SU1693726A1 - Method of transmission and reception of analog signals and device to implement it - Google Patents

Abstract

The invention relates to communication technology. The purpose of the invention is to reduce distortion at the transmitting side after the selection of the envelope of the input signal. For this, parallel transmission of two orthogonal components of the input signal — the envelope of the input signal and the high-frequency component transferred to the low frequencies — is carried out in parallel. The device contains the first phase shifter 1, the envelope selection block 2, the first and second dividers 3 and 4, the first and second multipliers 5 and 6, the first generator 7, the adder 8, the second generator 9, the modulator 10, the second phase shifter 11, the third and the fourth multipliers are 12 and 13, the subtractor 14. The device is based on a comprehensive representation of the signals received by the phase shifter. 2 sec. f-ly, 1 ill. (/

Description

The invention relates to communication technology and can be used to transmit analog information.

The purpose of the invention is the reduction of signal distortion.

The drawing shows a structural diagram of a device for implementing a method of transmitting and receiving signals.

The signal transmitting and receiving device. · Signals contains the first phase shifter 1 and the envelope extraction unit 2, - the first 3, the second 4 dividers, the first 5 and the second 6 multipliers, the first generator 15 torus 7, adder 8, second generator 9, modulator 10, a second phase shifter 11, a third 12 and a fourth 13 multipliers and a subtractor 14.

The envelope extraction block 2 contains 20 — the first quadrator 15, the second adder 16, the square root extraction block 17, and the second quadrator 18 live.

The essence of the method · transmission and reception of signals is as follows .. 25

Its basis is the selection of several substitution signals from the original signal. the rate of change of each of which is less. the rate of change of the original signal.

Any narrowband signal is possible; present in multiplicative form

S (t) = A (t) cos (G3 _o t + Lf (t) J, 0>

where A (t) q> (t) is the envelope of the signal;

- increment of the total phase of the signal; · - carrier frequency of the signal., Near which the signal spectrum is concentrated.

ω ₀ \ If the signal spectrum occupies the polo; of frequencies from the lower frequency to the upper COg frequency, then, provided the carrier frequency is equal to the average frequency of the signal spectrum

Every signal has the properties of a narrow-band signal and can be represented by the multiplicative form (1), since under this condition the rate of change of the envelope and phase of the signal is always less than the rate of change of the signal itself.

The envelope of the signal S (t) was chosen as one of the slow substitute signals - the value A -; (t) in expression (1), and the factor g (t) = coa (W _o t + Lp as the second substitute signal (t)) in the expression (1).

I cannot directly use the latter to achieve my goal because the spectrum of the signal along the occupied frequency band does not differ from the spectrum of the original signal, and therefore the rate of change of this signal in time is not inferior to that for the original signal. Therefore, with respect to the signal g (t), its spectrum is transferred from the carrier frequency C0 _a to the frequency CO = 0, as a result of which it is converted into a new signal; f. (t) = cos If (t). The substitute signals A (t) and f (t) contain the necessary and sufficient number of informative features of the original signal S (t).

The signal g (t) is extracted by dividing the original signal S (t) by its envelope A (t). On the receiving side, reverse actions are performed in the reverse order.

The operation of a device that implements a method of transmitting and receiving signals is based on a complex representation of signals, where the real ¹ component is the original signal S (t), and the imaginary one is its Hilbert’t transformation which, in the case of ·, corresponds to the original signal to the expression. (1). has the form '

S _r (t) = A (t) sin (tj3 _Q t + (t)) '. (2)

Therefore, all processing is performed in the device with respect to two signals: S (t) and S _r (t). In this case, the signal S _r (t) is obtained from the signal S (t) by changing the phase of the latter by 47/2.

The device works as follows: at once.

The input signal | IS2Sodny signal S (t) in the first phase shifter 1 is converted into a new signal S _r (t), phase shifted by 90 ° relative to the original. This new signal and the original signal are fed to the corresponding inputs of block 2, specifically, to the inputs of the first 15 and second 18 squares, respectively, where they are squared. The results of squaring are summed in the second adder 16, after which the square root in the block is extracted from the sum

17. The result of the described operation · is a signal in the form of an exact envelope A (t) = -JS ² (t) + S ² (t) 'of the original signal S (t), which then goes to the control inputs of the first 3 and second Rogo 4 dividers. An initial signal is supplied to the signal input of the first divider 3, and as a result of dividing it by the envelope A (t), the signal g (t) is generated at the output of the first divider 3. At the same time, the signal S _r (t) is supplied to the signal input of the second divider 4, and as a result of dividing it by the envelope A (t), the signal g _r (t) is generated at the output of the second jq divider 4.

Further, the results of the division in the form of signals g (t) and g ^. (T) are respectively input to the signal inputs of the first 5 and second 6 multipliers, on which, 5 control inputs, which receive respectively the cosine and sine transforms g ₀ (t) = cosCJ ₀ Cu g _iT , (t) = 3031 (0 ^ 6 harmonic oscillations with a frequency (Q _o from the first generator 7. 20

In this case, at the output of the first multiplier 5, a signal is generated in the form of the product g (t) g ₀ (t), and at the output of the second multiplier 6, a signal is formed in the form of the product g _r (t) gr _o (t), which sum 25 with the first adder 8, and on its turn the first substitute signal is formed in the form of an oscillation f (t) = costp (t), which enters the second communication channel. B. The first communication channel enters 30 envelope * A (t) in the form of a second substitute signal

From the output of the second communication channel, the first substitute signal f (c) is supplied to the second phase shifter 11, as a result of which, at the output, the signal _x f / (t) = s inf (t) is received. Further, the signals f (t) and (t). Arrive respectively at the signal inputs of the third 12 and fourth 13 multipliers, the control inputs of which receive respectively the cosine and sine signals g _o (t) and gf _o (t) from the second generator 9 with a frequency of C0 _about .

As a result, the products f (t) g _e (t) and f _r (t) g _ro (t), respectively, are formed at their outputs, of which the first comes as a deductible and the second as a deductible by a subtractor 14, to the output of which the difference in the form of the signal φ (t) = cos £ l0 _o t + if (t) 3 is formed as a result of the operation of transferring the spectrum of the signal f (t) from the frequency С0 = 0 to the frequency which then goes to the signal ^ the input of the modulator 10, the control input of which comes from the output of the first communication channel, the second signal is a substitute A (t), resulting in a modulator output 10, the original signal S (t) = A (t) ces [GV + q> (t) j.

Claims (2)

Claim 1. A method for transmitting and receiving analog signals, in which the envelope of the input signal is extracted on the transmitting side, this envelope is transmitted, and the input signal is received on the receiving side using the amplitude module — cip ”of the high-frequency oscillation of the received envelope of the input signal, characterized in that , in order to reduce distortion on the transmitting side after selecting the envelope of the input signal, divide the input signal by the selected envelope, 'the spectrum of the signal obtained as a result of division, transferring in the region of low frequencies and transmitted in parallel the input signal envelope, and at the receiving side the received baseband signal spectrum is transferred to the original frequency-domain and the resulting signal is used as the high-frequency oscillations modulating the received input signal envelope. 2. A device for transmitting and receiving analog signals, comprising an envelope extraction unit, a first and a second multiplier and a modulator, characterized in that, in order to reduce distortion, a first phase shifter, a first divider, a third multiplier and an adder are connected in series, and a second a divider and a fourth multiplier, as well as a first, second, and second generator, a second phase shifter and subtractor, the first and second output of the first generator being connected to the second input of the third and fourth, respectively of the multiplier, the first rf the second output of the second generator is connected to the first input of the first and second multipliers respectively, the output of which is connected respectively to the first and second input of the subtractor, the output of which is connected * with the first input of the modulator, the input of which is the output of the first communication channel, whose input is the output of the envelope selection unit, the second input of the first divider, t> the first input of the second divider, the second input of which is connected to the input of the first phase shifter and the first input of the envelope extraction unit, the second input of which is connected to the second input of the adder, the output of which is the input of the second communication channel, the output of which is the second input of the first multiplier and the input of the second a phase shifter whose output is connected to the second input of the second multiplier. g. Compiled by A. Mikutsky