RU2013873C1 - Code modulator - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: code modulator has Walsh functions synthesizer, formed by master oscillator, unit for forming Walsh functions and frequency divider, numerical sequence generator, digital commutator, constant voltage supply, switch unit, frequency divider, switches. Frequency divider, NOT gate and multiplier are brought into the device additionally. EFFECT: improved reliability of operation. 5 dwg

Description

 The invention relates to radio engineering and can be used for code modulation of signals in various radio engineering devices.

 A code modulator is known that contains a Walsh function synthesizer, a numerical sequence generator, a digital switch, a constant voltage source, and a key unit (see G.I. Tuzov, V.A. Sivov et al. Interference immunity of radio systems with complex signals. M.: Radio and Svyaz, 1985, p. 69, Fig. 2.19, d).

 However, the output signals generated by the known code modulator have a large effective spectral width, which leads to low efficiency of using the frequency band to degrade the performance of the code modulator.

 The closest in technical essence to the invention is a code modulator containing a Walsh function synthesizer, consisting of a Walsh function generation unit, a frequency divider and a master oscillator, a numerical sequence generator, a digital switch, a constant voltage source, a key unit, an additional frequency divider and keys, moreover the output of the master oscillator is connected to the clock input of the Walsh function generation unit and to the clock input of the frequency divider, the output of which is the first clock output the synthesizer, the second clock output of which is the output of the master oscillator, the outputs of the Walsh function generation unit are the information outputs of the synthesizer, the first clock output of the synthesizer is connected to the clock input of the numerical sequence generator, the output of which is connected to the control input of the digital switch, the output of which is connected to the first input of the key block the second input of which is connected to the output of a constant voltage source, the output of an additional frequency divider is connected to the control key inputs, the information inputs of which are connected to the corresponding information outputs of the Walsh function synthesizer, the second clock output of which is connected to the input of an additional frequency divider, and the key outputs are connected to the corresponding information inputs of the digital switch (see author St. N 1758893, cl. H 04 L 27/04, 1990).

 However, the known code modulator generates signals having a large spectrum width, which leads to low bandwidth efficiency.

 The aim of the invention is to reduce the width of the spectrum of the output signals.

This goal is achieved by the fact that in a known code modulator containing a Walsh function synthesizer, consisting of a Walsh function generation unit, a first frequency divider and a master oscillator, a numerical sequence generator, a digital switch, a constant voltage source, a key block, a second frequency divider and keys, moreover, the output of the master oscillator is connected to the clock input of the Walsh function generation unit and to the clock input of the first frequency divider, the output of which is the first synthesis clock output an oscillator, the second clock output of which is the output of the master oscillator, the outputs of the Walsh function generation block are information outputs of the synthesizer, the first clock output of the synthesizer is connected to the clock input of a numerical sequence generator, the output of which is connected to the control input of the digital switch, the output of which is connected to the first input of the key block the second input of which is connected to the output of the DC voltage source, the output of the second frequency divider is connected to the control inputs of the keys, the information inputs of which are connected to the corresponding information outputs of the Walsh function synthesizer, the second clock output of which is connected to the input of the second frequency divider, a third frequency divider, the element HE and multipliers are introduced, the first inputs of the multipliers connected to the corresponding outputs of the keys, the outputs of the multipliers connected to the corresponding information inputs digital switch, the second clock output of the synthesizer is connected to the input of the third frequency divider, the output of which is connected to the input of the element H and second inputs of the first to 2 ^n-1 -th multipliers (where 2 ⁿ - number generation unit outputs a Walsh functions), the output element is coupled to the second inputs to (2 ^n-1 +1) -th to ^n-th multipliers 2 .

 In FIG. 1 is a structural diagram of a code modulator; in FIG. 2 is a timing diagram illustrating the process of generating the output signal K (6, θ) in the proposed code modulator, FIG. 3 is a view of the signals at the output of the analog device; in FIG. 4 is a view of the signals at the output of the prototype device; in FIG. 5 is a view of the signals at the output of the proposed code modulator.

 The code modulator contains a Walsh function synthesizer 1, consisting of a master oscillator 2, a Walsh function generation unit 3 and a first frequency divider 4, a numerical sequence generator 5, a digital switch 6, a constant voltage source 7, a key block 8, a second frequency divider 9, keys 10, third frequency divider 11, element NOT 12, multipliers 13.

 Code modulator works as follows.

With the beginning of the arrival of pulses from the output of the master oscillator 2 to the input of the first frequency divider 4 having a division coefficient 2 ⁿ , a modulating numerical sequence g (t) is generated at the output of the number sequence generator 5. Since the division coefficient of the frequency divider 4 is equal to 2 ⁿ , each symbol of the numerical sequence corresponds to one period of the Walsh functions generated at the outputs of the Walsh function generation unit 3, the clock of which receives a pulse sequence from the output of the master oscillator 2.

The pulses from the output of the master oscillator 2 also go to the input of the second frequency divider 9, having a division ratio of 2 ^n-1 . Thus, during the first half-period of the formation of Walsh functions at the output of the second frequency divider 9, "0" is generated, which is supplied to the control inputs of the keys 10. During the second half-period of the formation of Walsh functions at the output of the second frequency divider 9, "1" is formed, which goes to the control inputs keys 10.

 As in the prototype, the keys 10 operate as follows. Upon receipt of the key 10 "0" at the control input, a signal is generated at its output that is transmitted to its first information input, and when a key 10 "1" is received at the control input, a signal is generated at its output that is sent to its second information input.

Thus, during the formation of one symbol of the modulating sequence g (t) at the output of the number sequence generator 5, at the outputs of the keys 10, the functions L (0, θ), L (1, θ), are formed. . . , L (2 ⁿ - 1, θ), the duration of which is equal to the duration of the Walsh functions generated at the outputs of block 3.

 The pulses from the output of the master oscillator 2 also go to the input of the third frequency divider 11 having a division coefficient 2, as a result of which the duration of the rectangular pulses is equal to the duration Δt of the elements of the functions L (i, θ). The pulses from the output of the third frequency divider 11 are fed to the input of the element HE 12, the output of which forms a sequence of rectangular pulses, the duration of which is also equal to the duration Δt of the elements of the functions L (i, θ).

Since the pulses from the output of the third frequency divider 11 are fed to the second inputs of the multipliers 13, the first inputs of which receive the first half of the functions L (i, θ), then the signals K (0, θ), are formed at the outputs of these multipliers. . . , K (2 ^n-1 - 1, θ).

The pulses from the output of the element NOT 12 are fed to the second inputs of the multipliers 13, the first inputs of which receive the second half of the functions L (i, θ), as a result of which the signals K (2 ^n-1 , θ), are formed at the outputs of these multipliers. . . , K (2 ⁿ -1, θ).

 The alphabet of the numerical sequence generator 5 consists of 2n characters. The digital switch 6 generates at the output of that signal K (i, θ), the sequence number of which corresponds to the alphabet symbol, which is received at the control input of the switch 6 from the output of the number sequence generator 5.

 The constant voltage source 7 and the key unit 8 perform the functions of a signal amplifier K (i, θ) to the level necessary for radiation.

 In FIG. 2 shows timing diagrams illustrating the process of generating the output signal K (6, θ) in the proposed code modulator.

The diagrams show the temporary state:
a) the output of the master oscillator 2;
b) the seventh output of the block 3 of the formation of Walsh functions, on which the function Wal (6, θ) is formed;
c) the second output of the block 3 of the formation of Walsh functions, on which the function Wal (1, θ) is generated;
d) the output of the second frequency divider 9;
d) the output of the seventh key 10, on which the function L (6, θ) is generated;
e) the output of the third frequency divider 11;
g) the output of the element is NOT 12;
h) the output of the multiplier 13, on which the signal K (6, θ) is formed.

 In FIG. 3 shows Walsh functions formed by an analog; in FIG. 4 shows the functions L (i, θ) generated by the prototype, in FIG. 5 shows the signals K (i, θ) generated by the proposed modulator.

 The orthogonality of the signals K (i, θ) generated by the proposed code modulator can be verified by multiplying any generated signals and integrating the result of multiplication over time T (where T is the signal period).

 To transmit the signals generated by the modulator without distortion, it is necessary to provide a frequency band for transmitting the wideband signal itself.

If all the spectra of the signals included in the system have the same width and occupy the same frequency band, then F _sist = F, where F _sist is the bandwidth occupied by the signal system, F is the spectrum width of a single signal). For different spectral widths, F _syst = F _max is the maximum spectral width (see L. Varakin, Theory of Signal Systems. M.: Soviet Radio, 1978, p. 11).

, (1) где Δt - длительность элемента сигнала;
μ- число блоков сигнала;
N - число элементов сигнала (см. Варакин Л. Е. Теория систем сигналов. М. : Советское радио, 1978, с. 208, соотношение 11.11). При этом блок - последовательность элементов, имеющих фазу 0 или π, т. е. последовательность положительных или отрицательных элементов сигнала (см. Варакин Л. Е. Теория систем сигналов. - М. : Советское радио, 1978, с. 177).The effective spectrum width W _{μeff of} the _widest signal is determined by the formula
W _μeff =

, (1) where Δt is the duration of the signal element;
μ is the number of signal blocks;
N is the number of signal elements (see L. Varakin, Theory of signal systems. M.: Soviet Radio, 1978, p. 208, ratio 11.11). In this case, a block is a sequence of elements having a phase of 0 or π, i.e., a sequence of positive or negative signal elements (see L. Varakin, Theory of Signal Systems. - M.: Soviet Radio, 1978, p. 177).

In the analogue (see Tuzov G.I., Sivov V.A. et al. Interference immunity of radio systems with complex signals. - M.: Radio and communications, 1985, p. 69, Fig. 2.19, d) output signals are described Walsh functions (see Fig. 3) having the number of blocks
μ = 1,2,3,. . . , N.

, (2)
(см. Варакин Л. Е. Теория систем сигналов. - М. : Советское радио, 1978, с. 208, таблица 11.1, строка 2).Consequently, the output signals generated by the analog have a different effective spectrum width, while the maximum effective spectrum width has an output signal with the number of blocks μ = N, i.e., the meander
W _μeff =

, (2)
(see L. Varakin, Theory of Signal Systems. - M.: Soviet Radio, 1978, p. 208, table 11.1, line 2).

или μ =

и значение наибольшей эффективной ширины спектра выходного сигнала с учетом μ =

и соотношения (1) определяется согласно выражению
W_μэфф=

=

=

(3)
Выходные сигналы в предлагаемом кодовом модуляторе имеют одинаковое количество блоков (см. фиг. 5):
μ =

и значение наибольшей эффективной ширины спектра выходного сигнала определяется по соотношению (1) с учетом μ =

W_μэфф=

=

(4)
Согласно общим положениям теории информации, каждый m- ичный символ (где m = 2ⁿ) переносит n = log₂m двоичных единиц, т. е. m-ичный символ эквивалентен кодовой последовательности из n двоичных символов. Длительность m-ичного символа может быть определена из соотношения
T_m=

, (5) где R - скорость передачи информации (см. Варакин Л. Е. Теория систем сигналов. - М. : Советское радио, 1978, с. 55, соотношение 2.14). Из соотношения (5) следует, что скорость передачи информации определяется как
R =

(6)
Таким образом, при заданном объеме алфавита m = 2ⁿ и заданной скорости передачи R длительность T_m сигналов, используемых в аналоге, прототипе и предлагаемом модуляторе одинакова.The output signals generated by the prototype have the number of blocks (see Fig. 4)
μ =

or μ =

and the value of the largest effective spectrum width of the output signal with μ =

and relations (1) is determined according to the expression
W _μeff =

=

=

(3)
The output signals in the proposed code modulator have the same number of blocks (see Fig. 5):
μ =

and the value of the largest effective width of the spectrum of the output signal is determined by the relation (1) with μ =

W _μeff =

=

(4)
According to the general principles of information theory, each m-ary character (where m = 2 ⁿ ) carries n = log ₂ m binary units, that is, an m-ary character is equivalent to a code sequence of n binary characters. The duration of the m-ary character can be determined from the relation
T _m =

, (5) where R is the information transfer rate (see L. Varakin, Theory of Signal Systems. - M.: Sovetskoe Radio, 1978, p. 55, ratio 2.14). From relation (5) it follows that the information transfer rate is defined as
R =

(6)
Thus, for a given volume of the alphabet m = 2 ⁿ and a given transmission rate R, the duration T _{m of the} signals used in the analogue, prototype and the proposed modulator is the same.

The table shows the calculation data for the maximum effective spectrum width W _μeff for output signals generated by an analog, prototype, and the proposed code modulator for the case T _m = 1.

 According to the results of the table, we can conclude that the effective width of the spectrum of the output signals generated by the proposed modulator is much smaller than that of the signals generated by the analogue and prototype.

 In particular, the width of the spectrum of the output signals generated by the proposed code modulator is less than that generated by the analog by 29.29% for signals with any number of elements N, and less than that generated by the prototype by 16.33% for N = 4, by 8.71% for N = 8, 4.51% for N = 16, etc.

 Using the invention allows the creation of code modulators that reduce the width of the spectrum of the output signals, which increases the efficiency of using the frequency band.

Claims (1)

A CODE MODULATOR containing a Walsh function synthesizer, consisting of a master oscillator, the output of which is connected to the input of the Walsh function generation unit and to the input of a frequency divider, the output of which is the first clock output of the Walsh function synthesizer, the second clock output of which is the output of the master generator, outputs of the formation unit Walsh functions are information outputs of the Walsh function synthesizer, the first clock output of which is connected to the input of a numerical sequence generator, the output of which connected to the control input of the digital switch, the second clock output of the Walsh function synthesizer is connected to the input of the first frequency divider, the output of which is connected to the control inputs of the keys, the information inputs of which are connected to the corresponding information outputs of the Walsh function synthesizer, characterized in that the second frequency divider is introduced, element NOT and multipliers, and the first inputs of the multipliers are connected to the corresponding outputs of the keys, the outputs of the multipliers are connected to the corresponding inputs of the digital comm Tatorey second clock output Walsh functions synthesizer coupled to the input of the second frequency divider, whose output is connected to the input of NOT circuit and the second inputs of the first to 2 ^n-1 -th multipliers, where 2 ⁿ - number of Walsh functions forming unit outputs an output of NOT connected to the second inputs with (2 ^n-1 - 1) - 2 ^n- th multipliers each.

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