DE19643833C1 - Demodulating amplitude modulated input signal - Google Patents

Abstract

The demodulation method involves frequency modulation of the input signal in a first mixing stage. The input signal is modulated with an oscillator signal of a controllable oscillator, into an auxiliary signal, with an auxiliary carrier frequency controllable by the oscillation frequency of the oscillator signal. The auxiliary signal is synchronised to a reference signal with given reference frequency by regulating the frequency of the oscillator signal. The auxiliary signal is synchronously demodulated in a second mixing stage by a frequency translation with the reference signal. The auxiliary signal may be fed to the input of a third mixing stage, which generates a control signal with a spectral component, using a control frequency equal to twice the auxiliary carrier frequency. The control signal is fed to a control unit, which generates a control signal to regulate the oscillation frequency.

Description

The invention relates to a method for demodulating an amplitude modulated input signal.

Methods for demodulating amplitude-modulated input signals are for example from the Herter, Röcker, Lörcher reference: "Nachrichten technik ", 2nd edition, Carl Hanser Verlag, 1981, is known. On page 207 there describes a method in which by means of a narrow band Bandpass filter a synchronized to the carrier of the input signal Überla is derived from the input signal and the input signal gnal demodulated by frequency conversion with the beat signal becomes.

The main disadvantage of this method is that the De modulation required superposition signal for input signals with under pressed wearer or in the event of selective shrinkage of the wearer The corresponding signal component cannot be generated from the input signal.

From Börner H .: "Phase coupling systems in news, Measurement and control technology ", VEB Verlag Technik, Berlin, 1976, pages 141 to 143 are two methods for modulating amplitude modulation Suppressed carrier input signals known.

In one method, the input signal is in a square loop squared. As a result, a signal with twice the frequency of Carrier frequency generated for the carrier recovery of a phase rule loop is supplied as a reference signal. The phase locked loop that in  has a frequency doubler in its feedback branch the carrier frequency and delivers the oscillation signal to the modulation of the input signal required recovered carrier.

In the other method, the input signal is converted into a so-called Costas circuit with two oscillators that are 90 ° out of phase with each other signals of a controllable oscillator frequency converted into two mixed signals puts. After being filtered, these mixed signals become a control signal multiplied to control the oscillator. The oscillator controlled in this way locks onto the carrier frequency so that one of the mixed signals corresponds to the demodulated input signal.

The invention has for its object a simple method for De specify modulation of amplitude-modulated input signals with which input signals with suppressed carriers can also be demodulated.

The object is achieved by the features of patent claim 1. Advantage Strong further training and refinements result from the subordinate sayings.  

According to the invention, the amplitude-modulated input signal, the one Double sideband signal with two balanced to an input frequency Is sidebands, and an oscillator signal of a controllable oscillator ei ner first mixing stage supplied. This generates an auxiliary signal with it two sidebands symmetrical to a subcarrier frequency. The auxiliary gnal is fed to a second mixer, which it by frequency implementation with a reference signal with a given reference frequency syn chronically demodulated. The auxiliary signal is controlled by the oscillator frequency of the oscillator signal synchronized to the reference signal, d. H. the Subcarrier frequency is regulated to the value of the reference frequency and the auxiliary signal is in phase or in phase to the reference signal bound.

The auxiliary signal for regulating the oscillator frequency of the Oscillator signal fed to a third mixer, which a Regelsi generated signal, which has a spectral component at twice the value the subcarrier frequency has the same control frequency. This spectral part also arises due to the symmetry of the sidebands of the auxiliary signal for input signals with suppressed carrier; the control frequency will then derived from the sidebands of the auxiliary signal. The control signal is fed to a control unit, which generates a control signal therefrom controllable oscillator controls and by which the oscillator frequency of Oscillator signal is regulated. By controlling the oscillator frequency the control signal is preferably at twice the reference frequency Corresponding further reference signal connected in a phase-locked manner. The Refe reference signal and the further reference signal are permanently coupled to one another, so that due to the phase-locked connection of the control signal to the white tere reference signal also the auxiliary signal phase locked to the reference signal connected, d. H. is synchronized to the reference signal.

It is essential that a Re gel signal with a control frequency that is harmonic to the subcarrier frequency is generated and that the control signal by varying the oscillator frequency phase locked to a harmonic to the reference signal is bound.  

In an advantageous development of the method, the auxiliary signal of the second mixing stage supplied via a bandpass filter, the Durchlaßbe have a smaller width than the bandwidth of the input signal points. The subcarrier frequency can then be specified by specifying the reference Set the frequency so that unwanted frequency components of the auxiliary gnals are outside the pass band and are therefore not demodulated will.

In this way one of the sidebands of the auxiliary signal can be suppressed, by the subcarrier frequency by specifying the reference frequency to the upper or lower edge of the pass band is placed. The auxiliaries can also be placed in the middle of the pass band. As a result, the bandwidth of the demodulated auxiliary signal, i. H. of the out output signal of the second mixer, reduced. With a pass band, which is equal to half the bandwidth of the input signal, the Bandwidth of the output signal with respect to the bandwidth of the input signal halved.

The method according to the invention combines several advantages:

• - It can be used to demodulate amplitude-modulated input use signals with or without suppressed carrier,
• - A sideband selection or band limitation is simple feasible without the use of tunable filters,
• - The auxiliary signal can be in a low-frequency band process with inexpensive circuit parts.

The invention is described below using an exemplary embodiment Described in more detail with reference to the figure. The figure shows a scarf device arrangement for performing the method according to the invention.

According to the figure, the circuit arrangement has a first mixer M₁, a second mixer M₂, a third mixer M₃, a control unit R, egg NEN controllable oscillator OSC₁, a superposition generator U and a bandpass filter BP. The first mixer M _{1 is} designed as a multiplier M _1M with a downstream low-pass filter M _1TP . The one input M _{1E1 of} the multiplier M _1M is fed the amplitude-modulated input signal u _E , whose carrier oscillates at the input frequency f _E , and the other input M _{1E2 of} the multiplier M _1M is the oscillator signal generated by the controllable oscillator OSC₁ and oscillating at the oscillator frequency f₀ u₀ fed. The first mixer M ₁ supplies at its output M _1A the auxiliary signal u _H formed by frequency conversion of the input signal u _E with the oscillator signal u. The input frequency f _E is downmixed to the subcarrier frequency f _H which is the same as the difference between the input frequency f _E and the oscillator frequency f₀. Spectralan share in the sum of the input frequency f _E and oscillator frequency f₀, which arise due to the multiplication of the input signal u _E with the oscillator signal u₀ at the output of the multiplier M _1M , are suppressed in the low pass filter M _1TP .

The third mixing stage M₃ has a multiplier M _3M , two limiting elements M _3B1 , M _3B2 and a phase shifter M _3P , for example an integrator. The output M _{1A of} the first mixer M ₁ is via the series circuit from the phase shifter M _3P and the one limiting element M _3B1 with one input M _{3E1 of} the multiplier M _3M and over the other limiting _element M _3B2 with the other input M _{3E2 of} the multiplier M _3M connected. The phase shifter M _3P causes a 90 ° phase shift of the signal supplied to it, so that the multiplier M _{3M can be designed} as an EXOR gate that can be implemented in a simple manner. The third Mischstu fe M₃ generated from the auxiliary signal u _H by self-mixing at its output M _3A pending control signal u _R with the subcarrier frequency f _H har monic control frequency 2 f _H. This double the value of the subcarrier frequency f _H same control frequency 2 f _H arises by mixing the auxiliary carrier frequency f _H with itself and by mixing the frequencies from the sidebands of the auxiliary signal u _H with the subcarrier frequency f _H symmetrical frequencies from the opposite Sidebands of the auxiliary signal u _H. It therefore also arises in the case of auxiliary signals u _H which do not contain any spectral component at the auxiliary carrier frequency f _H , ie in the case of input signals u _E with a suppressed carrier.

The overlay generator U delivers to the reference frequency f _Ref os zillierende reference signal and _ref and to harmonious further reference signal and _Ref2. The frequency of the further reference signal u _Ref2 is equal to twice the frequency value 2 f _{Ref of} the reference frequency f _Ref . The superimposition generator U has a local oscillator OSC₂ for generating the further reference signal u _Ref2 and a local oscillator OSC₂ connected to the frequency divider FT with the divider factor 2 for generating the reference signal u _Ref . To compensate for different signal transit times through the bandpass filter BP and through the third mixer M₃, a phase shifter P is provided, which is connected to the frequency divider FT in series.

The control loop R has a phase detector PD, to which the control signal u _R and the further reference signal u _{Ref2 are} supplied and which, depending on the phase position of the control signal u _R with respect to the further reference signal u _Ref and in accordance with the frequency difference between the frequency 2 f _{Ref of} the further reference signal u _Ref2 and the control frequency f _R generates a control signal u _s which drives the controllable oscillator OSC₁. The taxable oscillator OSC₁ is a series connection of a voltage controlled oscillator VCO and a loop filter SF, via which the control signal u _{s is} fed to the voltage controlled oscillator VCO.

The oscillator frequency f₀ is controlled by the control signal u _{s in} such a way that the control signal u _{R is} phase _locked to the further reference signal u _Ref2 . Since the reference signal u _{Ref represents} a subharmonic oscillation of the further reference signal u _Ref2 , this control of the oscillator frequency f₀ synchronizes the auxiliary signal u _H with respect to the reference signal u _Ref . The auxiliary signal u _H is in this way connected in phase or in phase to the reference signal u _Ref .

The second mixing stage M₂ is like the first mixing stage M₁ as a multiplier M _2M with a downstream low-pass filter M _2TP . One input M _{2E1 of} the multiplier M _2M is connected via the bandpass filter BP to the output M _{1A of} the first mixer M ₁ and the other input M _{2E2 of} the multiplier M _2M is connected to an output of the superposition generator U at which the reference signal u _Ref is present , connected. The auxiliary signal u _H filtered by the bandpass filter BP is frequency converted with the reference signal u _Ref into the output signal u _A. Since the auxiliary signal u _H and the reference signal u _Ref are synchronized with each other, this is a synchronous demodulation. Sum spectral components, which are the sum of the auxiliary carrier frequency f _T and the reference frequency f _Ref and which arise due to the multiplication of the auxiliary signal u _H with the reference signal u _Ref at the output of the multiplier M _2M , are suppressed in the low-pass filter M _2TP .

The input signal u _E is, for example, a signal which is frequency-converted to an intermediate frequency of 455 kHz which is common in broadcast technology. The bandpass filter BP has a pass band, for example from 11 kHz to 15 kHz. The reference frequency f _Ref can be set to the values 11 kHz, 13 kHz or 15 kHz, ie to the lower or upper limit frequency or to the middle of the bandpass filter BP. At a reference frequency f _Ref of 11 kHz, the lower sideband of the auxiliary signal u _{H is} suppressed, at a reference frequency f _Ref of 15 kHz, the upper sideband of the auxiliary signal u _{H is} suppressed, and at a reference frequency f _Ref of 13 kHz, spectral components that are in the low-frequency output signal u _A correspond to the frequency range above 2 kHz, suppressed. A band limitation or sideband selection of the input signal u _E can therefore be carried out in a simple manner.

Claims (7)

1. Method for demodulating an amplitude-modulated input signal (u _E ) in the

• - The input signal (u _E ) in a first mixer (M₁) with an oscillator signal (u₀) of a controllable oscillator (OSC₁) in an auxiliary signal (u _H ) with a by the oscillator frequency (f₀) of the oscillator signal (u₀) controllable subcarrier frequency ( f _H ) frequency conversion,
• - The auxiliary signal (u _H ) is synchronized by controlling the oscillator frequency (f₀) of the oscillator signal (u₀) to a reference signal (u _Ref ) with a given reference frequency (f _Ref )
• - And the auxiliary signal (u _H ) in a second mixer (M₂) by frequency conversion with the reference signal (u _Ref ) is synchronously demodulated.

2. The method according to claim 1, characterized in that the auxiliary signal (u _H ) is fed to the inputs of a third mixer stage (M₃) which from the auxiliary signal (u _H ) is a control signal (u _R ) with a spectral component at a double value the subcarrier frequency (f _H) of the same control frequency (2 f _H) is generated and that the control signal (u _R) is supplied to a control unit (R) which is a the controllable oscillator (OSC₁) which activates control signal (u _s) for regulating the oscillator frequency (f₀ ) generated. 3. The method according to claim 2, characterized in that the control signal (u _R ) for synchronizing the auxiliary signal (u _H ) to the reference signal (u _Ref ) sen stiff at a double value ( 2 f _Ref ) of the reference frequency (f _Ref ) ent speaking further reference signal (u _Ref2 ) is connected. 4. The method according to claim 3, characterized in that the control signal (u _R ) and the further reference signal (u _Ref2 ) in the control unit (R) one of the control signal (u _s ) generating phase detector (PD) are supplied. 5. The method according to any one of the preceding claims, characterized in that the auxiliary signal (u _H ) of the second mixer (M₂) via a bandpass filter (BP) with respect to the bandwidth of the input signal (u _E ) smaller pass band is supplied and that for the auxiliary frequency (f _H ) by specifying the reference frequency (f _Ref ) a frequency value is selected in which undesirable frequency components of the auxiliary signal (u _H ) are outside the pass band of the bandpass filter (BP). 6. The method according to claim 5, characterized in that a frequency value is selected for the reference frequency (f _Ref ) at which the auxiliary frequency (f _H ) is in the middle or at the edge of the pass band of the bandpass filter (BP). 7. The method according to claim 6, characterized in that the width of the pass band of the bandpass filter (BP) is set to half the bandwidth of the input signal (f _E ).