UA80262C2 - Method (variants) and apparatus (variants) for transformation with reducing frequency of received signal, receiving device and machine-readable carrier for saving programm module for implementation of the method - Google Patents

Abstract

A carrier recovery method and apparatus using multiple stages of carrier frequency recovery are disclosed. A receiver uses multiple frequency generation sources to generate earner signals used to downconvert a received signal. An analog frequency reference (114) having a wide frequency range and coarse frequency resolution is used in conjunction with a digital frequency reference (110) having a narrow frequency range and fine frequency resolution. The multiple carrier signals are multiplied by a received signal to effect a multi-stage downconversion, resulting in a baseband signal. A frequency tracking module (108) measures the residual frequency error present in the baseband signal. The measured residual frequency error is then used lo adjust the frequencies of the carrier signals generated by the multiple frequency generation sources (114 and 110) through a processor

Description

Description of the invention

The priority of this application is claimed on the basis of the previous US application Mob0/337469, filed on 11/9/2001, for the 2nd invention "Method and device for matching the carrier frequency of a receiver".

The embodiments of the invention described below relate, in general, to the field of wireless communication, and more specifically, to matching the frequency of the received carrier signal in a mobile wireless communication system.

As modern wireless communication systems become more and more widespread, the need to increase the bandwidth of the wireless communication system is increasing. To increase the number of subscribers served, a wireless service provider can either increase the frequency spectrum used by its systems or find a way to support more subscribers in the already allocated frequency spectrum. Without the ability to obtain additional frequency spectrum, wireless service providers often have to look for ways to increase bandwidth without using additional spectrum. In other words, wireless service providers must find more efficient ways to use the spectrum they have.

In response to the need for more efficient use of the spectrum, manufacturers of wireless equipment are developing various methods of increasing the bandwidth of wireless communication systems. One of the ways to ensure effective broadcast and data transmission is the use of methods of multi-station access with code separation of channels (CBDS). Several standards for the application of BDKR methods for terrestrial wireless broadcast and data transmission systems have been developed. It is possible, for example, to name such standards as "TIA/EIAL5-95 - Mobile station compatibility standard with a base station for a dual-mode broadband cellular communication system with spread spectrum", hereinafter referred to as I5-95, as well as the standard "TIA/ EIAL5-2000", hereinafter referred to as BDKR20O00. Other standards have also been proposed for wireless communication systems that are optimized to provide high-speed wireless data transmission. An example of 29 standards for high-speed data transmission is the "TPA/EIA/5-856" standard, hereinafter referred to as VPD Ge) (high-speed data transmission).

In a system with VAP, the speed at which the subscriber's equipment can receive data can be limited by the quality of the signals received by the subscriber's equipment. In such a system, the rate of data transfer in the signals sent to the subscriber's equipment is determined based on measurements of the quality of the received signals, which are performed at the subscriber's equipment. One of the types of quality measurement used to determine the data transfer rate is the determination of the ratio of the carrier power to the interference level (N/P) in the received signal. If the received signal has a high power compared to the power of the interfering signal, c then the N/P value will be high. If, on the other hand, the received carrier signal has a weak power compared to the Ha") obstacle, then the N/L will be low. With a high N/L value, the subscriber device can receive more than 325 data in a given time period. With a low N/A ratio, the data rate sent to the UE is reduced to maintain an acceptable frame error rate.

Carrier frequency recovery is one aspect of subscriber equipment design that can significantly affect the N/A perceived by the subscriber equipment. Carrier frequency restoration means "generation of a reference carrier signal in the subscriber's equipment, which has the same frequency as the carrier signal received from the base station. The subscriber unit uses the reference carrier signal to demodulate the data signals received from the base station. Mismatch between the reference carrier signal and the received one

With" the carrier signal, called carrier frequency mismatch, reduces the efficiency of the demodulation process.

The subscriber device perceives such a reduced demodulation efficiency as a reduction in N/P. Therefore, carrier frequency mismatch reduces the rate at which data can be sent to the subscriber unit. 45 Along with the need for accurate restoration of the carrier frequency, there is a desire to reduce the cost of the SO hardware in the subscriber unit. The market of subscriber equipment, such as radio telephones and modems, exists in conditions of av| fierce competition and is often characterized by low profit margins, and sometimes even subsidies from communication service providers. Therefore, there is a need for methods that would allow increasing the accuracy of carrier frequency recovery in subscriber equipment without significantly increasing the cost of hardware. b 20 The following variants of the invention make it possible to satisfy the above-mentioned needs by dividing the task of restoring the carrier frequency into several levels with different resolution. According to one exemplary aspect of the invention, the subscriber station monitors the frequency of signals received from the base station. The base station often uses a very accurate frequency source, for example, a global positioning system (GPS) signal receiver, which allows for the use of simpler and cheaper frequency sources in the subscriber unit. An exemplary subscriber apparatus has means for generating an indicating error signal

HF) the difference between the frequency of the received carrier and the frequency of the locally generated reference carrier. This error signal is used to correct the frequency of the reference carrier until it matches the frequency of the received carrier.

In one exemplary aspect, the reference carrier is generated using two levels: a first level 60 generates a carrier that has a wide frequency range but low frequency resolution, and a second stage carrier has a narrower range but higher frequency resolution. In this aspect, the first level is implemented by an analog device, such as a voltage controlled oscillator, and the second level is implemented by a digital device, such as a digital oscillator. The frequency of the signal generated at the first level can be adjusted in such a way that the frequency of the signal generated at the second level can be kept within a predetermined frequency range.

The word "exemplary" in this context means "one that serves as an example or illustration." Any embodiment of the invention described as an "exemplary embodiment" should not be considered superior or advantageous over other embodiments.

Brief description of the drawings

Fig. 1 - a multi-stage device for restoring the carrier frequency,

Fig. 2 - the device of the frequency tracking module and

Fig3 is an algorithm illustrating a method of correcting down-converted signals in a multi-stage carrier frequency recovery system. 70 The subscriber apparatus referred to in this context may be mobile or stationary and may communicate with one or more base stations. The subscriber unit transmits and receives data packets through one or more base stations. Base stations are called modem pool transceivers. Each modem pool transceiver can be connected to a base station VDP controller called a modem pool controller (MPC). Modem pool transceivers and modem pool /5 controllers are part of a network called an access network. Interconnected nodes of the access network usually communicate with each other by means of fixed terrestrial connections, such as a TI connection. The access network forwards data packets between multiple subscriber units. The access network may also be connected to additional networks outside the given access network, such as a corporate local area network or the Internet, and may forward data packets between each subscriber unit and such external networks. A subscriber device that has established an active connection via the traffic channel with one or more transceivers of the modem pool is called an active subscriber device and is considered to be in the traffic state. A subscriber device that is in the process of establishing an active connection via a traffic channel with one or more transceivers of the modem pool is considered to be in the state of establishing a connection. A subscriber's device can be any device for data transmission, which communicates via a wireless channel or a wired channel, for example, using fiber optic or coaxial cables. The subscriber device can also be any of a number of devices, i) which includes, without limitation to the above, a PC card, a compact flash, an external or internal modem, or a wireless or wired telephone device. The communication line on which the subscriber device sends signals to the transceiver of the modem pool is called the reverse communication line. The communication line on which the transceiver of the modem pool sends signals to the subscriber's device is called a direct communication line.

Figure 1 shows a structural diagram of an exemplary version of a multi-stage device for restoring the carrier frequency. In the shown variant, carrier frequency restoration is divided into two levels, one uses the source 114 of the analog carrier signal, and the other uses the source 110 of the digital carrier signal. A variant using more than two levels or other combinations of analog and digital o levels is possible. co

The signal is received by the antenna 100 and mixed with the analog signal of the carrier frequency in the analog converter 102. The analog carrier signal is produced by a variable frequency signal source, such as a voltage controlled generator (VCG) 114. The frequency of the carrier signal generated by the VCG 114 varies depending on the input voltage. The input voltage is based on a digital control signal provided by the control processor 112. In the exemplary embodiment shown, the digital control signal is converted to an input voltage in the DCC 114 using a pulse density modulator (PDC) 118 and a low-pass filter (LFF) 116. MSHCI 118 receives a digital value from the control processor 112 and outputs a sequence of pulses having a working ;" a loop that is based on a given digital value. FNU 116 can be a simple KS-chain, or an integrator, or any equivalent circuit. The low-pass filter 116 converts the sequence of pulses from the output of the MSHI 45. 118 into a direct current voltage, which determines the frequency of the carrier signal at the output of the GKN 114. In an alternative

Go! variants MSHCI 118 and FNU 116 are replaced by a simple digital-to-analog converter (DAC).

The difference in voltage adjustments that can be made at the input of the GKN 114 is relatively low. In other words, a change of the lower order in the digital value coming from the control processor 112 in the MSHI 118 can cause a relatively large change in the frequency of the carrier signal at the output of the GKN 114. Thus, the control processor 5o 0112 usually cannot ensure the matching of the carrier signal on outputs GKN 114 with the carrier frequency of the signal,

Me received from the antenna 100. Even if the low-pass filter 116 and the low-pass filter 118 are replaced with a high-resolution DAC, the analog

Ge noise at the input of the GKN 114 will make the precise adjustment of the output frequency of the GKN very imprecise.

Due to the expected frequency mismatch between the output of the GKN 114 and the carrier frequency of the signal received from the antenna 100, the output signal of the analog frequency converter 102 is not a pure signal of the band of modulating bignals (baseband). In other words, the output signal of the analog-to-frequency converter 102 will generally preserve the low-frequency component of the carrier.

F) In the illustrated example, the residual low-frequency carrier is extracted from the required baseband signal in the digital section. Therefore, the output signal of the analog frequency converter 102 is subjected to digital sampling in the sampler 104 and is mixed with a low-frequency digital carrier in the digital frequency converter 106. The output signal of the digital frequency converter 106 is a down-converted baseband signal, which is fed to such known decoding circuits as filters, convolution devices of the PS signal and/or Walsh sequences, inverse interleaving devices and decoders.

Digital generator 110 generates a low-frequency digital carrier. The carrier frequency generated in the digital generator 110 can be adjusted with a higher resolution than the carrier frequency generated by the GKN 114, although the GKN 114 can be adjusted over a wider frequency range. For example, the GKN 114 can produce signals in the frequency range -7-45 megahertz in steps of 30 hertz, and the digital generator 110 can generate signals with arbitrarily high resolution and a frequency range limited only by the sampling frequency of the analog-to-digital converter. It should be clear to those skilled in the art that obvious options for using other combinations of digital and analog frequency generators and frequency converters are alternatives to the above-described embodiment of the invention.

In one exemplary embodiment, the digital generator 110 is a digital rotator capable of generating frequency and phase correction signals with high resolution. By increasing the number of bits used to represent the frequency and phase inputs, a digital rotator with higher frequency and phase resolution can easily be constructed. In an alternative embodiment, the digital generator 110 is a digital 7/0 binesizer with direct frequency synthesis (FFS). The digital generator 110 may also be any other type of digital reference frequency generator. GKN 114 can be any of a number of voltage-controlled generators, including a quartz oscillator with temperature stabilization (CGTS) or a thermostated quartz generator (TSCG).

The frequency tracking module 108 measures the residual frequency error in the output signal of the digital /5 frequency converter 106 and generates at least one error signal that is fed to the control processor 112. The control processor 112 uses this at least one error signal from the frequency tracking module 108 to corrections of the control signals supplied to the digital generator 110 and MSHCI 118.

By making a change in the control signal supplied to the MUSCLE 118, the control processor 112 changes the frequency of the signal at the output of the GKN 114.

In one exemplary embodiment of the invention, the control processor 112 adjusts the output frequency of the GKN 114 so that the required residual frequency correction is within the given optimal or operating range of the digital oscillator 110. For example, even if the digital generator 110 is capable of generating frequencies in a band width of several megahertz, the GKN 114 is adjusted so that the frequency of the digital oscillator 110 can be kept within a band width of 128 hertz. In addition, it may be necessary to keep the reference frequency of GKN sch ov Relatively close to the carrier frequency of the received signal. Correction of the frequency of the GKN 114 so that it is as close as possible to the received carrier frequency will lead to a decrease in the frequency of the signal at the output of the digital generator i) 110.

In addition, in order to maintain the operation of the digital generator 110 in the optimal or operating frequency range, the control processor 112 increases the frequency of the GKN 114 and decreases the frequency of the digital generator 110. Conversely, if necessary, the control processor 112 decreases the frequency of the GKN 114 and increases the frequency of the digital generator 110. generator 110. ise)

In one exemplary embodiment of the invention, the control processor 112 adjusts the coarse frequency in steps of the same frequency by varying the digital control signal applied to the DPI 118. For example, if the DPI has a resolution of 30 Hz per bit, the control processor 112 may increase the DPI control signal by 30 . At the same time, the control processor 112 co adjusts the control signal sent to the digital generator 110, so that the output frequency of the digital generator 110 is reduced by 30, 60 or 90 Hz. Due to the low resolution of the output signal of the GKN 114, the size of the frequency step for the GKN 114 can only be estimated. | in contrast, the frequency step size of the digital oscillator 110 is very precise. Therefore, even after correcting the frequency of the digital generator 110 to compensate for the step change in the frequency of the GKN 114, the digital generator 110 must undergo additional correction before the output signal of the digital frequency converter 106 will have a frequency and phase that are most consistent with the frequency and phase of the received carrier signal . 2 shows a more detailed diagram of a variant of the frequency tracking module 108 suitable for use in a VPD system. In one exemplary embodiment, the receiver uses exclusively the signals received in the two pilot signal packets received in each time slot ("time slot"). For example, in the system

Go! In VDP, each such time slot has a duration of 1.667 milliseconds, with one pilot packet centered in each half of the time slot. In other words, each time slot has a first pilot packet centered at 417 milliseconds from the start of the time slot and a second pilot packet centered at 1.25 k milliseconds from the start of the frame. In the VPD system, each pilot signal packet has a duration of 96 code elements of the big signal at a transmission frequency of code elements equal to 1.2288 megahertz. Before transmitting packet signals

Me, the pilot signal is multiplied by a pseudo-noise (PS) sequence. Frequency tracking module 108 is shown

Ge in Fig. 2, serves to remove the PS component from the down-converted baseband signal received from the digital frequency converter 106, and accumulates part of the signal received in the pilot signal packets.

The synchronizer 210 code elements of the pilot signal packet generates synchronization signals during the pilot signal packets of each received time slot. Synchronous signals are fed to the PSH 208 generator, which then

F) generates a PS signal having the same synchronization frequency as the synchronizer of 210 code elements of the pilot signal packet. This PS signal is then mixed with the down-converted baseband signal in a digital frequency converter 202 to produce a PS compressed pilot signal. The PS compressed pilot signal is then accumulated during the period of the pilot signal packet in the accumulating adder 204. The output signal of the accumulating adder 204 will be a phase error signal that corresponds to the phase error of the now fully demodulated pilot signal. This phase error signal is then fed to a frequency tracking (FFT) system 108, which converts the phase error signal into a digital signal that can be used by the control processor 112. It should be understood by those skilled in the art that the FFT 108 can be a first-order 65 bistem, a second-order system, or another IED configuration.

In one exemplary embodiment of the invention, the frequency tracking module 108 produces one estimate of the phase error per time slot using two periods of pilot signal packets in the time slot. Alternatively, the frequency tracking module 108 produces more than one phase error estimate per time slot. For example, the frequency tracking module 108 may produce one estimate of the phase error for each period of half of the pilot packet, resulting in four estimates of the phase error. The phase error estimation data can then be used to estimate the rate of phase change, and thus the residual frequency error in the baseband signal. Because of the shorter sampling period used to produce the phase error estimate, phase error measurements based on half a pilot packet contain more noise than a single estimate produced over two pilot packet periods. In another alternative, one estimate of the phase error is produced for each period of the pilot packet in the time slot, resulting in two estimates of the phase error. In another alternative, one estimate of the phase error is produced using the periods of the pilot signal packet in more than one time slot.

Due to spectral overlay problems, the choice of the number of phase error estimates for a given number of time slots represents a trade-off between signal noise and the amount of detectable frequency error. In an alternative /5 variant, the frequency tracking module 108 can be configured by the real-time control processor 112 to operate in any of several modes, each of which uses a different ratio of phase error estimates to time slots.

In the VPD system, the pilot signal is expanded using an all-ones code, so there is no need for a Walsh convolution device between the frequency-to-digital converter 202 and the integrator 204. In one 2nd Exemplary embodiment of the invention, the PN generator 208 generates the complex PN code, and the digital converter 0202 frequency is a complex multiplier. The complex output signal of the digital frequency converter 202 is accumulated in the accumulating adder 204 so that the phase information is stored in the real and imaginary parts of the accumulated value.

Fig. 3 presents the algorithm for performing an exemplary method of correcting the frequencies of the down-conversion of the low-frequency conversion in the multi-stage carrier frequency restoration system shown in Fig. 1. During the operation of the carrier frequency restoration system, step 302 monitors the exact value of the frequency E;, to determine when the system i) is operating in the optimal or operating frequency range of the source of the exact frequency generation, such as the digital generator 110 shown in Fig.1. At step 304, the exact value of the frequency E ; is checked to determine whether the coarse output frequency of the coarse frequency generation source, such as the GKN 114 shown in Fig. 2, needs to be corrected. If correction is required, both frequencies are corrected at step 306 - ER; and Eb. If correction is not required, then correction step 306 is skipped. If at stage 306 EE"; increases, then Es decreases ise) by approximately the same amount. If E, decreases, then ER; increases by approximately the same amount. with

It should be clear to those skilled in the art that information and signals can be presented using any of a number of other methods and technologies. For example, data, instructions, commands, information, signals, bits, symbols, etc

335 The code elements that may be mentioned above can be represented as voltages, currents, electromagnetic waves, magnetic fields or particles, optical fields or particles, or any combination thereof.

Those skilled in the art should also appreciate that the various illustrative logic blocks, modules, circuits, and algorithm operations described in connection with the disclosed embodiments may be implemented in electronic hardware, computer programs, or combinations thereof. In order to clearly show such interchangeability of hardware and software tools, various illustrative components, blocks, modules, circuits and operations have been described above based on their primary functional purpose. Implementation of these functions in hardware or software depends on . specific application and constructive limitations imposed on the system in general. Experienced specialists and? will be able to implement the functions described above in different ways for each specific application, but these solutions should not be considered beyond the scope of this invention.

The various illustrative logic blocks, modules and circuits described in connection with the disclosed embodiments of the invention can be implemented or performed using a general-purpose processor, digital signal processor (DSP), application integrated circuit (API), programmable gate array in operating conditions (VMPE), or other programmable logic device, a separate gate or co-transistor logic circuit, separate hardware components, or any combination thereof, intended for

Performance of the described functions. A general purpose processor can be a microprocessor, but alternatively this

Me. the processor can be any conventional processor, controller, microcontroller or terminal

It's automatic. A processor, such as the control processor 112 described above, can also be implemented as a combination of computing devices, for example, a combination of a CPU and a microprocessor, a plurality of microprocessors, one or more microprocessors together with a CPU core, or any such configuration.

The operations of the method or algorithm described in connection with the disclosed embodiments of the invention can be implemented directly in hardware, in a software module executed by a processor, or in their

F) combinations. The program module can be permanently located in RAM memory, flash memory, PZP memory, EPPZP memory, PPZP memory, registers, on a hard disk, a removable disk, SO-COM, or on any any other known form of information carrier. The sample data carrier is connected to the processor in such a way that the processor can read and write information on it. Alternatively, the storage medium may be embedded in the processor.

Such a processor and information carrier can be located in the ISPP. This ISPP can be located in the subscriber's device. Alternatively, the processor and the information carrier can be separate components of the subscriber's device.

The above description of the variants will enable any person skilled in the art to make or use the present invention. 65 Various modifications of these variants will be apparent to those skilled in the art, and the described general principles of the invention can be applied to other variants without departing from the scope of the invention. Therefore, the present invention is not limited to the described variants, but has the widest scope corresponding to the disclosed principles and new essential features.

Claims (36)

2 Formula of the invention 1. A method of down-conversion of a received signal, which consists in generating an analog carrier signal having a first frequency from a first generation source having a first 70 frequency range and a first frequency difference, generating a digital carrier signal having a second frequency, from the second generation source, which has a second frequency range and a second frequency resolution, the first frequency range being greater than the second frequency range, and the first frequency resolution less than the second frequency resolution, and multiplying the received signal by an analog carrier signal and a digital signal carrier to produce a /5 down-converted signal. 2. The method according to claim 71, which is characterized by additionally measuring the residual frequency error in the down-converted signal and correcting the second frequency based on said measurement. C. The method according to claim 1, which is characterized by the fact that the first frequency is additionally increased by the step size of the coarse frequency and the second frequency is decreased by the step size of the coarse frequency. 4. The method according to claim 1, which is characterized by the fact that the first frequency is additionally reduced by the coarse frequency step size and the second frequency is increased by the coarse frequency step size. 5. The method of down-conversion of the received signal, which consists in generating an analog carrier signal having a first frequency from a first generation source having a first frequency range and a first frequency difference, then multiplying the received signal by an analog carrier signal for generating a corrected analog signal, o sampling the corrected analog signal to obtain a stream of digital samples, generating a digital carrier signal having a second frequency from a second generation source having a second frequency range and a second frequency resolution, the first frequency range being greater than the second frequency range, and the first frequency difference is less than the second frequency difference, and multiply the corrected analog signal by the digital carrier signal to produce a down-converted signal. bachelor's degree The method according to claim 5, which is characterized by additionally measuring the residual frequency error in the down-converted signal and correcting the second frequency based on said measurement. at 7. The method according to claim 5, which is characterized by the fact that the first frequency is additionally increased by the step size of the coarse frequency and the second frequency is decreased by the step size of the coarse frequency. 8. The method according to claim 5, which is characterized by the fact that the first frequency is additionally reduced by the coarse frequency step size and the second frequency is increased by the coarse frequency step size. 9. A device for down-conversion of the received signal, containing " 20 means for generating an analog carrier signal having a first frequency from a first generation source, which with c has a first frequency range and a first frequency resolution, means for generating a digital carrier signal , having a second frequency, from a second generation source having a second frequency range and a second frequency resolution, wherein the first frequency range is greater than the second frequency range and the first frequency resolution is less than the second frequency resolution, and means for multiplying of the received signal into an analog carrier signal and a digital carrier signal to produce a down-converted signal. 10. The device according to claim 9, which is characterized by the fact that it additionally contains means for measuring the residual frequency error in the down-converted signal and means for correcting the second frequency based on said measurement. 11. The device according to claim 9, which is characterized by the fact that it additionally contains a means for increasing the first frequency by (2) a coarse frequency step size and a means for reducing the second frequency by a coarse frequency step size. GE 12. The device according to claim 9, which is characterized by the fact that it additionally contains a means for reducing the first frequency by a coarse frequency step size and a means for increasing the second frequency by a coarse frequency step size. 13. A device for down-conversion of a received signal, comprising means for generating an analog carrier signal having a first frequency from a first generation source having a first frequency range and a first frequency resolution, (F) means for multiplying the received signal by an analog a carrier signal for generating a corrected GI analog signal, a sampler for sampling the corrected analog signal to obtain a stream of digital samples, means for generating a digital carrier signal having a second frequency from a second generation source having a second frequency range and a second frequency resolution, and the first frequency range is greater than the second frequency range and the first frequency resolution is less than the second frequency resolution, and means for multiplying the rectified analog signal by the digital carrier signal to produce a down-converted signal. 14. The device according to claim 13, which is characterized by the fact that it additionally contains means for measuring the residual frequency error in the down-converted signal and means for correcting the second frequency based on said measurement. 15. The device according to claim 13, which is characterized by the fact that it additionally contains a means for increasing the first frequency by a coarse frequency step size and a means for reducing the second frequency by a coarse frequency step size. 16. The device according to claim 13, which is characterized by the fact that it additionally contains a means for lowering the first frequency by a coarse frequency step size and a means for increasing the second frequency by a coarse frequency step size. 17. A receiving device comprising an analog generator having a first frequency range and a first frequency resolution for generating a 7/o analog carrier signal having a first frequency, an analog frequency converter for multiplying the received signal by an analog carrier signal to produce a first converted from by reducing the frequency of the signal, a digital generator having a second frequency range and a second frequency resolution to generate a digital carrier signal having a second frequency, the first frequency range being greater than the second /5 frequency range and the first frequency resolution being less than the second frequency range discrimination, and a digital frequency converter for multiplying the first down-converted signal by the digital carrier signal to produce the second down-converted signal. 18. The device according to claim 17, which is characterized by the fact that it additionally contains a frequency tracking module for measuring the residual frequency error in the second down-converted signal and a control 2o processor for correcting the first frequency of the first carrier signal and the second frequency of the second carrier signal based on said measurement . 19. The device according to claim 18, which is characterized in that the frequency tracking module is a frequency tracking system. 20. The device according to claim 18, which is characterized by the fact that the frequency tracking module is a first-order frequency tracking system. 21. The device according to claim 18, which is characterized by the fact that the frequency tracking module is a system of i) frequency tracking of the second order. 22. The device according to claim 17, characterized in that the digital generator is a digital rotator. 23. The device according to claim 17, which is characterized by the fact that the digital generator is a digital synthesizer with direct frequency synthesis. 24. The device according to claim 17, characterized in that the analog generator is a voltage-controlled generator. ise) 25. The device according to claim 17, which is characterized by the fact that the analog generator is a quartz generator with temperature stabilization. 26. The device according to claim 17, which is characterized by the fact that it further includes a pulse density modulator for forming a pulse train having a duty cycle that varies according to the digital input signal, and a low-pass filter for converting the pulse train into a voltage that is approximately time-invariant, wherein the time-invariant voltage magnitude varies according to the duty cycle of the pulse train, and the first frequency varies according to the approximately time-invariant voltage. " 27. The device according to claim 17, which is characterized by the fact that it additionally contains a control processor for correcting the first frequency and the second frequency. . 28. The device according to claim 27, which is characterized by the fact that it additionally contains a machine-readable medium, which is connected to the mentioned control processor and contains a program module executed by the mentioned control processor, while the execution of the program module by the control processor ensures the implementation of the conversion method with frequency reduction of the signal received by said receiving device, which includes measuring the residual frequency error in the down-converted signal and correcting the second frequency based on said measurement. o 29. The device according to claim 27, which is characterized by the fact that it additionally contains a machine-readable medium, which is GI connected to the mentioned control processor and contains a program module executed by the mentioned control processor, while the execution of the program module by the control processor ensures the implementation of the method Me. conversion with a decrease in the frequency of the signal received by the mentioned receiving device, which includes increasing the first frequency by the size of the coarse frequency step and decreasing the second frequency by the size of the coarse frequency step. ZO. The device according to claim 27, which is characterized by the fact that it additionally contains a machine-readable medium, which is connected to the mentioned control processor and contains a program module executed by the mentioned control processor, while the execution of the program module by the control processor ensures the implementation of the method (F, down-conversion frequency of the signal received by the said receiving device, which includes decreasing the first frequency by the step size of the coarse frequency and increasing the second frequency by the step size of the coarse frequency. 31. Machine-readable medium for storing the software module, made with the possibility of execution by the software processor of the receiving device, while the execution of the software module by the processor ensures the implementation of a method of conversion with a decrease in the frequency of the signal received by the receiving device, which includes the generation of a first frequency control signal to control the first frequency of the analog signal 65 of the carrier at the output of the analog generator having the first frequency range and the first frequency resolution, generating a second frequency control signal to control the second frequency of the digital carrier signal at the output of the digital generator having the second frequency range and the second frequency resolution, and the first frequency range greater than the second frequency range, and the first frequency resolution is less than the second frequency resolution, measuring the residual frequency error in the down-converted signal and correcting the second frequency based on said measurement I. 32. The machine-readable medium according to claim 31, which is characterized by the fact that the method implemented during the execution of the mentioned module additionally includes correction of the first frequency control signal to increase the first frequency by the step size of the coarse frequency and correction of the second frequency control signal to decrease the second /o frequency by coarse frequency step size. 33. The machine-readable medium according to claim 31, which is characterized by the fact that the method implemented during the implementation of the mentioned module additionally includes correction of the first frequency control signal to reduce the first frequency by a step size of the coarse frequency and correction of the second frequency control signal to increase the second frequency by a step size coarse frequency. 34. The machine-readable medium according to claim 31, which is characterized by the fact that in the method implemented in the execution of the mentioned module, the first frequency control signal is a digital signal that is fed to the pulse density modulator of the mentioned analog generator. 35. The machine-readable medium according to claim 31, which is characterized by the fact that in the method implemented in the execution of the mentioned module, the control signal of the second frequency is a digital signal that is fed to the digital rotator 2o of the mentioned digital generator. 36. The machine-readable medium according to claim 31, which is characterized by the fact that in the method implemented in the execution of the mentioned module, the second frequency control signal is a digital signal that is fed to a digital synthesizer with direct synthesis of the frequencies of the mentioned digital generator. s schi 6) s (Se) s «c) d) - and? (ee) («c) name) (o) Ko) name) 60 b5