains 213 with the adjustable phase and as counter phase to be fed into the high power amplifier 214 via the variable phase shifter 316; Fig. 6D shows the amplified RF signal with the intermodulation signal obtained by amplifying the pre-distortion signal fed into the main amplifier 214 and in the form of Fig. 6C. Fig. 6E shows the intermodulation signal obtained by neutralizing the signal distortion in the amplified RF signal in the signal canceller 219 of FIG. 6A; FIG. 6F shows the signal that adjusts the intermodulation signal of FIG. 6E and adjusts the counterphase 35 in the output of the main amplifier 215 as shown in FIG. 6D, and FIG. 6G finally shows the final output with suppression of the intermodulation signal. by coupling the extracted intermodulation signal with the amplified RF signal, all this in reverse phase.

Fig. 3 shows the structure of the pre-distortion circuit 5 213 of FIG. 2. The divider 312 takes part of the RF signal at the input terminal and supplies the Rf (RF; vert.) Sub-signal. An automatic level control (hereinafter referred to as ALC) keeps the level of the input RF signal constant so as to generate constant harmonics independently of variations in the level of the input RF signal. The harmonic generator 314 receives the RF signal with level adjusted in the automatic level control 313 and generates third, fifth, seventh and higher harmonics of the RF signal. A variable attenuation 315 is supplied with the harmonic signal supplied by the harmonic generator 314 and controls the gain of the harmonic distortion by the attenuation control signal ATT3 which is output from the controller 237. The variable phase shifter 316 is supplied with the harmonic signal output by the harmonic distortion circuit under the control of the phase control signal PIC3 supplied by the controller 237. A second delay circuit 311 delays the RF 25 signal input through the main road during the time period in which the pre-distortion occurs. A signal coupler 317 is located between the output terminal of the second retarder 311 and the input terminal of the main power amplifier 214, thereby adding the pre-distortion signal to the delayed RF signal.

The harmonic generator 314, shown in FIG. 3, is constructed with a signal coupler and a Schottky diode. The RF signal is applied to the Schottky diode, the Schottky diode generates the higher harmonics depending on the level of the input RF signal. Accordingly, with the RF signal applied to the Schottky diode being set at a level most desirable for suppressing the intermodulation signal that occurs in the output of the main power amplifier 214. For this purpose, the automatic level control 313 is provided for the connection 5 of the harmonic generator 314 so that the RF signal can always be supplied with a certain level.

The automatic level control 313 controls and delivers the RF signal at a certain level, independent of variations in the level of the RF signal applied to the linear amplifier. Fig. 4 shows the structure of the automatic level control 313 in FIG. 3; a variable attenuator 412 is included between the divider 312 and the harmonic generator 314. The divider 414 is applied to the input terminal of the harmonic 15 generator 314 and supplies a portion of the adjusted level RF signal which is supplied to the harmonic generator 314. The detector 315 converts the RF signal into a DC voltage and applies the converted signal to the level controller 416. The level controller 416 controls the variable attenuator 412 in accordance with the DC voltage supplied by the detector 415 so that the RF signal is always correct. level is applied to the harmonic generator 314.

The detector 415 (Fig. 4) must detect the multiple carrier 25. Detector 415 must be supplied with the RF signal and converted into a DC voltage. Fig. 5 shows the structure of the detector 415 of FIG. 4; an RF transformer 451 is supplied with the RF signal and generates two signals with a mutual phase difference of 180 °; these two signals, supplied by the RF transformer 451, are supplied through lines 452 and 453 to the Schottky diodes 454 and 455, converted to a DC level while the resulting signal is filtered by the capacitor 456 and the resistor 457 and as filtered output signal is output.

i 1006031 15

As to the operation of the circuit of FIGS. 3 and 4: the RF transformer 451 generates signals with a phase difference of 180 ° and the detector 415 generates two signals by separating the input RF 5 signal by half a wave. The Schottky diodes 454 and 455 convert the two signals supplied via transmission lines 452 and 453 to a DC voltage level. Thus, the average power of the multiple carrier is observed without error, so that the level of the RF signal applied to the harmonic generator 314 can be converted exactly into an equal voltage.

The level control 416 generates the control signal depending on the DC voltage of the RF signal output from the detector 415 and supplies the generated control signal to the variable attenuator 412. The level control 314 may be implemented with an operational amplifier. The control signal output in the level control 416 is generated so that the attenuation control becomes stronger as the voltage increases, this in accordance with the DC voltage of the detected RF signal, thereby decreasing the attenuation as this voltage decreases. Thus, the variable attenuator 412 attenuates the RF signal to a certain level independent of the level of the input RF signal and supplies that attenuated signal to the harmonic generator 314.

When the variation of the level of the supplied RF signals is 10 dB, the operating range of the automatic level control 313 must be such that the level is controlled above at least 10 dB. The output level of the RF signal from the automatic level control 313 must be set to optimally suppress the intermodulation signal generated by the harmonic generator 314 in the main power amplifier 214 as the pre-distorted signal. Since the harmonic generator 314, which supplies the output signal of the automatic level control, receives the RF

1006031 16 receive signal at a defined level, stable harmonics can be generated. To the extent that the harmonics output by the harmonic generator 314 are input to the main amplifier 214 coupled to the RF signal, the main amplifier 214 can prevent harmonics from occurring when amplifying the RF signal.

When inputting the harmonics to the main amplifier 214 as described above, it must be possible to set magnitude 10 and phase location of the harmonics during amplification. The variable attenuator 315 and the variable phase shifter 316 (Fig.

3) adjust the harmonics as desired.

The controller 237 controls the signal selector 235 and 15 selects to output the main amplifier 214 to the divider 232, and the signal detector 236 detects the RSSI of the intermodulation signal in the output of the main amplifier 214 - see Fig. 6D. After comparing and analyzing the RSSI value of the intermodulation signal output in the signal detector 236 with the RSSI value of the previous state, the attenuation control signal ATT3 and the phase control signal PIC3 are generated so that the suppression of the intermodulation signal by the main amplifier 214 proceeds smoothly.

Thereafter, the variable attenuator 315 adjusts the amplitude of the pre-distorted signal generated in the harmonic generator 315 by the attenuation control signal ATT3, and the variable phase shifter 316 adjusts the phase so that the pre-distorted signal can be applied to the main amplifier 214 in counter-phase. supplied. Adjusted in this way, the harmonic signal of FIG. 6D is generated in the generator 314 with proper amplitude and phase and the signal coupler 317 applies the intermodulation signal to the input terminal of the main amplifier 214. Then, as shown in FIG. 3, the second retarder 311 for delaying the input RF signal, delaying the RF signal until the pre-distorted signal is coupled to the input terminal of the main amplifier 214. It is preferred the position where the intermodulation signal is coupled to the RF signal as shown in FIG. 6 can be selected with a reverse phase at the input terminal of the tracing transistor in the main amplifier 214.

As mentioned, the pre-distortion 213 gives a "prediction" regarding the intermodulation signal that will be generated in the main power amplifier 214 for generating the pre-distorted signal and controls phase and attenuation of the harmonics to prevent the generation of a maximum intermodulation signal, and supplies the attenuated and phase-controlled signal to the main amplifier 214. The pre-amplifier 213 mainly eliminates the third harmonics which are generated the highest level between the harmonics that could be formed in the main amplifier 214. Eliminating the intermodulation signal in the pre-distortion system can significantly eliminate the intermodulation load of the signal by applying the pre-coupling system. Insofar as the adjustment of the pre-feedback system is done accurately, the pre-distortion system gives an improvement of a few dB.

After suppressing the intermodulation signal that is distorted in the main power amplifier 214 by the pre-distortion system as described above, the intermodulation signal that cannot be suppressed in second instance by the pre-coupling system is suppressed. In the feed-back system, the steps for reducing the intermodulation signal from the main power amplifier 214 can be divided into two steps. One is to eliminate the pure intermodulation signal distortion by neutralizing the input RF signal and the output of the main amplifier 214. The other is neutralizing the intermodulation signal distortion in the output of the 1 0 0 <5 0 3 1 18 main amplifier 214 after correction of amplitude and phase of the extracted intermodulation signal to reduce the intermodulation signal in the output signal which eventually takes the perfect shape.

5 First, an explanation will be given of the first step of the feed-back system. The on-the-way signal divider 216 divides the RF signal applied as shown in Fig. 6A in the under-way, and the first delay unit 217 delays the RF signal divided into the divider 216 for the time required for the pre-distortion and RF gain, after which the delayed signal is applied to the signal canceler 219. Thus, the RF signal distortion of FIG. 6A performed from the first delay 217 is neutralized with the RF signal distortion of the amplified signal of FIG. 6D, which is shared in the divider 218 to extract and output the pure intermodulation distorted signal.

The signal canceler 219 as the core of the forward link system is for detecting only the intermodulation signal in the main power amplifier 214. The signal canceler 219 may be constructed as a subtractor or as a summing device. When the circuit is constructed as a subtractor, two RF signals must be input with the same phase. When the circuit 219 is constructed as a summing device, the two RF signals must be input in reverse phase. In the preferred embodiment, the signal canceller 219 is not constructed as a subtraction circuit, but as a summing device. In that case, the subtractor circuit has a signal coupler, a signal of the two RF signals is applied to the signal coupler having the same phase as the other signal, and the other signal is inverted in phase, the reverse signal being applied to the signal coupler. When the RF signal of Fig. 6A and the RF signal of Fig. 6D are applied to the signal canceller 219 which is designed as a subtractor, the two distorted RF signals will have an equal phase so that the RF signal is neutralized and only the intermodulation distortion signal is supplied.

Here, the levels and phases of the two RF signals supplied to the signal canceler 219 must be exactly the same. For this purpose, the amplified RF signal output in the main amplifier 214 of the main signal path and the RF signal input through the on the way must have the same group delay and delay characteristics, preferably avoiding phase distortion of the RF signal.

As described, when the level and phase of the RF signal supplied in the first delay 217 and the output of the main amplifier 214 are not exactly matched, the RF signal is not accurately removed in the signal canceller 219. To prevent this, the first variable attenuator 211 in Fig. 2 adjusts the level of the RF signal input by the attenuation control signal ATT1 output in the controller 20 237 and the second variable phase shifter 212 adjusts the phase of the RF signal input by the phase control signal PIC1 output by the controller 237. The first variable attenuator 211 and the second variable phase shifter 212, respectively, adjust the phase and level of the RF signal in the way to that of the main road RF signal. The signal canceller 219 then mutually neutralizes these two RF signals which are supplied with the same level and phase.

for controlling phase and level of two RF 30 signals, the controller 237 supplies a switching control signal SWC for selecting a third signal SF3 for the signal selector 235 and outputs the control data PCD for the detection of the RSSI of the RF signal distortion of the third signal SF3 in the signal detector 236. Accordingly, the signal selector 235 selectively selects the third signal SF3 as the output of the signal canceller 219, dividing the output of the signal selector 219 into the divider 233, and generates the signal selector 236 the RSSI, which converts the RF signal distortion of the third signal SF3 into a DC voltage. The controller 237 generates the attenuation control signal ATT1 and the phase-5 control signal PIC1 to attenuate the RF signal distortion in the signal canceller 219.

The first variable attenuator 211 attenuates the input RF signal by determining the attenuation factor via the attenuation control signal ATT1, and the first variable phase shifter 212 controls the phase of the input RF signal via 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 of the RF signal to be output to the signal canceler 219 and the preceding RSSI controls the first variable attenuator 211 and the first variable phase shifter 212 two RF signals according to Fig. 6D and 6A such that these RF signals ultimately have the same phase and level.

The reason for canceling the RF signal in the signal canceller 219 is that it should not affect the error amplifier 222 connected thereto so that, when the RF signal is completely suppressed, only the intermodulation signal distortion remains. If the RF signal is not effectively eliminated, if a relatively high level RF signal is applied to the error amplifier 222, it may be damaged.

The second step of the feed-back system is as follows: the intermodulation signal output by the signal canceller 219 receives phase and level adjusted in the second variable attenuator 220 and the second variable phase shifter 221 and the intermodulation distortion still present in the output signal 35 of the main amplifier is removed by inserting the thus adjusted signal into the main signal path. The intermodulation signal input through the signal coupler 1006031 21 to 223 must be in phase opposition to the amplified and output signal.

The controller 237 generates the switching control signal SWC for selecting the fourth signal SF4 as the final output signal which is shared in the divider 234 and resulting in the control data PCD for the detection of the RSSI of the harmonics of the intermodulation signal of the fourth signal SF4. The signal selector 235 selectively outputs the fourth signal SF4 through the divider 234 under the influence of the switching control signal SWC, the signal detector 236 and goes to the controller 237 to detect the RSSI of the harmonics of the fourth signal SF4 by the control data PCD. The controller 237 compares and analyzes the RSSI of the intermodulation signal in the final output signal with the RSSI of the previously obtained intermodulation signal so that the attenuation control signal ATT2 and the phase control signal PIC2 suppress the final intermodulation signal depending on the result of the analysis can be adjusted.

The second variable attenuator 220 through which the output of the signal canceler 219 passes adjusts the level of the intermodulation signal under the influence of the attenuation control signal ATT2 and the second variable phase shifter 221 to which the signal output by the second variable attenuator 220 is applied the phase of the intermodulation signal via the phase control signal PIC2. Then, the second variable phase shifter 221 controls the phase of the intermodulation signal such that it has the reverse phase of the signal on the coupler 223 by means of the phase control signal PIC2. The error amplifier 222 between the second variable phase shifter 221 and the signal coupler 223 amplifies and provides the intermodulation signal with level and phase adjusted as described above.

1006031 22

The linear power amplifier according to the described embodiment of the invention uses the pre-torque system and the pre-distortion system to suppress the intermodulation signal occurring in the gain signal. To suppress the intermodulation signal, the intermodulation signal that could be generated in the main amplifier 214 is pre-suppressed by the pre-distortion system, and thus the intermodulation signal occurring in the output of the main power amplifier 214 is detected by the pre-coupling system, thereby coupling the detected signal with the final output signal and reducing the intermodulation signal step by step. When the intermodulation signal is suppressed only by the feed-back system because the design and construction of the main amplifier 214 and the error amplifier 222 are difficult, an intermodulation signal of certain amplitudes is pre-suppressed by the pre-transmitter 213 and the rest of the 20 intermodulation signals are then suppressed by the forward coupling system. This can facilitate the design and construction of the linear power amplifier.

In the following, the steps of suppressing the intermodulation signal using the feed-down system and the pre-distortion system focused on the controller 237 will be described concretely.

Fig. 7 shows the structure of the signal detector 236 30 in FIG. 2.

The attenuator 711 attenuates an SF signal from the signal selector 235. A filter 712, which is a wide pass band filter, filters the signal in the pass band. A phase lock loop (hereinafter referred to as 35PLL) 713 with the oscillator 714 generates a corresponding local frequency LF1 through the control data PCD supplied by the controller 237. Said local 1006031 23th frequency LF1 determines the detection frequency for the RSSI of the selected SF signal. A mixer 715 mixes the signal from the filter 712 with the local frequency LF1 and generates the intermediate frequency IF. A filter 716,5 acting as an intermediate frequency filter filters a subtracting signal SF-LF1 from the two frequencies in the output of the mixer 715 and in this way generates an intermediate frequency LF1 as a filtered signal. An oscillator 719 generates a fixed local frequency LF2. The mixer 718 10 mixes the intermediate frequency LF1 output from the intermediate frequency amplifier 717 to the intermediate frequency IF2. The filter 720 filters a signal IF1 - IF2 from the two frequencies in the output of the mixer 718 and supplies the filtered signal as local frequency LF2. A logarithmic amplifier 721 converts the intermediate frequency IF2 output from the filter 720 into a DC voltage and generates it as the RSSI signal.

As to the operation of Fig. 7: the signal selector 235 selectively outputs the corresponding RF sig-20 sew as one of the signals from the first through fourth signals, SF1 through SF4, by the switching control signal SWC of the controller 237. The filter 712 of the signal detector 236 filters the RF signal and supplies the filtered RF signal to the mixer 715. The PLL 713 and the oscillator 714 generate the local frequency LF1 for the choice of the RF signal or the harmonics of the signal selected by the control data PCD1 of the controller 237. Accordingly, the mixer 715 mixes the SF and local frequency LF1 30 signals and the filter 716 filters the frequency corresponding to the subtraction of these two signals and provides the filtered frequency as intermediate frequency IF1. The structure as described above determines the frequency for the detection of the RSSI in the selected SF signal and simultaneously performs the frequency down-conversion.

1006031 24

The mixer 718 mixes the local frequency LF2 of the oscillator 719 and the intermediate frequency IF1 and the filter 720 filters the frequency corresponding to the difference between the intermediate frequency IF1 and the local frequency LF2 to the second intermediate frequency IF2. The down-conversion in the second step takes place via this structure. The logic amplifier 721 receives the intermediate frequency IF2 as an input signal and converts the supplied intermediate frequency IF2 into the DC voltage to be output. The output signal then becomes the RSSI.

Fig. 8 shows the structure of the controller 237 of FIG. 2. According to FIG. 8, an analog-to-digital converter 814 (hereinafter referred to as ADC) converts the RSSI output in the signal selector 236 into the digital data to be output. An exclusively readable memory 812 (hereinafter referred to as ROM) has stored the attenuation and phase control program in this embodiment. A central processing unit (CPU) generates the control data PCD for selecting the frequency for choosing the desired RSSI in the selected SF signal and the switching control signal SWC for choosing the RF signal, depending on the program in ROM 812, and generates the attenuation control signals ATT and phase control signals PIC after a comparison and analysis of the RSSI performed in the ADC 814. A random access memory 813 (RAM) temporarily stores all kinds of data generated during the execution of the program. A digital-analog converter 815 (DAC) converts the attenuation control data and phase control data 30 output in the controller 811 into analog data and outputs the converted data as attenuation control signals ATT and phase control signals PIC. A communicator 816 provides status information regarding the linear power amplifier under the control of CPU 816.

FIG. 9 is a flow chart illustrating the operation of level and phase adjustment under the control of the above variable attenuators and the variable phase shifters by the controller 237 according to an embodiment of the invention. In Fig. 9, attenuation values are plotted along the x axis and phase variation values along the y axis. When changing the value of the variable attenuator from Pa to Pb at the point where the RSSI is input, as the amplitude of the detected signal decreases, the phase variation value changes from Pb to Pc. Then, when the variable attenuator value changes from Pc to Pd at the point where the RSSI is input, when the detected signal is magnified again, the phase variation value will change in the direction of Pc. Here, Pc is the point where the magnitude of the attenuation value is temporary. When the phase variation value changes from 15 Pc to Pe and the amplitude of the detected RSSI decreases, the variable phase shift shifts the phase variation value in the direction of Pf.

When attenuation and phase are repeatedly controlled in the manner described above, a value 20 can be found for the variable attenuator and the variable phase shifter in which the detected SF signal is minimal. Fig. 10 is a flow chart for the operation of the variable attenuator and the variable phase shifter of the controller 237 in the described embodiment. As shown in Fig. 10, after an initial control of the phase of the detected signal, the attenuation of the signal is performed. However, it is also possible to control the phase of the signal after its attenuation.

As shown in Fig. 10, the steps for eliminating the intermodulation distortion are roughly quartered. First, the RSSI of the first signal SF1 is detected, a channel in which the RF signal is detected in the transmitter band is set, thereby determining 35 service channels. Second, the RSSI of the second signal SF2 is detected and the high power amplifier 214 suppresses the intermodular signal to amplify the received RF signal, thereby generating the pre-distorted signal. Third, the RSSI of the third signal SF3 is detected, and thus the intermodulation signal 5 for neutralizing the RF signal distortion in the signal canceler 219 is detected. Fourth, the RSSI of the fourth signal SF4 is detected and the intermodulation signal contained in the final output signal output to the main amplifier 214 on the main road can be suppressed.

Fig. 11A through 11C show the characteristics of the frequency adjustment to control the attenuation and the phase of the signal, FIG. 11A showing the second signal SF2 as the output signal of the main amplifier 214, which signal is shared by the signal coupler 232; Fig. 11B shows the signal SF3 as the signal shared in the signal coupler 232, and Fig. 11C shows the fourth signal SF4 as the final output signal from the signal coupler 224.

As shown in Figs. 10 and 11, the controller 237 controls the initialization operation of the linear power amplifier in step 100. After initializing, CPU 881 reads the voltage values of the attenuation control signals ATT1 through ATT3 and the phase control signals PIC1 through PIC3 with the associated specific voltages and frequencies, stores the readout 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 the transmit channel and the service channel information. The initialization as described above is carried out only the first time the linear power amplifier is turned on.

When the initialization is complete, CPU 35811 outputs the switching control signal SWC for selecting the first signal SF1 outputted in the divider 231 for determining the service channel in step 1011 and outputs the control data PCD for the selecting the first channel of the transmitter band in step 1013. In that case, the signal selector 253 selectively supplies the first signal SF1 by the switch control signal SWC and the signal detector 236 detects the RSSI for the first channel frequency via the control data PCD. Thereafter, the controller 237 stores the received RSSI in the set channel in the corresponding channel area of RAM 813 in step 1015 and increments the channel tuner to detect the RSSI of the next channel in step 1017. Scanning the channels as described above is performed up to the last channel of the transmitter band with repeated steps 1011 through 1019.

Regarding the channel selection operation described above, the controller 237 detects the RSSI detected in each channel and stores the detected RSSI by sequentially increasing the channel number from the first channel to the last channel over the total of the channels of the channel. transmission band. In the case where the mobile communication system is a code multiplex accessible system (such as the CDMA system), the transmission band is from 869.640 MHz to 893.19 MHz and the channel interval is 1.23 MHz. In the case of the CDMA system, the band of the first signal SF1 is 869.640 MHz to 893.19 MHz, and the control data PCD must indicate the first signal SF1 of the first channel frequency 869.640 MHz as the 20th channel frequency, 893.10 MHz in an interval of 1.23 MHz in sequence. In the CDMA system, the controller 237 detects the RSSI of the designated channel and stores the detected RSSI in RAM 813, sequentially designating each channel frequency of the transmission band from 869.640 MHz to 893.19 MHz during the channel scan.

When the channel scan is finished, the controller 237 sums the RSSI of all channels stored in RAM 813 in step 1021 and calculates the average value 1 0 0 6 0 3 1 28 by dividing the total value of the RSSI of all channels by the number of channels in step 1023. Thereafter, in steps 1015 to 1035, controller 237 determines the service channels. Regarding the steps of determining the service channel, the controller 237 has access to the RSSI values of each channel stored in RAM 823 and compares the engaged value with the average value. After checking in step 1027 that the RSSI of the channel is higher than the average value, the controller 237 checks in step 1029 whether or not the RSSI value of the corresponding channel is higher than a reference value + a. It is assumed that a = 3 dB.

If the RSSI value of the present channel is higher than the average value and the reference value in the aforementioned steps 1027 and 1029, the control in step 1029 checks whether the RSSI value of the corresponding channel is more than 30 dB higher than the reference value + a . This is to ensure that the channels have the reliable signal distortion of the service channel 20 even when the detected RSSI value is higher than the average value. When the RSSI value of the present channel is more than the average value and the reference value + a, the controller 237 sets the corresponding channel as the service channel in step 1031. Under 25 repeating steps 1025 through 1035, the controller checks 237 the size of the RSSI of all channels and sets the service channels.

After selecting the first signal SF1 as described above, the controller 30 237 detects and analyzes the RSSI value of all channels of the band of the first signal SF1, and sets and stores the channel to be transmitted and operated. Thereafter, the controller 237 amplifies and outputs the RF signals from the set service channels. For the sake of simplicity, however, it will be described how two consecutive channels are treated in the present embodiment. The frequency of the RF signal of each channel is assumed to be fl and f2, and the intermodulation signal is designated IM1 and IM2.

In steps 1111 through 1163 in Fig. 10, the controller 237 checks the intermodulation signal 5 present in the output of the main amplifier 214 and controls the variable attenuator 315 and the variable phase shifter 316. The pre-distortion 213 generates the pre-distortion signal to suppress the intermodulation signal that could be generated at amplification in the main amplifier 214, and the controller 237 detects the RSSI of the intermodulation signal contained in the output of the main power amplifier 214 and controls phase and level of the pre-distorted signal such that the intermodulation signal in main amplifier 214 can be well suppressed. In the present embodiment, after detecting the RSSI of the intermodulation signal output in the main power amplifier 215, it is assumed that the controller 237 compares the detected value of the RSSI of the intermodulation signal with the previous state, and performs a three-step control. in accordance with the comparison results. Here it is assumed that the ADC 814 and ADC 815 are 16-bit converters, the first step is set to three steps, the second 25 step to ten steps and the third step to 20 steps. The step becomes a quantization step in A / D conversion. At the time the initial level and phase are controlled, the controller 237 increments the phase and attenuation control signal by one step and the RSSI of the IM signal from the second through the Xth control operations is detected. The controller 237 controls as the first step in the case where the comparison difference is below ten stages, it controls the second step in which the comparison difference is below 20 stages, and it controls as the third step in the case where the comparison difference is above 20 stages. as mentioned above, the operation of controlling 1006031 level and phase of the pre-distortion signal X is performed successively.

The controller 237 outputs the switching control signal SWC for the selection of the second signal SF2 in step 5 1111. The signal selector 235 selects the signal of Fig. 11A output in the main amplifier 214, thereby supplying the selected signal to the signal detector 236. In step 1113, the controller 237 checks whether or not the value of the HG count has reached 0. At this time, the HG count counts the suppressed number of the intermodulation signal contained in the main amplifier 214. When the value of the HG count is found to be 0, the control 237 outputs the phase control signal PIC3 as the phase 15 control signal PPPIC3 (vert. ) + 1 step value from the previous state in step 1115, and converts the phase control signal PIC3 into the analog signal in DAC6 of the DAC 815 to be then fed to the variable attenuator 316. Thus, the variable attenuator 20 sets 316 213 adds the phase of the pre-distortion signal output by the harmonic generator 314 through the phase control signal PIC3 and applies the adjusted level to the input terminal of the main amplifier 214. In step 1117, the controller 237 25 stores the phase control signal PIC3 as the previous phase control signal PPIC3. for the next state. In step 1119, the controller 237 supplies the phase control signal ATT3 as the attenuation control signal PATT3 + 1 of the previous state and converts the phase control signal ATT 3 into an analog signal through DAC5 to be applied to the variable attenuator 315. Then, the variable sets attenuator 315 of the pre-distortion 213 enters the level of the pre-distortion signal supplied to the harmonic generator 314 by the attenuation control signal ATT3 and inputs the adjusted level up to the input terminal of the main amplifier 214. Then, the controller 237 stores the attenuation signal ATT3 1006031 31 as the previous attenuation control signal PATT3 in step 1121.

Thus, it appears that the first phase and level control of the pre-distortion signal is performed by applying a stage to the previous control signal. However, the corresponding control signal may reappear when comparing the difference between the currently detected control signal and the previous control signal. After controlling phase and level of the pre-distortion signal in the manner described above, the controller 237 increases the HG count in step 1161.

After controlling the phase and level of the pre-distortion signal as described above, the controller 237 again performs steps 1123 through 1135, detects the RSSIs of the intermodulation signals IM1 through IM4 in the output of the main amplifier 214 and selects in step 1139 the intermodulation IM with the highest RSSI value.

To satisfy this, the controller 237 sequentially outputs the control data PCD for designating the signals IM1 through IM4 as intermodulation signals in the output signal of the main amplifier 214 supplied to the signal detector 236, as shown in FIG. 11A, and receives and remembers the RSSI value 25 of the corresponding intermodulation signal IM1 through IM4.

Subsequently, in step 1141, the controller 237 compares the RSSI of the IM signal selected with the phase control signal PPIC3 of the previous state. At this time, when the IM signal is higher than the phase control signal PPIC3, the controller 237 sets in step 1143 that the phase control value is to be decreased and, when the IM signal is less than the phase control signal PPIC3, the control 237 sets the phase control value. in step 1145 should be increased. After adjusting the increase / decrease of the phase control, the controller 237 in step 1147 obtains the difference between the value 1006031 32 of the IM signal and the phase control signal PPIC3 in the previous step, thereby, depending on the result of this subtraction operation, the phase control signal PIC3 exciting. The phase control signal PIC3 is applied via DAC 815 to the variable phase shifter 316. Thereafter, the controller 237 stores the phase control signal PIC3 as the "previous" phase control signal PPIC3, to be used in the next step.

In addition, after generating the phase 10 control signal PIC3 as explained above, the controller 237 compares the RSSI of the selected IM signal with the attenuation control signal ΡΑΊΤ3 of the previous state in step 1151. Then, when the IM signal is higher than the attenuation control signal PATT3 controller 237 15 sets the attenuation control signal to be decreased in step 1153. On the other hand, when the IM signal is lower than the attenuation control signal PATT3, the controller 237 states that the attenuation control signal must be increased in step 1155. After setting the increase / decrease of the attenuation control signal, the controller 237 obtains the difference between the value of the IM signal and the attenuation control signal PATT3 from the previous state in step 1157, thereby corresponding to the subtract operation the attenuation control signal ATT 3 exciting. The attenuation control signal ATT3 is supplied through DAC 815 to the variable attenuator 315. Thereafter, the controller 237 stores the attenuation control signal ATT3 as the "previous" attenuation control signal PATT3 in step 1159.

Then, in step 1161, the controller 237 increases the HG

count with one and check whether or not the HG count becomes the X value. When the HG count does not become equal to the X value, the controller 237 returns to step 1071, repeating the steps 35 described above. Repeating these steps, the controller 237 detects the RSSI of the intermodulation signal present in the output of the high power amplifier 1006031 33 214 and thereby adjusts phase and level of the pre-distortion signal by comparing it with phase and attenuation control signals PIC and ATT and determining the control direction and control size. The pre-distortion signal is applied in counter-phase with the intermodulation signal to be generated in the main amplifier 214. When adjusting phase and level of the pre-distortion signal, the controller 237 prevents the generation of the intermodulation signal and, when the HG 10 becomes count X, completes the operation of adjusting the pre-distortion signal.

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

Referring to FIG. 10, the controller 237 in steps 1211 through 1255 detects the RF signal distortion occurring in the output from the signal canceler 219 and controls the first variable attenuator 211 and the first variable phase shifter 212. The signal canceler 219 neutralizes the output signal of the signal canceller 219. main amplifier 214 as shown in Fig. 11A and the RF signal to be input and only detects the gain generated intermodulation signal. Here, the controller 237 detects the RSSI of the RF signal contained in the output of the signal canceller 219 (see Fig. 11B) and variably controls the level and phase of the RF signal to gradually suppress the RF signal in the signal canceller 219 In the present embodiment, after detecting the RSSI of the RF signal output in the signal canceller, the controller 237 compares the detected value with the RSSI of the RF signal in the previous state and performs this control in three steps, depending on the result of the comparison. The ADC 814 is assumed to be a 16-bit converter, and then the first step is three stages, the second step is ten stages, and the third step is 1006031 34 stages. The stage becomes the quantization stage in the A / D conversion. When phase and level are first controlled, the controller 237 controls phase and level as the first step independently of the RSSI actually detected, it controls as the first step in the case where the comparison difference is less than ten stages, if second step in the case where the comparison difference is less than 20 steps and third step in the case where the comparison difference is greater than 20 steps. As described above, the operations of controlling the level and phase of the pre-distortion signal X are performed successively.

The controller 237 outputs the switching control signal 15 SWC for the selection of the third signal SF3 in step 1211. The signal selector 235 selects the signal of FIG. 11A which is applied to the signal canceller 219, thereby supplying the selected signal to the signal detector 236. Thereafter, the controller 20 237 detects and analyzes the RSSI of the intermodulation signal contained in the signal canceller 219 and controls the first variable attenuator 211 and the first variable phase shifter 212 and adjusts level and phase of the RF signal.

The controller 237 checks in step 1212 whether the subt count is set to 0. The subtitle counts the number of canceling the RF signal in the signal canceller 219. When the subtitle value is 0, the controller 237 supplies the phase control signal PIC1 as the phase control signal PPIC1 + 1 stage of the previous signal to be set in step 30 1215. are stored and converts the phase control signal PIC1 into the analog signal through DAC2 of DAC 815 for supply to the first variable phase shifter 212. Thus, the first variable phase shifter 212 adjusts the phase input of the RF signal by the phase control signal PIC1 and supplies the adjusted phase to the main amplifier 214. In step 1217, the controller 237 stores the phase control signal PIC1 as 1006031 35 the "previous" phase control signal PPIC1 for the next state. Furthermore, the controller 237 supplies the attenuation control signal ATT1 as the attenuation control signal PATTI + 1 stage of the previous state in step 1219, and 5 converts the attenuation control signal ATT1 into the analog signal by DAC1 to then be applied to the variable attenuator 315. Thus, the first variable attenuator 211 updates the level of the input RF signal through the attenuation control signal ATT1 and supplies the adjusted level to the main amplifier 214.

The first phase and the first level of the RF signal as described above is controlled by adding a stage to the control signal of the previous state. However, the corresponding control signal 15 can occur when comparing the difference between the currently detected control signal and the control signal of the previous state. After controlling phase and level of the RF signal in the manner described above, the controller 237 increases the subtelling in step 20 1253.

On the other hand, when it is determined in step 1211 that the SUB count is 0, the control 237 sequentially provides the control data PCD for indicating the signals f1 and f2 in the output signal of the signal canceler 25219 of Fig. 11B, receives the RSSI value of the corresponding signal fl and f2 and stores them. The controller 237 selects the f signal with the largest RSSI value from the f1 and f2 signals in step 1231.

Thereafter, the controller 237 compares the RSSI of the selected f signal with the phase control signal PPIC of the previous state in step 1233. Then, when the f signal is greater than the phase control signal PPIC1, the controller 237 controls that the phase control value must be decreased in step 1235 and when the f signal is lower than the phase control signal PPIC1, the controller 237 controls that the phase control value is increased in step 1237. After setting the increase / decrease of the phase control 1006031 36, the controller 237 obtains the difference between the value of the f signal and the phase control signal PPIC3 from the previous state in step 1239, thereby corresponding to this difference formation the phase control signal 5 PICl exciting. The phase control signal PIC1 is supplied through the DAC 815 to the first variable phase shifter 212. Thereafter, the controller 237 stores the phase control signal PIC1 as the "previous" phase control signal PPIC1, to be used in the following state.

After generating the phase control signal PIC1 in step 1243, the controller 237 compares the RSSI of the selected f signal with the value of the attenuation control signal PATT1 in the previous state. When the f signal is higher than the attenuation control signal PATT1 15, the controller 237 controls that the attenuation control signal PATT1 is lowered in step 1245 and, when the f signal is less than the attenuation control signal PATT1, the controller 237 causes the attenuation control value PATT1 in step 1247. After adjusting the attenuation / attenuation of the attenuation control, the control 237 forms the difference between the value of the f signal and the attenuation control signal PPIC1 of the previous state in step 1249, thereby corresponding to this difference formation the attenuation control-25 signal ATT1 exciting. The attenuation control signal ATT1 goes through DAC 815 to the first variable attenuator 211. 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 in step 1253, the controller 237 checks whether or not the SUB count becomes the Y value. If the SUB count does not become the Y value, the controller 237 returns to step 1223, thereby again performing the steps described above. When repeating the above steps, the controller 237 detects the RSSI of the RF signal contained in the signal canceller 219 and 1006031 37 thereby adjusts phase and level of the RF signal by comparing the RSSI of the RF signal performed in the previous phase by the signal canceller 219 and determining the direction and size of the control to be performed. When adjusting phase and level of the RF signal, the controller 237 prevents the generation of an RF signal so that, when the SUB count becomes Y, the operation of suppressing the RF signal in the signal canceller 219 is completed.

As indicated in Fig. 10, the controller 237 in steps 1311 through 1363 detects whether the f signal is higher than the attenuation control signal PATT1, the controller 237 sets the attenuation control signal PATT1 in step 1245 and sets when the f 15 is signal is lower than the attenuation control signal PATT1 that the attenuation control signal is increased in step 1247. After determining the increase / decrease of the attenuation control, the controller 237 obtains the difference between the value of the f signal and the attenuation control signal PPIC1 from the previous state in step 1249, thereby corresponding to the result of this difference formation the attenuation control signal. ATT1 exciting. The attenuation control signal ATT1 is supplied through DAC 815 to the first variable attenuator 211. In step 1251, the controller 237 then stores the attenuation control signal ATT1 as the previous attenuation control signal PATT1.

After increasing the SUB count by one in step 1253, in step 1253 the controller 237 checks whether or not the SUB 30 count becomes equal to the Y value. If the SUB count does not become the Y value, controller 237 goes back to step 1223, repeating the steps described above. While repeating these steps, controller 237 detects the RSSI 35 of the RF signal contained in the signal canceler 219 and controls phase and level of the RF signal by comparing the RSSI of the signal supplied by the signal canceler 219 in the previous phase. RF signal and determining the direction and size of the control. By adjusting phase and level of the RF signal, the controller 237 prevents an RF signal from being generated and completed when the SUB count Y becomes the operation of suppressing the RF signal in the signal canceller 219.

In Fig. 10, the controller 237 in steps 1311 through 1363 detects the intermodulation signal IM 10 occurring in the RF signal as ultimately supplied by the main amplifier 214 and controls the second variable attenuator 220 and the second variable phase shifter 221. The RF signal output by the main amplifier 214 is compensated via the second delay 215 during the time in which the intermodulation signal detected is processed in the on-way, and the intermodulation distortion occurring in the RF signal which is finally output is suppressed by reverse phase feedback via the signal coupler 223 of the intermodulation distortion signal. This ensures that the intermodulation distortion is suppressed. The controller 237 detects the RSSI of the intermodulation signals IM1 through IM4 in the output of the main amplifier 214 (see FIG. 11C) and controls phase and level of the intermodulation signals IM1 through IM4 such that intermodulation signal distortion in the final output RF signal is suppressed. According to the invention, after detecting the RSSI of the intermodulation signals IM1 to IM4 occurring in the final amplified and output RF signal, the controller 237 assumes that the detected value of the RSSI of the intermodulation signals IM1 to IM4 of the previous one is assumed. condition compares and performs the three-step control operation depending on the comparison results. Assuming that the ADC 814 is a 16-bit converter, the first step has three stages, the second step has ten stages, and the third 1006031 has 39 stages. At A / D conversion the stage becomes the quantization stage. When the initial level and the initial phase are controlled, the controller 237 increments the phase and attenuation control signal by one step and the RSSI of the IM signal is detected from the second control to the Xth control. The controller 237 controls it as a first step in the case where the comparison difference is less than ten stages, as a second step in the case where the comparison difference is less than 20 stages, and as a third step when the comparison difference is within 20 stages. The operation of controlling the level and phase of the pre-distortion signal is performed Z times in succession.

As shown in Fig. 10, steps 1311 through 1363 are performed in the same order as steps 1111 through 1163 for adjusting the level and phase of the pre-distortion signal. The controller 237 controls the signal selector 235, selects the fourth signal 20 SF4, controls the signal detector 236 and sequentially selects the intermodulation signals IM1 through IM4. Thereafter, the controller 237 successively receives the RSSI # s of the intermodulation signals IM1 through IM4 detected in the signal detector 236. After selecting the intermodulation signal IM1 with the largest RSSI in the received intermodulation signals IM1 through IM4, the controller 237 compares the RSSI of the currently detected intermodulation signal IM with the corresponding intermodulation signal 1m of the previous state. The controller 237 controls the second variable phase shifter 221 and the second variable attenuator 220 with the phase control signal PIC2 and the attenuation control signal ATT 2 in accordance with the comparison result between the two intermodulation distortions. Then, the controller 237 controls the second variable attenuator 220 and the second variable phase shifter 221 Z times.

1006031 40

The linear amplifier according to the invention, as shown in FIG. 10, sets the service channels and sets the level and phase of the pre-distortion signal to suppress the intermodulation signal generated in the main amplifier 214 in a sequential manner. The amplifier controls phase and level of the RF signal input to the main road to suppress the RF signal in the signal canceller 219, with the level and phase of the intermodulation signal 10 supplied by the signal canceller 129 such that the intermodulation signal in the eventually amplified and output RF signal is suppressed.

As described, in this embodiment, first of all, a selection is made of the service channels, then phase and level of the pre-distortion signal are controlled, then phase and level of the input RF signal are controlled, and fourth, phase and level of the intermodulation signal distortion in the signal canceller 219 controlled. In another embodiment, the operation of selecting the service channels can be performed through a time interrupt in a given time interval. When this control method is used, the controller 237 performs the service channel search operation when the time interrupt 25 is generated and the variable attenuator controls its variable phase shifters in the remaining periods. When the time interrupt is generated during the control of the variable attenuator and the variable phase shifter, the controller 237 interrupts this operation and executes the time interrupt routine, returning to the main routine and continuing the operation.

The number, X, Y and Z, of the times on which the variable attenuators and phase shifters are controlled can be set as the number by which effective control is obtained of the level and phase of the signal applied to the corresponding variable 1006031 41 attenuators and variable phase shifters and this number can each be set to 5.

Fig. 12 is a block diagram of a linear power amplifier according to a second embodiment. The linear power amplifier according to this second embodiment has the same structure as the first embodiment; the difference is that the first variable attenuator 211 and the first variable phase shifter 212 are disposed in an underway.

As shown in FIG. 12, the main road pre-distortion 213 has the same structure as that shown in FIGS. 3 and 5, generates harmonics corresponding to the input RF signal, controlling level and phase of the harmonics depending on the attenuation control signal ATT3 and the phase control signal PIC3 from the controller 237, supplies the controlled signals to the input RF signal, converts the input signals into the pre-distorted RF signal and supplies the converted signals to the main amplifier 214. The main amplifier 214 is supplied with the output voltage from the pre-distortion 213 , amplifies the preformed RF signal and delivers an RF signal that suppresses intermodulation signal distortion.

The rest of the structure of the linear power amplifier is equal to that of the first embodiment of Fig. 2 except for the above mentioned differences. The reference numbers used in this second embodiment are therefore the same as those used in the first embodiment. Furthermore, the controller 237 selectively supplies the first signal SF1 through fourth signal SF4 in the manner described with reference to Fig. 10 and generates attenuation control signals ATT1 through ATT3 and phase control signals PIC1 through PIC3 with detection of the RSSI of the RF 35 signal or the interraodulation signal in the selected SF signal. After setting the service channels, the controller 237 successively adjusts phase and level of 1005031 42 the distortion signal to suppress the intermodulation signal formed in the main amplifier 214, adjusts the level and phase of the RF signal input in the way to suppress the RF signal distortion in the signal canceller 219 and finally adjusts level and phase of the intermodulation distortion in the signal canceller 129 (219; vert.) To suppress the intermodulation distortion in the amplified and finally output RF signal.

FIG. 13 shows in block diagram form the construction of a linear amplifier according to a third embodiment. This amplifier has the same structure as the second embodiment; the difference is that the first variable attenuator 211 and the first variable phase shifter 212 are disposed between the main road and the underway.

The main road pre-transducer 213 has the structure shown in FIGS. 3 and 5 and generates the harmonics of the input RF signal, level and phase of the harmonics are driven by the attenuation control signal ATT3 and the phase control signal PIC3 of the controller 213; the controlled signals control the input RF signal and the converted signal is supplied to the main amplifier 214. The main amplifier 214 is supplied with the output of the pre-scrambler 213 and supplies the RF signal in which the intermodulation distortion is suppressed.

The first delay 217 in the way is supplied with the shared RF signal from the divider 216, delays the RF signal to the extent that the RF signal is processed in the pre-distortion 213 and the main amplifier 214, and supplies the delayed RF signal the signal canceller 219.

The first variable attenuator 211 and the first variable phase shifter 212 are included between divider 218 and signal canceller 219 which control level and phase of the input RF signal, respectively, through the attenuation control signal ATT1 and the phase control 1006031 43 signal PIC1 from control 237 and supplying the controlled level and phase signal to the signal canceler 219. The first variable attenuator 211 and the first variable phase shifter 212 are located between the main road and the under way, and phase and level of it in the main amplifier 214 on the main road. the output of the RF signal is thereby controlled.

The rest of the linear power amplifier is the same as the first embodiment of Fig. 2. Thus, like reference numerals have been used.

The controller 237 selectively supplies the first through fourth signals SF1 through SF4 in the same manner as described with reference to Fig. 10 and generates the attenuation control signals ATT1 through ATT3 and the 15 phase control signals PIC1 through PIC3 with detection of the RSSI of the RF signal or the intermodulation signal in the selected SF signal. After setting the service channels, the controller 237 controls phase and level of the pre-distortion signal to suppress the intermodulation signal in the main amplifier 214, controls the level and phase of the RF signal input in the way to suppress the RF signal distortion in the signal canceller 219 and controls level and phase of the intermodulation distortion in the signal canceller 129 (219; 25 vert.) to suppress it.

Like the linear amplifiers according to the first embodiments, the linear amplifiers according to the second and third embodiments first select the service channel, then control phase and level of the pre-distortion signal, control phase and level of the input RF signal, and finally control phase and level of the the intermodulation signal formed in the signal canceller 219. As another embodiment, the selection of the service channel can be performed through a time interrupt. The controller 237 then performs the channel selection when the time interrupt is formed and controls the variable attenuators and phase shifters in the remaining 1006031 44 periods. When the time interrupt is generated when the variable attenuator and phase shifter are controlled, the controller 237 interrupts this operation and forms the time interrupt service routine, then returning to the main routine and further executing the respective operation.

The number of times, X, Y, Z, that the variable attenuators or variable phase shifters are controlled can be set to a number sufficient to suitably control the level and phase of the input signal; these respective numbers may be the same and more particularly equal to 5.

As described above, the linear power amplifier according to the invention removes intermodulation signal distortion by means of the pre-distortion and pre-coupling system. First of all, the intermodulation distortion that can occur in the main amplifier is suppressed by the pre-distortion system, and then the intermodulation signal remaining at the output of the amplifier is suppressed by the pre-coupling system. Main amplifier and error amplifier 222 design is easy. Since the variable attenuators and variable phase shifters have a linear action with a large flat bandwidth characteristic, the linear amplifier according to the invention can also be used for other purposes as described.

1006031

Claims (15)

Linear power amplifier comprising a main amplifier for eliminating intermodulation signals, characterized by: a pre-distortion circuit for suppressing an intermodulation signals generated in the amplification of the RF signal in the main amplifier by generating harmonics corresponding to the input RF signal and a pre-distortion signal by combining the RF signal with these harmonics; 10 and a feed-back circuit for further suppressing the intermodulation signal by neutralizing the input RF signal with the output signal of the main amplifier, extracting an intermodulation distortion signal, amplifying the extracted in-termulation error signal and supplying the amplified intermodulation error signal. at the output of the main amplifier. 2. Device according to claim 2, characterized in that the pre-distortion chain consists of: a divider for extracting a part of the input RF signal; an automatic level control for controlling and outputting this extracted RF signal at a certain level; a harmonic generator for generating harmonics corresponding to the level-controlled RF signal; and a signal coupler for coupling this harmonic signal to the input RF signal to form a preformed RF signal. 3. Device as claimed in claims 1-2, characterized in that the feed-back circuit consists of: a divider for dividing the RF signal input in the main road and supplying the extracted part thereof to a substation. away; a signal canceller for canceling the RF 5 signal in the way and at the output of the main amplifier and detecting the intermodulation signal; an error amplifier for amplifying the intermodulation distortion signal supplied by the signal canceller; and a signal coupler for supplying the output signal of the error amplifier to the output signal of the main amplifier on the main road to suppress the intermodulation distortion in the output RF signal. Linear power amplifier, characterized by: a first variable attenuator and phase shifter in the main signal path for adjusting level and phase of the input RF signal; 20 a pre-distortion circuit for generating harmonics corresponding to the RF signal supplied by the first variable attenuator and phase shifter and thus generating the pre-distorted RF signal with the RF signal; 25 a main amplifier for amplifying and outputting the preformed RF signal; an on-way delay circuit for delaying the shared RF signal adapted to the delay in the main road; 30 a down-way signal canceller for neutralizing the divided output voltage on the main road and the output voltage of the first delay circuit, thereby obtaining an intermodulation signal contained in the amplified RF signal; 35 a second variable attenuator and phase shifter for adjusting the level and phase of this intermodulation signal; 1 0 0 6 03 1 an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter? a second delay circuit for delaying the output of the main amplifier; and a signal coupler for coupling the intermodulation signal supplied in the error amplifier to the output of the second delay circuit, thereby suppressing the intermodulation signal of the final RF signal. Device according to claim 4, characterized in that it comprises the deformation chain; a divider for sharing the RF signal; an automatic level control circuit for controlling and outputting the RF signal at a certain level; a harmonic generator for generating harmonics corresponding to the level-controlled RF signal; 20 a third variable attenuator and phase shifter for adjusting the level and phase of the harmonics formed in the harmonic generator; a delay circuit for delaying the input RF signal; and a signal coupler for coupling the harmonics generated in the third variable attenuator and phase shifter with the delay signal output signal and generating a distorted RF signal. 6. Linear power amplifier, characterized by: a main road distortion circuit for generating harmonics corresponding to an input RF signal, combining these harmonics with the RF signal and generating a distorted RF signal; a main power amplifier for amplifying and outputting the preformed RF signal; 1006031 a first attenuator and phase shifter in a lower signal path for controlling level and phase of the divided RF signal taken from the main path; a first delay circuit for delaying the RF signal applied thereto from the first variable attenuator and phase shifter; a signal canceller included in the road for canceling the portion of the output signal extracted from the main road of the main amplifier by the output signal of the delay circuit, thereby obtaining an interraodulation signal; a second variable attenuator and phase shifter for controlling the level and phase of this intermodulation signal; 15 an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter; a second delay circuit for delaying the output signal of the main amplifier and a signal coupler for combining the intermodulation signal at the output of the error amplifier with the output signal of the second delay chain, thereby suppressing intermodulation signals in the final output RF signal. The device of claim 6, characterized in that the pre-distortion circuit comprises: a divider for obtaining a portion of the input RF signal; an automatic level control circuit for controlling the level of this RF signal portion at a certain predetermined level; a harmonic generator for generating harmonics from this level-controlled RF signal; a third variable attenuator and phase shifter 35 for controlling the level and phase of the harmonics formed in the harmonic generator; 1006031 a delay circuit for delaying the input RF signal; and a signal coupler for combining harmonics outputted in the third variable attenuator and phase shifter with the delay signal output signal and generating a distorted RF signal. 8. Linear power amplifier comprising: a pre-distortion circuit in the main signal path for generating a harmonic signal corresponding to an input RF signal, combining this harmonic signal with the RF signal and generating a pre-distorted RF signal; a main power amplifier for amplifying and outputting the preformed RF signal; a first delay circuit in a lower signal path for delaying the RF signal portion out of the main path; a first variable attenuator and phase shifter 20 between the road and the main road for controlling level and phase of the signal portion taken from the main road; a signal canceller in this main signal path for canceling the RF signal of the first variable attenuator and phase shifter with the output of the first delay circuit, thereby obtaining an intermodulation signal contained in the amplified RF signal; a second variable attenuator and phase shifter 30 for controlling the level and phase of the output signal supplied by the signal canceller; an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter; 35 a second delay circuit for delaying the output signal from the main amplifier; and 1 0 0 6 03 1 a signal coupler for combining the intermodulation signal output in the error amplifier with the output of the second delay circuit, thereby suppressing the intermodulation signal in the final RF signal output. Device according to claim 8, characterized in that the pre-distortion circuit comprises: a divider for obtaining a portion of the input RF signal; 10 an automatic level control circuit for bringing and outputting the portion of the RF signal at a certain level; a harmonic generator for generating harmonics corresponding to the level-controlled RF signal; a third variable attenuator and phase shifter for controlling the level and phase of the harmonics formed in the harmonic generator; a delay circuit for delaying an input RF signal; and a signal coupler for combining the harmonics supplied by the third variable attenuator and phase shifter with the delay signal output signal and generating a pre-distorted RF signal. 10. Linear power amplifier circuit, characterized in that it comprises: a first variable attenuator and phase shifter in a main signal path for controlling level and phase of an input RF signal by a first attenuation control signal and a first phase control signal; a pre-distortion circuit for generating harmonics corresponding to the RF signal input into the first variable attenuator and phase shifter, controlling the level and phase of these harmonics by a third attenuation control signal and a 1006031 third phase control signal, and thus generating the pre-distorted Link the RF signal with the RF signal; a main power amplifier for amplifying and outputting the preformed RF signal; 5 a first delay circuit in an underway for the portion of the main road RF signal; an on-the-go signal canceller for canceling the portion of the main amplifier output signal in the main road and the delay circuit output signal, thereby obtaining the intermodulation signal in the amplified RF signal; a second variable attenuator and phase shifter to which an intermodulation signal is applied supplied by the signal canceller and whose level and phase is controlled by a second attenuation control signal and a second phase control signal; an error amplifier for amplifying the intermodulation signal supplied by the second variable attenuator and phase shifter; a second delay circuit for delaying the output signal from the main amplifier; a signal coupler for combining the intermodulation signal supplied by the error amplifier 25 with the output of the second delay circuit, thereby suppressing the intermodulation signal occurring in the final output RF signal; a signal selector with dividers which respectively share the output signal of the main amplifier, the output signal of the signal canceller and the final output signal for selectively outputting a corresponding divided signal by means of switching control signals; a signal detector for supplying the output signal of the signal selector, synchronization frequencies of RF signals and intermodulation signals via 10 6 0 3 1 control data and detecting the RSSI of this signal; a control circuit for generating the switch control signals for sequential control of the signal selector, outputting the output data to synchronize the intermodulation signals of the main power amplifier by selecting the output signal of the main power amplifier, comparing the RSSI of the intermodulation signal in the signal detector with the RSSI of the intermodulation signal of a previous state, generating the third intermodulation control signal and the third phase control signal in accordance with the comparison result, outputting control data to synchronize the RF signals from the output of the signal canceller when selecting the signal canceller output, comparing the RSSI of the RF signals applied to the signal detector with the RSSI of this RF signal in a previous state, generating the first attenuation control signal and the first phase control signal in accordance with the comparison result, outputting the control data to synchronize the intermodulation signals contained in the RF signal when selecting the final output RF signal, comparing the RSSI of the intermodulation signals output by the signal detector with the RSSI of the intermodulation signal in the previous state and generating the second attenuation control signal and the second phase control signal in accordance with the comparison result. The device according to claim 10, characterized in that the pre-distortion circuit comprises: a divider for obtaining a portion of the input RF signal; 35 an automatic level control for controlling and outputting the shared RF signal at a certain level; 1006031 a harmonic generator for generating harmonics corresponding to the level-controlled RF signal; a third variable attenuator and phase shifter 5 for adjusting the level and phase of the harmonics generated in this harmonic generator; a delay circuit for delaying the input RF signal; and a signal coupler for coupling a harmonic signal output in the third variable attenuator and phase shifter to the output signal of the delay circuit and thus generating a distorted RF signal. 12. Device according to claim 10 or 11, characterized in that the signal detector comprises: a phase lock loop to which the control data is input for generating a local frequency corresponding to the input control data; a mixer for mixing a signal supplied by the signal detector with the output of the phase-locked loop; a frequency down filter to a frequency supplied by the mixer; and a logarithmic amplifier for converting the output signal of the filter into a DC voltage and supplying the converted voltage as the RSSI value. 13. A method of eliminating an intermodulation signal in a linear power amplifier device comprising a main power amplifier, characterized by the steps of: (a) first suppressing the intermodulation signal generated upon amplification of an RF signal in the main amplifier by generating harmonics corresponding to the input RF signal and a pre-distortion signal by coupling the RF signal to these harmonics; and 1006031 (b) thereafter suppressing the intermodulation signal by canceling the input RF signal with the output signal of the main power amplifier, extracting an intermodulation distortion signal, amplifying the extracted intermodulation distortion signal and combining the amplified intermodulation signal. lation signal with the output signal of the main amplifier. A method according to claim 13, characterized in that step (a) consists of: dividing the input RF signal and keeping the level of the shared RF signal constant; generating a harmonic signal corresponding to the RF signal; 15 combining the harmonic signal with the RF signal and generating a pre-distorted RF signal; and suppressing an intermodulation signal generated upon amplifying the pre-distorted signal. A method according to claim 13 or 14, characterized in that step (b) consists of: neutralizing the suppressed power amplified signal and the input RF signal and extracting the intermodulation signal; 25 strengthening the extracted intermodulation signal; and suppressing the intermodulation signal in the RF signal by coupling the amplified intermodulation signal with the suppressed power amplified signal. 10 0 & 03 1