FR2632796A1 - Duplex communication system and telephone installation with single optical fibre - Google Patents

Abstract

The duplex communication system comprises first and second complementary transmit/receive end circuits 1, 1a connected by a single optical fibre for transmission FO. An optical fibre coupler 10 is provided in each of the end circuits so as to couple one end of the optical fibre for transmission to a transmission path and a reception path of the end circuit. The transmission path and the reception path of the first and second end circuits respectively are tuned to a first carrier frequency F1. The transmission path and the reception path of the second and first end circuits respectively are tuned to a second carrier frequency F2. First and second light signals L1, L2 representing first and second modulated information signals M1, M2 having the first and second carrier frequency respectively are transmitted in the optical fibre for transmission.

Description

Duplex communication system and single fiber optic telephone installation
The present invention relates generally to. fiber optic communications. More particularly, the drawback relates to a duplex communication system for transmitting communication signals in two directions simultaneously between two terminals or circuits of transmission and reception
In known duplex communication systems - by optical fiber, two optical fibers are provided as a bidirectional transmission medium between the terminals. One of the optical fibers is assigned to one direction of transmission and the other optical fiber is assigned to the other. direction of transmission. Each of the fibers conveys a signal in baseband or a signal multiplexed in wavelength or in frequency and carrying several signals in baseband. I1 is regrettable in particular when the distances between terminals or binding circuits are relatively large having to use two optical fibers when a single optical fiber could be enough to pass the two directions of communication.

 More recently,. research has focused on single fiber optic communication systems. In the latter systems, the transmission in both directions is digital and is not simultaneous, but is carried out in the half-board or also said in "simplex" or "half-duplex" mode. If these systems offer savings in fiber optics, it is to the detriment of the increasing complexity and cost of terminals. Indeed, each terminal must include a synchronous clock, and buffer memory and coding-decoding circuits necessary for the implementation of the half-day transmission, and an expensive opto-electronic element sometimes allowing the transmission of signal luminous in the optical fiber, sometimes the reception of light signal in the optical fiber. when blocked by a determined voltage, for reception.

 Such an alternation system is for example used for a link along a telecommunications antenna mast between the antenna and an antenna control and site circuit, and only strikes relatively cost of such an already expensive application.

 However, because of its cost, this half-duplex and single-fiber optic transmission system cannot be envisaged for applications relating to the consumer telecommunications field, in particular, or when the terminals are not connected to a special and complex infrastructure.

 The present invention aims to provide a duplex communication system offering the same advantage as a work-study system while avoiding its drawbacks.

 To this end, a duplex communication system according to the invention with an optical fiber type transmission medium comprising first means connected to the transmission medium for transmitting a first electrical information signal to a first end of the transmission medium in the form a first light signal and simultaneously for receiving a second electrical information signal delivered by the first end of the transmission medium in the form of a second light signal, and second means for transmitting the second information signal to a second end of the transmission medium in the form of the second light signal and simultaneously for receiving the first information signal delivered by the second end of the transmission medium in the form of the first light signal, is characterized in that the transmission medium is consisting of a single optical fiber simultaneously conveying the first and second light signals, and in that the first and second means for transmitting and receiving each comprise means for coupling the end of the optical transmission fiber to a transmission path and to a reception path in the means for transmitting and to receive.

According to the invention, the first and second means for transmitting and receiving each preferably comprise
in the route of transmission,
modulation means for producing a carrier frequency modulation signal modulated by the information signal to be transmitted, and means for converting the modulation signal into the transmitted light signal, and
in the reception channel,
means for converting the light signal delivered by the means for coupling into an electrical reception signal, filtering and level control means for recovering the modulation signal transmitted by the other means for transmitting and receiving from the electric signal reception, and demodulation means for demodulating the modulation signal recovered by the filtering and level control means into the information signal transmitted by the complementary means for transmitting and receiving,
the modulation means in the first and second means for transmitting and receiving respectively producing first and second modulation signals having frequency spectra without intersection.

 The bidirectional communication system according to the invention can be produced in different forms and in particular in the form of a fiber optic telephone installation.

The fiber optic telephone installation according to the invention comprises
a telephone set connected to a first end of the optical transmission fiber and comprising said first means for transmitting and receiving, and
an adaptation circuit connected to a second. end of the fiber and to a telephone line and comprising said second means for transmitting and receiving.

The invention will be better understood on reading the following description of several preferred embodiments of the duplex communication system according to the invention with reference to the corresponding appended drawings in which
- Fig. 1 is a block diagram representing the basic structure of the duplex communication system according to the invention;
- Fig. 2 shows an embodiment of the system according to the invention in the form of a fiber optic telephone installation; and
- Fig. 3 is a detailed block diagram of a line adaptation circuit included in the telephone installation shown in FIG. 2 to connect a telephone line and an optical fiber.

 With reference to FIG. 1, the duplex optical fiber communication system according to the invention comprises two complementary end-to-end transmission-reception circuits by optical fiber 1 and the interconnected by a single optical fiber FO constituting the transmission medium.

 The end circuits 1 and 1a are respectively associated with terminals T and Ta having to communicate with each other by means of the bidirectional communication system according to the invention.

 In order to transmit through the same transmission optical fiber two information signals S1 and S2 having the same base frequency band, for example the base band from 300 to 3400 Hz in the case of telephone audio signals S1 and S2, respectively from terminal T to terminal Ta and conversely from terminal Ta to terminal T, frequency duplexing is used. The signals S1 and S2 modulate in frequency signals of local oscillator carrier OL1 and OL2 of frequencies separate F1 and F2 to produce frequency modulation signals M1 and M2 having frequency spectra without intersection centered around the carrier frequencies F1 and F2.

After conversion into light signals of the same wavelength, the signals M1 and M2 are injected into the transmission optical fiber FO. In a reception channel, the end circuit 1 comprises a bandpass reception filter tuned to the second carrier frequency F2 in order to recover the modulated signal M2 which is intended for it. Similarly, the end circuit la comprises in its reception channel a reception filter tuned to the first carrier frequency F1 in order to recover the modulated signal M1 which is intended for it.

 The end circuits 1 and 1a are said to be complementary in the sense that they comprise transmission channels and reception channels which are tuned in a complementary manner. Thus for example, the transmission channel and the reception channel respectively of the end circuits 1- and la are tuned to the carrier frequency F1 = 1250 kHz, and the transmission channel and the reception channel respectively of the circuits end la and 1 are tuned to the carrier frequency F2 = 500 kHz.

 The end circuit I is shown in detail in FIG. 1. The transmission path and the reception path of circuit 1 are connected to the transmission optical fiber FO by means of a fiber optic coupler Io, optical fibers of connections 111, 112 and 12, and a fiber optic connector 13.

 The transmission path of circuit 1 comprises, connected in cascade, an input amplifier 141, a low-pass filter in baseband 151, a frequency modulator 161 and an optical modulator with light-emitting diode (LED) 171.

Amplifier 141 is a low frequency amplifier having the function of amplifying the first baseband information signal S1 delivered by the terminal T and to be transmitted to the terminal
Your. An output of the amplifier 141 is connected to an input of the low-pass filter in base band 15 The filter 151 provides the output the signal to be transmitted S1 filtered in the base band. The signal S1 supplied by the filter 151 is applied to a first input of the frequency modulator 161.

 The modulator 161 is preferably of the saturated modulation type and typically allows a peak frequency excursion #F equal to 50 kHz. A second input of the frequency modulator 16 receives the local oscillator signal OL1 of frequency FL1250 kHz.

The signal OL1 as well as the local oscillator signal OL2 of frequency F2g500 kHz intended for the reception channel of circuit 1 are produced by a local oscillator included in the end circuit 1. The frequency modulator 161 outputs a signal of modulation M1 at carrier frequency F1 = 1250 kHz frequency modulated by the signal to be transmitted S1. The modulated signal K1 is applied to the input of the optical LED modulator 171.

 The optical modulator 171 comprises a light-emitting diode 1701 intended to produce an inconsistent light signal L1 representative of the modulation signal M1. To this end, the diode 1701 is supplied with a current proportional to the modulation signal M1 and delivers in response the first light signal L1 modulated with a modulation index typically equal to 0.8.

 The light signal L1 is not very coherent in order to avoid the introduction into the signal Li of a modal noise due to interference during the transmission of the signal L1 in the optical fiber FO, these interferences being able to notably affect the reception of the signal. luminous L1 in the receiving circuit of the end circuit la. The light signal L1 typically has a central wavelength B = 850 nm and a spectral bandwidth Qu = 50 nm. A first end of the optical connection fiber 111 receives the light signal L1. The light signal L1 is conveyed by the connecting fiber 111 and is transmitted at once by optical fibers 10.

 The coupler 10 is a coupler with three accesses of type 2 to 1.

First and second ports 101 and 102 of the coupler 10 are respectively connected to a second end of the connecting fiber 111 and to a first end of the connecting fiber 112. The connecting fiber 112 connects the coupler 10 to the reception channel of circuit 1. A third port 103 of coupler 1 is connected to the optical fiber connector 13 by the connecting fiber 12. First and second ends of the transmission optical fiber FO are connected respectively to the optical fiber connector 13 of the circuit d end 1 and to an identical optical fiber connector 13 of the end circuit 1a.

The coupler 10 receives the light signal at the first access 101
L1. A first part a.L1 of the light signal L1, where a is a coupling coefficient between. the first and third ports 101 and 103 of the coupler 10, is transmitted by the coupler 10 in the transmission fiber FO through the third port 103, the connecting fiber 12 and the connector 13. Due to the crosstalk of the coupler 10, a second part B.L1 of the light signal L1, where 6 is a coupling coefficient between the first and second ports 101 and 102 of the coupler 10, is transmitted by the coupler 10 to the reception channel of circuit 1 through the second port 102 and the connecting fiber 112.

 The coupler 10 receives at the third port 103 an incoming light signal a.L2 analogous to the outgoing light signal a.L1. The signal a.L2 is transmitted by the end circuit la and is conveyed to circuit 1 by the transmission fiber FO. The light signal a.L2 carries the baseband signal 52 transmitted by the terminal Ta and intended for the terminal T. First and second equal parts y .. (.L2) of the light signal a.L2, where y is a coupling coefficient between the third and first or second ports 103 and 101 or 102 of the coupler 10, are transmitted respectively to the first and second ports 101 and 102 of the coupler 10.

 The transmission optical fiber FO as well as the connecting fibers 111, 112 and 12 are preferably multimode optical fibers, for example of the 50/125 μm or 100/140 μm type. Thus the inconsistent light signals which propagate in these multimode optical fibers are transported in the form of a. large number of propagation modes in the cores of the fibers and the wave fields corresponding to these different propagation modes due to the lack of coherence of the light signals do not have phase relations between them and therefore do not cause interference. However, the duplex communication system according to the invention also works with single-mode fibers.

 The reception channel of circuit l comprises, connected in cascade, an optical photodiode detector 142, a reception filter 152, a level regulator with automatic gain control (AGC) 162, a frequency demodulator 172, a pass filter. low in baseband 182, and an output amplifier 192.

 The optical detector 142 is equipped with a PIN type photodiode 1402 sensitive to light radiation ~ centered on the wavelength Au 850 nm and of spectral bandwidth Ex = 50 nm. Photodiode 1402 receives a composite light signal L = B.L1 + yaL2 delivered by a second end of the connecting fiber 112. The signal L is made up of part B.L1 of the signal signal L1 transmitted from access 101 to the access 102 of coupler 10 and of part y.-a.L2 of the light signal a.LZ transmitted from access 103 to access 101 of coupler 10. Current variations occur in photodiode 1402 in response to variations in intensity of the received light signal L. These variations in current are amplified in the detector 142 in order to produce an electrical reception signal R2 representative of the received light signal L and at a level sufficient to be applied at the input of the reception filter 152 .

 The reception filter 152 is a bandpass filter with a central frequency F2 = 500 kHz. The filter 152 is suitable for receiving the signal M2 carried by the light signal .L2 transmitted by the circuit la. The modulation signal M2 has a carrier frequency F2 = 500 kHz frequency modulated by the baseband signal S2. The filter 152 eliminates from the signal R2 a carrier frequency component Fl-i250 kHz due to the component B.L1 of the received light signal L - B.Li + y.a.L2. The filter 152 delivers at output a frequency modulated signal representative of the component y.a.L2 of the light signal L; this signal is applied at the input of the level regulator with automatic gain control 162 which restores the output of the signal M2 at a constant level. The signal M2 is supplied to a first input of the frequency demodulator 172.

 The frequency demodulator 172 has the function of frequency demodule of the signal M2 in order to recover the second information signal in baseband S2. A second input of the demodulator 172 receives the local oscillator signal OL2 of frequency F2 = 500 kHz. An output of the demodulator 172 is connected to an input of the low-pass baseband filter 182. The filter 182 outputs the baseband signal S2. The signal S2 delivered by the filter 182 is amplified by the output amplifier 19 before being supplied to the terminal T.

 The duplex communication system according to the invention can be implemented for numerous applications, particularly in the field of transmitting analog signals such as, for example, telephone audio signals in the base band from 300 to 3400 Hz, audio signals from HI.FI quality in the frequency band from 20 Hz to 20 kHz, and video signals in the frequency band from o to 250 kHz. Furthermore, signals with a bandwidth greater than 250 kHz can be transmitted by choosing carrier frequencies F1 and F2 greater than 1250 kHz and 500 kHz.

 An application of the duplex communication system according to the invention in the form of a telephone installation with a fiber optic link is now described with reference to FIGS. 2 and 3.

 As shown in Fig. 2, the telephone installation according to the invention-comprises a telephone set P, a transmission optical fiber F0, and a line adaptation circuit CA.

The telephone set P and the line matching circuit CA are connected via the transmission optical fiber
FO. The line matching circuit CA is connected to a conventional two-wire telephone line LT connected to a local automatic branch exchange of a telecommunications network.

 Such a telephone installation with a fiber optic link is particularly recommended, in particular when high confidentiality of telephone communications is sought, for example, when the subscribers are government bodies processing secret information. It is possible with a telephone installation of this type to link- by optical fiber to guarantee a high security against any eavesdropping by detection of electromagnetic radiation. Indeed, the transmission medium between the telephone set and the PABX, which by its length which can reach several kilometers is generally the most difficult element to protect, here consists of an optical fiber perfectly impervious to electromagnetic radiation. The AC line adaptation circuit is located in the premises of the local exchange which is installed in a Faraday cage. The telephone set P is preferably also shielded in a Faraday cage. In addition, filters may be provided in continuous power supplies for the telephone station -P and the line adaptation circuit CA in order to avoid the injection of communication signals into an electricity distribution network to which is connected for power supply. telephone installation.

 The telephone set P shown in detail in FIG. 2 essentially comprises a transmission-reception end circuit 1b, a dial-multifrequency keypad 3, a call signaling circuit 4, and a continuous supply 5.

 The end circuit 1b included in the telephone set P has some modifications compared to the basic end circuit 1 shown in FIG. 1. In the transmission path of the end circuit 1b, the output of the input amplifier 14l is connected to the input of the low-pass filter in baseband 15 through a two-way relay switch 300. In the reception channel, the output of the level regulator with automatic gain control 162 is connected to the input of the frequency demodulator 172 through another two-way switch 200, and the amplifier 192 comprises two inputs, a first input connected to the output of the baseband low-pass filter 182 of the reception channel and a second input connected to the output of the baseband low-pass filter 151 of the transmission channel.

 The telephone handset 2 includes a microphone 21 and an earpiece 22.

 The microphone 21 is connected input the input of the input amplifier 141 of the transmission path of the circuit lb and a reference ground of the telephone set P. A direct supply voltage V1 is supplied to the microphone 21 through a resistance 23. The microphone 21 delivers the audio signal in baseband Si in response to sound vibrations detected by a membrane of the microphone 21. The signal S1 is applied to the input of the amplifier 141 to be transmitted to the circuit d line adaptation CA and the telephone line LT when a telephone conversation is established.

 The earphone 22 is connected between the output of the output amplifier 192 of the reception path of the circuit lb and the reference ground.

 The multifrequency dialing keyboard 3 is an integrated circuit keyboard delivering a dialing signal with two voice frequencies N and a signaling signal SI. A relay 30 is associated with the dialing keypad 10. Pressing a key on the keypad 3 controls the activation of the signaling signal SI to an active logic state "1" and the transmission of the dialing signal N corresponding to the key pressed. of keypad 3. Signal SI in state "1" energizes a coil 301 of relay 30.

The excitation of the coil 301 controls the switching of the contact of the switch 300 included in the relay 30 from a stationary resting contact R connected to the output of the amplifier 141 to a stationary working contact T connected to the keyboard 3. The switch 300 being in working position T, the numbering signal N is applied at the input of filter 151 of the transmission path of circuit 1 and is transmitted to the line matching circuit-CA and the telephone line LT. When no key on the keyboard 10 is pressed, the signal SI is in the inactive state "0". The coil 301 is then deactivated and the switch 300 in the idle state R connects the output of the amplifier 141 à Input of the filter 15I in order to authorize the transmission of the signal Si delivered by the microphone 20.

 Conventionally, a return of the baseband signal S1 and of the dialing signal N to the earpiece 22 of the handset 2 is provided in the telephone set P. This return is carried out in the circuit Ib using the output amplifier with two inputs 192, one input of which is connected to the output of the baseband filter 15 The amplifier 192 supplies the listener 22 with a signal S2a representative of a sum of two signals S2 and S1 or S2 and N applied respectively at the inputs of the amplifier 192. The signal S2 is the baseband audio signal received delivered by the demodulator 172 and the filter 182 when the communication is established.

 The call signaling circuit 4 includes a carrier detector 40, and a buzzerX41.

 The carrier detector 40 is tuned to the carrier frequency F2 = 500 kHz and outputs an AP signal at a logic state "1" when a frequency signal F2 = 500 kHz is detected at the input and at a logic state "0 " otherwise. The AP signal is applied to the buzzer 41. The AP signal in the "1" state controls the buzzer 41 which consecutively emits an audible signal SS.

In order to obtain correct operation of the telephone set
P, the circuits or active elements included in station P are supplied or not supplied with voltage depending on the off-hook or on-hook status of handset 2.

 The off-hook or on-hook state of the telephone handset 2 is conventionally detected by an off-hook switch 20 on which the handset 2 rests when it is hung up. The switch 20 includes the switch 200 and a switch 201 which change state simultaneously. The switch 201 is open when the handset 2 is hung up.

 The DC supply 5 produces two DC supply voltages VO and V1 from an AC voltage Ut220 V supplied by an electricity distribution network. Preferably, the power supply 5, like that in the line adaptation circuit CA described below, is provided with a backup storage battery. The DC voltage VO is continuously supplied to the active elements 142 and 162 of the reception path of the circuit lb and to the carrier detector 40 of the call signaling circuit 4. The DC voltage V1 is supplied through the switch 201 to all the active elements 14, 16 and 171 of the transmission path of the circuit lb, to the microphone 21 of the handset 2, to the active elements 172 and 192 of the reception path of the circuit lb, and to the multifrequency dialing keyboard 3; These different elements are thus supplied when the handset 2 is off the hook and the switch 201 is closed. When the handset 2 is hung up, the switch 201 is open and only the active elements 142 and 162 of the reception path of the circuit lb and the call signaling circuit 4 are supplied. The telephone set P is then in standby state, awaiting a call signal from an incoming call.

 In the telephone installation according to the invention, the signaling between the telephone set P and the line adaptation circuit CA to indicate a call originating from the telephone line LT for an incoming call and to pick up or hang up the handset 2 is achieved by the transmission or non-transmission of carrier signals OL1 and OL2.

During a call from the telephone line LT, a call signal transmitted by the local automatic exchange is detected in the line LT by the line adaptation circuit CA and this transmits the signal OL2 of frequency F2 = 500 kzz to telephone set P in response to this detection. The call signal is preferably an alternating call signal at constant frequency FA-50 Hz and of amplitude 75 V, although it can be a clocked call signal formed by pulses modulated by a carrier at 50 Hz, or 25 Hz. The handset 2 of station P being hung up, switch 200 and switch 201 are respectively in position CR and in the open state, and the transmission of signal OL2 by the line adaptation circuit CA is detected by the call signaling circuit 4. In response to the detection of the signal OL2, the sound signal SS is emitted by the circuit 4 in order to warn the subscriber of a call originating from the line
LT.

When the handset 2 is off the hook, the switch 200 and the switch 201 are respectively in the CD position and in the closed state. All the active elements of the telephone set P are then supplied and in particular the frequency modulator 161 of the transmission channel of the circuit 1b which transmits the frequency signal OLI
Fl = 1250 kHz. The signal OL1 is detected by the line matching circuit CA which connects in response to this detection to the telephone line LT and establishes in the line LT a current loop.

The establishment of a current loop in the LT line signals the local PABX that the handset 2 has been lifted, and thus the LT line is picked up by station P. When the handset 2 is hung up, the frequency modulator 161 n 'being not supplied, the circuit CA does not receive the signal OLI and the telephone line LT is kept unbuckled to prevent the establishment of the loop current.

 With reference to FIG. 3, the line adaptation circuit CA essentially comprises a transmission-reception end circuit ic, a 2-wire-4-wire coupler 6, a call detector 7, a carrier detector 7a, two relays 8 and 8a , and continuous feeding 9.

 The end circuit lc is complementary to the end circuit lb included in the telephone set P; it includes a transmission channel and a reception channel respectively tuned to the carrier frequencies F2-500 kHz and Fls1250 kHz.

 The input amplifier 141 of circuit lb is connected as an input to a first terminal 61 of the 2-wire-4-wire coupler 6 in order to receive the signal S2 from the telephone line LT through the coupler 6. The amplifier output 192 of circuit lb is connected as output to a second terminal 62 of coupler 6 in order to transmit the signal Si to the telephone line LT through coupler 6.

 The 2-wire 4-wire coupler 6 is a conventional telephone coupler with balanced differential transformer shown diagrammatically in FIG. 3. Third and fourth terminals 64 and 63 of the coupler 5 are respectively connected to a first wire of the telephone line LT through a two-way switch 80 of the relay 8 and to a second wire of the line LT. A movable switch contact 80 is connected to the first wire of the line LT. Two stationary contacts T and R of the switch 80 are respectively connected to the coupler terminal 64 and to a first terminal of the call detector 7 through a connection capacitor 70, the call detector having a second terminal connected to the second wire of the LT telephone line.

 The call detector 7 has the function of detecting a call signal emanating from the telephone line LT. To this end, the call detector 7 is a voltage and frequency detector tuned to the frequency FA = 50 Hz and outputs a DA signal in logic state "1" when an alternating signal of 75 V at 50 Hz indicating a call is detected on input and in logic state "0" otherwise. The signal DA is applied to a first input of an OR gate to two inputs 70 included in the line adaptation circuit CA and controls, at state "1", through the gate 70, the excitation of a coil 80a of relay 8a.

The carrier detector 7a has the function of indicating to the
Circuit CA the off-hook or on-hook state of the handset 2 of the telephone set P, that is to say the establishment or breakdown of a communication. The detector 7a comprises an input connected to the output of the level regulator with automatic gain control 162 of the lo circuit and is tuned to the carrier frequency F1a1250 kHz.

The detector 7a outputs a signal DP in the logic state "1" when a frequency signal F111250 kHz is detected at the input and in the logic state 11011 otherwise. The signal DP is applied to a second input of the OR gate 70 and controls in the 8'1 "state, through the gate 70, the excitation of the coil 80a of the
relay 8a. The DP signal in state i also commands
the excitation of a coil 81 of relay 8.

Continuous feeding 9 is analogous to feeding
continuous 5 from telephone set P. Supply 9 produces two
continuous supply voltages VO and Vi from the voltage
alternative U = 220 V supplied by the distribution network
of electricity. The direct voltage VO is permanently delivered
active elements 142 and 162 of the circuit reception channel
lc as well as detectors 7 and 7a and OR gate 70. The voltage
continuous V1 is supplied to all active elements 141, 161 and 171 of the transmission path of circuit ic and to active elements 172
and 192 of the lc circuit reception channel through a contact
of work 81a of relay 8a.

It is now considered an initial state where the circuit
AC line adaptation is in standby state. In this state of
standby, coils 81 and 80a of relays 8 and 8a are not
excited. The switch 80 is in the rest position R and loops the
telephone line LT through the call detector 7, and the
relay contact 81a is open.

When an incoming communication call from the
LT line intervenes, call detector 7 receives a signal
75. V AC call at 50Hz, and the DA signal comes on
"1". The signal DA = "1" controls the excitation of the coil 80a of the
relay 8a and relay contact 81a closes. All the elements
assets of the AC line adaptation circuit are then supplied. The
signal OL2 of frequency F2 = 500 kHz is transmitted to the station
telephone P and controls the emission of the sound signal SS.

When the handset 2 of telephone set 1 is lifted by
the subscriber, the signal OL1 of frequency F1-1250 kHz is transmitted by
station P to the line adaptation circuit CA. The OL1 signal
transmitted by the station P is received by the carrier detector 7a and
the DP signal comes to state "1". Signal DP- "1" command
the excitation of the coils 81 and 80a of the relays 8 and 8a. In response to the excitation of the coil 81, the switch 80 of the relay 8 switches
in working position T, connect circuit ic to the line
telephone LT through coupler 6 and a loop current is
then established in line LT. In response to the excitation of the coil 80a, the contact 81a of the relay 8a closes and all the active elements of the line adaptation circuit AC are then supplied.

 In the case of an outgoing call, lifting the handset 2 of the telephone set P causes the transmission of the carrier F1 = 1250 kHz to the circuit CA. In the circuit CA, the signal DP = "1" replaces the signal DA, which remains in the state "0", to activate the relay 8 and thus take the line LT, and to activate the relay 8a and fully supply the AC line matching circuit.

Claims (11)

R-CLAIMS  1 - Duplex communication system with optical fiber (FO) type transmission medium comprising first means (1) for transmitting a first electrical information signal (S1) to a first end of the transmission medium (FO) in the form a first light signal (L1) and simultaneously to receive a second electrical information signal (S2) delivered by the first end of the transmission medium in the form of a second light signal (L2), and second means (2) for transmitting the second information signal (S2) to a second end of the transmission medium (FO) in the form of the second light signal (L2) and simultaneously for receiving the first information signal (S1) delivered by the second end of the transmission support (FO) in the form of the first light signal (L1), characterized in that the transmission support consists of a single optical fiber (FO) simultaneously conveying the first r had second light signals (L1, L2), and in that the first and second means for transmitting and receiving (1, la) each comprise means (10) for coupling the end of the transmitting optical fiber (F0) to a transmission channel and to a reception channel in the means for transmitting and receiving (1, la).  2 - Duplex communication system according to claim 1, characterized in that the first and second light signals (L1, L2) transmitted in the optical transmission fiber have the same wavelength (and are not very coherent.  3 - Duplex communication system according to claim 1 or 2, characterized in that each (1) of the first and second means for transmitting and receiving (1, la) comprises  in the route of transmission,  modulation means (I6l) for producing a modulation signal (M1) at carrier frequency (F1) modulated by the information signal to be transmitted (Si), and means (171) for converting the modulation signal ( MI) in the; transmitted light signal (L1), and  in the reception channel,  means (142) for converting the light signal (L2) delivered by the means for coupling (10) into an electrical reception signal (R2), filtering and level control means (152, 162) for recovering the signal modulation (M2) produced by the other means for transmitting and receiving (la) from the electrical reception signal (R2), and demodulation means (172) for demodulating the modulation signal (M2) recovered by the means of filtering and level regulation (152, 162) into the information signal (S2) transmitted by said other means for transmitting and receiving (la),  the modulation means (161) in the first and second means for transmitting and receiving (1, la) respectively producing first and second modulation signals (M1, M2) having frequency spectra without intersection.  4 - Duplex communication system according to claim 3, characterized in that the first and second modulation signals (M1, M2) are produced by frequency modulations of two different carrier frequencies by the first and second information signals ( S1, S2) respectively.  5 - Duplex communication system according to claim 3 or 4, characterized in that, for each (1) of the first and second means for transmitting and receiving (1, la), the means for converting (171) in the path of transmission comprise a light-emitting diode (1701) for transmitting the transmitted light signal (L1) to the coupling means (10), the means for converting (142) in the reception channel comprise a PIN type photodiode for receiving the the other light signal (L2) delivered by the coupling means, and the means for coupling (10) comprise an optical fiber coupler (10), access optical fibers (11in 112, 12) which are respectively connected to the light emitting diode (1701) in the transmission path, the photodiode (1402) in the reception path and the transmission optical fiber (F0) -.  6 - Duplex communication system according to any one of claims 1 to 5, characterized in that the optical transmission fiber (F0) is of the multimode type.  7 - Fiber optic telephone installation comprising a telephone set (P) and an adaptation circuit which is connected to the station by a duplex transmission medium and which is connected to a telephone line (LT), characterized in that the transmission medium consists of a single optical fiber (F0), and  the telephone set (P) comprises said first - means for transmitting and receiving (lb) connected to a first end of the optical transmission fiber (F0) and in accordance with any one of claims 1 to 6, and  the adaptation circuit (CA) comprising said second complementary means for transmitting and receiving (tic) connected to a second end of the fiber (F0) and in accordance with any one of claims 1 to 6.  8 - Telephone installation according to claim 7, characterized in that the telephone set (P) comprises, in addition to the first means for transmitting and receiving (lb),  a telephone handset (2) for producing a microphone signal as the first information signal (S1) and receiving a headphone signal as the second information signal (S2),  a multi-frequency dialing keyboard (3) for producing a voice frequency dialing signal (N) as the first information signal (S1) during the dialing phase of a telephone call, and,  switching means (20) for controlling the transmission of a first carrier signal (OL1) by the first means for transmitting and receiving (lb), as long as the handset (2) is off the hook, and  in that the adaptation circuit (CA) comprises, in addition to the second complementary means for transmitting and receiving (tic),  2-wire 4-wire coupling means (6) for coupling the telephone line (LT) to the transmission and reception channels of the second means for transmitting and receiving (1c), and  first means (7a, 70, 8a, 8d for detecting reception in the second means for transmitting and receiving (lc) the first carrier signal (yes) as the first information signal (S1) indicating the handset pickup (2 ) from the telephone set (P) in order to connect the telephone line (LT) to the transmission and reception channels of the second means for transmitting and receiving (lc) through the 2-wire-4-wire coupling means (6).  9 - Telephone installation according to claim 8, characterized in that the switching means (20) comprise a switch (201) which is closed as long as the handset (2) is off-hook in order to power at least the transmission channel (161, 171) in the first means for transmitting and receiving (lb), said keyboard (3) and a microphone (21) included in the handset (2) by a power supply (5) included in the telephone set (P) .  10 - Telephone installation according to claim 8 or 9, characterized in that the adaptation circuit (CA) comprises second means (7, 70, 8a) for detecting in the telephone line (LT) a determined call signal (75 V-50 Hz) emanating from the telephone line (LT) in order to control the transmission of a second carrier signal (OL2) by the second means for transmitting and receiving (ii), and  the telephone set (P) comprises means (4) for detecting the second carrier signal (OL2) in the first means for transmitting and receiving (lb) in order to signal by an audible signal (SS) a call originating from the telephone line (LT) as long as the handset is hung up, and switching means (20) for connecting the means for detecting the second carrier signal (4) to the first means for transmitting and receiving (lb) as long as the handset (2) is hung up.  11 - Telephone installation according to claim 10, characterized in that the first and second means for detecting (7, 70, 8a; 7a, 70, 8a, 8) comprise a switch (81a) which is closed in response to a detection of the first carrier signal (OL1) or detection of a call signal (75 V-50 Hz) respectively, in order to supply at least the transmission channel (141, 161, 171) in the second means for transmitting and receive (1c) by an electrical supply (9) included in the adaptation circuit (CA).