DE1282745B - Method and arrangement for receiving an amplitude-modulated high-frequency signal, in particular for single sideband reception of amplitude-modulated audio broadcasts - Google Patents

Description

Method and arrangement for receiving an amplitude-modulated radio frequency signal, in particular for single-side reception of amplitude-modulated audio broadcasts. The previously known radio receiver for amplitude modulated sound broadcasting need an input signal with carrier and two symmetrical to these sidebands due to the used diode rectifiers for distortion-free demodulation, while also amplitude modulated picture carrier of the television broadcast of a carrier frequency, one - full and there is a vestigial sideband and after a Nyquist specified method is also demodulated with a diode rectifier. This transmission system, used as a residual sideband method in television broadcasting, requires a standardized selection curve in the receiver, the course of which forms a unit together with the transmission method.

Since the complete information of the modulation signal is already in a sideband can be included in demodulation on one of the two broadcast sidebands be waived. As a result, the entire bandwidth of the high-frequency amplifier is available on the receiving side available for the useful information.

Special single sideband receivers are currently only available for the commercial radio traffic built and used since here. a much bigger one technical effort and no great quality requirements for the transmission path are portable compared to broadcasting.

All known single sideband systems work with direct demodulation by an additional carrier generated in the receiver itself or, as is usual on television, with a standardized receiver transmission curve, the course of which together with the transmission method forms a unit.

For audio broadcast receivers, this technology could be used because of the great technical effort involved in the use of steep-edged, i.e. H. more expensive, filters for filtering out a sideband or the in-phase carrier addition with direct demodulation have not yet found input. Sound broadcasting receivers therefore still need twice the bandwidth of the modulation spectrum used by the transmitter in the high-frequency section (greater susceptibility to interference from neighboring transmitters) as well as an input signal that consists of the carrier and two symmetrical sidebands and therefore results in particularly strong modulation> distortions due to selective fading occurring at the receiving location . In addition, due to incorrect signal-to-noise ratio considerations, the audio broadcast receivers are partially -. already executed on the high-frequency side so narrow-band that only a fraction of the transmission-side modulation spectrum can be used and therefore z. B. already the ground wave supply of medium wave broadcast radio only has the quality of an information program.

The invention is based on the object of improving the reception quality of, amplitude-modulated sound and television broadcast transmitters by measures on the receiving end to improve.

This object is achieved according to the invention in that for the implementation * and conversion of a received, - asymmetrically amplitude-modulated RF signal UE with carrier frequency f, into a symmetrical double sideband signal Us niii carrier frequency f, the former is fed to two mixer stages at the same time and so in one with the help of a -Oscillator frequency f "1 of the size f" = (f, + f ;,) under 'reversal of the frequency: Chase its side # changes and in the second with the help of an oscillator frequency f "2 -,' of the size f, 2 = (f, -f ") and while maintaining the frequency position of its sidebands in each case an amplitude-modulated signal of the same carrier frequency f, is implemented that their sum signal U, after filtering in a low-pass filter, is an exactly symmetrical double sideband signal with carrier frequency fz, which is on the one hand a demodulator w f 2, supplied - fz for demodulation and on the other hand a non-linear network for screening out the carrier frequency and "the doubling of the amount of frequency ird, and that a third mixer with the help of the frequency supplied by the network - 2 f, converts the oscillator frequency generated by an oscillator of one mixer into the oscillator frequency of the second mixer.

An exemplary embodiment of a circuit arrangement for carrying out the new method is shown in the block diagram F i g. 1 shown schematically and serves to explain the invention.

That too. demodulating, asymmetrically amplitude-modulated HF (input) signals Üj, - z.SI. e "m 'amplitude-modulated§ single sideband sig # UE = A cos .- 2 nf, t + Mo' cö s 2n (f # whose carrier signal is amplitude A and frequency f, and whose (upper) sideband is amplitude m, and the (pages -) Freqgenz . (F, + fm), is fed to a transposition circuit consisting of two input-side parallel-connected mixing stages 1 and 2 of the same mixing constants, which are connected on the output side via a low-pass filter 3 to the input of a demodulator_4. The low-pass filter 3 is like this It is laid out that it suppresses the sum frequency signals of the mixing or modulation products of both mixing stages 1 and 2 supplied to it and only transmits the difference frequency signals occurring in their mixing or modulation products to the input of the demodulator 4.

In a mixing step 1 is your RF signal UE [Equation (1)] a high from an oscillator 5 frequency stability generated and supplied to oscillator frequency + f.,) Superimposed multipEkativ, the arbitrary one, in the # pre-established # Vrequenzbetrag f, greater than der'göllwert derträgerque "des' to demodÜherenden HF signal U, fre nz f -E is dimensioned and with which the mixer 1 the HF signal UE in a known manner, neglecting the simultaneously occurring in their mixed product and from the low pass 3 suppressed sum frequency # signals into the difference frequency signal generic -, - UI '= C {Acos27v (fol-fe) t + mocos2n ff-, - (A + MI tj, ie, da or into an intermediate-frequency single sideband signal U,'# C { A cos 27vfz t + mo cos 2n (fz - f.) Tl (2) with the carrier frequency f, and a side band in the lower frequency range.

In the second mixer stage 2, an oscillator frequency f "is superimposed on the RF input signal UE [equation (1)], which according to the invention is dimensioned so that it oscillates by the same frequency amount f, below the carrier frequency f, of the RF signal Uu , around which the oscillator frequency fo, of the first mixer 1 above the carrier frequency fe, oscillates, that is to say that, since f, 1 = (f, + f,), both the condition f02 # fe - f ' (3 a) as and the condition f = f112 #, 1 - 2 f - (3 b) are satisfied order that the oscillator frequency f ", these conditions even at f a in its carrier frequency, fluctuating, i. e. H. HF signal UB which deviates from the nominal value are met, it is, as described and explained below, with the aid of a further. Mixing stage 6- derived from the oscillator frequency f "generated by the oscillator 5 , the first mixer stage 1. #, Mit.- der, # - ßu, bemesseneii '0'iiiiiatötfe« quonz # f ## sets the * ## e'ite M''-s'chs'tu'fe RF signal UE [equation (1)] ii # <#. "dää #, -:' Difference frequency signal mixture j 2- - - '- ü # I f _2) -C- , { Ä c, ps, 2z 0 md-c9 & 9 d- .. h., Dae.fö, # - (fä is, also in an intermediate frequency: qöntes "13i, ii # eitenliändsignal U, ' = {A cos 27v fz - t + mo cos 2n (f # - f.) t} (4) with the carrier frequency f, and with a sideband, ixi, the lower frequency range.

Due to the different frequency position of the sidebands of the intermediate-frequency single sideband signals U, ' and U,' emitted by the two mixer stages [equations (3) and (4) ], their sum signal Us C {2 A cos, which occurs at the output of low-pass filter 3, results 27r f, t + mo cos 2n (ft + f, #) t + m, cos 2n (A - f.) T # (5) a - exactly symmetrical, with the carrier frequency fz. oscillating, two-side band signal, the upper and lower side bands of which have the same amplitude rn.

As the comparison of equations (1), (2) and (4) shows, the conversion of the asymmetrically amplitude-modulated, with the carrier frequency fe oscillating RF signal UE [equation (1)] into an exactly symmetrical one in mixer stages 1 and 2 The amplitude-modulated double sideband signal oscillating with the intermediate frequency carrier frequency f " is achieved in that, on the one hand, both mixer stages 1 and 2, due to the same frequency spacing ft of their oscillator frequencies f #, 1 and f" 2 from the Dräger frequency fe, generate the HMignal UE [equation (1)] the . fz implement same intermediate-frequency carrier frequency and in that the other part f in the implementation of the HP signal UE to the intermediate-frequency carrier frequency # whose (upper) S eitenband in a mixing stage 1, due f by their above the carrier frequency, running oscillator frequency f "i = (f , + ft), into the reversed (lower) frequency position, while in the second mixer stage 2, due to its oscillator frequency j #, = (fe, - fz), which oscillates below the carrier frequency fe, it transposes again into the same (upper) frequency position will.

The described properties of the two mixer stages 1 and 2 and their oscillator frequencies measured according to the invention have the effect that these not only, as calculated and explained above, amplitude-modulated single sideband signals, but also all other possible asymmetrical amplitude-modulated RF signals, such as e.g. B. asymmetrically amplitude-modulated double sideband signals or residual sideband signals in exactly symmetrical amplitude-modulated double sideband signals with the carrier frequency f. - According to a further feature of the invention s iebt a non-linear network 7 from the sum signal U8 [equation (5)], d. H. from the in - this contained fo of the (first) Mischstafe 1 by means of their fed from the oscillator 5 Oszülatorfrequenz, generated and transmitted by the low-pass filter 3 difference frequency composite signal U '[Equation (2)] f is the carrier frequency of the sum signal U, forming the difference frequency , = (f " - f,) and leads this, doubled to the amount 2 f, = 2 (f" - f,) , the already mentioned (third) mixer 6 of the transposition circuit F i g. 1 to. With the help of the frequency 2f generated in this way, the mixer 6 sets the oscillator frequency f fed to it by the oscillator 5. I = (fe + fz) of the (first) mixer 1 into the difference frequency f # 2 = (f " I - 2 f #) = ( fe, - f ;,) to that of the (second) mixer stage 2 either directly, e.g. via an amplifier and limiter, or indirectly, e.g., as in the exemplary embodiment Fig. 1, via an oscillator that does not oscillate independently 8, is supplied as the oscillator frequency. the network 7 is expediently designed so that it includes the frequency amount 2 fz also from the non-linear addition of the two side frequencies (f ;, + f.) of the sum signal U # obtained when the intermediate-in sum signal U " carrier signal f; "d h f is the frequency difference signal = (f..", - fe,) z. B. due to failure or selective fading of the carrier signal f, the received RF signal Ue. does not exist.

With the described method for generating the oscillator frequency f "of the second mixer 2 from the oscillator frequency f" output by the oscillator 5 , the first mixer 1 achieves and ensures that even with a single or recurring change in the carrier frequency f, the received RF Signal U_P by the frequency amount -E f, or with a single or recurring change in the frequency f "of the oscillator 5 by the amount + f", the received RF signal UB from the two mixing stages 1 and 2 always in two intermediate-frequency RF signals U, 'and U2' of the same carrier frequency is implemented, the phase equality of the two intermediate-frequency RF signals U, 'and U2' z. B. with the aid of a switched between the outputs of the two mixer stages 1 and 2 and coupled via an adjustable reactance stage 9 to the oscillator 5 phase criminator 10 can be set up or set.

The process according to the invention requires little technical effort in order to be carried out. The conversion achieved with it of an asymmetrically amplitude-modulated RF signal into an intermediate-frequency double sideband signal to be demodulated by a demodulator without additional measures is independent of the fluctuations in the carrier frequency of the received RF signal and enables e.g. B. from a broadcast double sideband signal, only one sideband, e.g. B. the sideband less disturbed by a neighboring transmitter to receive and with a demodulator, d. H. without additional carrier to demodulate.

Claims (2)

Claims: 1. A method for receiving an amplitude-modulated high-frequency signal, in particular for receiving amplitude-modulated radio transmitters which broadcast a double sideband, vestigial sideband or single sideband broadcast, characterized in that for converting and converting an asymmetrically amplitude-modulated RF signal UE with a carrier frequency f into a symmetrical two-sideband signal U # with carrier frequency f, the former at the same time two mixer stages (1 and 2) - supplied and so in the one with the help of an oscillator frequency f ", of the size f", = (f, + f ;,) with the inversion of the Frequency position of its sidebands and in the second with the help of an oscillator frequency f "2 of the size f" 2 = (fe - fz) and while maintaining the frequency position of its sidebands in each case an amplitude-modulated signal of the same carrier frequency f, is converted so that their sum signal U, after filtering in a low-pass filter (3) an exactly symmetrical double sideband signal with carrier fr equenz f, which is fed on the one hand to a demodulator (4) for demodulation and on the other hand to a nonlinear network (7) for filtering out the carrier frequency fz and doubling it to the frequency amount 2 f, and that a third mixer (6) with the aid of the frequency 2 f supplied by the network (7) , which converts the oscillator frequency of one mixer stage generated by an oscillator (5) into the oscillator frequency of the second mixer stage. 2. Arrangement for carrying out the method according to claim 1, characterized in that the phase equality between the two output signals of the mixing stages (1) and (2) transmitted by the low-pass filter (3 ) can be set via a phase discriminator (10) and the variable reactance stage (9) is.