FR2482339A1 - Single sideband transmission system using two pilot frequencies - uses two local oscillators controlling reception and transmission heterodyne signal oscillators for each repeater - Google Patents

Abstract

The transmission system has a number of relay stations between the transmitter and the receiver, each with two local oscillators delivering reception and transmission heterodyne signals. The transmitted signal contains two pilot sub-signals and each repeater has two filters respectively tuned to the frequency of the two pilot sub-signals, each soupled to an amplifier chain and to a respective input of a mixer delivering a beat frequency. A third local oscillator has a slave circuit controlled by the beat frequency and its output signal controls a circuit supplying a signal at the initial pilot frequency. The slave circuits for the local oscillators for the reception and transmission heterodyne signals are controlled by the signal provided by the third local oscillator and by the signal at the initial pilot frequency.

Description

 The present invention relates to a radio transmission system BLU using two pilot frequencies for the control of local oscillators. It finds application in telecommunications and especially in the production of radio links.

 A radio link installation comprises, in a conventional manner and according to the general scheme of FIG. 1, a transmitting station 10, a succession of relay stations 11,. , 19 and a receiving station 20.

Each relay station comprises a repeater whose structure is shown diagrammatically in FIG. 2. The repeater 25 shown is connected to a reception element 30 picking up the radio signal transmitted by the preceding relay station, and it comprises a first local oscillator 0 (fr) providing a reception heterodyne signal having a frequency fr, an input mixer 32 connected to the receiving member 30 and receiving the reception heterodyne signal from 0 (fr), this mixer delivering a signal located in a band of intermediate frequency (f1), an amplification chain 34 operating in this intermediate frequency band, a second local oscillator O (fe) delivering a transmit aerodyne signal at a frequency fe the frequencies fr and being different from an amount f said transposition frequency, an output mixer 36 connected to the chain 34 and receiving the heterodyne signal dBémiss sion d e Q (fe). The output of the repeater 25 is connected to a transmitting member 38 retransmitting a radio signal towards the next relay station.

As an indication, the emission frequencies fe and reception r may differ, for example, from 213 kEiz for the frequency plan used in France in the band 3.8 to 4.2 GHz. The intermediate frequency is generally close to 70 Hz or 140 Hz zen
In such a system, one can make use of so-called single-sideband (SSB) amplitude modulation. The corresponding frequency plan is schematically shown in FIG. 3 where sidebands 41, 42, 43 are shown representing multiplexed transmission path packets. (The frequencies fmt fm f1 and f2 that appear in this diagram will be the subject of the following description).

 Radio-relay systems working in single-sideband amplitude modulation as well as digital radio-relay systems require very good compensation for amplitude distortion. This is caused by destructive interferences between different paths taken by the radio wave between the transmitting and receiving stations. Furthermore, in amplitude-modulated analogue radio-relay systems as well as in digital radio-relay systems carrying amplitude-modulated and phase-modulated carrier frequency multiplexes by digital multiplex trains, it is necessary to restore, after each repeater and with very high accuracy, the frequencies of the multiplex emitted.

 The heterodyne waves of radio relay stations are traditionally generated from guartz oscillators, followed by multipliers and / or frequency dividers and associated with in-phase servocontrol means.

 The known type of radio beams, operating in amplitude modulation with a single lateral band, employ local oscillators of traditional type with, however, quartz of very high stability and a simple loop of control of the frequency of the heterodyne wave of the last transposition bringing the multiplexes from the intermediate frequency to the baseband. This slaving is achieved by means of a pilot frequency inserted in the multiplex and compared to a frequency reference generated locally, from reference waves provided by a buried coaxial cable transmission network. The detection of the level of the pilot frequencies necessary for the control of the dynamic amplitude equalizers, is effected by straightening the pilot wave extracted from the multiplex by a very narrow bandwidth filter.

 This prior art has many disadvantages. First, the generation of heterodyne waves of emission and reception is quite complex. Then, the exact reproduction of the frequencies of the intermediate frequency multiplex is not ensured, and the exact reconstruction of the baseband multiplex requires the use of reference frequencies transmitted by a network of cables. Finally, the extraction of the pilots requires filters of very low bandwidth, which are of delicate realization, and it does not allow by obtaining information on the relative phase of the pilots in the band.

The subject of the invention is precisely a transmission system which overcomes these drawbacks, in particular in that it leads to a simplification of the microwave circuits born
necessary for the generation of heterodyne waves, - coherent detection of the pilot frequencies, which
greatly simplifies the filters used for extra-
re the pilots of the multiplex and allows the determination
relative phase shifts of the pilot waves, phase shifts
caused by the distortions due to the propagation
radio frequency, resulting in more precise control of
compensation circuits for amplitude distortion
and phase, - the possibility of inserting or extracting carriers
modulated, directly in intermediate frequency, me
me in the relay stations.

 These objects are achieved, according to the invention, by the insertion into the transmitted signal of sinusoidal signals giving rise in the intermediate frequency band (that is to say after mixing with the receiving heterodyne wave). at two frequencies f1 and f2 (these are the frequencies shown in FIG. 3) and by extracting, in each repeater, the beat frequency f3 between these two frequencies; this frequency f3 being independent of the frequency fluctuations of the receiving heterodyne wave, it can be used as a reference frequency for controlling the two heterodyne local oscillators. The set of frequencies used in the system is thus locked on the difference - f2 initial and the corresponding frequencies fl and f2. All frequencies used are thus carried from one end to the other of the system, from station to station. These frequencies make it possible to calibrate the intermediate local oscillators and the BLU demodulation by the reconstituted carrier (which requires a precision of 2 Hz). Naturally, the frequencies f1 and f must not be arbitrary in order to facilitate the servocontrol operations of the oscillators located in the repeaters.

More precisely, the subject of the present invention is a transmission system of the type of those described above and which is characterized in that
A) - the transmitting station includes means for inserting
in the signal transmitted two signals to frequen
these corresponding drivers, in the frequency band
middle frequency, at frequencies fl and f2
falling between multiplexed channels, the frequen
these fl and f2 (f2> fl) being chosen from such sor
that, the difference between them verifies the rela
tions :: f3 = f4 / n and pf3 = qfl where n, p and q are
integers (fq being always the difference
this frequencies fr and fe);
B) - Each repeater includes
a) - a first filter centered on the frequency pi
lote fl and connected to the amplification chain,
b) - a second filter centered on the pilo frequency
te f2 and connected to the amplification chain,
c) - a mixer with two inputs connected to the pre
first and second filters and a deli exit
providing a signal at the beat frequency f3 = 2 '
d) - a third local oscillator 0 (f4) deli
having a frequency f4, this oscillator being
associated with a servo circuit C4 of its
frequency f4 at the beat frequency f31
e) - a circuit C (f1) for forming a signal of
frequency fa enslaved to the signal delivered by
the oscillator 0 (f4),
f) - Servo-control means of the two local reception oscillators O (fr) and of emission
O (fc) from the signals delivered by the os-
O (f4) and the C (f1) circuit.

The reason for these particular relations between the frequencies as well as other characteristics of the invention will appear better after the description which follows, exemplary embodiments given for explanatory and non-limiting purposes. This description refers to drawings in which:
FIG. 4 represents a first servocontrol loop applied to the local oscillator O (f4) and working on the beat frequency of the pilot waves,
FIG. 5 shows a second control loop applied to the local reception oscillator (fr) and using the circuit C (fl) for forming a frequency signal f11
FIG. 6 represents a first embodiment of this circuit
FIG. 7 represents a second embodiment of this circuit C (fl),
FIG. 8 represents a third servocontrol loop, applied to the oscillator - local emission (fe) and using the oscillator O (fq),
FIG. 5 represents a particular embodiment of a circuit delivering the heterodyne transmission frequency f
FIG. 10 illustrates a particular frequency plan that can be adopted according to the invention,
- Figure 11 generally represents an alternative embodiment of a repeater according to the invention, corresponding to the previous frequency plan.

The servocontrol loop shown in FIG. 4 comprises: a) a first filter 51 centered on the pilot frequency
f1 and connected to the amplifier chain 34 of the repetition
b) - a second filter 52 centered on the pilot frequency
f and connected to this same amplification chain 34, c) - a mixer 54 with two inputs connected to the first
and second filters 51 and 52 and a deli output
providing a signal at the beat frequency
f3 f2 fl (if f2 is greater than fl as sup
posed), d) - a local oscillator O (fq) delivering a frequency
f4, this oscillator being associated with a circuit C4
servo-control at the beat frequency f3.

 In a first variant, this circuit C4 comprises: a frequency divider 56 by n, connected to the oscillator O (fq) to reduce the frequency f4 to the frequency f3, (f 3 being indeed equal to f4 / n by hypothesis ), a phase detector 58 with two inputs connected to the divider 56 and the other at the output of the mixer 54, a control loop 60 of the oscillator O (fq) from the signal delivered by the detector of phase 58.

 In a second variant, a little more complex, the servocontrol circuit C4 of the local oscillator O (f4) comprises, in addition to the divider 56 and the phase comparator 58, a second divider 62, an oscillator reference 0 (f5) controlled by the comparator 58, this oscillator O (f5) and the divider 62 being designed so that the frequencies f5 they deliver are the same, and finally a phase comparator 66 with two inputs connected to the divider 62 and the oscillator O (fg), this comparator controlling the oscillator O (f).

 FIG. 5 represents a second control loop which is applied to the local oscillator O (f), which outputs the reception heterodyne signal. The circuit shown comprises a circuit G (fli forming a signal at the frequency f11 a phase comparator 70 with two inputs respectively connected to this circuit and the first filter 51 center on f1F a control loop 72 of the first local oscillator O (fr) from the signal delivered by the phase comparator 70.

Figures 6 and 7 show two particular embodiments of the circuit C (f) for forming the frequency signal f1. In the variant of FIG. 6, this circuit comprises, in addition to the oscillator 0 (f4) already introduced, a frequency divider 80 by q, this divider being connected to O (f4) in order to reduce the frequency f4 to the value f4 / q, a local oscillator O (f1) delivering a signal at frequency f1, a frequency divider 82 by p, this divider being connected to the oscillator
O (f1) for returning the frequency f1 to the flip value, a phase comparator 84 with two inputs connected to the two dividers 80 and 82, this comparator thus receiving two equal frequencies since, hypothetically, we have qE1 = pf4, therefore f1 / p = f4 / q and finally, a loop 86 for controlling the fourth oscillator O (f1) from the signal delivered by the phase comparator 84.

 In the variant of FIG. 7, the circuit for forming the frequency signal f1 is simply constituted by a divider 88 by r connected to the third oscillator O (f4), which supposes that the relation f1 = f4 / r is satisfied, in other words, the numbers p, q and r are linked by the equality: g = r.

p
FIG. 8 represents another servocontrol loop applied this time to the local oscillator
O (fe) which delivers the heterodyne transmission signal at the frequency fe. This loop comprises a two-input mixer 90 connected respectively to the first and second oscillators O (fr) and o (fe) and an output delivering a signal at the transposition frequency f4, (f4 = | fr - fe |) a comparator of phase 92 with two inputs respectively connected to the mixer 90 and to the oscillator O (f4) already introduced and a control loop 94 to control the second oscillator (fe) from the signal delivered by the comparator 92.

 The transmission frequency f e can be obtained by other means, which is shown in FIG. 9 and which simply comprises a mixer 96 connected to the reception oscillator O (fr) and to the local oscillator O (f 4). This mixer delivers a signal of frequency equal to the difference between f r and f4, that is to say, by hypothesis, at the frequency fe.

 FIGS. 10 and 11 show an exemplary embodiment corresponding to the following frequencies: f1 = 71 MHz (14.2 x 5 MHz), f2 = 85.2 MHz (14.2 x 6 MHz), f2 fl = 14.2 MHz , f4 = 213 MHz (14.2 x 5 x 3 MHz), fr = 4 GHz, f5 = 4.7333 MHz (14.2: 3 MHz).

 The diagram of FIG. 11 shows the variants illustrated by FIGS. 4, 5, 7 and 9.

 As for the pilot wave fm represented in FIGS. 3 and 10, it is obtained from f1 and f3 by the relation s (fl -;) = tf3 where s and t are integers (in the particular case of the plane of frequency of FIG. 10, this = = 1) This particular wave can be obtained by simply beating from f1 and f2, the beat product being filtered and then amplified.

If s and t are greater than or equal to 2, this pilot frequency can be obtained by slaving or dividing from the oscillator O (f4). Naturally, several waves of this type (fm, fm ', ... see FIG. 3) can be generated to obtain the information necessary for the dynamic compensation of the amplitude and phase distortions brought about by the radio propagation. .

Claims (7)

 1. A single-sideband and multiplexed-type radio transmission system comprising a transmitting station (10), a relay station suite (11, ... 19) and a receiving station (20), each relay station comprising a repeater (25) constituted by a first local oscillator (O (fr) delivering a reception heterodyne signal at a frequency fr applied to an input mixer (32) which delivers a signal in an intermediate frequency band (fi), an amplifier chain (34) connected to the input mixer and operating in said intermediate frequency band, a second local oscillator O (fe) delivering a heterodyne transmission signal at a frequency the frequencies fr and fe differing from a quantity 4, an output mixer (36) connected to this chain (34) and receiving the heterodyne transmission signal, this system being characterized in that :: A) - the transmitting station includes means for inserting  in the signal transmitted two signals to frequen  these corresponding drivers, in the frequency band  intermediate frequency, at frequencies f1 and f2  falling between multiplexed channels, the frequen  these fl and f2 (f2> f1) being chosen from such sor  that the gap f3 between them checks the relations  f3 = f4 / n and pf3 = qfl, where n, pet q are nouns  whole bres ;; B) - Each repeater includes  a) - a first filter (51) centered on the frequency  driver f1 and connected to the amplifica chain  tion (34),  b) - a second filter (52) centered on the frequency  f2 driver and connected to the amplifica chain  tion (34),  c) - a mixer (54) with two inputs connected to  first and second filters (51 52) and at a  output delivering a signal at the beat frequency f3 = f2 - f1,  d) - a third local oscillator 0 (4) deli  displaying a frequency signal f4, this oscilla  being associated with a servo circuit C4  its frequency to the beat frequency  f3 ;;  e) - a circuit C (f1) for forming a signal of  frequency f1 slaved to the signal delivered by  the oscillator 0 (f4);  f) means for servoing the two oscillations  Local transmitters (fr) and transmitters  O (fe) from the signals issued by lgos-  0 (4) and the C (fl) circuit  2. System according to claim 1, characterized in that the control circuit C4 of the local oscillator O (f) comprises a frequency divider (56) by n connected to said oscillator for reducing the frequency f4 to the frequency f3, a phase detector (58) with two inputs connected to a divider (56) and the other at the output of the mixer (54) delivering the beat signal at frequency f3, a control loop (60) said oscillator 9 (f4) from the signal delivered by the phase detector (58).  3. System according to claim 2, characterized in that the servocontrol means of the first local oscillator Otr) working at the reception frequency (fr) comprise a phase comparator (70) with two inputs respectively connected to the circuit C. (f1) for forming the controlled signal of frequency f1 and for the first filter (51) centered on the frequency f1, a control loop (72) acting on the first local oscillator O (fr) from the signal delivered by the comparator phase (70).  4. System according to claim 3, characterized in that the circuit C (f1) for forming the frequency signal f1 comprises a frequency divider (80) by q connected to the third local oscillator C (f4) to reduce the frequency f4 to the value f4 / q, a fourth local oscillator O (f1) delivering a signal at the frequency f1, a frequency divider (82) by p connected to the said fourth local oscillator to reduce the frequency f1 to the value f1 / p, a comparator phase (84) with two inputs, connected to these two dividers (80, 82) and a control loop (86) of the fourth oscillator Olfl) from the signal delivered by the phase comparator (84).  5. System according to claim 3, characterized in that p and q being linked by the relation  2 - r (r integer), we have fl = f4 / r and in that the cir  The frequency signal formation circuit C (f1) is constituted by a divider (88) connected to the third oscillator 0 (f4).  6. System according to claim 2, characterized in that the servocontrol means of the second local oscillator O (fe) operating at the transmission frequency fe comprise a mixer (90) with two inputs connected respectively to the first and second local oscillators O (fr) and O (fe) and an output delivering a signal at frequency f4, a phase comparator (92) with two inputs respectively connected to said mixer (90) and to the third enslaved oscillator O (fq ), a control loop (94) of the second oscillator (fe) from the signal delivered by this comparator (92).  7. System according to any one of the preceding claims, characterized in that each repeater comprises means for restoring at least one pilot frequency fm such that s | fm - f1 | = tf3, s and t being integers, the frequency f m used to obtain information necessary for dynamic compensation of amplitude and phase distortions.