DE2439204C2 - Circuit arrangement for obtaining clock signals for the demodulation of time division multiplex signals - Google Patents

Description

25th

3 °

55

The invention relates to a Schallungsan-arrangement for obtaining clock signals for the Demodulation of Zeiimultiplexsignalen according to the preamble of claim I.

From the periodical "Eleklro Technology", November 1962, p 94, Fig. 16 and 17, with the associated description ^it is already known to characterize the synchronizing pulse (clock pulse) in that it is always the n-th or . That it has a greater amplitude or width than the other pulses.

From the textbook "Theory and Technology of Pulse Modulation", Hölzler / Holzwarth, Springer-Verlag Berlin / Göttingen / Heidelberg, 1957, page 450, last Paragraph up to page 451, first paragraph, it is also known to send a clock pulse via a suitable clock pulse sieve derived from a time multiplex signal and further processed separately.

From DE-AS 12 26 630, column 4, last paragraph to column 5, second paragraph, it is also known ^{to supply a synchronization signal from a .Signalgenerator controlled by a clock pulse generator to a second 6s} input of an additive mixing device in which it is with the Information signal formed by the information pulses is mixed. The synchronization signal should have a specific phase relation to the information signal.

Prior art not previously published, but the starting point of the present invention is from to filter out the frequency of the transmitted useful signal from the time division multiplex signal and with it, for example, to synchronize an astable multivibrator, the multivibrator in turn controls a frequency divider, at the output of which a frequency corresponding to the frequency of a Identification signal can be tapped. The frequency of the obtained from the time division multiplex signal in a second channel Identification signal restarts the frequency divider with each identification signal with the exact phase position. With such Digitally operating arrangements in which the signal is derived from analog signals is the However, the risk of interference and signal corruption is very high.

The invention is based on the object of providing a circuit arrangement of the type mentioned at the beginning create that is as insensitive as possible to interfering signals.

According to the invention, the solution is provided by what is specified in the characterizing part of claim 1 Measures.

It has proven to be advantageous to mix the identification signal and the useful signal in the mixer stage in this way make that the identification signal at the output of the mixer has a much greater amplitude than that Has useful signal.

The synchronization between the oscillator and the time division multiplex signal can be further improved. that the sine wave oscillator is additionally in the phase relationship to the aforementioned second frequency Zeiimultiplexsignal is kept constant.

The invention is explained in more detail below with reference to the drawing figures. It shows

Fig. La a from Kennsigna. ¹ and .Vutzsignal composite time-division multiplex signal,

F i g. Ib the course of the function obtained from the identification signal with the frequency f \,

F i g. Ic is the course of the function obtained from the useful signal with the frequency f2,

Fig. Id shows a pulse diagram of the gate pulse, which is decisive for the temporal position of the identification signal,

F i g. Ie the course of the signal present at the output of the mixer stage,

Fig. If the course of the synchronized on according to the invention Oscillator available signal,

F i g. 2 shows a block diagram of the entire circuit arrangement and

F i g. 3 is a circuit diagram of the oscillator.

According to the invention, from a predetermined AM-modulated Time division multiplex signal a clock signal can be derived, which is later used for demodulation by means of a "sample and hold" circuit Can be used. A phase relationship between the two must be as exact as possible Oscillator and time division multiplex signal are present. The time division multiplex signal is used to phase the oscillator provided with an identification signal that is repeated at known intervals. This identification signal corresponds to in its frequency is the frequency of the oscillator and determines its phase position.

In FIG. 1 a, a Zcitmiiltiplcxsignal composed of identification signal 40 and useful signal 42 is shown, the part labeled I representing the identification signal 40. The identification signal 40 is characterized in that the amplitudes of the signal sections B are

borrowed are greater than the amplitudes of the signal absorption C and both amplitudes are in a predetermined fixed ratio to one another.

Section II of the time division multiplex signal according to FIG. 1 a contains the information A, B and C. The information A is determined by the amplitudes of the minima, the information B by the amplitudes of the odd-numbered maxima and the shape C by the amplitudes of the even-numbered maxima of the useful signal 42 marked

As shown in FIG. La, the frequency f \ of the identification signal 40 is only half as great as that of the frequency / "2 of the useful signal 4Z because of the practically suppressed information C

The time-division multiplex signal according to FIG. 1 a is fed to a circuit arrangement shown in principle in FIG. Bandpass stages 10 and 11 select the frequencies f \ of the identification signal 40 and (2 of the useful signal 42 from the signal mixture activated and the Ib g in F i. characteristic signal represented at frequency f \ reaches the mixing stage IZ the band pass filter 11 is inhibited during this period. in the absence of the gate signal 50, however, the bandpass filter 11 is enabled and the bandpass filter 10 disabled. during this time The useful signal reaches the mixer 12 at the frequency (2) . The signal shown in FIG. 1e is available at the output of the mixer 12. The part of the signal shown in section I changes to that shown in section I of FIG ID signal 40. This part of the overall signal preferably has significantly greater amplitudes than that part of the overall signal shown in section II of FIG.

This signal is fed via a coupling capacitor 15 to the base of a transistor 16 connected as an impedance converter, the collector of which is connected to a DC voltage source 17 and its emitter, on the one hand, via a resistor 18 to ground and, on the other hand, via a coupling capacitor 19 to the base of an oscillating transistor 20 connected is. Both the base of the transistor 16 and the base of the transistor 20 are each connected to a tap of a voltage divider consisting of resistor 21 and 22 or 23 and 24, which are each connected between the DC voltage source 17 and ground. In this way, the respective optimal working range of the transistors is selected.
The transistor 20 is part of one known per se

ίο Sine oscillator in three-point connection. The oscillator circuit consists of the parallel connection of a capacitor 25 and an inductance 26, which between the DC voltage source 17 and the collector of transistor 20 are connected. The emitter of the transistor is on the one hand via a resistor 27 and a capacitor 28 connected in parallel to ground and on the other hand Connected to a tap of the inductance 26 via a capacitor 29. The output signal the oscillator circuit is connected to the collector of the

ίο transistor 20 tapped and stand at output 30 to disposal.

The oscillator has only weak feedback and oscillates at the fundamental frequency f \ of the identification signal. It is influenced by the applied composite signal in such a way that a rigid phase relationship is established between the time-division multiplex signal and the oscillator 14 during the time of the identification signal. During the period without the identification signal, the oscillator 14 is expediently kept constant or corrected in the phase relationship by the higher-frequency oscillation (2) . The oscillation corrected in this way with the frequency f \ is shown in FIG.

The oscillator 14 operated in three-point connection can be adjusted with the aid of the measures according to the invention change in its phase position in a surprisingly simple manner, provided that it has a very low resistance at the base of its Oscillating transistor 20 is controlled.

A very important advantage of the arrangement according to the invention is the insensitivity to random Interfering and false signals in the area of the useful signal.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for the recovery of Clock signals for the demodulation of time division multiplex signals using a gate signal of suitable length, characterized in that that for the demodulation of AM time division multiplex signals, which consists of an identification signal (40) with a first frequency (71) and a useful signal (42) with a second frequency (72), the second frequency being an integral multiple on average the first frequency, a first bandpass circuit (10) which can be activated by the gate signal (50) to select the first frequency (71) from the identification signal (40) and a second, in the pauses of the Gate signal (50) activatable bandpass circuit (11) for selecting the second frequency (72) the Nutzsi ^ nal (42) are available that the outputs of the two bandpass circuits (10, 11) are connected to a common mixer (12) and that the mixer (12) in turn with a Sine wave oscillator (14) is connected in a three-point circuit, which is via a low-resistance impedance converter (13) can be controlled at the base of its oscillating transistor (20). 2. Circuit arrangement according to claim 1, characterized in that the mixture of the identification signal (40) and useful signal (42) in the mixer (12) takes place in such a way that the identification signal (40) at the output the mixer stage has a significantly greater amplitude than the useful signal (42). 3. Circuit arrangement according to claim 1 or 2, characterized in that the sine wave oscillator (14) is additionally kept constant in the phase relationship to the time-division multiplex signal by the aforementioned second frequency (f2). 15th