RU2172059C2 - Gear and method of compensation for phase distortions - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: invention is related to method of compensation for phase distortions emerging in amplified output signal of power amplifier and to gear for compensation of phase distortions. Gear includes circuit 30- 39 of phase synchronization and conversion with rise of frequency that is connected to input of power amplifier 40. Approach includes supply of portion of signal (e_pha) subject to amplification back into circuit 35 which integrates this first mentioned signal with portion of amplified signal (e_out) fed back from output of power amplifier 40 to obtain smooth transfer in domination of one signal relative to another signal when two signals are integrated to generate new feedback signal (e_fdb) from circuit 35. EFFECT: compensation for effect of phase modulation of amplitude with regard to pulse power amplifiers. 14 cl, 9 dwg

Description

 The invention relates to the compensation of phase distortions that occur in the output amplified signal due to the output power of the amplifier. The invention also relates to a phase distortion compensation device.

BACKGROUND OF THE INVENTION
The digital system GSM (Global System for Mobile Communications) uses mdvrk (Multiple Access with time division of channels). In this method, each carrier frequency is divided into eight time slots, thereby providing the ability to serve eight requests simultaneously on the same carrier frequency. Each terminal station includes a power amplifier in the transmitter portion of the terminal station, which transmits modulated radio frequency information to the antenna. The function of the power amplifier is to sufficiently amplify the signals for satisfactory reception at the nearest base station. This function will be performed with the smallest possible addition of power from the terminal batteries due to their limited capacity.

Power amplifiers tend to introduce phase distortion into the transmitted output signal. These distortions depend on the output power and increase with its increase. These distortions can be expressed as a mathematical vector model: y (t) = re ^{jwt + f (r)} The gain r, which in this case is the same as the amplitude, is included as a variable in the function f (r) of the phase. Thus, it is believed that the gain / amplitude determines the effect of phase modulation in the output signal.

 Some non-linear amplifiers give pronounced phase distortions at high powers, although these amplifiers can nevertheless be used, since they are more efficient than linear amplifiers.

 CDMA uses pulsed amplifiers. Thus, the power is linearly increased to an output power suitable for transmission in accordance with a sawtooth function. At the end of the transmission, the power accordingly linearly decreases, in accordance with the sawtooth function. A linear increase and a linear decrease in output power occurs over very short time intervals. The dependence of the phase modulation on the linear increase and linear decrease in the output power leads to the expansion of the frequency spectrum of the output signal. Phase modulation compensation increases the ability to meet these standard requirements (e.g. GSM).

 From the published PCT patent application WO-A1-95 / 23453 (Motorola), it is known to neutralize phase distortion by feedback, which is connected to the output of the power amplifier and the power amplifier is included in the phase synchronization circuit. A phase-modulated signal is supplied to the power amplifier from the phase modulation control loop, which includes a phase synchronization loop with a feedback circuit connected to the input of the power amplifier. The inclusion of a switching circuit in a phase modulation control loop allows switching between two feedback loops. However, it is practically impossible in a known manner to achieve fast phase synchronization in the correct phase by switching between feedback loops. Since the corresponding linear increase and linear decrease occur very quickly, problems arise, especially in the case of mdvc radio communications using pulsed amplifiers. Emissions at the front of the pulse, which are formed in the envelope of the output signal, are fed back and added to the transients caused by switching between the two feedback loops. In addition, phase synchronization takes an unacceptably long time. Phase synchronization may not even occur. These shortcomings and problems can lead to complete or partial loss of important information stored in the signal. Therefore, it can be considered desirable to find a new solution to these shortcomings and problems that are burdened by known methods.

 The present invention relates to a problem regarding a method of compensating for the effect of phase modulation of amplitude with respect to switching power amplifiers.

 Another problem related to the invention relates to a method by which it is possible to quickly, accurately and at a suitable time synchronize the phase detector in the correct phase before ramping up or ramping down the power amplifier.

 As was established above, previously known methods of phase synchronization are difficult due to some disadvantages and problems. To address these shortcomings and problems, the present invention is directed.

 An object of the present invention is to provide a method and apparatus that compensate for the effect of amplitude phase modulation.

 Another objective of the present invention is to provide a method and apparatus that eliminate transients and feedback signals with noise.

 Another objective of the present invention is to provide a method and device that allows you to quickly, accurately and at the right time to synchronize the phase detector in the correct phase before the linear increase or linear decrease in the power of the power amplifier.

 Another objective of the present invention is to provide a method and device that neutralize the disadvantages and problems associated with existing methods of phase synchronization.

 The solution includes providing a signal for amplified feedback to a circuit that combines part of this first mentioned signal with part of the amplified signal fed back from the output of the power amplifier to make a smooth transition when one signal prevails over another signal, when the two signals are combined to form output signal combining circuit.

 The phase-locking and up-conversion circuit includes a phase detector, an integrating filter circuit connected to said detector, a voltage controlled oscillator connected to the output of said filter circuit, and a feedback loop connected to the mixer input, which includes an additional input for the signal coming from the source of the local generator, and an output that is connected to one of the two inputs of the phase detector. A power amplifier is connected to the output of a voltage-controlled generator, although the amplifier is not included in the loop. The concept includes the use of the existing phase-locked loop and conversion with increasing frequency by supplementing the said loop with a signal combining device, the so-called combining circuit, as well as a second feedback loop from the output of the power amplifier. In addition, a power amplifier can be included in the phase synchronization and conversion circuit with increasing frequency. The phase-locked loop and up-conversion can also be called the phase-modulated control loop, which has the functions of phase-locked and up-conversion. Before the linear increase in the signal of the power amplifier starts, the circuit is synchronized by the output signal of the voltage controlled by the generator using the first feedback loop. When the output power increases, the signal fed back from the output of the power amplifier through the second feedback loop gradually takes precedence over the generator signal coming back through the first feedback loop. This gradual (or sequential) change in the relationship between the signals from the two feedback loops in the new feedback signal can be described as a smooth transition. If the circuit has a sufficiently large bandwidth, the phase shift of the power amplifier during the ramp period is excluded.

 One advantage of the present invention is that the transition is smooth, so that no transients are formed that can extend over the time that the phase synchronization function takes in the phase modulation control loop to synchronize in the correct phase.

 Another advantage provided by the present invention is that the broadband noise from sources upstream of the phase detector in the phase modulation control loop is effectively filtered out. One such source may be the noise produced by the IQ modulator.

 Another advantage is that the developer has greater freedom in choosing between various existing power amplifiers that can provide the desired characteristics when applying the concept of the invention.

 Another advantage provided by the invention is that it can be used in mobile telephony, regardless of whether the information signal is phase modulated or amplitude modulated.

 Now the invention will be described in more detail with reference to preferred options for its implementation, as well as with reference to the accompanying drawings.

 FIG. 1A is a block diagram illustrating a transmitter equipped with an antenna.

 FIG. 1B is a power axis that illustrates the relative state between different output powers of a transmitter.

FIG. 2A is a temporal amplitude diagram showing how the control signal I _oust changes over time in accordance with the established GSM standard.

 FIG. 2B is a diagram that shows the change in output power P over time, where the power amplifier is controlled in accordance with the GSM standard.

 FIG. 3 is a block diagram illustrating an existing transmitter.

 FIG. 4 is an electrical circuit diagram of one embodiment of a combining circuit.

 FIG. 5 is an electrical circuit diagram of another embodiment of a combining circuit.

 FIG. 6 is a block diagram illustrating one embodiment of the inventive phase distortion compensation device.

 FIG. 7 is a block diagram illustrating another embodiment of the inventive phase distortion compensation device.

 FIG. 8A illustrates the principle of temporarily controlling the phase synchronization shown in FIG. 7 devices using the time axis and time stamps.

 FIG. 8B is a temporal amplitude diagram illustrating a change in time of an output signal of a sweep circuit included in FIG. 7 device.

 FIG. 9 is a flowchart illustrating a phase distortion compensation method corresponding to the concept of the invention.

 The following embodiments of the invention relate to applications in radio transmitting devices. However, it should be understood that phase distortion compensation appropriate to the concept of the invention can be used in other applications.

FIG. 1A is a block diagram illustrating a power amplifier (PA) 3 included in a transmitter and having a signal input for an input signal, s ₁ , a control input for a control signal I _us, and a signal output for a signal s ₂ having an output power P _o . The input signal I _{USC is} generated in the amplifier control device 5 (CID), which operates to control the output power P _o . The phase modulation control loop 7 generates a signal s ₁ . The amplifier control device is not described in detail in this document.

During the time interval used, the power amplifier 3 represents the output power P _o in two values that are between P _max and P _min . The signal s ₁ transmitted to the power amplifier has a constant input power. Two feedback signals s ₁ and s ₂ have the same weight at a given output power P _o = P _{T '} , P _T <P _min . In FIG. 1B shows the relative state of the output powers with respect to the power P _T.

The power amplifier 3 is controlled by a control signal 1 of a pulse type of the output power, in accordance with which, for example, the corresponding mobile telephony system is determined. In FIG. 2A shows how the control signal I _us changes with time in accordance with the established GSM standard. The control of the power amplifier 3 leads to the control of the output power. In FIG. 2B shows the envelope E of the output signal P _o with linear increase and linear decrease in the output signal of the power amplifier 3. The time on this graph is indicated by t. They seek a smooth envelope of output power to prevent the spread of the spectrum of transmitted signals. In FIG. 2B also schematically shows the time patterns, F ₁ and F ₂ , to which the output power should be adapted and which are defined in the GSM standard. The duration of the linear increase or linear decrease should not exceed Δ T = 28 μs.

 FIG. 3 is a block diagram illustrating the aforementioned former transmitter from PCT patent application WO-A1-95 / 23453. A known transmitter is generally subdivided into a phase modulation control loop 117 and an amplitude modulation control loop 115. The amplitude modulation control loop includes a power amplifier 107, a directional coupler 109, and an envelope detector 111 that is connected to one of the signal inputs of the differential amplifier 113. An amplitude reference signal 125 is provided to another signal input. The differential amplifier 113 generates a voltage differential signal as a result of the difference between the two signal inputs. A differential amplifier is connected to an input for controlling the gain of the power amplifier 107. Amplitude modulation of the output signal of the power amplifier is achieved by changing the voltage of the amplitude reference signal.

 The problem of shifting the frequency of the reference phase signal 121 to the proper channel frequency is solved in this known device by the phase modulation control loop 117. The circuit includes a mixer 101, a phase detector 103, and a voltage controlled oscillator 105, a UNG, and a feedback loop connection 131 from the generator output to the switch circuit 130. As mentioned above, non-linear amplifiers at high powers exhibit explicit phase distortion. This distortion can be neutralized by the feedback circuit 132, which is connected to the output 109 of the power amplifier, and which, due to this, introduces the power amplifier into the phase modulation circuit. The inclusion of the switching circuit 130 in the phase modulation control loop allows switching between the two feedback circuits 131 and 132. One of the feedback signals is fed back to the mixer 101. The mixer generates an intermediate frequency signal 127, the frequency of which is equal to the difference between the frequencies of the reference signal 123 and the signal which is fed back from the switching circuit 130. The phase detector 103 generates a mismatch signal, which depends on the phase difference of the intermediate frequency signal 127 and the reference signal 121 phase. The error signal is fed to the generator frequency control input. Thus, the generator output signal obtains a phase that is approximately equal to the phase of the reference phase signal 121, which means that phase modulation of the output signal is obtained using the reference phase signal 121. The frequency of the output signal depends on the sum of the alternative difference between the frequency of the reference frequency signal and the frequencies of the reference phase signal.

 However, in accordance with the known method, it is practically impossible to achieve fast synchronization in the correct phase by switching between two feedback loops. The problem is that the linear increase and linear decrease of the signal occur very quickly. Switching between the two feedback loops results in phase distortion that cannot be attenuated quickly enough. In the worst cases, the loop loses its synchronization.

 In accordance with the present invention, it is more convenient to replace the switching circuit 130 with a combining device, the combining circuit of which leads to a smooth transition between the two circuits of feedback signals. With a linear power amplifier, the output signal of the combining circuit to the phase detector is restrained by the feedback signal from the output of the voltage-controlled generator at low power output signals. In the case of a rapid linear increase in the output power with increasing as a result of phase distortion, the contribution of the signal from the feedback loop, which includes the power amplifier, also increases. This is resolved by combining at a rate of increase in the amplitude of the output signal. In this case, the phase detector has time to eliminate the phase mismatch. At full amplifier output, the feedback output completely dominates the output of the combiner circuit. The combining circuit can be either circuits that include exclusively passive elements, or circuits that include active elements (transistors).

Next, an embodiment of a combining scheme that includes passive elements and a combining scheme that includes active elements will be described. Both embodiments include a restriction circuit. The limitation is necessary to guarantee the correct operation of the downstream mixer, which means that the output amplitude of the mixer will be constant. The combining circuit represents the addition of two feedback signals s ₁ and s ₂ in FIG. 1A.

In FIG. 4 shows an embodiment of a CO1 combining circuit that is configured with passive elements — in the illustrated case, resistors R ₁ and R ₂ — and a limiter L1. Each of the feedback signals s ₁ and s ₂ in FIG. 1A is supplied to a corresponding signal input 11 and 12. Each signal input includes one of the respective resistors R ₁ and R ₂ . The signal inputs are connected to a common point A _sum sum for signals s ₁ and s ₂ . By summation point A _sum is also connected the voltage source 13 through a resistor R _3. Point A _sum connected to input 14 of the limiter L1. Since signal 51 is constant as well as relatively weak compared to signal s ₂ , which is fed back from the output of the power amplifier, the signals will preferably be weighted. A suitable choice of the values of the corresponding resistances allows you to sum the two signals into a new signal s _sum , which is limited by the limiter L1 to a new feedback signal s ₃ at the common output 15 of the limiter and combining circuit СО1. Weighing is carried out in such a way that the transition from a state in which the signal s ₁ dominates in the feedback signal s ₃ to a state in which s ₂ dominates, and vice versa, is carried out at a suitable output power. It was determined that the transition should take place when the output power from s ₂ becomes greater than P _T (see Fig. 1B), where P _T <P _min . By predominance, it is understood that one of the signals constitutes the majority of the feedback signal. As mentioned above, a restriction is necessary to ensure that subsequent circuits will work correctly.

The described feedback of the signal s ₃ from the combining circuit СО1 means that the power amplifier 3 (PA) in FIG. 1A will be included in the phase synchronization loop of the phase modulation control (UFM) loop 7, which also synchronizes in phase the output signal s ₂ from the power amplifier 3.

FIG. 5 illustrates another advantageous embodiment of a CO2 combining scheme. This CO2 scheme is made with active elements. The circuit is an amplifier that has two inputs 21 and 22. Each of the signals that come back from s ₁ and s ₂ in FIG. 1A is supplied to the corresponding one of the signal inputs 21 and 22. The amplifier includes two transistors T1 and T2. Signal s ₁ at input s ₂ is supplied to the base of transistor T1 through bias circuit 23A. Signal s ₂ at input 22 is supplied to the base of transistor T2 through bias circuit 23B. In the illustrated case, both transistors are bipolar npn transistors, although other types of transistors can be used. Transistor emitters are connected to a common DC generator 24. The transistors are powered by a voltage V _CC excitation from a voltage source 25. The amplifier has two shoulders. The collector of transistor T1 is connected to voltage source 25 through arm 26, and the collector of transistor T2 is connected to voltage source 25 through other arm 27. As shown in FIG. 5, each arm may include a collector resistor R _C. Signal s _A passes from arm 26A through element 27A. Signal s _R passes from arm 26B through element 27B. The outputs of resistors 27A and 27B are connected to a common _sum sum point A1. This point is connected to input 28 of the limiter L1. Thus, shoulders 26A and 26B are combined with elements 27A and 27B so as to obtain a weighted sum s1 _{sum of} feedback signals s ₁ and s ₂ at point A1 _sum . The new signal s1 _{sum is} limited in the limiter L1 to a new feedback signal s ₃ at the output 29 of the limiter, which is also the signal output of the combining CO2 circuit.

The feedback of the signal s ₃ from the combining CO2 circuit means that the power amplifier 3 in FIG. 1A will be included in the phase-locked loop for the phase-modulated control loop 7, which thereby synchronizes in phase the output signal s ₂ from the power amplifier 3.

FIG. 6 illustrates a preferred embodiment of the inventive phase distortion compensation device. The signal entering the device is a phase signal e _phr , that is, a signal in which information is in phase. The phase signal e _phr contains phase information to be modulated and transmitted at the appropriate carrier frequency.

Conversion with increasing frequency of the phase signal e _phr relative to the correct channel frequency is performed in the phase modulation control loop for phase synchronization and conversion with increasing frequency. The circuit includes a mixer 30, a phase detector 31, a voltage controlled oscillator (UNG) 32, an integrating filter circuit 34, a combining circuit 35, and a feedback circuit 33 from the output of the generator 32 to the first input of the combining circuit 35 through the first coupler means 37. The generator 32 is connected to the input of the power amplifier 40, the output of which is connected to the antenna 50. The phase modulation control loop also includes a second feedback circuit 36 from the output of the power amplifier 40 to the second input of the combining circuit 35 through the second conductor means 38. This circuit can be constructed in the same way as described with reference to FIG. 4 or FIG. 5.

The mixer 30 produces an intermediate frequency signal e _ifs , the frequency of which is equal to the difference between the reference frequency signal e _{frs from} the frequency synthesizer 39 and the feedback signal e _fdb from the combining circuit 35. Feedback signal e _fdb corresponds to signal s ₃ in FIG. 4 and 5.

The phase detector 31 generates a mismatch signal e _phf , which depends on the phase difference of the intermediate frequency signal e _ifs and the phase signal e _phr . An integrating filter circuit 34 is connected between the phase detector and the voltage-controlled oscillator in such a way as to reduce the risk of phase distortion, noise transmission and frequency band expanding as a result of wideband noise. The filter circuitry effectively eliminates broadband noise. The noise comes from sources in the phase detector. One such source may be a 1Q modulator used in some types of radio transmitter.

The mismatch signal e _phf is supplied to the input of the filter circuit 34, and from there to the input of the frequency controlled oscillator 32. Thus, the output signal e _{pha of the} generator 32 forms a phase that is approximately equal to the phase of the phase signal e _phr , which means that the output signal e _{pha is} modulated phase by phase signal e _phr . The frequency of the output signal e _pha is the sum or difference between the frequency of the signal e _{frs of the} reference frequency and the frequency of the phase signal e _phr .

The e _pha signal is coupled to a power amplifier 40, which amplifies the e _pha signal in response to a control signal I _us . The signal e of the _output antenna of the amplifier 40 to the antenna 50 will then be in the form determined by the control signal I _us .

If this embodiment is included in a transmitter that operates in accordance with GSM standards, the output signal receives the envelope shown in FIG. 2B. The output signal e _out corresponds to the signal s ₂ in FIG. 1A, and the signal e _pha corresponds to the signal s ₁ .

Combining means, i.e. combining circuit 35, receives part of the signal e _pha and e _O signal portion, each via respective signal couplers 37 and 38. These signal taps may have the form of directional couplers or some form of voltage divider (capacitive or resistive taps). Two circuits 33 and 36 connect the corresponding coupler 37 and 38 to their specific input in the combiner circuit 35. It combines the two signals e _pha and e _output from the respective circuits in accordance with the gain of the amplifier 40 in order to provide a new feedback signal e _fdb in the loop. Each of the couplers 37 and 38 outputs a certain part of the respective signals e _pha and e _o . These taps can also be managed. In addition, the magnitude of the respective parts of the signals that are output in this way can be controlled individually, which can be beneficial. An example of one such coupler is a guided directional coupler.

Before starting a linear increase in the signal of the amplifier 40 of the power of the PA, the circuit is synchronized by the output signal from the voltage-controlled generator 32 using the first feedback circuit 33. As the output power increases in response to the control signal I _us , the e _output signal, which is fed back from the output of the power amplifier through the second feedback circuit 36, gradually becomes dominant over the generator signal e _pha fed back through the first feedback circuit 33 as a signal e _fdb feedback.

 Without circuit 33, phase synchronization cannot be achieved at the appropriate time before activating the power amplifier when the transmitter is started. When the circuit has a sufficiently wide operating frequency band, the circuit has time to compensate for the phase shift in the power amplifier 40 during a linear increase in the output power. Feedback will be established via circuit 36, and said synchronization will be achieved in order to obtain an estimated phase distortion compensation of approximately 10 dB at full output power.

 A phase distortion compensating device according to this embodiment of the invention includes an amplifier 40, the input of which is connected to the output of the phase-locked loop and up-conversion. This circuit includes first and second feedback circuits 33 and 36, respectively, where the first feedback circuit 33 is coupled to coupler means 37 for branching a portion of the modulated signal at the input of the power amplifier, and the second feedback circuit 36 is coupled to coupler means 38 branches of the amplified modulated signal at the output of the power amplifier 40.

 Each of the circuits 33 and 36 is associated with a respective input of the combiner 35, which combines the two input signals from the respective circuits in such a way as to produce a new feedback signal in the circuit.

The phase distortion compensation method of this embodiment includes combining two signals e _pha and e _output from respective circuits 33 and 36 to form a new feedback signal e _{fdb in the loop} . If the gain in the amplifier 40 changes, the proportionality with which the feedback signals come back also changes and their predominance in the feedback signal to the phase synchronization loop and conversion with increasing frequency. The inventive method provides a smooth and continuous transition between the parts of the signals that are fed back, and at the same time, dominates the feedback signal so that the phase synchronization and upconversion circuits can be synchronized in phase in time before the fast change in the output power of the power amplifier while maintaining phase synchronization during linear increase and linear decrease in signal. According to the inventive method, the prevalence of the feedback signal that is output from the output of the power amplifier 40 in the new feedback signal increases with increasing output powers of the amplifier. The signal fed back from the output of the power amplifier dominates the new feedback signal when the power amplifier amplifies at full output power, while the signal fed back from the input of the power amplifier dominates the new feedback signal when the output power of the amplifier low.

As a result of the application of the proposed method, the phase synchronization and conversion circuit with increasing frequency is synchronized by a modulated signal e _pha at the input of the power amplifier 40 to increase the output power of the power amplifier. When a linear increase in the amplifier signal begins, the phase-locked loop and up-conversion are synchronized by the amplified modulated signal at the input of the power amplifier before the output of the power amplifier reaches its full value.

FIG. 7 illustrates an embodiment that is slightly different from the inventive device shown in FIG. 6. In accordance with FIG. 6, the phase modulation control loop includes a phase detector 31, a filter circuit 34, a generator 32, a combining circuit 35, a mixer 30, and a local oscillator 39. The phase modulation control loop in FIG. 7 also includes a scan circuit (CP) 60 connected between a voltage controlled oscillator 32 (UNG) and a filter circuit 34. To ensure fast phase synchronization of the circuit, the control voltage of the UNG generator is deployed over the voltage interval in which the synchronization of the generator is expected. The sweep can be initiated and stopped by the control signal I _st at the control input 61 of the sweep circuit 60. The frequency of the generator output signal changes due to a change in the control voltage for the generator.

FIG. 8A illustrates the principle of controlling the phase synchronization time shown in FIG. 7 devices using the time axis and time stamps. The initial pulse I _st starts the sweep circuit at time t _svp , and the output voltage of the circuit for voltage-controlled oscillator 32 changes with time in accordance with a predetermined function within a suitable voltage range in which loop synchronization is expected. The sweep of the voltage interval begins at a suitable time until the time t _up , at which a linear increase in the output power of the power amplifier 40 (UM) begins. It is necessary that the sweep circuit 60 have enough time for one sweep over the voltage span. The circuit is synchronized at the derivative time t _1sk and remains synchronized during the linear increase and linear decrease, which occur at the corresponding time t _up and t _down . The circuit can be kept synchronized since the combining circuit 35 creates a smooth transition from one feedback circuit 33 to another feedback circuit 36. On the other hand, phase synchronization is lost when fast switching is performed, besides leading to a loss of information in the output signal of the power amplifier.

To the sweep circuit 60, a voltage signal e _svp is supplied from the filter circuit 34. From the output of the sweep circuit, the voltage signal e _vco is supplied to a voltage controlled oscillator 32. The signals e _svp and e _vco include the phase information to be transmitted. The scan circuit 60 adds a scan to the information in e _svp . At time t _svp , a trigger pulse I _st is supplied to the input 61 of the scan circuit. Then, the scanning circuit 60 begins to change e _vco in time in accordance with a predetermined time function. FIG. 8B illustrates an example of how the signal e _vco can sweep the scan circuit 60 and change with time t in the desired voltage range V _int = [V _start , V _stop ]. The voltage decreases linearly from a constant high value V _start at the beginning of the voltage sweep. As e _vco changes, the frequency of the output signal of generator 32 changes. In FIG. 8B, the circuit locks (V _lock ) when e _vco controls the voltage-controlled oscillator 32 so that e _ifs = e _phr . This occurs at an arbitrary point in time t _lck . The e _vco signal is maintained at the V _lock level until the output power begins to gradually decrease at time t _end . The voltage sweep starts again with the voltage V _start at the arrival of the next starting pulse.

The trigger pulse I _{st is} generated at the start of the transmitting device and can be generated in the control part of the radio transmitting device. The scan pattern can be programmed to provide the ability to store other scan control parameters in the scan pattern control unit. The voltage interval V _int = [V _start , V _stop ] to be scanned can be determined at the same time as the time interval from the time when the starting pulse I _{st is} received at the control input 61 of the scanning circuit 60.

FIG. 9 is a graphical diagram of a program illustrating a phase distortion compensation method corresponding to the claimed concept. Some of the reference numbers used in the subsequent text can be found in FIG. 6 and 7. The method relates to phase distortion compensation in the amplified modulated power signal at the output of the power amplifier 40, in which the amplifier has an input connected to the output of the phase synchronization circuit (30-39) and conversion with increasing frequency (the circuit is also designated as a phase control loop modulation). The circuit includes first and second feedback circuits 33 and 36, respectively. The method starts when the loop starts at the initial position 200. In the first step 202 of the method, a part of the modulated signal e _pha at the input of the power amplifier 40 is output or removed through the first feedback circuit 33. At step 204, a portion of the amplified modulated signal e _out at the output of the power amplifier 40 is output or removed through the second feedback circuit 36. In a third step 206, two tap signals are combined in a combiner 35 to provide a feedback signal e _fdb that contains both tap signals. In a next step 208, a feedback signal is fed back to the phase-locked loop and upconverted. The circuit synchronizes in phase the output signal e _out by the phase reference signal e _phr in the next step 210 and at the same time compensates for phase distortion in the output signal e _{out of the} power amplifier. When the output of the amplifier changes, the combining means 35 combines the two allocated signals in such a way as to change their relative dominance in the feedback signal in a smooth transition so as not to lose phase synchronization and at the same time compensate for phase distortion, which is performed at step 212. Execution The method continues until the circuit is in operation and is not interrupted until the transmitter in which the circuit is included is no longer included.

 This step 214 is shown in the program flowchart by returning to step 212. When the transmitting device is turned off, the end position is immediately adopted (step 216).

 Since the inventive method provides a smooth and continuous change in the mutual proportionality of the output signals in the feedback signal and at the same time the relative dominance of the mentioned signals in the feedback signal, the phase synchronization and conversion circuit with increasing frequency can be synchronized in phase at the appropriate time before the fast change of the output power amplifier power. It was not possible to achieve this phase synchronization using known methods that use a switch to switch between two feedback loops. This method introduces a high degree of sensitivity when switching is performed. In addition, when switching is performed, there is a risk of introducing a transient in the circuit. Such transients can cause loss of phase synchronization along with valuable information in the loop input.

 When implementing the proposed method in a closed loop are not made any transients.

 The inventive method and the claimed device solve the above problems associated with phase compensation in various applications, such as radio communications, etc.

Claims (14)

1. A device for compensating for phase distortions in an amplified modulated signal ( _eout ) at the output of a power amplifier (40), the input of which is connected to the output of the phase synchronization and phase-conversion conversion circuit (30-39), and the circuit includes the corresponding first and second feedback circuits (33 and 36), wherein the first feedback circuit (33) is connected to a coupler (37) to divert part of the modulated signal (e _pha ) at the input of amplifier (40), and the second feedback circuit (36) is connected to coupler (38) to lead part reinforced a modulated signal (e _o ) at the output of the amplifier (40), characterized in that each of the two feedback circuits (33.36) is connected to the corresponding input of the combining means (35), which combines two input signals from the corresponding circuits (33.36 ) feedback to provide a signal (e _fdb ) feedback in the circuit (30-39) phase synchronization and conversion with increasing frequency. 2. The device according to claim 1, characterized in that the coupler (37) for diverting a portion of the amplified modulated signal ( _eout ) at the output of the amplifier (40) and a coupler (38) for diverting a portion of the modulated signal (e _pha ) at the input of the amplifier ( 40) are directional couplers. 3. The device according to claim 2, characterized in that the coupler (37) for diverting a portion of the amplified modulated signal (e _o ) at the output of the amplifier (40) and a coupler (38) for diverting a portion of the modulated signal (e _pha ) at the input of the amplifier ( 40) are guided directional couplers. 4. The device according to claim 1, characterized in that the coupler (37) for diverting a portion of the amplified modulated signal (e _o ) at the output of the amplifier (40) and a coupler (38) for diverting a portion of the modulated signal (e _pha ) at the input of the amplifier ( 40) are voltage dividers.  5. The device according to claim 1, characterized in that the circuit (30 -39) of phase synchronization and conversion with increasing frequency includes a scanning circuit (60).  6. The device according to any one of claims 1 to 5, characterized in that the phase synchronization circuit (30-39) and conversion with increasing frequency includes a low-noise powerful voltage-controlled generator (32).  7. The device according to any one of claims 1 to 6, characterized in that the power amplifier (40) is a pulse. 8. A method of compensating for phase distortions in an amplified modulated signal at the output of a power amplifier (40), the input of which is connected to the output of a phase synchronization and phase-conversion converter (30-39) with increasing frequency, and the circuit includes the first and second circuits (33.36 ) feedback, while the aforementioned method involves the removal of part of the modulated signal at the input of the amplifier (40) through the first feedback circuit (33) and the removal of part of the amplified modulated signal at the output of the amplifier (40) through the second feedback circuit (36), exc sistent in that the method comprises the further steps of combining two signals designated (e _O, e _pha) in the means (35) for combining a signal (e _fdb) feedback signal supply (e _fdb) to the feedback circuit (30-39) phase synchronization and conversion with increasing frequency, phase synchronization of the amplified modulated signal (e _o ), by the phase reference signal (e _phr ) entering the loop (30-39) of phase synchronization and conversion with increasing frequency, and changes in the mutual dominance of the output signals ( e _out , _pha ) in the feedback signal (e _fdb ) by smoothly changing in case of changing the output power of the amplifier (40). 9. The method according to claim 8, characterized in that it provides for an increase in the dominance in the feedback signal (e _fdb ) of the signal (e _o ) extracted from the output of the power amplifier (40), while increasing the output power of the amplifier (40). 10. The method according to claim 8 or 9, characterized in that the synchronization of the circuit (30-39) phase synchronization and conversion with increasing frequency of the amplified modulated signal (s _o ) at the output of the amplifier (40) until the output power of the amplifier reaches its full value . eleven . A method according to claim 10, characterized in that the amplified modulated signal (e _o ) at the output of the amplifier (40) dominates the feedback signal (e _fdb ) when the amplifier (40) produces amplification with full output power.  12. The method according to claim 8, characterized in that the synchronization circuit (30-39) phase synchronization and conversion with increasing frequency at the input of the amplifier (40) to increase the output power of the amplifier (40). 13. The method according to p. 12, characterized in that the modulated signal (e _pha ) at the input of the amplifier (40) is dominant in the feedback signal (e _fdb ) when the output power of the power amplifier is low.  14. The method according to any one of claims 8 to 13, characterized in that the power amplifier (40) is pulsed.

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