Abstract:
The transparency to the operating signals of a digital signal radio link repeater is obtained by using a demodulator with a carrier signal recovery circuit, whose band width is determined in such a way that the regenerated carrier signal is used in the reconstitution of the modulated signal, after regeneration of the digital train, whilst transmitting the original modulation by the operating signals.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to digital radio repeaters with regeneration and more specifically to those permitting the formation of links where operating signals are to be transmitted through the repeaters. 
     It is well known that good quality digital links and particularly long links having numerous repeaters necessitate a regeneration of the binary train transmitted in the latter or at least in some of them and this regeneration is preceded by a demodulation and is followed by an intermediate frequency modulation. 
     The operating signals received with the information signal to regenerate at each repeater station and, eventually, operating signals locally generated in this station have to be transmitted to the following repeater station. Angle auxiliary modulation of the carrier by the operating signals being suppressed when demodulating the carrier to restitute the information signal, an auxiliary path has to be provided for demodulating the auxiliary modulation and restitute the operating signals. After regeneration of the information signal and remodulation of carrier by this signal, the operating signals remodulate the carrier. This complicates the equipments and reduces their reliability. 
     BRIEF SUMMARY OF THE INVENTION 
     The present invention aims at obviating these disadvantages and ensuring the transparency of the repeaters to the operating signals in transit. 
     According to the invention, a radio repeater transmitting a carrier signal phase-modulated by a digital signal and modulated in angular manner by the operating signals comprises in series a phase demodulator with a carrier recovery circuit, a device for regenerating the digital signal and a phase modulator, the pass band of the carrier recovery circuit being at least equal to the frequency spectrum due to the angle modulation by the operating signals and the recovered carrier signal being applied to the modulator for the phase modulation thereof by the regenerated digital signal. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention is described in greater detail hereinafter relative to non-limitative embodiments and the attached drawings, wherein show: 
     FIG. 1 a general diagram of a radio repeater according to the invention. 
     FIG. 2 a preferred embodiment of the repeater of FIG. 1. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 shows an intermediate frequency conversion and amplification circuit 1 which receives at an input terminal 2 the signals collected by a not shown antenna. Its output 3 is connected to a first input of a phase comparison device 4 and to a carrier recovery circuit 5. The output 6 of the latter is connected to a second input of device 4 and to the input of the carrier signal 12 of a phase modulator 7, whose modulation input 8 is connected to the output of device 4 across a regenerator 9. The output of modulator 7 is connected to the output of repeater 10 across a high frequency conversion and amplification circuit 11. 
     Device 4 and circuit 5 constitute a carrier recovery phase demodulator as is provided on a conventional digital radio link repeater. However, the presently described arrangements differ from the prior art by the use of a carrier recovered on terminal 6 as the carrier signal to be transmitted to modulator 7, which reconstitutes the intermediate frequency (I.F) modulated train from the binary train regenerated in device 9. 
     Thus, the present arrangement obviates the conventionally provided intermediate frequency signal generator and also ensures the transparency of the repeater for the operating signals transmitted by an auxiliary angle modulation of the signal carrier received. 
     Thus, assuming that the signal received is phase modulated with eight phase states by the binary information train to be transmitted and also angle modulated by the operating signals, it is sufficient for said auxiliary angle modulation to have a peak index well below 2π/8 radian and for the pass band of circuit 5 to be at least equal to the frequency spectrum due to this angle modulation and well below the digital information train frequency for the demodulation of the latter by device 4 to be correctly ensured and for the carrier signal applied at 12 to modulator 7 to have the original auxiliary angle modulation, which will thus again be transmitted to the repeater output 10. 
     A preferred embodiment of the invention is shown in FIG. 2. The reference numerals which are the same as those in FIG. 1 relate to identical components and the output 6 of circuit 5 supplies the input of carrier signal 12 across an angle modulator 20 having a modulation input 21 at which are applied locally generated operating signals. In addition, the carrier recovery circuit 5 has a phase comparator 52, whose first input 53 is connected to the output of an oscillator 54 and to the output terminal 6 of circuit 5 and whose second input 55 is connected to the input of circuit 5 in the signal travel direction across a multiplier 56, a band pass filter 57 and a divider 58 which are mounted in series. It also has a low pass filter 59 inserted between output 60 of comparator 52 and the frequency control input 61 of oscillator 54, whereby said input 61 is also connected to the output terminal 62. 
     The signals apply to input 2 and are assumed to be a carrier signal modulated in phase with four states by a digital train and by operating signals whose highest transmitted frequency is 52 kHz, the peak modulation index being ±π/12 radian. Device 4 and circuit 5 here constitute a coherent demodulator with four phase states. Multiplier 56 and divider 58 have the same coefficient equal to 4 and filter 57 has a pass band of approximately 140 kHz corresponding to the Carson band of the auxiliary modulation. 
     Thus, the signal received at input 55 of comparator 52 no longer has the main quadriphase modulation, because the phase jumps are all converted into phase variations equal to multiples of 360°. However, the analog modulation by the operating signals is wholly transmitted and is therefore communicated to the output signal of intermediate frequency generator 54 by the action of the feedback loop, whose filter 59 transmits the complete spectrum of frequencies of the operating signals received. The latter are collected for local processing on the output terminal 62. The local transmission of these signals is ensured by phase angle modulator 20 across its modulation input 21, the level applied being adjusted so that it does not exceed the overall peak modulation index of π/12 radian. As a variant, this transmission could also be ensured by a phase modulation of the local oscillator of the converter included in circuits 11 for transposing the intermediate frequency signal to the final transmission frequency. 
     It is pointed out that the arrangements described have the advantage of rendering superfluous a demodulator for the operating signals associated with a connector of the reinjected local signals, as well as an intermediate frequency signal generator, whilst ensuring the transmission of the operating signals in the case of a breakdown of the digital train regeneration device. This significantly reduces the cost price and increases the reliability compared with known digital repeaters. 
     The invention is not limited to the embodiments described and represented hereinbefore and various modifications can be made thereto without passing beyond the scope of the invention.