SU192253A1 - - Google Patents

Description

The present invention relates to telecommunications, and specifically to multichannel systems, communications in which channels differ only in the form of signals transmitted by them. In such systems, the signals of the subscriber stations (subscriber addresses) occupy the same frequency band and can appear at the receiver input to any subscriber station independently of one another in time.

Known multichannel systems have low efficiency, i.e., for a given signal-to-noise ratio at the output of the channel formed when two subscribers communicate in

common communication system the ratio is

turns out to be excessively large (F is common; and the frequency band used by the communication system, and K. the number of active channels).

The proposed method allows to reduce this value by about 6 times, reaching the maximum possible (notional) value of the separation efficiency of the signals.

For this purpose, in a transmitting device, each subscriber station generates signals in the form of segments of sinusoidal oscillations of the same amplitude and duration, but of different frequency. Signals follow each

other without pauses and differ only in the order of these segments.

The frequency of each m-th segment of the m-th signal is determined by the rule / ", f5 +

+ -Р „г А /, where ,, is some, the initial frequency is preselected; Р „,„ -value, comparable with the product of the n-t but the module; L - the number of elements (segments) of the signal, i.e. P „,„ / gm (mod N), L - a prime number; BUT/ -

frequency separation between the nearest but the frequency elements of the signal.

The value of A / can be selected within

D / tgp- - (T - duration

any signal / F and Af, „„ У

la

In the event that A / Af, v, then V FT, where M is the number of subscriber stations included in the communication system. If it is necessary to include the maximum number of subscribers in the system, the frequency spacing A / should be minimal, and then Ai, FT.

With this method, the sigpal, formed by each station, has a spectrum, the envelope of which is uniform over the entire frequency band occupied by the communication system. A view of this rounding is depicted in FIG. one.

the frequency band of the system is related, then the optimal selector of the useful signal is the correlation preamp or the receiver that has at its output a linear filter matched with the corresponding station's signal. The use of matched filtering allows simultaneous operation of the maximum possible number of active subscribers in a communication system with separation of signals according to the form, which is determined by the first signal-to-noise ratio at the channel output.

The proposed method allows the use of any kind of discrete modulation. In particular, in FIG. 2 and 3 are functional diagrams of a transmitting receiver; subscriber station of the communication system with the separation of signals in the form when using implicit-phase modulation.

In the transmitting device (see Fig. 2), the arming pulses, which follow with a clock frequency from the oscillator 1, are fed to the modulator 2 of the pulses in phase. A low-frequency modulating voltage is applied to the other output of the modulator. C modulator impulses

having a duration equal to - and modulated in phase (one time per transmission cycle), all the generators 3 of the shock excitation simultaneously excite. Each of these generators is tuned to one of the frequencies fn 1 and thus, at the L inputs of the switch 4, radio pulses occur simultaneously, which are elements (segments) of the generated signal. The order of placement of the radio pulses in the signal (and the shape of the signals) is determined by the connections reproduced in the switch. The outputs of the switch are connected either to the tapes of the multi-tap ultrasonic line 5 delay ULS, or to the inputs of individual ULL that delay the radio pulses for different times.

Since each radio pulse is delayed in a time interval different from the delay interval of any other radio pulse, a signal formed according to the above rule will appear at the output of the ULLD. The signal is amplified in amplifier 6 and by the antenna of the RTX.

It is also possible to transpose the frequency spectrum of the generated signal.

The received antenna signals (ciM. Fig. 3) are amplified in a linear broadband amplifier 7 (and if the signal spectra in the transmitting device were transposed to higher frequencies, then using a conventional mixer and a heterodyne, reverse transposition is performed) and fed simultaneously to N called “quasi-optimal filters 8. Each such filter is designed to receive one per clock radio frequency pulse f„ with the greatest

practically achievable signal-to-noise ratio at its output. It is known that when constructing such a filter using a two-circuit circuit with capacitive coupling, it is sufficiently close to 5 to approach the optimal reception of a radio pulse with a rectangular envelope.

From the outputs of the filters 8, the radio pulses of a diamond shape and a different frequency are fed through the switch 9 each to one of

10 taps of a multi-dividing DPS 10 or each at the output of its DIP, delaying such a signal for a previously known time interval. The value of this interval is defined as the difference between the duration T of the received signal and the delay time of the corresponding element of the common signal at the transmitting end.

From the output of the ULZ, the time-compressed signal is fed to the threshold device // and demodulated in demodulator 12, from the output of which a low-frequency signal is generated. It should be borne in mind that the amplifier 6 also produces (if necessary) the allocation of the clock frequency.

5 As in the receiving device, the radio pulse switch is used to dial the number of the correspondent (his address). Using the switch, you can listen to the work of any subscriber included in the communication system.

Subject invention

A method of multichannel communication in section 5 of research institutes of channels in the form of signals occupying a common frequency band with time independent signal transmission by any subscriber station, characterized in that, in order to increase the number of simultaneously operating stations at a given frequency band and their interference immunity subscriber stations generate signals in the form of parcels of sinusoidal voltages or currents of the same amplitude and duration, but with filling of different frequencies, place them in each signal without p in a different order determined by the connections in the switch of each transmitter, the sum of such

The 0 signals have an energy spectrum that is uniform in the frequency band of the communication system, and the signal is extracted from the kpm of the communication system at the receiving end by means of matched filtering or correlation reception.

5 2. The method according to claim 1, characterized in that

the frequency of each / r-th element of the t-from signal is determined according to the rule "", "/ o -f Pmt f

where P „„ is the result of comparing the product

pt modulo L; L is a prime number; fo -

The start frequency is selected. A / is the frequency separation value for the two frequency elements of the frequency.

k

wmw