DE2444429B1 - CIRCUIT ARRANGEMENT FOR CARRIER PHASE CONTROL DURING THE TRANSMISSION OF A DATA SIGNAL - Google Patents

Description

«5

The invention relates to a circuit - where f (t) means the filtered, receiving-side arrangement for carrier phase control in the recovered baseband signal, } {t) the transmission of a data signal with an amplitude transformation of f (t), Φ die Phase difference between

3 4

see the fictitious receiving-side carrier and the represented. The signal A 1 is used by the pulse shaper

actual receiving-end carrier. IF fed to the square wave signal A1 in a for

The known circuit arrangement has the data transmission suitable, band-limited Si

part that for generating the signals / (i) and J (i) and gnal is converted so that the at the sampling times 11

to delay the de- 5 to 1 8 given binary values at the receiving end are retained. With

modulated signals a relatively large technical signal B 1 becomes a carrier generated on the transmit side

Effort is required. amplitude modulated and from the output of the transmitter

The invention is based on the object of an SE being emitted and via a single sideband signal

Carrier phase control using the receive transmit a transmission link,

receiver input signal and without transmission of an io On the receiving side, the amplitude modulus is

carrier on the transmit side or a pilot signal or single sideband signal CX to the two demodulators

a remainder of the suppressed sideband with losers DM1 and DM2 supplied. Also will

Equally little technical effort due to these two demodulators DM1 and DM2

respectively. generated with ilem carrier generator TG carrier -TTL

According to the invention the following are provided: a first carrier 15 and the 90 ° phase shifted carrier Γ.2 to the multiplier, to which the first demodulated is fed, and the demodulated signals D 1 signal and the target samples of the hilberttransfor- or D 2 are sent to the low-pass filter TPl or TP 2 are fed down data signal and give a. Via the outputs of the low-pass filter TP1 or emits a first multiplicative mixed signal; a second TP2 , the signals Hl multiplier shown in FIG. 2, to which the second demodulated 20 or H 2 are emitted at the beginning. The zero lines of this and also the signal and the nominal sample values of the other signals on the receiving side are carried by dash-dotted lines to be supplied to a recovered data signal. There are two nominal amplitudes of the signal Hl and which denotes a second multiplicative mixed signal ab- with the reference symbols +2 and −2. To give; an adder with which the error signal is derived by subtracting the sampling times ti to i8, the amplitudes of the first and second multiplicative mixed signals 25 of the signal Hl approximately equal to the nominal amplitudes. +2 and -2. The signal H 2 is that of the signal Hl

The circuit arrangement according to the invention, graphically transformed signal.

net is achieved through little technical effort, the signal Hl is the decision stage ES

because no analog delay elements are supplied, in which the signals S1 and 52 are derived

to delay the demodulated signals. The nominal amplitudes of signals 51 and 52, respectively

are borrowed and because the multipliers for generation are with the reference symbols + α, -α and + b, -b

of the multiplicative mixed signals with a simple structure are designated With the decision level ES

can be, since the receiving side regained the ones occurring at the sampling times ti to t &

NEN setpoint samples of the data signal and the associated amplitudes of the signal Hl are determined, and it is

Hilbert transformed signal are digital signals, in 35 these amplitudes the closest setpoints + b

Contrasted with the filtered baseband signal and assigned to or -b of signal 52 and during the

Hilbert-transformed, filtered baseband signal is retained for the duration of one bit. For example, will

the known circuit arrangement mentioned at the beginning of the amplitude of the Si determined at time t5

tion. gnals Hl the setpoint + b of the signal 52 assigned

In the following, exemplary embodiments of the Er- 40 and up to time t6 are retained. The Si

The invention is described with reference to FIGS. 1 to 4, with signal 52 denoting the

the same objects shown in several figures obtained target samples of the data signal and

are identified by the same reference numerals. It therefore corresponds to that of the pulse shaper on the transmitter side

shows IF output signal Bl. As a comparison of the

Fig. 1 shows a first single sideband transmission 45 signals B1 and 52 are through both signals

system, the same data, namely the word LMMLLMLM

FIG. 2 signals which are shown in the case of the one shown in FIG. 1. The signal 51 is the auxiliary to the signal 52

System occur, bert-transformed signal. That from the decoder DC

3 shows a second single sideband data transmitted signal that is reproduced on the receiving side.

transmission system and 50 obtained data signal which is similar to signal A 1

F i g. 4 signals which, in the case of the in FIG. 3 is shown and the data sink DS is supplied.

System occur. Using the multipliers MUl resp.

The system shown in Fig. 1 contains send MU 2 , the products of the signals Hl-Sl are formed so the data source DQ, the pulse shaper IF, or H2 · S2 . Respectively via the outputs of the Multiden stations SE and receiving ends, the demodulation 55 plikatoren MUL .. MU2 the multipliers DMI, DM2, Θ the phase shifter, the gravure tive mixed signals Gl = Hl ■ 51 and G2 = H2 · 52 are passe% TP TP 2, the carrier generator TG, the sum output, and in the summer SU the difference mierer SU, the multipliers MUl, MU2, the signals Gl and G2 is formed. The Feblersignal Fl emitted by the summation decision stage ES, the decoder DC and the rer SU thus has M data sink DS. Fig. 2 shows some of the signals which have the form:

in the data transmission system according to FIG. 1 on - Fl = G2 - Gl - H2 - S2 - Hl'Sl
step. The abscissa direction refers to the

Time t. The data source DQ are shown in FIG. 2 DAR The error signal Fl is from the phase of the carrier Imagined signal A1 to the pulse shaper IF. The gers Tl regulated, the binary values of this signal A 1 generated in the carrier generator TG are with the reference B5.

characters L and M denoted. In contrast to the in the description introduction points ti to 1 8, the binary values L, M, M, L, L, M, L, M are the multipliers after the signal Al of the device MU2

5 6

or MUl not the analog receiving side again signal 54 corresponds to the signal 52 and takes the

filtered data signal obtained or not the corresponding setpoint values + b, 0, -b . The signal 54 is similar

Hilbert-transformed, analog filtered data signal, the signal B 3. The decoder DCl outputs a signal

but the non-filtered digital signals 52 and 52, which is similar to the signal A3. The signal 53

51 supplied. Due to these measures, 5 corresponds to the signal 51 and shown in FIG. 2

Generators for generating the filtered help adopts the setpoints + α, 0, -α . With the development

bert-transformed data signal and the generation of the separation stage ES , as in the case of FIG. 1,

of the filtered data signal, furthermore the occurrences at the sampling times il to il2 are superfluous.

Delay stages for delaying the signals Hl correspond to the amplitudes of the signal £ 3

and Hl. Since the signals 51 and 52 digital signals io assigned to nominal amplitudes of the signal 54 and up to

are, the multipliers MUl and MUl can be retained for the next sampling time. The Si

be constructed as switching stages. The product of the signal 54 identifies the nominal sample values of the data

signals Hl and 51 is then, for example, such a signal. The signal 53 is that of the signal 54 hilbert-

formed that when the target amplitude + a is present, the transformed signal.

of the signal 51 the signal Hl as multiplicative Si is taken over with the multipliers MU 3 and MU 4 wefden gnal Gl , while the products of the signals E3 and 53 or EA and duration of the nominal amplitude -a of the signal 51 the 54th formed and the multiplicative mixed signals G 3 signal Hl reversed polarity obtained as multiplicative or G 4. In this way, the fault signal Gl is accepted. In a similar way, the eraser signal F 3 is derived, which is represented by the following equation, the product formation of the signals H1 and 52. 20:

If signals 51 and 52 were analog signals, F3 = G4 - G3 = jB4-54 - E3-53
would have to be provided as multipliers MUl and MUl much more complex circuit arrangements. The error signal F 3 is fed to the integrator INT , which integrates the signal F 3 and the integrated

FIG. 3 shows a further exemplary embodiment of a 25 grated error signal F 4 to the carrier generator TG

Data transmission system that gives itself to the. The error signal FA becomes similar to

The system shown in FIG. 1 is essentially determined by the phase of the carrier T1 with the error signal F1

the pulse shaper / Fl, regulated by the two scanning.

stages ASl, AS 1, differentiated by the integrator INT and because of the digital nature of the signals 53 and 54 by the decoder DCl. With the 30, the two multipliers MU3 and MUA Pulse Shaper / Fl will be constructed relatively simply as switching stages for the individual binary values, with partial response pulses being assigned to signal A3, for example in the case of multiplier MU3 from net, and their superimposition makes this possible in the time ί 1 to time 8, the signal 1 El Fig. 4 shown signal B 3 is formed. For example, it is output as signal G3, from which time the individual binary values of the signal A 3 35 dot * 8 up to the time t9 the signal E 3 is output with partial response pulses of class 4 assigned reversed polarity and with. The setpoint amplitudes of the signal B 3 are again identified at the time i9, the signal E 3 with the darden reference symbols +2, O, -2. set polarity is emitted as signal G 3.
The data to be transmitted are identified by the set amplitudes of the signal B 3. The multipliers used as switching stages are used. With the 40 MU 3 and MU A , in the present case, signal B 3 must be able to and must be able to and must be similar to that in the case of the three switching positions. 1 data transmission system described on sen during the duration of a first or second of the transmission side modulates a carrier, and from the transmission or third switch position parts of the signals £ 3 and the SE is an amplitude-modulated one-side EA or a signal with the amplitude 0 or Part of the band signal is transmitted to the receiving end. 45 of the signals E 3 and RA with reversed polarity

The received signal C 3 is fed to the two dem summers SU .

modulators DM1 and DM2 supplied. Via the multipliers MU3 shown in FIG. 3 outputs of demodulators DM1 and DM2 become or Mt / 4, the signals D 3 and DA from the sampling stages and signals E 3 and EA via the outputs are fed. It would be the low-pass filter ΓΡ1 or TP1 , the demodulating 50 are conceivable, instead of these signals E 3 or EA, the lated signals H 3 or HA are emitted. The nominal Signaleii 3 or HA to be supplied, as in the case of the amplitudes of the signal H3 are marked with the reference Fig. 1 shown data transmission system in characters +2, 0, -2. With the scanning similar way happens. It would also be at level .451 is scanned, the signal H3 to the working time of the data transmission points shown in Fig. 1 il to tll, and to this 55 system possible, the signals Hl or Hl sampling time points observed amplitudes to step and the output signals of these are recorded for the next sampling time. In these sampling stages, instead of the signals Hl or Hl , the signal E 3 results. In a similar way, multipliers MU1 and MU 2 are supplied. When using the sampling stage AS 2 from the example, the signal EA could be derived from the signal HA shown in FIG. 60 put signal Hl using a no

The signal Zs3 .If the decision stage sampling stage the signal shown El £ 5 win

which emits the signals 53 and 54. Feed that and the multiplier MU1.

For this purpose 4 sheets of drawings

Claims (4)

1 2 patent claims · modulated single sideband signal; with a receiving-side inertia generator, which has a receiving 1. A circuit arrangement for the carrier phase is generated and which has a control input for the transmission of a data signal with an amplitude-modulated single sideband 5 of the carrier for an error signal for controlling the phase position; with a phase signal; with a receiving-side carrier generator slider, which is initially connected to the output of the carrier gate, which generates a receiving-side carrier generator and which the phase of the Träund. which shifts a control input for an error signal gers by 90 °; with a first or two for controlling the phase position of the receiving-side demodulator, both of which have the received gene carrier; with a phase shifter, the single sideband signal and to which individually the carrier input is connected to the output of the carrier generator or the carrier phase-shifted by 90 ° and which leads the phase of the carrier by 90 ° and a first and second demo-shifts; emit with a first or second demodulated signal; with a first or two modulator, to both of which the received one-th low-pass filter, to which the first or sideband signal is fed at the input and to which the carrier 15 is fed individually, the second demodulated signal and the carrier, phase-shifted by 90 °, a first at the output and second band-limited ones, respectively, and which emit a first and second demodulated signal, respectively; emit a decision-modulated signal; with a first generation stage, which, depending on the first band or second low-pass filter, to which the limited demodulated signal is initially fed the first and second demodulated signal at the receiving end, is fed back target samples of the data signal and at the output a first or second and of the Hilbert transformed signal for this purpose,
output band-limited demodulated signal; In the case of the amplitude-modulated single sideband with a decision stage that requires a carrier at the receiving end as a function of transmission, the first band-limited demodulated signal which, in terms of frequency and phase, corresponds to a desired sample value 25 recovered at the receiving end, the carrier present at the transmitting end. Using this carrier on the receiver side, a mated signal is emitted, characterized by demodulating the receiver input signal, and it shows that a first multiplier (MU 1, the data are reproduced on the receiving side, MU 3) is provided, the first of which was entered on the transmission side. For the modulated signal (Hl, H 3) and the target sampling carrier phase control on the receive side, the values of the Hilbert-transformed data signal (51, carrier present on the transmitter side with transmitted wer-S 3) can be supplied and the first multi- or it can Frequencies are transmitted, a multiplicative mixed signal (Eq, G 3) emits that the carrier is harmonically related to the carrier present in front of a second multiplier (ME / 2, MU 4) on the transmission side. It is also known to transmit the second demodulated 35 special pilot frequencies at the beginning and thus the signals (H 2, H 4) and the setpoint samples of the data signal recovered on the receiving side to be carried out ) and the second must emit demultiplicative mixed signal (G 2, G 4) in addition to the single sideband signals, and neither the carrier nor phase-locked with the carrier that an adder (517) is provided, which is connected by 40 frequencies or special pilot frequencies -Subtraction of the first and second multiples are transmitted. Cative mixed signal (Eq, G 3 or G2, G4) A carrier phase control can also be achieved in this way the error signal (Fl, F 3, F 4) derives (Fig. 1 causes both a remainder of the sub- to 4). depressed collateral ligament as well as the full one 2. Circuit arrangement according to claim 1, that 45 sideband are transmitted and that by Verdurch characterized in that a first sampling stage is equal to the remaining sideband with the fully transmitted - (., 45I) or a second sampling stage (^ 452) in front of the sideband checked the carrier phase control to whom the first or second will be introduced. modulated signal (Hl, H 3 or, H 2, H 4) to- The two known carrier phases described- and the first and second controls have the disadvantage of reducing energy Send scanning signal (£ 1, E3 or E2, E4) . need for signals - for example for the 3. Circuit arrangement according to claim 1 carried carrier or for the transmitted pilot and 2, characterized in that the first frequencies or for the co-transmission of a remainder of the multiplier (Mt / 1, MU3) or the second of the suppressed sideband — the not immediate Multiplier (Mi / 2, MU 4) the first or 55 bar are used to transfer data. second scanning signal (El, £ 3 or El, E4) to With a known circuit arrangement (DT-OS Position of the first or second demodulated Si 21 64 796), a carrier phase at the receiving end is gnais {iil, .03 or, H2, H 4) are supplied. regulation carried out without the sending side 4. A circuit arrangement according to claim 1, there- carrier or pilot frequencies or remnants of the sub-characterized in that the output of the 60 pressed sideband must be transmitted with the summator (5ί7) via an integrator (INT) on th. With this known circuit arrangement, the carrier generator (TG) is connected to the error signal F according to the following equation (Fig. 3). derived: