CH667169A5 - METHOD FOR TRANSMITTING A LOW-FREQUENCY MODULATION SIGNAL AND CIRCUIT ARRANGEMENT FOR IMPLEMENTING THE METHOD. - Google Patents

Abstract

1. Method for the phase-locked transmission of a voice-frequency modulation signal from a central signal source via feeder connections to a plurality of spatially distributed base stations of a common-frequency radio system, in which method phase rotations of the modulation signal in the feeder connection are compensated, characterized in that - an auxiliary carrier (AC) located outside the voice-frequency band (VB) of the modulation signal is generated ; - the auxiliary carrier (AC) is mixed with the modulation signal ; - the lover sideband (LSB) resulting from the mixing, together with a residual auxiliary carrier (RAC), is transmitted to the base stations (B, B1, ..., B3) ; and - the original modulation signal is recovered at the base stations (B, B1, ..., B3) from the lower sideband (LSB) by mixing with the aid of the residual auxiliary carrier (RAC) transmitted.

Description

DESCRIPTION

The invention relates to a method for the phase-locked transmission of a low-frequency modulation signal according to the preamble of claim 1 and a circuit arrangement for carrying out the method. A method of the type mentioned is e.g. known from Brown Boveri Mitt. 5/6, 1983, pp. 186-188.

Common-frequency radio is frequently used for frequency-economical radio coverage of large areas, in which a plurality of interconnected base stations are operated simultaneously on the same frequency channel. The base stations are distributed in such a way that the areas covered by them adjoin each other and cover the entire radio coverage area.

In order to keep the reception interference in the unavoidable overlap areas of several base stations as low as possible, certain conditions with regard to the synchronization of the base stations would have to be observed.

In the case of a fully synchronous system, which is associated with a high level of technical complexity, the carrier frequencies of the different base stations are coupled to one another and absolutely identical.

In a quasi-synchronous system, a separate, highly stable oscillator for the carrier frequency is provided in each base station, the maximum deviation between the carrier frequencies of different base stations not being allowed to be more than 5-20 Hz.

In addition to the reception interference caused by carrier frequency differences in the overlap areas of a quasi-synchronous single-frequency system, there are also the modulation-dependent interference: The modulation signals are transmitted from a central signal source to the individual base stations via feeder connections, where they modulate the respective carrier. Since the base stations are at different distances from the central signal source and different technical systems (LF line, directional radio link, etc.) may be used for the feeder connections, there are in particular runtime and phase differences between the modulation signals transmitted on different feeder connections, which are balanced in a suitable manner must be in order to limit disturbing interference phenomena in the overlap areas.

It is now known when using NF lines

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

3rd

667 169

or channeling radio links as feeder connections to compensate for the phase shift by means of suitable phase correction elements and runtime elements inserted into the connection, each of these elements having to be matched to the special transmission properties of the respective feeder connections (Brown Boveri Mitt. 5/6, 1983, pp. 186-188 ). For each single-wave radio system, this requires a special structure in the individual feeder connections and therefore leads to increased expenditure.

In addition, any carrier frequency transmission systems cannot be used as feeder connections, because the transposition of the different channels at the different locations produces signals with different phases and frequencies, which cannot be matched to one another in the known way by inserting correction elements.

The present invention is therefore based on the object of specifying a method for the phase-locked transmission of modulation signals from the central signal source to the base stations of a single-wave radio system, in which the compensation of occurring phase errors is achieved regardless of the type of feeder connection, and which therefore also Permission to use any carrier frequency transmission system as feeder connections.

The object is achieved in a method of the type mentioned by the features from the characterizing part of claim 1.

The essence of the invention is to mix the modulation signal with a subcarrier before transmission, to transmit at least one of the side bands resulting from the mixing together with the subcarrier to the base stations and there to mix again with the transmitted subcarrier or with a phase-locked coupling to it to demodulate locally generated subcarriers. Since the sideband signal and the subcarrier always experience the same phase shifts on the feeder connection, the phase shift of the modulation signal during demodulation is automatically compensated for by the transmitted subcarrier.

The side band and subcarrier preferably lie in the same channel, which is designed as a telephony channel.

The circuit arrangement for carrying out the method has a modulator with a local oscillator, preferably a quartz oscillator, and a first mixer behind each signal source and a corresponding demodulator with a second mixer and means for recovering the auxiliary carrier in front of each base station.

The invention will now be explained in more detail below on the basis of exemplary embodiments in connection with the drawing. Show it:

1 shows the block diagram of a known single-wave radio system with different types of feeder connections,

2 shows the block diagram of an individual feeder connection with carrier frequency transmission system and phase correction according to the invention,

3 shows the block diagram of an exemplary embodiment of the modulator from FIG. 2,

4 shows the corresponding block diagram for the demodulator from FIG. 2,

5a-c the frequencies and frequency bands occurring in a modulator according to FIG. 3,

6a-c the corresponding frequencies and frequency bands in the demodulator of FIG. 4th

1 shows an exemplary single-wave radio system according to the prior art. The radio coverage of a large area takes place via a plurality of base stations B1, ..., B3, which simultaneously transmit the carrier signal modulated with a low-frequency modulation signal via corresponding antennas AI, ..., A3.

The modulation signal comes from a low frequency signal source 1, e.g. a microphone, and is distributed via feeder connections to the individual base stations Bl, ..., B3. The feeder connections can be realized by LF lines 11, 12 of different lengths, but also by a single-channel radio link 13 with a radio relay 2 and a radio receiver 3.

In order to compensate for the phase differences occurring on the different feeder lines, phase correction elements 4 are provided in the lines, which compensate for phase differences by means of runtime differences and differences in the phase response. Each of these phase correction elements is matched to the transit time and phase response of the respective transmission path and fulfills this function in a frequency channel with a relatively narrow bandwidth (e.g. telephony channel with A f = 3.1 kHz).

According to the invention, the modulation signal is now changed before it is transmitted via the feeder connection in such a way that the phase change can be corrected by the feeder connection at the base station without knowing the properties of the connection itself. This is particularly advantageous for applications in which any carrier frequency systems with FDM (Frequency. Division Multiplex) are used as feeder connections.

The block diagram of an individual FDM feeder connection of this type with phase correction according to the invention is shown in FIG. 2. Since an FDM system only makes sense if several channels have to be transmitted at the same time, a plurality of low-frequency signal sources 1 is assumed in FIG. Each of the signal sources is assigned its own channel. The modulation signals coming from the signal sources 1 are first modified within their channel by a subsequent modulator in the sense of the method according to the invention. The details of this modification will be discussed in more detail later in connection with the design of the modulator 5.

After the modulation signals in the modulators 5 have been modified, the individual channels are transposed to higher frequencies in a manner known per se by a carrier frequency multiplexer 6 and frequency-wise connected to a carrier frequency receiver 8 via a carrier frequency transmitter 7 and a carrier frequency path 14. A subsequent carrier frequency demultiplexer 9 returns the channels to their starting position in terms of frequency and forwards them separately to a number of demodulators 10 corresponding to the number of channels, in which the respective phase shift is corrected and the original modulation signal is recovered.

The recovered modulation signals are then passed on to a base station B, where they modulate the carrier signal emitted via an antenna A.

A preferred exemplary embodiment of the modulator 5 from FIG. 2 is shown with its block diagram in FIG. 3. A detailed representation of the circuitry structure of the individual blocks has been dispensed with here as well as with the corresponding circuit diagram of the demodulator 10, because the execution is known to every person skilled in carrier frequency technology.

The modulation signal from the signal source 1 is first given within the modulator 5 via a first isolating transformer 15, which preferably has a transmission ratio of 1: 1 and an impedance of 600 ohms, to the input of a first input amplifier 16 and there to one for further signal processing favorable level strengthened.

The first input amplifier 16 is followed by a band limit filter 17 which limits the frequency band of the modulation signal and preferably has an upper limit frequency of approximately 3 kHz. The flow characteristic of the

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

667 169

4th

Band limitation filter is entered as a dashed line in FIG. 5 a, a lower limit frequency of 3.2 kHz is entered from FIG. 6 a, which has the result of the limitation between, the subcarrier residue HTR branches off and to the local one

0.3 and 3 kHz low frequency band NB of the modula- generation of a phase-locked coupled subcarrier in the de-

tion signal shows. modulator 10 used.

The low-frequency band NB is fed to the one input of a. The branched subcarrier residue HTR is fed to a first mixer 18, which amplifies the modulation signal with carrier signal amplifier 30 and, for synchronization, an auxiliary carrier HZ of preferably 3.3 kHz, represented on a PLL (phase locked loop ) Circuit 31 at their syn-

the frequency axis in Fig. 5b, mixes. The HT subcarrier is forwarded to the chronological input. The PLL circuit generates from the oscillator frequency of a local oscillator, preferably preferably a frequency of 6.6 kHz, which in a subsequent

of a quartz oscillator 20, e.g. 3.3792 MHz using the second frequency divider 32 with a sub-ratio of carries and divided by a subsequent first frequency divider 21 2: 1 down to 3.3 kHz and via a feedback

Divided down to 3.3 kHz with a part ratio of 210: 1, loop to the feedback input of the PLL circuit 31

becomes. Other oscillator frequencies require correspondingly.

their partial ratios. In this way, at the output of the second frequency part

When the modulation signal and subcarrier 15 are mixed, a locally generated undisturbed subcarrier of 3.3 kHz is generated

HT, a lower sideband USB and an upper side are available, which on the modified modulation signal tenband OSB are symmetrical to the frequency of the subcarrier HT. coupled with the transmitted subcarrier residue HTR

Both sidebands are shown in Fig. 5c. The bottom is.

The tenband USB corresponds to the low frequency band NB in Kehr. The local subcarrier is located in the second mixer 25 and contains, in itself, the same information. 20 amplified modified modulation signal mixed, which

In order to save bandwidth, a lower sideband USB and an upper side

Most mixer 18, a first sideband filter 19 with an OSB in FIG. The lower sideband corresponds to USB

5c, the transmission characteristic curve shown in broken lines after the original low frequency band NB from FIG. 5a and tet, which is with an upper cutoff frequency of 3 kHz by a second sideband filter 26 (upper cutoff frequency

Subcarrier HT and the upper sideband OSB suppressed. 25 quenz: 3 kHz), whose pass characteristic is shown in Fig. 6b

The remaining lower sideband USB reaches one, separated (FIG. 6c), in an output amplifier 27, input of an adder amplifier 23. Strengthens to another input and via a second isolating transformer 28 (transmission

the adder amplifier 23 has a reduced amplitude ratio: 1: 1; Impedance: 600 ohms) to the

Subcarrier residue HTR given that passed on via a harmonic filter 22 de base station.

with an upper cut-off frequency of e.g. 4 kHz, at the output 30 Da for mixing in the second mixer 25 of the demodulator

of the first frequency divider 21 is removed. tors 10 with the transmitted lower sideband USB to the

At the output of the adder amplifier 23, the transmitted subcarrier residue HTR then appears phase-locked.

modified modulation signal, which uses two signal sizes from the lower side, locally generated subcarriers, and the adjacent subcarrier group HTR, both of which are the phase change by the feeder

put together. Both are shown in solid lines in FIG. 5c. 35 bind to the same extent, compensate each other

The modified modulation signal can now automatically mix these phase changes using any mix,

feeder connection with the corresponding bandwidth as by the preferred restriction of the low-frequency band

e.g. The FDM system of FIG. 2 is transmitted to the base stations at frequencies between 0.3 and 3 kHz and the selection is where it has previously been corrected in the demodulator 10 and an auxiliary carrier HT with 3.3 kHz can be converted back to the modified one becomes. 40 modulation signal (lower sideband USB upside down +

A preferred auxiliary carrier residue HTR) suitable for the modulator of FIG. 3 via any internationally standardized telephoto

Example of the demodulator 10 is transmitted with its blockphonic channel, which has a minimum bandwidth of 0.3 to

Circuit diagram shown in Fig. 4. The modified, which has 3.4 kHz.

Incoming feeder modulation signal of the FIG. Overall there is one with the inventive method

6a is first available in the modulator 10 in a second 45 method in order to control basic

Input amplifier 24 amplified and fed to a second mixer 25 of a single-wave radio system regardless of the type. At the same time, the amplified signal by means of the feeder connection easily turns the phase of a high-pass filter 29 which has to be compensated for the modulation signal to be transmitted for the exemplary transmitters.

v

3 sheets of drawings

Claims (9)

667 169 1. A method for the phase-locked transmission of a low-frequency modulation signal from a central signal source via feeder connections to a plurality of spatially distributed base stations of a single-wave radio system, in which method phase changes of the modulation signal in the feeder connection are compensated, characterized in that an outside of the low-frequency band (NB) of the modulation signal lying subcarrier (HT) is generated; the subcarrier (HT) is mixed with the modulation signal; the lower sideband (USB) resulting from the mixture is transmitted to the base stations (B, Bl, ..., B3) together with an auxiliary carrier residue (HTR); and the original modulation signal is recovered from the lower sideband (USB) at the base stations (B, Bl, B3) by mixing with the aid of the transmitted subcarrier remnant (HTR). 2. The method according to claim 1, characterized in that the low frequency band (NB) of the modulation signal and the subcarrier (HT) are within a telephony channel, the low frequency band (NB) preferably ranging from 0.3 to 3 kHz and the subcarrier (HT) preferably has a frequency of 3.3 kHz. 2nd PATENT CLAIMS 3. The method according to claim 2, characterized in that at the base stations (B, Bl, ..., B3) the transmitted subcarrier remainder (HTR) is separated from the lower sideband (USB), and a phase-locked to the subcarrier remnant (HTR) coupled local subcarrier of the same frequency is generated and used for mixing with the lower sideband (USB). 4. The method according to claim 1, characterized in that the lower sidebands (USB) multiplexed a plurality of modulation signals with the associated subcarriers (HT) according to the carrier frequency method and transmitted as a multiplex signal to the base stations (B, Bl, ..., B3) and there be demul-tiplexed before the original modulation signals are recovered. 5. Circuit arrangement for performing the method according to claim 1, characterized in that in each feeder connection from the signal source (1) to a base station (B, Bl, ..., B3) behind the signal source (1), a modulator (5) and in front of the base station (B, Bl B3) a demodulator (10) it is arranged that the modulator (5) contains a local oscillator for generating the subcarrier (HT) and a first mixer (18) for mixing the modulation signal with the subcarrier (HT), and that the demodulator (10) contains a high pass filter (29) for Separation of the transmitted auxiliary carrier residue (HTR), a second mixer (25) for recovering the original modulation signal with the aid of the transmitted auxiliary carrier residue (HTR) and a second sideband filter (26) arranged at the output of the second mixer (25) for suppressing the auxiliary carrier (HT) and the upper sideband (OSB) formed during mixing. 6. Circuit arrangement according to claim 5, characterized in that in the modulator (5) behind the output of the first mixer (18) a first sideband filter (19) for suppressing the auxiliary carrier (HT) and the upper sideband (OSB) formed during mixing is provided , and that the subcarrier remainder (HTR) is added to the remaining lower sideband (USB) in an adder amplifier (23) and is taken from a quartz oscillator (20). 7. Circuit arrangement according to claim 6, characterized in that the local oscillator is the quartz oscillator (20), vibrates at a frequency that is a multiple of the frequency of the subcarrier (HT) and that the quartz oscillator (20) is followed by a first frequency divider (21) for generating the subcarrier (HT). 8. Circuit arrangement according to claim 7, characterized in that in the demodulator (10) behind the high-pass filter (29) a carrier signal amplifier (30) and subsequently a PLL (Phase Locked Z, oop) circuit (31) is arranged, one to the subcarrier rest (HTR) phase-locked coupled local subcarrier of the same frequency generated and forwarded to the second mixer (25). 9. Circuit arrangement according to claim 8, characterized in that the quartz oscillator (20) generates a frequency of 3.3792 MHz, the first frequency divider (21) has a division ratio of 210: 1, the first and second sideband filters (19, 26) have an upper cut-off frequency of 3 kHz, the high-pass filter (29) has a lower cut-off frequency of 3.2 kHz, and a band-limiting filter (17) with a bandwidth of 0.3 to 3 kHz is arranged in front of the first mixer (18).