RU2092968C1 - Method and demodulator for amplitude-modulated signal demodulation - Google Patents

Abstract

FIELD: electronic engineering. SUBSTANCE: amplitude-modulated signal carrier is compared with threshold value. As soon as it become equal to threshold value, pre-scale amplitude-modulated signal value is stored and used as demodulated signal. Scaling factor is inversely proportional to threshold value. Demodulator implementing this method has comparison unit 1, reference signal unit 2, storage unit 3, and scaling unit 4. EFFECT: improved demodulation accuracy. 3 dwg

Description

 The invention relates to the field of electrical engineering and can be used, for example, in communication systems, television automation. The primary field of application is the processing of amplitude-modulated signals in automatic control systems using digital computers.

 A known modulation method is that the modulated signal is interrogated at a frequency several times higher than the carrier frequency in a computer according to the dependences of the Kotelnikov theorem (taking into account that the amplitude-modulated signal is the product of the carrier by the modulating function, if necessary shifted ([6] p. 72-74) the shape of the modulating function is restored from the sample of values of the amplitude-modulated signal [1] The disadvantage of this method is the need for a high sampling frequency, as This means that the signal recovery requires a large number of polls (a large amount of memory) and the use of trigonometric functions, which increases the time it takes to solve the problem. Despite these difficulties, due to the lack of information about carrier accuracy, demodulation accuracy is limited by tolerance on carrier parameters.

 A known method of signal demodulation, namely, that the amplitude-modulated signal is multiplied by the carrier, the high-frequency components are filtered out and scaled according to the filter parameters [4] The disadvantage of this method is that when the carrier amplitude changes, the error in the recovery of the modulating function changes in proportion to the square of the relative change carrier amplitude.

 There is also a method of demodulating an amplitude-modulated signal, which consists in the fact that the amplitude-modulated signal is multiplied by the carrier signature, the high-frequency components are filtered off and scaled taking into account the filter parameters ([5] p. 80.81). When the carrier amplitude changes, the error in the restoration of the modulating function changes in proportion to the change in the carrier amplitude.

In addition, a method for demodulating an amplitude-modulated signal is known, when a component at a carrier frequency is extracted from it, the amplitude-modulated signal is multiplied by this component, and high-frequency components are filtered out [6], p. 254,255). This method has the following disadvantages:
firstly, it is not sensitive to the phase of the carrier, while the filter that emits it may introduce additional phase errors;
secondly, since the amplitude of the carrier remains unknown, scaling can only be done qualitatively. These shortcomings do not allow the use of such a method of demodulation in automation devices due to the uncertainty of both the magnitude of the transmission coefficient of the demodulator and its sign.

Closest to the claimed technical solution is the description in [2]
When using this method, the amplitude-modulated signal is scaled, stored at times when the carrier reaches its maximum value, and the stored value is used as the value of the demodulated signal. Due to the fact that with this method the carrier shape and its amplitude are assumed to be unchanged, an error occurs proportional to the deviation of the largest carrier value from the a priori of a given level.

As is known ([6] p. 74, formula (3.4), [7] p. 403, formula (9.13)), the amplitude-modulated signal can be represented as the product of the modulating function by the carrier:
U _AM = U • U _H , (1)
where U _{AM is the} current value of the amplitude-modulated signal;
U current value of the modulating function;
U _H current carrier value.

Let U _H U _M sin ft. Then the maximum carrier is achieved at sin ft 1 and is equal to U _M. The value of the demodulated signal is
U _DM U _AM (U _H max) (2)
In this case, the coefficient is selected from the condition
U _DM U, if max (U _H ) U _MH , (3)
where U _{MH is the} nominal value of the amplitude of the carrier.

Основным техническим результатом предлагаемого технического решения является повышение точности выделения модулирующей функции из амплитудно-модулированного сигнала. Дополнительным техническим результатом при использовании цифровой обработки является уменьшение частоты опроса ( до минимально необходимой для восстановления модулирующей функции) и числа операций, требуемых для выделения модулирующей функции. Кроме того, предлагаемый способ демодуляции не зависит от формы несущей и нечувствителен к ее изменениям.If during operation, the amplitude of the carrier can change, i.e.
U _M kU _MH , (4)
then

The main technical result of the proposed technical solution is to increase the accuracy of isolating the modulating function from the amplitude-modulated signal. An additional technical result when using digital processing is to reduce the polling frequency (to the minimum necessary to restore the modulating function) and the number of operations required to isolate the modulating function. In addition, the proposed method of demodulation does not depend on the shape of the carrier and is insensitive to its changes.

 To achieve these results, the method of demodulating the amplitude-modulated signal, which consists in scaling the amplitude-modulated signal, periodically memorizing it and using the stored value as a demodulated signal (modulating function), is supplemented by operations of measuring the carrier and comparing the measured value with a given threshold, while the modulated signal is stored at times when the carrier becomes equal to the threshold value, and the scaling factor tantalize inversely with the threshold value.

Тем самым исключается ошибка, вызванная флуктуациями несущей (как отклонениями формы, так и амплитуды). При этом, поскольку уровень порога задается заранее, операция деления фактически заменяется операцией умножения на постоянный коэффициент (операцией масштабирования). Это позволяет достаточно просто реализовать предлагаемый способ на практике, т.к. даже при реализации с использованием аналоговой элементной базы могут использоваться относительно дешевые и точные операционные усилители, а не блоки умножения-деления. Следует также отметить, что при соответствующем выборе порогового значения при цифровой реализации операция деления может быть заменена операцией сдвига, выполняемой гораздо быстрее.As follows from (1), when implementing the proposed method, the modulated signal is divided into the current, exactly known carrier value:

This eliminates the error caused by carrier fluctuations (both shape deviations and amplitudes). Moreover, since the threshold level is set in advance, the division operation is actually replaced by the operation of multiplying by a constant coefficient (the operation of scaling). This allows you to quite simply implement the proposed method in practice, because even when implemented using an analog element base, relatively cheap and accurate operational amplifiers, rather than multiplication-division blocks, can be used. It should also be noted that with a suitable choice of the threshold value for digital implementation, the division operation can be replaced by a shift operation, which is performed much faster.

 Various device options were considered on the basis of which the proposed method could be implemented. The peak detector described in [3] is recognized as the closest in the number of matching features. This demodulator contains a scaling amplifier connected in series, to the input of which an amplitude-modulated signal and a storage unit are supplied. The storage unit is an aperiodic RC unit, the input of which is connected through a transistor switch to the output of a scaling amplifier. The transistor switch is controlled by signals from a peak detector, to the input of which a carrier is supplied. As indicated in [8] p. 403, peak value is the largest value of any value. The peak detector described in [3] emits the largest modulus value of the negative carrier half-wave. In this case, the current value of the carrier signal is compared with its previous value. After reaching the extremum, the peak detector is restarted again when the carrier reaches a certain predetermined value, which, however, is not used to analyze the demodulated signal, because the next value for the period is stored at the moment in time when the negative half-wave of the carrier reaches a local extremum.

 In order to implement the method for demodulating an amplitude-modulated signal described above, it is necessary to introduce a series-connected reference signal block and a comparison block into a device containing a series-connected simulation block and a storage block, apply a carrier signal to the second input of the comparison block, and connect the output of the comparison block to the input control recording a storage unit. The resulting device will perform the functions of a half-wave demodulator.

 In FIG. 1 shows a functional diagram of a half-wave demodulator; in FIG. 2.3 diagrams of the modulated and demodulated signal in different ways, respectively, for the meander and triangular modulating functions.

 A half-wave demodulator consists of a series-connected scaling unit 4 and a storage unit 3 and series-connected unit of the reference signal 2 and the comparison unit 1 (Fig. 1). The output of the comparison unit is connected to the input of the recording control of the storage unit. The amplitude-modulated signal is fed to the input of the scaling unit 4, and the carrier is fed to the second input of the comparison unit.

 Each of the proposed units individually is known: the scaling unit can be performed on an operational amplifier, the storage unit is similar to the prototype, the reference signal unit on a precision rectifier, the comparison unit on a null indicator.

 Consider the operation of a half-wave demodulator. From the block of the reference signal to the block of comparison, a signal of a set level is received. A carrier signal is applied to another input of the comparison unit 1. If these signals are equal, the comparison unit will issue a command to the recording control input of the storage unit 3 (that is, the comparison unit performs the function of a null indicator compare [8] p. 305). To the data input of the storage unit 3, an amplitude-modulated signal scaled in the scaling unit 4 is supplied. Obviously, the instantaneous value recorded in block 3 will be proportional to the value and coincide in sign with the modulating function.

It follows from formula (1) that
UU _AM / U _H. (5a)
In real technical systems, this dependence is not realized due to the uncertainty of the multiple division value at the carrier values close to zero. Typically, with a sinusoidal carrier shape, the demodulator performs the function of multiplying the amplitude-modulated signal by the carrier or the function of the carrier signature.

In the first case
U _DM = U • U $\genfrac{}{}{0ex}{}{\text{2}}{\text{M}}$ sin ² ft (6)
In the second case
U _DM U • U _M sin ft sign (sin ft) (7)
That is, the amplitude of the demodulated signal is proportional not only to the amplitude of the modulating function, but also to the amplitude of the carrier. The waveforms of the demodulated signals are shown in FIG. 3 (curves c, d, e correspond to the cases of a phase-sensitive rectifier, formula (7), a linear demodulator to formula (6), curves a and b correspond to the amplitude-modulated signal and carrier, respectively). If the carrier amplitude changes during operation, and the demodulator scaling factor remains unchanged, then the error occurs the greater, the greater the change in the carrier (formulas (6), (7)). Similarly, an error occurs when the carrier amplitude changes and when using peak demodulators (formulas (2) (5)).

 To eliminate this error, it is necessary to measure the carrier at least once per period (or even several periods) and, in accordance with (5a), at this moment divide the amplitude-modulated signal by the measured carrier value. However, the division block is generally quite complex and, at least in analog design, has low accuracy. In the proposed device, the division operation is replaced by a scaling operation, since the division is carried out in advance by a predetermined constant value specified by a threshold value.

 It should be noted that the value of the threshold signal should not be greater than the nominal value of the carrier amplitude, reduced by the maximum value of its change, otherwise the comparison unit will not (when the carrier amplitude decreases below the threshold) give a signal even when the carrier maximum is reached. On the other hand, for the demodulation result to be more accurate, especially in digital systems, it is necessary that the amplitude-modulated signal at the moment of division is as large as possible, and, therefore, in accordance with (1), the carrier should be as large as possible at this moment . Therefore, the threshold value cannot be arbitrarily small and it is desirable to maximize it (modulo). Illustratively on the curves, the circles on the pulses of the demodulated signal show the value of the amplitude-modulated signal at the time of measurement, and the dotted envelope of the demodulated signal.

 By writing the scaling result to the storage unit, it is possible to use the demodulation result until the next measurement step. The need for filtering or other processing of the received signal is determined by the requirements of external devices consuming a demodulated signal, and should be considered separately, as well as reading control.

 If the scaling factor is chosen correctly, then at the time of recording, the demodulated signal is exactly equal to the modulating function, because Considering the above, the current value of the carrier at this moment is exactly equal to the threshold value. That is, the transmission coefficient of the scaling unit should be proportional to (1 / U), based on formula (5a). In other words, inversely proportional to the threshold value, ceteris paribus.

 It can be seen from the foregoing that the use of the method of demodulating an amplitude-modulated signal, in which the value of the modulating function is taken to be the value of the amplitude-modulated signal multiplied by an amount inversely proportional to the reference signal, at the moment the carrier is equal to the reference signal, improves the accuracy of demodulation. Based on this method, a half-wave demodulator is proposed.

Information sources:
1. The patent of Germany N 38 16 568, 1989, MKI H 03 D 1/00.

 2. French patent application N 2 098 193, 1972, MKI H 03 D 1/00.

 3. US patent N 3 651 419, NKI 329-101, 1972.

 4. Japanese patent application N 63-30805, MKI H 03 D 1/22.

 5. The use of integrated circuits. A practical guide. Ed. A. Williams, Prince 1M. World, 1987.

 6. Gonorovsky I.S. Radio engineering targets and signals.-M. Radio and Communications, 1986.

 7. Herpy M. Analog Integrated Circuits.-M. Radio and Communications, 1983.

 8. Dictionary of amateur radio. Ed. L.P. Kraismera.-L. Energy, 1972.

Claims (2)

 1. The method of demodulating the amplitude-modulated signal, in which the amplitude-modulated signal is scaled and periodically stored, and the stored value is used as a demodulated signal, characterized in that the carrier is measured, compared with a threshold value, remembered the amplitude-modulated signal at the time of equal carrier threshold value, and the scaling factor is set inversely proportional to the threshold value.  2. A demodulator of an amplitude-modulated signal containing a series-connected scaling unit and a storage unit, characterized in that the reference signal unit and the comparison unit are connected in series, the output of the comparison unit is connected to the recording control input of the storage unit, and the second input of the comparison unit is a carrier input moreover, the transmission coefficient of the scaling unit is set inversely proportional to the signal value at the output of the reference signal unit.

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