RU2152075C1 - Method and device for simultaneous execution of precise division of instantaneous frequency and precise power calculation for acoustic signal envelope - Google Patents

Abstract

FIELD: instruments, in particular, recording and playing acoustic signals. SUBSTANCE: method for processing of input signal involves its Hilbert transform, preliminary multiplication by absolute value of Hilbert signal transform, and dividing by Hilbert signal transform. This operation after scaling produces output signal. Device has phase shifter, multiplier, analog signal divider, units calculating absolute value and sign functions, and scaling amplifier. EFFECT: improved quality for transmission of wide-band acoustic signals through narrow-band channels. 2 cl, 1 dwg

Description

 The group of inventions relates to the field of instrumentation, can be used in the transmission of audio signals, during their recording and reproduction, and is intended for simultaneous accurate analog division of the instantaneous frequency and accurate raising to the power of the envelope of the audio signals without causing noticeable distortions in the recovered signals and a noticeable decrease in the ratio signal / noise, which, for example, is necessary when implementing the invention according to A.C. USSR, N 1644212.

 A known method of frequency division proposed by Mark P. and Dage J. [1,2,3], for signals with a previously limited dynamic range.

 The reasons that impede the achievement of the required technical result when using the known method, namely, accurate analog division of the instantaneous frequency of the signals while simultaneously accurately compressing their dynamic range without noticeable distortion in the recovered signals and a noticeable decrease in the signal-to-noise ratio, include the fact that although the authors recorded the division of the instantaneous frequency on the transmitting side of the channel and its multiplication by reception, but in fact they did not what they recorded [3]. In our opinion, as an explanation, it suffices to say that the continuous change in the instantaneous frequency during signal processing using this method was replaced by a step one already on the transmitting side. This explains: the distortions that occurred, the loss of part of the information in the transmission process. In addition, the limited dynamic range could no longer be restored.

 The closest method of the same purpose to the one claimed in the group of inventions according to the totality of features is the method implemented in the device according to A.S. USSR N 714473.

 The closest device of the same purpose to the claimed device in the group of inventions is a device according to the USSR AS N 714473.

The reasons that impede the achievement of the required technical result when using the known method and device for its implementation, adopted as a prototype, is that for the simultaneous accurate compression of the frequency and dynamic ranges of the sound signal, it is necessary to precisely divide the instantaneous frequency of this sound signal and at the same time precisely raise to the power its envelope. To do this, you must:
- firstly, distinguish these modulating functions: the envelope and instantaneous frequency in the form of proportional voltages (or currents) to them;
- secondly, process them accordingly: 1) to scale down the voltage proportional to the instantaneous frequency by the required number of times; 2) to raise the voltage proportional to the envelope to the required degree;
- thirdly, to synthesize the required sound signal from these modulating functions obtained during processing.

 The reasons that prevent accurate division of the instantaneous frequency include the following.

 The fact of frequency demodulation in itself leads to a decrease in the noise immunity of a signal, as an action opposite to frequency modulation, which, as is known, allows one to obtain a gain in noise immunity. That is, the ratio of the power of the useful message to the noise power at the output of the FM demodulator is greater than the same ratio, but at the receiver input [4]. In other words, a frequency-modulated signal is less distorted by noise in the transmission channel than, for example, signals with amplitude modulation. It was established [4] that the instantaneous frequency of the sum of the signal and noise is almost equal to the instantaneous frequency of that oscillation, which is larger in magnitude. There is nothing but noise in the pauses of sounds in the transmission channel. Therefore, at the output of the frequency demodulator, we get not only the instantaneous frequency of the signal. At the output of the frequency demodulator, the instantaneous signal and noise frequencies replace each other with the repetition rate of pauses, since pauses are an integral part of audio signals. In addition, due to the suppression of a weak signal, the signal frequencies during transients are more distorted, and this is not only the beginning and end of each sound, but sometimes its very middle. This explains the noticeable distortion that arises in the recovered signals, and a noticeable decrease in the signal-to-noise ratio.

Reasons that prevent accurate envelope raising include the following:
1) the distortion of small levels of the envelope due to the presence of thermal noise and zero drifts in those circuit elements that separate and process it;
2) inaccurate practical implementation when performing exponentiation operations, especially for small signals.

 The invention consists in the following.

 The single task to be solved by the claimed group of inventions is to improve the quality of transmission of broadband audio signals through narrow-band channels. In particular, through channels with recording signals on a moving medium (for example, film tape).

The only technical result that can be obtained by implementing the group of inventions is the exact analog division by 2 times of the instantaneous frequency of the sound signal and the exact compression of its dynamic range, performed simultaneously by raising the envelope to a power of 2 ^-1 , and without isolating these modulating functions, which ensures the accuracy of the conversion and allows you to accurately restore the signals without causing them noticeable distortion and a noticeable decrease in signal-to-noise ratio. (An example of a device for accurate signal recovery is given in Appendix 1).

 The specified single technical result in the implementation of the group of inventions on the object - the method is achieved by the fact that, as in the known method, to obtain the output signal, the input signal during processing is converted according to Hilbert, but unlike the prototype, the input sound signal is multiplied by the signal sign function, obtained after the Hilbert transform; the resulting product is divided by the modulus of the signal obtained after the Hilbert transform; the division result is subjected to the Hilbert transform mentioned above, after which the sign function of this signal is generated, which is used in multiplication, in addition, the Hilbert-converted module of the signal used in the division is calculated, and in addition, the signal obtained after the Hilbert transform becomes output after the scale transform .

 As an example of the implementation of the proposed method, the proposed device.

 The specified single technical result in the implementation of the invention is achieved by the fact that in the known device containing a phase shifter that implements the Hilbert transform, a multiplier and a divider of analog signals, a module calculation unit, a sign function calculation unit and a scale amplifier are additionally introduced, the device input being formed by the first input of the multiplier, the second input of the said multiplier is connected to the output of the sign function calculation unit, the output of the multiplier is connected to the first input (numerator) of the cases of Tell analog signals, the second input of the divider (denominator) coupled to an output of calculating unit module having an input coupled to an output of the phase shifter and input scaling amplifier and a calculation unit in function of the sign, the divider output coupled to an input of the phase shifter, wherein the output of scaling amplifier is formed by the output of the entire device.

 The analysis of the prior art by the applicant, including a search by patents and scientific and technical sources of information, made it possible to establish that the applicant did not find an analogue for both the method and the device, characterized by features identical to all the essential features of both the method and the device of the claimed group of inventions , and the determination of the number of identified analogues of the prototype as the closest in the set of features allowed us to determine the set of significant in relation to the technical result recognition aka in the claimed subject matter set forth in the claims.

 Therefore, each of the objects of the claimed group of inventions meets the requirement of "novelty" of the current legislation.

 To verify the conformity of the claimed invention with the requirement of an inventive step, the applicant conducted an additional search for known solutions in order to identify features that match the features that are distinctive from the prototype, the results of which showed that each of the objects of the invention does not follow explicitly from the prior art, since the level of the technique defined by the applicant, the effect of the transformations provided for by the essential features of the claimed invention on the achievement of s technical result.

 Therefore, the claimed invention meets the requirement of "inventive step" of the current legislation.

Figure 1 shows the structural diagram of the claimed device, where 1 is the multiplier of analog signals; 2 - divider of analog signals; 3 - phase shifter; 4 - unit calculation module (absolute value of the signal); 5 - scale amplifier with a transmission coefficient M = 2 ^-0.5 ; 6 - block function calculation function of the sign.

 Information confirming the possibility of carrying out the invention to obtain the above technical result are as follows.

Причем текущая фаза представляет собой функцию мгновенной частоты ω(t), которая определяет частотные свойства реальных звуковых сигналов.We take as a mathematical model of the input signal
s _in (t) = S (t) sinx (t), (1)
where S (t) is the envelope, that is, the modulating function, which determines the amplitude of the signal at each moment of time, x (t) is the current phase, which is equal to

Moreover, the current phase is a function of the instantaneous frequency ω (t), which determines the frequency properties of real sound signals.

Suppose that at the output of the proposed device that implements the operations of the proposed method, an oscillation is formed
s _o (t) = Z (t) cos y (t), (3)
moreover, the following conditions must be met
Z (t) = S ^0.5 (t) and y (t) = x (t) / 2, (4)
Show it.

 Note.

 Since time does not transform, the last equality means that the instantaneous frequency should decrease by 2 times.

 The proposed device operates as follows.

The signal at the output of the analog signal multiplier (1, Fig. 1)
s _mind (t) = [S (t) sin x (t)] [sign (siny)]. (5)
As you know, the sign function - sign - takes only two values: plus and minus one, indicating the sign of the signal. Thus, equality (5) can be written as follows
s _mind (t) = S (t) sinx (t) for siny (t)> 0
s _mind (t) = -S (t) sinx (t) with siny (t) <0 (6)
Signal at the output of the analog divider
s _affairs (t) = s _mind (t) / [2S (t)] ^0.5 | siny (t) | (7)
This device implements the formula known from trigonometry
sin2a = 2sin (a / 2) cos (a / 2), (8)
which in our notation will take the form
S (t) sinx (t) = 2S (t) sin 0.5x (t) cos0.5x (t). (9)
Therefore, equality (7) can be rewritten for the values siny (t)> 0
s _affairs (t) {S (t) cosx (t) / [2S (t)] ^0.5 sin0.5x (t)} =
= [2S (t)] ^0.5 cos0.5x (t). (10)
For siny (t) <0, both the numerator (10) (as can be seen from (6)) and the denominator (due to the operation of the module) are multiplied by (-1). Thus, the signal at the output of the divider is always
s _affairs (t) = [2S (t)] ^0.5 cos0.5x (t).

After performing the Hilbert transform at the output of the phase shifter (3, Fig. 1), we obtain
s _fv (t) = [2S (t)] ^0.5 sin0.5x (t). (eleven)
This signal through the module calculation unit (4, Fig. 1) is fed to the second input of the divider (2, Fig. 1) via the feedback circuit
s _bvm (t) = [2S (t)] ^0.5 | sin0.5x (t) |. (12)
It was this signal that we expected to receive by writing equalities (7) and (10).

 Note. It is necessary to calculate the sign function and the modulus of the signal converted according to Hilbert because the denominator of the dividers of analog signals, which are currently implemented as integrated circuits, can supply voltage of only one sign.

The output signal is generated by a large-scale amplifier, the transmission coefficient of which is M = 2 ^-0.5 , and the output signal
s _o (t) = [S (t)] ^0.5 sin0.5x (t). (thirteen)
This is the result that we wanted to show.

Thus, the above information indicates the fulfillment of the following conditions when using the claimed invention:
- a tool embodying the claimed invention in its implementation, is intended for use in industry, namely in communication technology, sound recording on a moving medium;
- for the claimed invention, in the form described in the claims, the possibility of its implementation using the methods and methods described above or known prior to the priority date is confirmed.

 Therefore, the claimed invention meets the requirement of "industrial applicability" under applicable law.

Literature
1. Marcou P., Daguet J. New Methods of Speech Trasmission (Center National d'Etudes des Telecommunications, Franse) (1955).

 2. Mark P., Dage J. New methods of speech transmission. Digest of articles. Theory of messaging. (Proceedings of the Third International Conference). Ed. IN AND. Siforova. - M .: "Publishing house of foreign lit.", 1957, p. 158-178.

 3. Sapozhkov M. A. A speech signal in cybernetics and communications.-M.: “Svyaz-Izdat”, 1963.

 4. Vinitsky A. S. Modulated filters and FM tracking. - M .: "Soviet Radio", 1969.

Claims (2)

 1. A method for simultaneously accurately dividing the instantaneous frequency and accurately raising the degree of envelope of the sound signals, in which to obtain the output signal it is necessary to perform a Hilbert transform, characterized in that the input sound signal is multiplied by the sign function of the signal obtained after the Hilbert transform, the resulting product is divided by the module of the signal obtained after the Hilbert transform, the division result is subjected to the mentioned Hilbert transform, after which the function As a signal that is used in multiplication, in addition, the modulus of the Hilbert-converted signal that is used in division is calculated, and, in addition, the signal obtained after the Hilbert transform becomes output after the scale transformation.  2. The device for implementing the method according to claim 1, comprising a phase shifter, a multiplier and an analog signal divider, characterized in that it further includes a module calculation unit, a sign function calculation unit and a scale amplifier, the device input and the second input being formed by the first input of the multiplier the multiplier is connected to the output of the sign function calculation unit, the output of the multiplier is connected to the input of the numerator of the analog signal divider, the input of the denominator of the divider is connected to the output of the module calculation unit, input which is connected to the output of the phase shifter and the inputs of the scale amplifier and the sign function calculation unit, the output of the divider is connected to the input of the phase shifter, while the output of the entire device is formed by the output of the scale amplifier.