SU45862A1 - Radio - Google Patents

Description

When receiving signals by the usual phase of the modulated transmitter, i.e., when receiving signals from a transmitter emitting the main and two sidebands, in order to eliminate distortion, it is necessary to have a linear demodulator in the receiver, in other words, such a demodulator, rectification and amplitudes the output of which would be directly proportional to high-frequency amlititudes. However, when receiving a transmitter that operates with core and two side frequencies, even in this case, distortions occur, since the envelope of the modulated high-frequency oscillations does not match the shape of the modulating oscillations. For the case of the transmission of one tone, a quadratic detector can be considered absolutely non-distorting. However, when simultaneously transmitting a group of tones, as is the case in speech or music, during demodulation, in the best case, in addition to the main tones, difference tones arise, which are formed by all simultaneously transmitted frequencies. This phenomenon is almost unnoticeable in those cases when the amplitude of the carrier frequency is large compared to the amplitude of the side

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bands, i.e., when the transmitter modulation depth is small. With a large coefficient of modulation, the distortions become very significant. In order to eliminate these claims, it was proposed to apply oscillations to the receiver from a local oscillator having a frequency equal to the carrier frequency of the receiving station. This achieves that the oscillations delivered to the demodulator have a modulation depth smaller than the modulation depth of the received oscillations. If the amplitude of oscillations of a local source is large enough, the modulation depth can be made sufficiently small, as a result of which the distortion during demodulation will not occur. In practice, however, such a method encounters a number of obstacles, the main ones of which are the requirement of extreme constancy of the transmitter carrier frequency and exact adjustment of the frequency of the local source of oscillations to the carrier frequency of the receiving station. In order to achieve the same effect as previously described, the present invention provides for the use of a superheterodyne-type receiver, a resonant curve at an intermediate frequency in which, at the end of the passband, has a peak of very small width (as shown in the figure). If such a filter is adjusted in such a way that the carrier frequency falls at the peak of the resonance curve, the carrier frequency will be amplified more than the side frequencies, as a result of which the modulation depth is reduced and, accordingly, the distortion when rectifying the signals of a deeply modulated transmitter decreases.

Such a device is equally suitable for receiving a modulated transmitter with two sidebands. In this case, only one sideband will be demodulated. However, the distortion will be eliminated.

The resonance peak can be obtained in various ways. For example, it is possible to turn off a filter with a very narrow band parallel to a broad bandwidth filter, for example, a mechanical quartz resonator or a magnetostrictively excited steel rod.

In the event that the receiver tuning tuning is excluded, the above-described resonance curve may not be given at the intermediate frequency $ perheterodyne receiver, but it may be the overall resonance cord of the direct amplifier receiver.

The subject of the patent.

Claims (2)

1. A receiver for receiving signals from modulated transmitters, especially for receiving signals from transmitters operating from a carrier part (and that one sideband often, characterized in that before the last modulator a filtering device is switched on, a much better transmitting carrier frequency and worse evenly, lateral frequencies, 2. The form of the radio receiver, in accordance with claim 1, characterized in that parallel to the contours, the sideband designed for the transmission of the sideband is often switched on the resonant system is very | small attenuation, such as electrical equipment; cic resonator.