RU2821367C1 - Radio frequency modulation method - Google Patents

Abstract

FIELD: wireless communication systems; digital communication technology.

SUBSTANCE: result is provided due to the fact that the output register of the digital information source is conditionally divided into a number of connected K n-bit units, information from which is transmitted to the antenna unit of the transmitter, having n parallel-connected output stages. Each of the n-bit units K_i=N/n, where N is the capacity of the output register, an is the number of synthesizer frequencies, which coincides with the number of bits of each of the K_i units and the number n of output stages. Each of K_i n-bit units has its own amplitude of output pulses, and all similar bits of each K_i unit are connected to each other. This allows summing the output signals of each of them at one of the frequencies. Discharges are also connected to each of the n output units of the transmitter, and each of the n frequencies coming from the switch is supplied to the output units, creating n! combinations of frequencies, wherein a plurality of signals B is formed as B = n!mⁿ, where m is a possible number of amplitudes obtained in each of n output stages as a result of summation of signals of like digits.

EFFECT: high noise-immunity of the system, wider message alphabet and simple radio signal modulation scheme.

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Description

The invention relates to wireless communication systems, namely, digital communication technology, and can be used to transmit discrete information over radio communication channels.

There are quite a lot of methods for physically encoding digital information. Multi-position carrier keying, which exists in two main types: phase PSK and quadrature amplitude QAM, is currently considered the most effective. In this case, one carrier frequency is used and radiated into the air.

Devices that implement these methods are described in a number of sources, in particular, see Sklyar, Bernard. Digital communication. Theoretical foundations and practical application / Digital Communications: Fundamentals and Applications. - 2nd ed. - M.: “Williams”, 2007. - P. 1104. - ISBN 0-13-084788-7.

The disadvantage of these devices and the coding methods implemented in them is the limitations on the data transmission rate associated with the complexity of receiving signals subjected to multi-position manipulation at sufficiently large values of the parameter m.

The closest in technical essence is the method of spatial encoding and transmission of digital information adopted as a prototype, which consists in the fact that digital signals are emitted in the form of radio waves through an antenna unit, which receives one of n frequencies from a frequency synthesizer, which are modulated independently of each other. each other, and then are summed up in a summing device. This signal, total over all frequencies, is the output signal of the device arriving at the antenna, providing the number B = 2 ⁿ combinations of signals emitted into the air, where n is the number of frequencies of the synthesizer (see RF patent No. 2757486, IPC N03M 13/00, publ . 2021).

The disadvantage of this known method is the relatively complex circuit of the transmitter and, accordingly, the receiver, since with large values of the alphabet of transmitted messages, the modulation positionality increases due to the large number of amplitude values and initial phases of the encoded signals, and this, in turn, entails a significant decrease in noise immunity signal, which depends not only on the signal-to-noise ratio, but also on the configuration of the “constellation” used.

The technical problem to be solved by the invention is to increase the noise immunity of the system, expand the alphabet of messages and simplify the modulation scheme of radio signals.

The solution to the posed technical problem is achieved by the fact that in the method of radio frequency modulation, which consists in the fact that digital signals are emitted in the form of radio waves through n output stages, each of which receives one of the n frequencies from a frequency synthesizer to emit messages from a plurality of digital messages into the air B through an antenna unit containing n antennas, and each of which is connected to a source of digital information, according to the invention that the output register of the source of digital information is conditionally divided into a number of K n-bit blocks connected in series, information from which is supplied to the antenna unit of the transmitter , having n parallel-connected output stages, each of which emits signals at a given frequency, while the signal is sent from the frequency synthesizer to the switch, each of the n-bit blocks K _i =N/n, where N is the bit capacity of the output register, an is the number frequencies of the synthesizer, coinciding with the number of bits of each of the K _i blocks, as well as with the number n of the output stages of the transmitter, and each of the K _i n-bit blocks has its own amplitude of output pulses, all the same bits of each of the K _i blocks are interconnected, providing the summation of the output signals of each of them at one of the frequencies, and are also connected to each of the n output blocks of the transmitter, and each of the n frequencies coming from the switch is fed in a given order to the given output blocks, creating n! combinations of frequencies, while the set of signals B is formed as B=n!m ⁿ , where m is the possible number of amplitudes obtained in each of the n output stages as a result of adding signals of the same bits of each K _i block at any of the n frequencies and modulating this frequency .

The solution to the posed technical problem becomes possible due to the fact that the N - bit register in which the number to be transmitted is written is divided into a number of series-connected blocks, for example, into K1, K2, KZ, which are bitwise interconnected, and each of which has its own amplitude of output pulses. Bitwise combination of blocks allows, by summing the amplitudes of the same bits at each frequency, to obtain m amplitude values of the output signal in each output stage. In this way, a unique amplitude-frequency code of any number from a set of signals (alphabet of messages) B = m ⁿ is created, i.e., a kind of new type of amplitude modulation. The frequency switch allows, according to a given algorithm, in given combinations, to direct the frequencies generated by the frequency synthesizer to given output stages. Thus, the number of possible codes (alphabet of signals) increases by n! once. Consequently, the total number of combinations that the proposed method allows will be the value B=n!m ⁿ .

In this case, only signal amplitudes are used - only (2 ^K -1) amplitude values. Control of the initial phases of signals for the proposed type of modulation is not required, which obviously leads to a simplification of the modulator circuit.

The method of modulating a radio signal for transmitting digital information is illustrated by a drawing, which shows a block diagram of an amplitude-frequency modulator (Σ - modulator), explaining the principle of amplitude-frequency modulation (Σ - modulation) using carrier frequencies, the number of which for example is taken to be 5, namely f1… f5.

The following designations are used in the drawing:

K1, K2, K3 - blocks into which the output register of the transmitting device is conventionally divided;

4V, 2V, 1V - amplitudes of output signals from each of the blocks K1, K2, K3;

1 ¹ , 2 ¹ , 3 ¹ , 4 ¹ , 5 ¹ - serial numbers of digits in each of the blocks of the output register of the transmitting device;

f1, f2, f3, f4, f5 - frequencies supplied to the output stages of the transmitter from the frequency synthesizer.

The radio signal modulation method assumes that digital signals are emitted in the form of radio waves through several output stages of an antenna unit, each of which receives frequencies from the synthesizer for emission on the air through an antenna unit containing n antennas, messages from a certain set of digital messages B. Each of the output cascades are connected to a source of digital information, more precisely, to its output register.

The output register of the source, containing digital information to be broadcast, is conventionally divided into a number of n-bit blocks connected in series, for example, K1, K2, K3. Then the information is sent to the antenna unit of the transmitter, which has n parallel-connected output stages, each of which emits signals at a given frequency, according to a certain algorithm. The number of blocks is determined by the formula K _i =N/n, where N is the capacity of the output register, and n is the number of frequencies of the synthesizer, which coincides with the number of bits of each of the K _i n-bit blocks, as well as the number n of the transmitter output stages.

All digits 1 ¹ ... 5 ¹ of each of the K ⁱ blocks have their own amplitude of output pulses, and, in addition, all the digits of the same name of each of the K _i blocks are interconnected. This ensures the summation of the output signals of each of the bits at one of the frequencies at which, according to a given algorithm, each of the K _i n-bit blocks is currently emitting. Due to the fact that each of the blocks can emit signals at any of the five f1 ... f5 frequencies, the set of signals B, which is formed in this way, is determined by the formula B = n!m ⁿ , where m is the possible number of amplitudes obtained in each of the n output cascades as a result of adding signals of the same digits of each K _i block at any of the n frequencies.

The method is implemented by a device that includes the output register 1 of the transmitting device, containing, for example, a 15-bit binary number, and conditionally divided, for example, into three independent blocks K1, K2, K3, each of which has its own amplitude of the output signals. The device also includes a block of 2 output stages containing five parallel channels, a 3-frequency switch and a 4-frequency synthesizer generating five different frequencies.

The method of modulating a radio signal is that digital signals from each of the bitwise combined K blocks are summed up in block 2 of the output stage, which allows for each number to be transmitted to obtain a unique amplitude-frequency code, and are subsequently emitted at frequencies f1 ... f5, the numbers of which are set, according to the adopted algorithm, by a 3-frequency switch.

The device implements the method as follows.

When digital information arrives in output register 1, the first 32 bits are written to any of the bits 1 ¹ , 2 ¹ , 3 ¹ , 4 ¹ , 5 ¹ of the first block K1, which has output pulse amplitudes of 4 V. Numbers with a large number of bits can be written sequentially in the second block K2, and then into the third block K3, which have output pulse amplitudes different from the amplitude of the first output block, as well as from each other, namely 2V and 1V, respectively.

The amplitude of each output register of one or another block K _i received from one or another bit 1 ¹ ... 5 ¹ is “automatically” summed up with the amplitude of the same bit of one or two other blocks K1-K3. This allows for each number from the set B (alphabet) of transmitted messages to create a unique amplitude-frequency code corresponding to the transmitted number.

Thus, each of the five bits 1 ¹ ... 5 ¹ of each of the blocks K ... K3 can be associated with any of the five f1 ... f5 frequencies, the numbers of which at the time of signal emission are set, according to the adopted algorithm, by switch 3.

According to the rules of Combinatorics (see, for example, Combinatorics, Vilenkin N.Ya., Vilenkin A.N., Vilenkin P.A., 2006), with the number of output stages n and the number of amplitudes in each of them m, and taking into account the possibility "rearrange" the frequencies in the output stages, you can create a set of B=n!m ⁿ different combinations of output signals. Really mastered modern technologies make it possible to use a modulation density of 2 ¹⁰ =1024 (alphabet of messages), using dozens of gradations of amplitudes and phases, which significantly reduces the noise immunity of the system.

In our case, we consider an example where five frequencies f1-f5 and three amplitudes of the bit signals of the output register of the transmitter are used: 1 V, 2 V, and 4 V. In this case, the possible number of total amplitudes at the output of each channel is eight: 0. 1, 2, 3, 4, 5, 6, 7. Therefore, in our case, the number of possible combinations (alphabet of messages) B=5!8 ⁵ =120*2 ¹⁵ =2 ^6.9 *2 ¹⁵ =3932160=2 ^{21 ,9} . This means that the proposed scheme allows you to transmit in one clock cycle any of 3932160=2 ^21.9 code values, which is significantly more than modern technologies.

Thus, in the proposed method, the number of amplitudes used is only 7 = 2 ³ -1, in addition, all signals have the same initial phases, which significantly simplifies the circuits of the modulator and the corresponding signal demodulator.

Using the proposed scheme, using five frequencies, 7 amplitudes and not using the initial phase of the signal as an information parameter, it is possible to significantly expand the alphabet of transmitted messages by 2 ^21.9 / 2 ¹⁰ = 3821.7 times, i.e., transmit binary number 2 ^11.9 . At the same time, a multiple reduction in the number of amplitudes of the transmitted signal, as well as the elimination of its initial phase as an information parameter, can significantly improve the quality of radio exchange and simplify modulation schemes and subsequent demodulation of the radio signal.

Thus, the invention makes it possible to increase the noise immunity of the system, expand the alphabet of transmitted messages, and also simplify the modulation schemes of the radio frequency carrying the useful signal.

Claims (1)

A method of radio frequency modulation, which consists in the fact that digital signals are emitted in the form of radio waves through n output stages, each of which receives one of n frequencies from a frequency synthesizer for broadcasting messages from a set of digital messages B through an antenna unit containing n antennas, and each of which is connected to a source of digital information, characterized in that the output register of the source of digital information is conditionally divided into a number of K n-bit blocks connected in series, information from which is supplied to the antenna unit of the transmitter, which has n parallel-connected output stages, each of which emits signals at a given frequency, while from the frequency synthesizer the signal is sent to the switch, each of the n-bit blocks K _i =N/n, where N is the capacity of the output register, an is the number of frequencies of the synthesizer, coinciding with the number of bits of each of K _i blocks, as well as with a number n of output stages of the transmitter, and each of the K _i n-bit blocks has its own amplitude of output pulses, all the same-name bits of each of the K _i blocks are interconnected, ensuring the summation of the output signals of each of them on one of frequencies, and are also connected to each of the n output blocks of the transmitter, and each of the n frequencies coming from the switch is supplied in a given order to the given output blocks, creating n! combinations of frequencies, while the set of signals B is formed as B=n!m ⁿ , where m is the possible number of amplitudes obtained in each of the n output stages as a result of adding signals of the same bits of each K _i block at any of the n frequencies and modulating this frequency .

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