FR2699770A1 - Non-linear corrector for signals transmitted on fibre optic cable - Google Patents

Abstract

The modulated signal (E) passes to an amplifier (4) then to a regulating unit (2). The signal then modulates a semiconductor optical junction (1) producing optical outputs.The regulator emitter is connected to a regulator circuit driven by a constant current generator (10). The generator drives a circuit in parallel to the amplifier including a series diode (9), and an LC circuit (5,6) in parallel. The circuit linearises the modulated output with input signal level.

Description

Ontario transmitter with non-linearity correcting device.

The invention relates to electrically controlled optical transmitters, in particular those which are intended to be used for ensuring the transmission of information via optical fibers and which have a transmitting member constituted by a light-emitting diode or a laser diode.

 It is known to excite the fibers of video communication networks by means of semiconductor optical transmitters which, in a manner known per se, are controlled by means of modulated electrical signals.

These optical transmitters operate on determined optical wavelengths, such as 0.8 or 1.3 gm, they are designed to be connected to optical fibers whose characteristics have been planned accordingly and which have variable lengths between predetermined limits, the latter being, in particular, a function of the powers likely to be developed by the transmitting members.

 It is therefore planned to adapt the power of the transmitters to real needs and therefore in particular to the lengths of the fiber links they serve, so as to obtain satisfactory transmission of information throughout the range of permitted lengths.

However, the curve representing the power delivered by an emission member, such as a light-emitting diode, as a function of the electric current passing through this member, is not linear and rather has an S-shape with an average area of approximately linear shape. ending in an extreme zone of saturation where the power stagnates despite the increase in the intensity of the current.

 It is therefore conventional to control the power of a transmitting member, as mentioned above, by acting on the current which passes through it via a member making it possible to vary this current, such as a transistor mounted so as to be traversed by the current flowing in the transmission member and controlled at its base by means of an operational amplifier.

Such an arrangement allows compensation for non-linearities disturbing the restitution in optical form of the modulations of the electrical signal corresponding to the information to be transmitted, if an appropriate feedback loop is associated with the amplifier which controls the current adjustment member. circulating in the transmitting member.

Indeed, non-linearity has drawbacks which can be particularly troublesome, in particular when there is more than one carrier wave simultaneously in the presence on the same fiber. In such a case, there may be creation of a baseband jammer by intermodulation between two carrier waves.

This is for example the case in the presence of two carrier waves TV1 and TV2 of respective frequencies 38.9 MHZ and 20.7 MHZ whose intermodulation gives rise to a line at 18.2 MHZ causing a jammer at 2.5 MHZ in base band. The jammer size is approximately -40 dBm if the signals are of the SECAM or D2 MAC type, which corresponds to a difference of 38 dB in radio frequency between the intermodulation level and the TV2 carrier level.

However, the corrective devices of the type mentioned above may not be sufficient under the actual operating conditions to which they may be subjected in installation, when these conditions vary widely and approach the accepted limits.

The invention therefore provides an optical transmitter comprising a semiconductor member with an optically transmitting junction electrically controlled by means of an adjustment member which acts on the electric current passing through this junction, as a function of an electrical control signal which it receives via a self-correcting device with amplifier associated with a loop feedback circuit.

According to a characteristic of the invention, the amplifier feedback circuit comprises first compensation means with non-linear response modifying the feedback effect as a function of the current flowing in the junction in cooperation with means constant current generators which are temperature compensated and which act accordingly on the non-linear response compensation means.

The invention, its characteristics and its advantages are explained in the description which follows in conjunction with the figures mentioned below.

Figure 1 shows a diagram of an optical transmitter according to the invention.

Figures 2 and 5 show two curves representing the variation of the power delivered by two different light-emitting diodes as a function of the currents flowing through them.

FIG. 3 respectively shows a curve representing the gain variation of an amplifier, as implemented in the proposed embodiment and a curve representative of the correction made.

Figure 4 shows a diagram of an alternative embodiment of the invention.

The optical transmitter presented in FIG. 1 is for example intended to ensure the transmission of information in the form of light signals via an optical fiber to which this transmitter is connected in a manner known to those skilled in the art. which will not be described here.

This optical transmitter comprises a transmission member 1, here assumed to be of the semiconductor type with optically transmitting junction controlled by means of an electrical signal, amplitude modulated, representative of the information to be transmitted. The emission member 1, which is for example of the light-emitting diode type, emits optical signals of determined wavelength, for example 0.80, 1.30, 1.55 gm or the like.

An adjusting member 2 controls the intensity of the electric current which ensures the excitation of the optically emitting junction of the emitting member 1 which it crosses.

This adjustment member 2 is for example an NPN type transistor in series with the emission member 1. When the latter is a light-emitting diode, it has its cathode connected to the collector of the transistor constituting the adjustment member 2 and its anode connected to a positive supply potential V; the emitter of the transistor is connected to a ground potential, via an adaptation resistor 3, and the base of this transistor is connected to the output of an amplifier 4, with linear response. This amplifier 4 receives the information signal to be transmitted which is here in the form of an electric signal modulated in amplitude.

The action of this amplitude-modulated signal on the base of the transistor of the regulating member 2 provides a corresponding modulation of the current passing in series through this transistor and the light-emitting diode.

The amplifier 4 is incorporated in a self-correcting device which is intended to linearize the response of the light-emitting diode with respect to the amplitude modulated electrical signal applied to the amplifier 4 to control it.

In known manner, the power response of a light-emitting diode to a control signal is likely to be represented by a roughly S curve, such as that presented in FIG. 2 for a diode emitting a carrier wave the length of which wave is assumed to be 1.3 gm, the intensity of the current passing through the diode being given on the abscissa and the power on the ordinate.

In known manner, the amplitude modulated electrical signal sent to the input E of the amplifier 4 causes the application, at the input of the light-emitting diode, of a modulation whose alternation is symbolized by M in FIG. 2 ; this symmetrical modulation would result in an asymmetrical signal at the output of this diode, as shown in this figure 2, if no correction was applied.

Consequently, the optical transmitters of the type mentioned here comprise a self-correcting device associating a feedback loop with the amplifier 4. In the example presented, this loop comprises two parallel branches each comprising a resistor connected in series with a capacitance , such as the resistor 5 and the capacitor 6, between the output of the adjustment member which constitutes the emitter of the transistor 2 and the input of the amplifier 4.

That of the two branches which consists of the resistor 7 and of the capacitor 8, further comprises a compensation member with non-linear resistance, this member is here constituted by a diode 9 inserted between the resistor 7 and the transistor 2, at the transmitter from which the cathode of the compensation diode 9 is connected.

The gain of amplifier 4 taken in isolation is linear, as indicated above, it is for example represented by line L in FIG. 3 which shows the variation of the output level NS of an amplifier as a function of its level of NE entrance

The compensation diode 9 introduces a correction which is here translated by the curve C and which makes it possible to slightly reduce the gain of the amplifier to compensate for the corresponding non-linearity of the light-emitting diode 1, during the operation of the optical transmitter of which part this light emitting diode and this amplifier.

When the intensity of the modulated current passing through the light-emitting diode tends to increase, the compensation diode 9 tends to block, the feedback impedance and consequently the gain of the amplifier 4 increase. When the intensity of the modulated current decreases, the compensation diode 9 becomes progressively on, the feedback impedance and the gain of the amplifier 4 decrease.

It is planned to bias the compensation diode 9 by connecting its anode to a current generator 10, of the type with constant current i. Insofar as the operating transmitter is liable to be disturbed by temperature variations which are common with this type of equipment, the current generator 10 is preferably of the temperature compensated type, for example for a range between 5 and 45 "C.

The self-correcting device additionally comprises an assembly intended to improve the reproduction, by the emission member 1, of the peaks of the electric signal modulated in amplitude, when the intensity of the current passing through this member leads it to the vicinity of its zone of saturation, see figure 2-. This additional assembly comprises a correction diode 11, the anode of which is here connected to the emitter of the transistor constituting the adjustment member 2 and the cathode of which is connected to an adjustable point of a divider bridge, here with resistors 12, 13, 14 in series, which is inserted between ground and supply potential V. This bridge makes it possible to choose the voltage release threshold of the correction diode 11, the function of which is to increase the current flowing in the transistor of member 2 and in the transmission member 1, when the intensity of the current is such that this transmission member reaches its saturation zone, as seen above. The choice of the threshold makes it possible to optimize the correction sought.

If the self-correcting device is well suited for a light emitting diode emitting on a wavelength of 1.3 tm as indicated above, it appears that a slight modification of this device makes it possible to solve the problem which arises. poses with light emitting diodes emitting on the wavelength of 0.8 gm knowing that the curve representing the variation in power of the latter as a function of the current - see FIG. 5 -, although also having an S shape, presents different characteristics, which implies a different operation of the corresponding transmitters and consequently a slightly different self-correcting device.

In this case as shown in Figure 4, the optical transmitter comprises a light emitting diode 1 'capable of transmitting on the wavelength of 0.8 gm or having a power / intensity curve which is similar. This light-emitting diode 1 'is mounted between supply potential V and ground potential just as was diode 1, having its electric excitation current controlled by a transistor 2', here again of the NPN type, the transmitter is connected to ground potential via a resistor 3 'having the same function as resistor 3.

The transistor 2 'has its base connected to the output of an amplifier 4', with linear response, which receives on an input E 'the information signal in the form of an electric signal modulated in amplitude.

The optical transmitter presented in FIG. 4 also includes a self-correcting device associating a feedback loop with the amplifier 4 ′ and comprising an additional corrective assembly composed of a diode 11 ′ and a divider bridge with resistors 12 ′, 13 ′, 14 ′ analogous in its connection and in its operation to the additional corrective assembly composed of the diode 11 and the resistor divider bridge 12, 13, 14 mentioned above.

The feedback loop associated with the amplifier 4 'also includes two parallel branches each comprising a resistor connected in series with a capacitance between the output of the regulating member which constitutes the emitter of the transistor 2' and the input amplifier 4 ', such as resistor 5' and capacitance 6 '.

The one of the two branches which consists of the resistor 7 'and the capacitor 8', further comprises a compensation member with non-linear resistance here constituted by a diode 9 'inserted between the resistor 7' and the transistor 2 'at the transmitter from which the anode of the compensation diode 9 'is connected, via a capacitor 16'.

It is also planned to bias the compensation diode 9 'by connecting its anode to a current generator 10', of the constant current type i ', via a resistor 15', for the same reasons as above.

For reasons notably related to the length desired for the optical fibers to be served, it may be necessary to use two different zones, shown here overlapping, of the power curve of the light-emitting diode 1 '- see FIG. 5 -, to obtain satisfactory transmission under predetermined conditions with a fiber whose length is for example in a range of lengths between 100 and 1100 meters.

To this end, it is planned to associate a current generator 19 'to calibrate the operational amplifier 4' according to the desired result. It is also planned to connect the common point to the resistor 7 'and to the capacitor 8' to the ground potential by a switching member 17 'in series with an adaptation resistor 18', this switching member being for example a transistor field effect type.

The control of the switch member 17 'and that of the current generator 19' can be performed simultaneously by the same control signal applied at their respective control inputs B and C.

When a maximum power Pmax is necessary, for example due to the length of the fiber served, the transmitting member 1 'operates in a median, substantially linear zone, of its power / intensity curve and it is not it is necessary to apply feedback correction, because the correction produced by the additional corrective assembly is sufficient during the operation of the emission member in the saturation zone.

Under these conditions, the switching member 17 'is controlled, via its input B, so as to be blocked, which in particular has the effect of preventing a bias current from passing through the compensation diode 9', that -this is therefore blocked. In this operating mode the resistor 18 'is in practice disconnected.

On the other hand, when an average power Pmoy less than
Pmax is necessary, the transmitting device 1 'operates in an area of its power / intensity curve which is less than that considered above and a counter-reaction correction is provided. Under these conditions, the switching member 17 ′ controlled by means of its input B is set to the saturated state and therefore conducting. This has the effect of simultaneously allowing the resistor 18 ′ to be paralleled on the input E ′ of the amplifier 4 ′, opposite the input signal applied to this input E ′ and the passage of a current polarization in the compensation diode 9 '.

The parallelization mentioned above causes a reduction in the level of the input signal of the amplifier 4 'and consequently a reduction in its output signal and this in particular as a function of the value of the resistance 18' chosen.

The passage of a bias current leads to a correction of feedback, because the compensation diode 9 'becomes progressively passable as the intensity of the modulated current which passes through the emission member 1' increases, the feedback impedance and the gain of the amplifier 4 'decrease. Conversely, when the intensity of the modulated current decreases, the compensation diode 9 'tends to be blocked, the counter-reaction impedance and the gain of the amplifier 4' increase.

The choice of the bias currents of the compensation diodes 9 and 9 'makes it possible to optimize the effectiveness of the desired non-linearity correction.

Claims (6)

1 / Optical transmitter comprising a semiconductor member (1, 1 ') with an optically transmitting junction electrically controlled by means of an adjustment member (2, 2') which acts on the electric current passing through this junction, as a function of a signal electrical control received via an auto-correcting device with amplifier (4, 4 ') associated with a feedback circuit in a loop, characterized in that the feedback circuit of the amplifier comprises first means compensation (9, 9 ') with non-linear response modifying the feedback effect as a function of the current flowing in the junction in cooperation with means (10, 10') generating constant current which are temperature compensated and which act accordingly on the non-linear response compensation means. 2 / Optical transmitter, according to claim 1, characterized in that the self-correcting device comprises an additional corrective assembly provided with second compensation means (11, 11 ') with non-linear response which are inserted in bypass, outside the loop of feedback, in the electrical supply circuit of the optical transmitting junction passing through the current adjusting member of this junction. 3 / Optical transmitter, according to at least one of the two preceding claims, characterized in that the feedback arrangement is constituted by a loop with two parallel branches identically comprising a resistor (5, 7, ~ 5 'or 7' ) and a first capacitor (6, 8, 6 'or 8') in series between an output of the regulating member (2, 2 '), of transistor type, and the input of the amplifier (4, 4 ') which controls the adjustment member, one of the branches further comprising compensation means (9, 9') with non-linear response constituted by a diode, mounted in series in this branch between the resistor (7 or 7 ') and the output of the adjusting member (2 or 2'), the anode of this diode also being connected to the output of a constant current generator compensated in temperature (10 or 10 '). 4 / optical transmitter, according to claim 3, characterized in that the feedback arrangement comprises a switching member (17 ') connected by a resistor (18'), called adaptation, at a point between the first capacitance (8 ') of the branch containing the compensation diode (9') and the resistor (7 ') connected to the cathode of this compensation diode, to ensure an adaptation of the level of the input signal of the amplifier ( 4 ') of the transmitter and an additional feedback correction, when this switching member (17') is on, or a cut-out of the branch containing the compensation diode (9 '), when said switching member (17 ') is ordered blocked. 5 / optical transmitter, according to claim 3, characterized in that the compensation diode (9) located in one of the branches of the feedback circuit is connected by its cathode to the emitter of the transistor, of NPN type, which constitutes the adjustment member (2), this transistor having its collector connected to the cathode of the light-emitting diode which constitutes the semiconductor member (1) with optically emitting junction. 6 / optical transmitter, according to claim 4, characterized in that the compensation diode (9 ') located in one of the branches of the feedback arrangement is connected by its anode and via a second capacitor (16') to the emitter of a transistor, of NPN type, which constitutes the regulating member (2 '), this transistor having its collector connected to the cathode of the light-emitting diode which constitutes the semiconductor member (1') to optically transmitting junction.