SU53002A1 - Method for automatic adjustment of the reception strength - Google Patents

Description

The invention relates to a method for automatically adjusting the reception strength, free from the influence of selective fading.

It is well known that when receiving radio telephony on short waves, the fading phenomenon is not only accompanied by changes in the receiving power, but causes very noticeable distortions. Introducing the LSR (Automatic Adjustment of Reception Force) to the receiver maintains the sound power at the same level, but is not a radical means to eliminate distortion. On the contrary, in some cases, VRS can be introduced as a source of new distortion. In the LRS used up to the present, the gain of the receiving device is controlled, in the absence of modulation, by the amplitude of the carrier frequency, and in the case of modulation, the modulated component of the modulated signal. With selective fadding (and just such fadding causes distortions), the usual gain control system does not prevent distortions, since with such fadding the relationship between the constant component of the modulated oscillation and the tone intensity of the sound frequency (at a constant

modulation depth ratio) is not linear.

One of the well-known methods of dealing with selective fad is to switch to emission of one sideband and use a special sound frequency for DRS, which lies outside the spectrum of transmitted frequencies. This method is described in the work of R. N. Reevesa (Journ. 1. E. E. Vol. 73. No. 441, Sept. 1933). According to the author, this method is advisable to apply only when operating without carrier frequency.

The proposed method of automatic adjustment of selectivity, largely free from the indicated drawbacks, is as follows: in addition to conversational frequencies, the radiotelephone transmitter is modulated with an auxiliary sound frequency of constant amplitude, operating continuously, i.e., even during pauses. The height of the auxiliary frequency is chosen in the order of 1000 Hz.

FIG. 1 shows a receiver for receiving such a transmission; FIG. 2-spectrum of the audio frequencies of the reception, divided into three parts, in FIG. 3 is a receiver for receiving such a spectrum.

To the output of a regular receiver /

Two low-frequency filters 2 and 3 are adventurous. Filter 2 is a notch that rejects from the sound frequency spectrum a possibly narrower frequency band surrounding the auxiliary frequency. The cut band is so narrow that it does not cause a decrease in the articulation factor. Filter 3 is a resonant filter finely tuned to the auxiliary frequency. A rectifier 4 is connected to filter 3; it performs RPC functions. The rectified voltage, as indicated by the dotted line, leads to the receiver and adjusts the bias voltage on the grids of the amplifying lamps. Thus, flPC does not operate on the voltage of a modulated signal, but on an audio frequency voltage. It is easy to understand that this system, keeping the auxiliary current intensity at the same level, i.e., the sound frequency (rather than the rectified component of the modulated oscillations, as usual), to a greater degree guarantees the absence of distortion. Of course, distortions are inevitable in this system, but their probability will be incomparably less than in a conventional system.

By making the receiver more complex, by developing the same principle, a more rational struggle with distortion can be achieved. Let us imagine that for this purpose the spectrum of sound frequencies necessary for the transmission of a conversation is divided into three equal parts of the frequency range (Fig. 2). In the middle of each of these ranges, select frequencies / 1 550 Hz, L 1050 Hz and / 2 1550 Hz and with these auxiliary frequencies, just as before, modulate the radiation of the transmitting station. The reception of such a transmission should be carried out at the receiver (Fig. 3), equipped with a high-frequency amplifier and a detector / and three amplification channels at intermediate and "fine frequencies 2, 3 and 4. At the output

Each of channels 2, 3 and 4 includes two filters. Filter Φ, accepts the frequencies of the first subband only (from 300 to 800 Hz) and rejects the frequency of / i 550 Ng. Filter 02 is resonant. It is tuned to the frequency / i and is connected to the output of the YARS rectifier, which regulates the gain over the intermediate frequency of the first channel. Filter Fd passes the frequencies of the second subband only and delays the frequency / 2. The other filters act similarly. The outputs of the filters Ф, Фз and Фг through transformers are connected in parallel, and the currents added in the secondary windings of the transformers contain the entire spectrum of sound frequencies. As can be seen from FIG. 3, here the gain of each of the subbands is adjusted (by the average frequency in this subband) individually, which further eliminates distortion.

As to the simple scheme, considered earlier, and to the complicated one, it is possible to apply the principle of multiple administration.

It is convenient to combine the complicated scheme with a multi-channel secret telephony system based on the frequency conversion of one subband into another.

The subject matter of the invention.

A method of automatically adjusting the reception power, designed to combat selective signal fading, especially at short waves, with modulation of an audio frequency transmitter, used to control receiver adjustment, characterized in that the control audio frequency lies in the transmitter’s sideband spectrum and is received at using a filter from the channel to enhance conversational frequencies, and in the control control channel, it is selected using another filter.

to the author's testimony of M. P. DoeNukhanov

Lo 53002