DE2257288B2 - PROCESS FOR PRODUCING THE PHASE CONFIGURATION AND CIRCUIT ARRANGEMENT FOR PERFORMING THE PROCESS - Google Patents

Description

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The invention relates to a method for producing phase synchronization in a synchronous Message transmission system with carrier suppressed on the transmit side, after which to regulate a A control system is provided on the receive-side carrier phase and clock phase, and then the message consists of a sequence of partial response pulses of class IV and with the help of single sideband amplitude modulation is transmitted.

In the case of synchronous transmission systems with a carrier suppressed on the transmit side, the receiver must Carrier frequency and carrier phase as well as clock frequency and clock phase can be recovered. Wall

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The recovery of the carrier frequency and the carrier phase can generally be carried out in a satisfactory manner is, an optimal control of the carrier phase and the clock phase is difficult because Already disturb phase errors of a few degrees. To regulate the carrier phase and the clock phase is For example, from GB-PS 13 23 446 a method is known that each using a control system regulates 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.

From the publication "First IEEE Annual Communications Convention", 7.-9. June 1965, pages 481 to 484, a message transmission system is also known in which control systems for control of the carrier and the clock are provided. However, in this known communication system only a coupling of the carrier frequency with the clock frequency is provided.

In the publication "Soviet Journal of Instrumentation and Control", No. 12, Dec. 1968, pages 41 and 42, describes a data transmission system with a carrier generator and a clock generator. Of the The carrier generator receives a pulse train from an oscillator to generate the carrier. Simultaneously the phase of the carrier is also regulated within the carrier generator. The clock generator generates the clock from a pulse train emitted by a frequency divider. The clock phase is also within the clock generator regulated. In this known data transmission arrangement, however, when the carrier phase changes does not change the clock phase.

From the DT-AS 12 86 073 there is a control system for controlling the clock phase on the receiving side, but not a control system for regulating the inertia phase on the receiver side is known.

The invention is based on the object of specifying a method with the aid of which phase synchronization in the case of a synchronous message transmission system with a carrier suppressed on the transmit side, a rapid and precise adjustment of the carrier phase and the clock phase is made possible.

According to the invention, the object is achieved in the method of the type mentioned in that the Control systems for regulating the receiving-side carrier phase and receiving-side clock phase in this way are coupled to one another that when there is a change in the carrier phase, there is also a change in the clock phase or conversely, when the clock phase is changed, the false phase is also changed, and that a change in 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 described, where The same components shown in both figures are identified by the same reference numerals. It shows

F i g. 1 a data transmission system in which the data is sent to a Recipients are transferred, and

2 shows a more detailed block diagram of the in F i g. 1 shown receiver.

The F i g. 1 shows the data source DQ, 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 can consist of partial response pulses of class IV. The signal emitted by the data source DQ is the

The transmitter SE is supplied with the modulator MO , which modulates the amplitude of a carrier as a function of the amplitude of the signal that is fed in

The signal emitted by the transmitter SE is transmitted over the transmission link US. The transmission can be based on a single sideband transmission method. be done with fully or partially suppressed carrier. A radio link or a telephone line can be provided as the transmission link US , for example, which enables the signal to be transmitted within the speech frequency range from 300 Hz to 3400 Hz.

The signal transmitted over the transmission link US is received by the receiver EM and supplied to the demodulator DM. In addition, the demodulator DM is supplied with a carrier which is generated in the carrier generator TRG and whose phase can be changed using the control stage RSi. The change in the carrier phase depends on the control signal that is generated in the control signal generator RSEi; o and fed to the control stage RST.

The output of the demodulator DM is connected via the sampling stage AB to the decoder DiC, from the output of which a signal is emitted which largely resembles the signal emitted by the data source DQ; if the carrier phase is set correctly.

A clock is generated in the clock generator TAG , which is fed to the sampling stage AB via the control stage RS2. Using the control stage RS2 , both the clock frequency and the clock phase can be changed. Changes to the clock phase and the clock frequency are carried out as a function of the control signal that is supplied by the control signal generator RE2.

Two control systems known per se are thus provided. The carrier phase is controlled using the control system R 1 with the control stage RSi and the control signal generator REi , whereas the clock frequency and the clock phase are controlled with the control system R 2 using the control stage RS 2 and the control signal generator RE 2. These two control systems R 1 and R 2 are coupled to one another via the coupling device KO in such a way that when the carrier phase changes, a clock phase change is automatically made. In particular, an optimal clock phase change is made as a function of a carrier phase change that has been 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 AB from the setpoint values of the signal output by the data source DQ is a minimum.

The signal is fed to the data terminal DE from the output of the decoder DK. A teleprinter, for example, can be provided as the data terminal DE.

The coupling of the control systems R i and R 2 depends on the pulse shape and the type of modulation of the selected transmission method. It becomes a Class IV partial response impulse with the form

sin Φ ⁽ '°

Φ ² - -τ ²

provided and single sideband amplitude modulation. Λ p

The following means: s (t) d \ e dependence of the amplitude s of the Her / pit t signal emitted by the data source DQ. Φ the TaktDhase.

It is

T '

where T is the period

Investigations have shown that, under the above conditions made, the control systems R 1 and R 2 should be coupled in such a way that a change in the clock phase Φ should be equal to twice the change in the carrier phase. Thus, for example, if the carrier phase is changed by one degree, then the clock phase should be changed by two degrees. The change in the clock phase can be made as a function of the change in the carrier phase or, conversely, the change in the carrier phase can be made as a function of the clock phase.

F i g. 2 shows in more detail the also in FIG. 1 illustrated receiver EM with exemplary embodiments of the control systems Ri, R 2 and the coupling device KO. The control system R i shown consists of the generator G 1, the on-blanking stage EA 1, the frequency divider FT and the control signal generator. A signal is generated in the generator G 1, the pulse repetition frequency of which is equal to / 7 times the carrier frequency. Frequency division with the factor η is effected in the frequency divider FT. Using the on-blanking stage EA 1, individual pulses are always added or pulses from the signal supplied by the generator G 1 are suppressed when a pulse arrives from the control signal generator REi. If no pulse is emitted by the control signal generator RE i , then the signal emitted by the generator G i is fed unchanged via the blanking stage EA 1 to the frequency divider FT . The generator G i and the frequency divider FT thus essentially correspond to that in FIG Carrier generator TRG shown schematically, whereas the on-blanking stage EA i shown in FIG. 2 corresponds to the control stage RS 1 shown in FIG.

The in Fig. The control system R 2 shown in FIG. 2 consists of the generator G 2, the on-blanking stage EA 2, the frequency divider FT2 and the control signal generator. The generator G 2 generates a signal whose pulse repetition frequency is equal to m times the pulse repetition frequency of the clock frequency. The frequency divider FT2 divides the frequency in a ratio of 1: m. Using the on / off stage EA 2 , individual pulses are always inserted between the pulses supplied via input a or individual pulses are suppressed when pulses are supplied via inputs b and c. If no pulses are supplied via the inputs b and c , then the signal supplied via the input a is output unchanged via the output d to the frequency divider FT2 . The generator G 2 and the frequency divider FT2 thus correspond to that in FIG. 1 clock generator TAG shown. The in F i g. Blanking stage EA 2 shown in FIG. 2 corresponds to that in FIG. 1 shown control stage RS 2.

The coupling device KO is shown in FIG. 2, the pulse doubler VD is provided, to which the pulses are fed via the input a and which emits twice the number of pulses one after the other via the output b. Since the output of the control signal generator REi is connected to the input a and the output b is connected to the blanking stage EA 2 , the control systems R i and R 2 are coupled to one another. For example, if the control signal generation

ger REi a single pulse is delivered to the Ein-Aus'aststufe EA 1, then a single pulse of the generator 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 RE 1 is fed to the input a of the pulse doubler VD , and two pulses are sent to the on-blanking stage EA 2 via the output b . In this way, two pulses from generator G 2 are suppressed, thus causing a shift in the clock phase.

For example, if a single pulse from the control signal generator REX causes the carrier phase to be shifted by one degree and if a pulse from the control signal generator is also used to shift the clock phase by one degree by suppressing a pulse using the on-blanking stage EA 2, then a pulse from the control signal generator REi shifts the carrier phase by one degree and shifts the clock phase by two degrees.

Tests have shown that such a coupling of the two control systems R 1 and R 2 can shorten the control times. The optimal setting of the clock phase can thus be achieved more quickly than using known circuit arrangements in which the control systems R 1 and R 2 are not coupled to one another.

Here / u 2 I5l; iti / jiduninucn

5

Claims (2)

Claims: 22 1. A method for establishing phase synchronization in a synchronous message transmission system with a carrier suppressed on the transmit side, according to which a control system is provided for regulating a carrier phase and a clock phase on the receiving side and according to which the message consists of a sequence of partial response pulses of class IV, ₀ and with With the help of single sideband amplitude modulation, the control systems (R 1, R 2) for controlling the receiving-side carrier phase and receiving-side clock phase are coupled to one another in such a way that when the carrier phase changes, there is also a change in the clock phase, or vice versa with a A change in the clock phase also changes the carrier phase, and a change in the carrier phase corresponds to a double change in the clock phase (i) 2. Circuit arrangement for performing the method according to claim 1, characterized in that a generator (G 1) is provided for generating the carrier on the receiving side, the pulses of which via an on-blanking stage (EA 1) and a frequency divider (FTX) a demodulator arranged on the receiving side (DM) that a control signal generator (RSX) is provided which generates a pulse-shaped control signal, the pulses of which are fed to the on-blanking stage (EA 1) and the insertion or suppression of one of the pulses from the generator (G 1) effect in that a further generator (G2) to the receiving-side generation of the clock is provided, the impulse blanking stage a (EA 2) a further frequency divider (FT2) are fed through another that a further control signal producer (RS 2) is provided, whose Control signal consists of individual further pulses which are fed to the further on-blanking stage (EA 2) and which facilitate the insertion or suppression of j e cause one of the pulses of the further generator (G 2) and that a pulse doubler (VD) is provided to which the pulses from the control signal generator are fed and which, via its output (b), send twice the number of pulses to the further on-blanking stage one after the other (EA 2) emits, which inserts or suppresses an impulse each time these impulses arrive (F i g. 2).