DE2357703B2 - Method for phasing reference carriers for a data transmission system with frequency-differential phase modulation - Google Patents

Description

1 shows a system for the transmission of data with frequency-differential phase modulation,

Fig. 2 and 3 representations of scales, which when System according to Fig. 1 occur,

FIG. 4 shows a more detailed illustration of the in FIG synchronizing device shown schematically,

FIG. 5 shows timing diagrams of signals generated during operation of the synchronizing devices shown in FIG occur and

FIG. 6 shows a more detailed illustration of the evaluation circuit shown schematically in FIG.

FIG. I shows a data transmission system for the transmission of data by means of frequency-differential phase modulation. The data source DQ outputs the data in the form of a binary signal which assumes two different amplitude values, the binary values of which are identified by the reference symbols 0 and 1. The SerieJJ-Parallel-WandJer SP receives the data serially and forwards them in parallel to the encoder KD . The modulators MD \ are connected to the encoder KD. MDl. MDi, MDA connected, each of which is supplied with a carrier F1 or F1 or F3 or F4 from the generator GEN. For the sake of simplicity of illustration, only four modulators MD1 to MD4 are shown, whereas in practice a significantly larger number of modulators and corresponding carriers are generally used.

The phase-modulated carriers FIO, F20, FIO. F40 are emitted from the outputs of the modulators MDl, MDl, MDi, MDA and fed together to the transmitter SE and via a transmission link - for example via a shortwave link
transmitted to the recipient EM.

The transmitted signal mixture is amplified in the receiver EM and the amplified signal mixture G is fed to the inputs of the demodulators DM1, DM1, DM3, DMA and the synchronization device SYN via the output. The synchronization device SYN supplies the reference carriers R1, R2, R3, R4, with the aid of which the individual phase-modulated signals are demodulated. The decoders DK1, DK1, DK3 are connected to the outputs of the demodulators and reverse the coding carried out using the encoder KD. With the parallel-serial converter PS , the parallel incoming data are serially output to the data sink ÖS. A teleprinter or a data display device, for example, can be provided as the data sink.

Fig. 2 shows schematically the carrier / ⁷ I to F4, which are multiples of the fundamental frequency of the fundamental FS . The fundamental oscillation Fj and the carriers F1 to F4 are phase-locked to one another. The zero crossings of the fundamental oscillation Fs are at the times / 11, / 20, / 30 ... / 143, / 152, / 161. At these times, all zero crossings of the carriers F1 to F4 simultaneously coincide. In one embodiment, the fundamental oscillation Fs has a pulse repetition frequency of 80 Hz. The period length ρ of the fundamental oscillation Fr is thus equal to 1/80 sec in this embodiment.

In the course of the phase modulation, phase changes occur in successive modulation sections m. The modulation section ml lasting from time / 11 to time / 21 is somewhat larger than the basic period pl lasting from time / 11 to time / 20. In this exemplary embodiment, the modulation sections ml, ml .. follow. m 14, m 15 with a repetition frequency of 75 Hz, so that each modulation section m has a duration of 1/75 sec. The beginning and end of the modulation sections «j generally do not coincide with the zero crossings of the fundamental oscillation Fj. At times f 11 and / 161, however, the beginnings of the modulation sections m coincide with zero crossings of the fundamental oscillation Fs ·. The superperiod q. which begins at time / 11 and at time

ίο / 161 ends, thus comprises 16 basic periods pl, pl ■ ■ ■ ρ 15, /> 16 and modulation sections ml, ml ... ml4, ml5. For the sake of simplicity, only the first two and the last two basic periods and modulation sections are shown. The repetition frequency of the overperiod is 5 Hz.

The carriers F1 to F4 occurring on the transmit side correspond to the reference carriers R 1 to RA on the receive side, the repetition frequencies of which are multiples of the fundamental frequency Fe on the receive side. The receiving side

ao occurring reference carriers A1 to RA and the receiving-side fundamental frequency Fe are also connected to one another in a phase-locked manner. All zero crossings of the reference carriers Λ1 to Λ4 coincide with the zero crossings of the fundamental frequency Fe on the receiving side.

In the modulation system with frequency-differential phase modulation, phase differences are assigned to the data to be transmitted in each case from two adjacent carriers. For example, such data can be transmitted through phase differences of the carriers F2 and F3. Since the carriers F1 to F4 have a different period, these phase differences change continuously from modulation section to modulation section. The phase differences in successive basic periods ρ have the same value, but not successive modulation sections in. For example, the carriers F1 and F2 at time / 11 have a phase difference of 0, whereas after the modulation section ml at time / 21 they have a phase difference of 90 ^r . If on the transmitting side the basic periods pl to /> 16 parts of the modulation sections ml to »il5 are assigned, then the phase positions of the reference carriers Rl to RA must be set on the receiving side in such a way that the same parts of the modulation sections ml to ml5 are again assigned to the receiving side basic periods pl to pid are.

For phasing the reference carrier Rl to RA shows a reference signal E is in accordance. I in the generator GEN generated that contains the information as to when the transmitting end the transfer period starts q, with the reference signal E, the carrier F4 is in the modulator MDA modulated and the modulated carrier F40 in released by the transmitter SE and transmitted to the receiver EM . At the receiving end, the phase position of the reference carriers R1 to RA is set with the aid of the modulated carrier F40.

The reference signal E shown in FIG. 3 is shown on a different time scale compared to FIG. From the point in time / 11 to the point in time / 311, a full period of the reference signal F. is shown, which is equal to the sum of the two superperiods q and ql . The period from time / 11 to time / 311 thus includes in the present case

Embodiment 30 modulation sections. The reference signal E consists of square-wave pulses, of which the pulses £ 3, EA, ES, E6, ET, F.8 each have the duration of two modulation sections,

whereas the pulses El and E9 a period of three time shift between the signal correspond

Have modulation sections. according to diagram F41 and the signals

Fig. 4 shows in more detail an embodiment of the diagrams K and H.

the synchronizing device shown in Fig. 1 In Fig. 5 are three Fälk: shown, which relate to

SKjV. This synchronization device consists of the 5 correctly synchronized reference carriers, on leading ones

Oscillator OS, from the frequency change stage FS, reference carrier and refer to the dead time range,

from the frequency dividers FTl, FTl, from the evaluation The signals N, L, P, M can be DC voltages

control circuit BW, the modulators MDS, MDd, assume between the amounts +2 V and -2 V,

furthermore from the correlators KRl, KRl, KR3, KRA, in particular the amounts OV, -IV, -2 V are a

drawn from the phase shifters PSl, PSl, from the signal 10. In the first case, the diagram part Kl

converter stage SU, the coarse synchronization run GSYN precisely timed within a modulation grid m.

and from the analog-to-digital converter AD. This case is characterized by the signal N ,

With the oscillator OS a clock signal becomes relative that assumes a voltage of OV at point ΛΊ,

The dead time signal Q assumes the binary value 0. in the

change level FS supplied, which is either a single 15 second case, the diagram part Kl leads ahead.

glare or a fade-out of individual impulses above the modulation grid m. In this case have

causes. the signals / V and L in points Nl and Ll, respectively

The frequency divider FT1 gives the same polarity shown in FIG. With a trailing signal part Kl would have

set signal C and the reference carriers Rl, Rl, A3, these two points Nl and Ll opposite

RA from. The frequency divider FTl generates the in Fig. 3 ao. Polarity. The dead time signal Q takes the binary value 0

signals Al, Al, A3, AA shown. at. In the third case, the time base is the recipient

The signal A1 is used to offset an amplitude modulation of the signal part K3 by one modulation section m with respect to the modulator MDS. This case is characterized by the fact that the signal L at point L3, a voltage signal AI, assumes a phase of 0 ° of the reference carrier Λ4 a $ of 0 V during the duration of the 1 values. In this case the dead time has been set, whereas the binary value 1 is set for the duration of the signal Q.

0 values of the signal AI no signal is emitted. The signals N, L, P, M serve as a criterion for the With the modulator MD6 a phase modulation rough phase correspondence of the transmit side is effected in such a way that during the duration of the 1 values and the receiving side occurring modulation of the signal Al the reference carrier RA with phase 0 ° 30 cuts. This phase correspondence is and is emitted during the duration of the 0 values of the reference in the present transmission method as a coarse carrier Λ 4 with a phase of 180 °. called synchronization. This coarse synchronization-addition, each of these modulated signals is gated in a known manner with the coarse syndrome shown in FIG. 4 acting as an integration clock signal A3. whereby the signal K 35 shown in FIG. 4 is carried out. The coarse synchronization GSYN is or H results. on the one hand connected to the frequency change stage FS

In Fig. 5, the diagram F41 is shown at the top, which causes the fade-in or fade-out there

the phase position of the drawing in Fig. I of individual pulses. On the other hand, the coarse

SignalsF40 shows. The two binary values of the diagram synchronize the signal S, which corresponds to the binary

FAl thus correspond to the phases of 0 ° or of 40 value 1 always assumes when the coarse synchronous

180 ^{r of} the signal F40. Diagram K shows that sizing has ended.

Amplitude of the reference carrier to be modulated Λ 4, The signals / V, L, P, M are also used for

where the reference numeral 1 or 0 a certain phasing of the superperiod, so that both transmit

Amplitude with phase 0 ° or no signal on the associated side and on the receiving side with the basic periods

net is. Diagram H shows the phase position of the same parts assigned to the modulation sections

modulating reference carrier RA, with the loading. This phasing is carried out with the one shown in FIG

Numeral 1 or 0 or -1 a phase of 0 or the schematically illustrated evaluation circuit BW

no signal or a signal with a phase of 180 ^c carried out to which the signals A4, Q, S are fed

assigned. the. The signal W only assumes a 1 value,

Two different types of correlators are provided for generating the signals L, M, N, P if the level of the signal shown in FIG. The mixture C is in the target range.

Correlators KRl and KRl form the correlation of the analog / digital converter functions shown in Fig. 4 between the signal corresponding to the receives the analog signals N, L, P, M and is via diagram FAl and the signal corresponding to its outputs the binary signals NA, LA , PA and MA diagram H. The correlators KR3 and KR4 map 55. The analog values below a threshold value corresponding to the correlation function between the signal are assigned the binary value 0 and, above the diagram F 41 and the signal corresponding to the predetermined threshold value, the binary value 1 corresponding to diagram K. The signal is assigned accordingly. For example, the signal N up to the diagram F41 is contained in the composite signal G. When the point N3 is reached, the binary value 0 of the signal is assigned. This means that the signal 7V4 assumes the binary value 1, ^{even with any phase position of the signal 6l} > N4 , and from the point N3 of the signal N in accordance with diagram F41, the correctors. How to provide a usable signal from the two Pha- Fig. 5 can be seen, a polarity senschieber PSl and PSl is provided, each made one.

Effect a phase shift of 90 °. It is from the signal converter stage SU shown in FIG

Signals / V and L can be seen that each correlator ⁶ S receives the signals NA, LA, PA, MA and input

KRl, KRl, KR3, KRA always generate the dead time signal Q over two times ti

and thus over two modulation sections m signal converter stage SU is from the below

integrated. The signals L, M, N, P are a measure of the table.

LA Tabel MA Q N / A 0
1
0 PA 0
0
0 1
0
1 - ο ο 0
0
I.

The dead time range is thus signaled with the signal Q = I. A dead time range occurs when either NA = I, LA = 0. PA = 0, MA - 0 or NA = O, LA = O, PA = I, MA = O. The signal Q = O indicates that there is no dead time range.

Fig. 6 shows the evaluation circuit BW in more detail. It consists of the NAND gates NA1, NA2, NA 3, the inverter IN, the NOR gates NOX, NO1 and the bistable flip-flops ST1, ST1, ST3.

An O signal is only emitted from the output of gate NA 1 when a dead time range is signaled with Q = I, when the completed coarse synchronization is signaled with S = 1 and when a setpoint level of the composite signal G is signaled with W = 1. The stages STl and STl form a first counter and the stage ST3 forms a second counter. As soon as the first counter with the stages STl and STl to 3 has been counted, the signal D appears at the output, whereby it is achieved that in the frequency change stage FS shown in FIG. 4, pulses are inserted. A phase shift is thus carried out by a modulation section. Simultaneously with the output of the signal D , the first counter is blocked via the inverter IN and via the gate NO1 , so that only a single phase shift by one modulation section is carried out with the signal 5 = 1. The stage ST3 is supplied with the signal AA shown in FIG. 3, which has a pulse repetition frequency of 2.5 Hz. The two stages STl and STl are reset via the output of the gate NA3 if no signal S = 1 occurs within a period of 2.5 Hz,

ίο with which the completed phasing is signaled.

When phasing in the reference carriers A1, R1, R3, RA generated on the receiving side, the coarse synchronization is thus first carried out in a manner known per se. In the course of this coarse synchronization, the transmission-side modulation sections and the reception-side modulation sections are brought into congruence. In general, it is not immediately achieved in this way that the first basic period and the first modulation section begin simultaneously. In

In this case, the dead time signal Q = 1 is generated because the dead time ranges described with reference to FIG. 5 occur. Using the signal D , the time base of the receiver is shifted in phase by a modulation section. This process is continued until no more dead time areas are signaled with Q = O. This ends both the coarse synchronization and the phasing of the reference carriers A1, R1, A3, RA . The signal converter stage SU shown in FIG

can for example be formed from the equivalent gate GT1 and from the two AND gates GT1, GT3 .

For this purpose 4 sheets of drawings

TO9 538/268

Claims (4)

Patent claims: I. A method for phasing reference carriers for a data transmission system with frequency-differential phase modulation, according to which on the transmission side several carriers that are phase-locked to one another are phase-modulated in consecutive modulation sections and transmitted together, and according to which the transmitted data are recovered from the transmitted phase-modulated carriers by demodulation with the reference carriers on the receiving side, wherein the carriers or the reference carriers are assigned a fundamental frequency of the same fundamental frequency on the transmission side and the reception side, respectively, and the repetition frequencies of the carriers or the reference carriers are multiples of the fundamental frequency and with a first number of fundamental periods being assigned to a second number of modulation sections on the transmitting side during an overperiod, characterized in that a reference signal (E) is generated on the transmission side, which indicates the beginning of the excess period (q) , that with the reference signal (E) a d the carrier (F4) is modulated so that the modulated carrier (40) contains not only the data to be transmitted and in addition to the information regarding the start of the modulation sections but also the information regarding the start of the excess period (q) that the modulated carrier (40) is transmitting and that the phase position of the reference carrier (A1 to Λ4) is set on the receiving side with the aid of the modulated carrier (^ 40) 2. The method according to claim I, characterized in that a rectangular signal is generated as the reference signal (E) , the pulse edges of which coincide with the beginning of the modulation sections occurring on the receiving side and whose square pulses have two pulse widths, a first pulse width of which the duration of the modulation sections and a second Pulse width marks the beginning of the overtime (q). 3. The method according to claim 2, characterized in that the first pulse widths are spaced apart by two modulation sections (m) and that the second pulse widths of the reference signal (E) are spaced apart by three modulation sections (m) . 4. The method according to claim 1, characterized in that in the course of a coarse synchronization, the transmitted modulation sections on the transmit side are brought into phase with the modulation sections occurring on the receive side, that with the help of the reference sipral (E) a dead time signal (Q = 1) is derived, which the Identifies the dead time position of the reference signal (E) in relation to the phase position of two basic periods occurring on the receiving side and that, by means of the dead time signal (Q), the phase positions of the reference carriers generated on the receiving side are shifted by one modulation section (m) each until there is no more dead time signal (Q = 0) is produced. The invention relates to a method for Einphasunj of reference carriers for a data transmission system with frequency-differential phase modulation, wonacl On the transmission side, several carriers lying in phase with one another in successive modulations sections are phase modulated and transmitted together. In doing so, on the receiving side from the dei transmitted phase-modulated carriers by demodulation with the reference carriers that are transmitted ίο data recovered, with the carriers or dei Reference carriers on the transmitting side and receiving side ji trains a fundamental oscillation of the same fundamental frequency and the repetition frequencies of the carrier or the reference carrier are multiples of the fundamental frequency. Au In addition, the transmission side during an overpe period, a first number of basic periods is assigned to a second number of modulation sections. According to the German Palentschrift 12 12 985, ei in data transmission known to generate eir reference signal (synchronizing signal) in time unc so as to modulate a carrier with command characters so that the modulated carrier besides the one to be transmitted Data and, in addition to the synchronization information, also the information about command characters »5 keeps transmitting this carrier and on the receiving side adjust the phase position of the receiver with the help of the modulated carrier. In the above-mentioned method for frequency differential Phase modulation are the the transmission side and the reception side occurring basic periods the same parts of the modulation sections assigned. The invention is based on the object of specifying a method that mils this assignment made possible with little technical effort. According to the invention, a reference signal is generated on the transmission side, which marks the beginning of the overperiod. With this reference signal, one of the carriers is modulated, so that the modulated carrier except for the transmitted data and in addition to information ♦ ° with regard to the beginning of the modulation sections also the Contains information regarding the start of the overtime. The modulated carrier is transmitted and On the receiving side, the phase position of the reference carrier is set with its help. ♦ 5 The method according to the invention stands out characterized in that it can be implemented with little technical effort, because the information regarding the beginning of the extra period is transmitted with no additional carrier but with one of the carriers, which are intended for data transmission. It is useful to generate a square-wave signal as the reference signal, the pulse edges of which coincide with the beginning of the modulation sections occurring on the receiving side and their RecnWkimpulse have two kinds of pulse widths, of which a first pulse width is the duration of the modulation sections and a second pulse width is the beginning which identifies superperiods. In a preferred embodiment of the finding have the first pulse widths of the reference signal a distance of two modulation sections, whereas the second pulse widths one Have a distance of three modulation sections each. In the following, exemplary embodiments of the Finding described with reference to FIGS. 1 to 6, wherein The same objects shown in several figures are identified by the same reference numerals. It shows