DE2257288A1 - METHOD FOR ESTABLISHING THE PHASE - Google Patents

Description

SIEMENS AKTIENGESELLSCHAFT Munich, 2 2. NOV. 1972

Berlin and Munich Wittelsbacherplatz 2

VPA 72/2166

Process for establishing phase synchronization

The invention relates to a method of manufacture phase synchronization in a synchronous message transmission system with a carrier that is suppressed on the transmit side. A control system is provided for regulating a carrier phase and a clock phase at the receiving end.

In the case of synchronous transmission systems with a carrier suppressed on the transmit side, the carrier frequency and carrier phase must be at the receiver also recovered the clock frequency and clock phase, will. While the recovery of the carrier frequency and the carrier phase can generally be performed satisfactorily is, an optimal control of the carrier phase and the clock phase causes difficulties, v / eil phase errors of a few Degree already disturb. To regulate the carrier phase and the clock phase, methods are known that use each of a control system regulate the carrier phase and the clock phase separately. This separate adjustment of the carrier phase and the clock phase has the disadvantage that relatively long control times are required.

The invention aims to provide a method that a enables rapid and precise adjustment of the carrier phase and the clock phase.

According to the invention, in a method of the type mentioned at the outset, the control systems for controlling the carrier phase and the clock phase coupled to one another in such a way that when the carrier phase changes, there is also a change in the clock phase and vice versa with a change in the clock phase as well

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a change in the carrier phase is made. The inventive Method is characterized in that the carrier phase and the clock phase in a shorter time than below Use of separate control systems can be regulated.

If the message consists of a series of partial response pulses of class IV and with the help of single sideband amplitude modulation is transmitted, then it is advisable to couple the control systems in such a way that a change the carrier phase corresponds to a double change in the clock phase.

In the following, exemplary embodiments of the invention are described with reference to FIGS. 1 and 2, the same components shown in both figures being identified by the same reference numerals.
Show it:

1 shows a data transmission system in which the data is transmitted to a receiver using a transmitter will and

FIG. 2 is a more detailed block diagram of that shown in FIG Recipient.

1 shows the data source 10, which emits a signal that represents the message to be transmitted. This signal can be a series of band-limited pulses. For example, the sequence of partial response impulses of the class IV exist. The signal emitted by the signal source 10 is fed to the transmitter 11 with the modulator 12, the modulates the amplitude of a carrier as a function of the amplitude of the supplied signal.

The signal emitted by the transmitter 11 is transmitted over the transmission link 13 transferred. The transmission can be based on a single sideband transmission method with completely or partially

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wise suppressed carrier. As a transmission link 1j5 can, for example, be a radio link or a telephone line be provided, which enables a transmission of the signal within the voice frequency band from 300 Hz to 3400 Hz.

The signal transmitted via the transmission link 13 is received by the receiver 14 and fed to the demodulator 15. In addition, the demodulator 15 is supplied with a carrier which is generated in the carrier generator 16 and its phase can be changed using the control stage 17. The change in The carrier phase is dependent on the control signal that is generated in the control signal generator 18 and fed to the control stage I7.

The output of the demodulator 15 is connected to the decoder 20 via the sampling stage 19, from whose output a signal is emitted, which largely resembles the signal emitted by the data source 10, if the carrier phase is correct is set.

In the clock generator 22 a clock is generated, which is via the control stage 23 of the sampling stage 19 is supplied. Using the control stage 23 is both the clock frequency as the clock phase can also be changed. Changes in the clock phase and the clock frequency are dependent on the control signal carried out, which is fed from the control signal generator 24.

Two control systems known per se are thus provided. Using the control system 25 with the control stage 17 and the control signal generator 18, the carrier phase is controlled, whereas with the control system 26 using the control stage 23 and the control signal generator 24, the clock frequency and the clock phase regulated. These two control systems 25 and 26 are coupled to one another via the coupling device 27 in such a way that that in the event of a carrier phase change, a clock phase change is automatically made. In particular,

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dependence on a carrier phase change made optimal clock phase change made. The clock phase is thus changed in such a way that the mean square deviation of the signal output via the output c of the sampling stage 19 from the setpoint values of the output from the data source 10 Signal is a minimum.

The signal is fed to the data terminal device 21 from the output of the decoder 20. As a data terminal device 21, for example a teleprinter may be provided.

The coupling of the control systems 25 and 26 is dependent on the pulse shape and the type of modulation of the selected transmission method. There will be a partial response impulse of the Class IV with the form

s (t) = 512-8 · 2 7Γ 0 -7Γ

provided and single sideband amplitude modulation.

The following mean: s (t) is the dependence of the amplitude s of the signal emitted by the data source 10 on the time t. 0 the clock phase.
Here 0 =, where T means the period duration.

Investigations have shown that under the conditions made above, the control systems 25 and 26 in such a way should be coupled that a change in clock phase 0 should be equal to twice the change in carrier phase. Thus, for example, if the carrier phase is changed by one degree, then the clock phase should be changed by two degrees will. The change in the clock phase can be dependent on the change in the carrier phase or vice versa the change in the carrier phase can be made as a function of the clock phase.

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Fig. 2 shows in more detail the receiver 14 also shown in Fig. 1 with exemplary embodiments of the control systems 25, 26 and the coupling device 27. The control system 25 shown consists of the generator 28, the on-blanking stage 29, the frequency divider 30 and the control signal generator 18. A signal is generated in the generator 28, the pulse repetition frequency of which is equal to η times the carrier frequency. Frequency division with the factor η is effected in the frequency divider 30. Using the on-blanking stage 29, individual pulses are always added or pulses of the signal supplied by the generator 28 are suppressed when from the control signal generator. 18 an impulse arrives. If no pulse is emitted by the control signal generator 18, the signal emitted by the generator 28 is fed unchanged via the blanking stage 29 to the frequency divider 30. The generator 28 and the frequency divider 30 thus essentially correspond to the carrier generator 16 _S shown schematically in FIG. 1, whereas the on-blanking stage 29 shown in FIG. 2 corresponds to the control stage 17 shown in FIG.

The control system 26 shown in FIG. 2 consists of the generator 32, the on-blanking stage 33 and the frequency divider 34 and the control signal generator 24. The generator 32 generates a signal whose pulse repetition frequency is equal to m times the pulse repetition frequency of the clock frequency «The frequency divider 34 causes a frequency division in the ratio m: 1. When using the on-blanking stage 33, then individual impulses inserted between the impulses supplied via input a or individual impulses suppressed, if pulses are supplied via inputs b and c. If no pulses are supplied via inputs b and c, then the signal supplied via input a is output unchanged via output d to frequency divider 34 » The generator 32 and the frequency divider 34 thus correspond to the clock generator 22 shown in FIG. 1.

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The blanking stage 33 shown in FIG. 2 corresponds to the control stage 23 shown in FIG. 1.

As a coupling device 27 according to FIG. 2, the pulse doubler is 35 is provided, to which the pulses are fed via input a and to which via output b one after the other emits twice the number of pulses. Since the output of the control signal generator 18 to the input 35a and the output 35b is connected to the blanking stage 33, the control systems 25 and 26 are coupled to one another. If, for example, a single pulse is output from the control signal generator 18 to the on-blanking stage 29, then a single pulse of the generator 28 is suppressed and in this way causes a shift in the carrier phase. on the other hand the single pulse of the control signal generator 18 is fed to the input 35a, and via the output 35b Two pulses are sent to the on-blanking stage 33. In this way, two pulses from the generator 32 are suppressed and thus causes a shift in the clock phase.

If, for example, by a single pulse from the control signal generator 18 a shift of the carrier phase by one degree is effected and if by suppression of a pulse a shift in the clock phase by one degree is also effected using the on-blanking stage 33, then by a pulse of the control signal generator 18 a shift in the carrier phase by one degree and a shift in the Cycle phase caused by two degrees.

Experiments have shown that such coupling'der let both control systems 25 and 26 shorten the control times. The optimal setting of the clock phase leaves can thus be achieved more quickly than using known circuit arrangements in which the control systems 25 and 26 are not coupled to each other.

2 figures

3 claims

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Claims (3)

Claims 1.j Method for establishing phase synchronization in a synchronous message transmission system with carrier suppressed on the transmit side, after which to regulate a receive-side Carrier phase and clock phase One control system each provided is, characterized in that the control systems (25, 26) for controlling the receiving-side The carrier phase and the clock phase at the receiving end are coupled to one another in such a way that when the carrier phase changes also a change in the clock phase and, conversely, in the event of a change in the clock phase, there is also a change in the carrier phase is made. (Fig. 1) 2. The method according to claim 1, characterized in that that the message consists of a sequence of partial response pulses of class IV and with With the help of single sideband amplitude modulation is transmitted and that the control systems (25, 26) are coupled in such a way are that a change in the carrier phase corresponds to a double change in the clock phase. 3. Circuit arrangement for carrying out the method according to Claim 2, characterized in that a generator is used to generate the carrier on the receiving side (28) is provided, the pulses of which via an on-blanking stage (29) and a frequency divider (30) on the receiving side arranged demodulator (15) are supplied that a control stage (18) is provided, which is a pulse-shaped Control signal generated, the pulses of which are fed to the on-blanking stage (29) and the insertion or suppression each one of the pulses of the generator (28) cause another to generate the clock on the receiving side Generator (32) is provided, the pulses of which over VPA 9/240/1091 - 8 - 409822/0539 a further on-blanking stage (33) can be fed to a further frequency divider (34) that a further control stage (24) is provided, the control signal of which consists of individual further pulses which are fed to the further on-blanking stage (33) and which carry out the insertion or the suppression of one of the pulses of the further generator (32) and that a pulse doubler (35) is provided, to which the pulses of the control stage (18) are fed and via its output (b) the double number of pulses one after the other to the further on-blanking stage (33), which inserts or suppresses a pulse when these pulses arrive (Fig. Z). VPA 9/240/1091 409822/0539 Empty soap