DE19654979B4 - Optical transmitter appts. for optical fibre communication - has electro-absorption modulator being controlled to absorb APC diode laser light corresponding to voltage from combined pre-voltage and modulation signal circuit - Google Patents

Abstract

The transmitter appts. includes a light source (2), an optical electro-absorbtion modulator (4), and an actuating circuit (6). The light source, e.g. a laser diode with automatic power control, has an actuating current directed into it to produce a carrier light corresponding in intensity to the actuating current. The actuating circuit is provided with a pre-voltage circuit (8) and a modulation signal producing circuit (10). The optical modulator receives the carrier light to absorb it in correspondence to a received voltage from the actuating circuit to output an intensity modulated signal. The pre-voltage circuit places an off-set voltage on the optical modulator so that the voltage applied to the optical modulator in a step region produces a stable carrier light. The modulation signal producing circuit receives an input signal to superpose a modulation signal on the offset signal.

Description

The The present invention relates to a driver circuit for a optical electroabsorption modulator.

In fiber optic communication systems decreases the modulation speed to. In direct intensity modulation A laser diode has the problem of wavelength chirping. The chirping leads to waveform distortion when signal light passes through an optical fiber guided which has color dispersion (wavelength dispersion). Out In terms of fiber loss, the most favorable wavelength for the application in a silica fiber 1.55 microns. At this wavelength a normal fiber has a color dispersion of about 17 ps / km / nm, what the transmission distance limited. To work around this problem, the use of an external Modulators increasingly expected.

When practical external modulator became a Mach-Zehnder optical Modulator (LN modulator) using a LiNbO3 substrate developed. carrier light with a constant intensity from a light source is supplied to the LN modulator, in which an intensity modulated Signal light is obtained by a switching operation using of light interference. However, the LN modulator has often mentioned disadvantages, which are: The requirement of a relatively high drive voltage (Operating voltage), the need for automatic voltage control to maintain a constant working point, which tends to to enlarge the Dimensions of the device leads, etc.

in the With regard to these disadvantages, an optical electroabsorption modulator has been proposed (EA modulator) proposed as an external modulator, which it allowed to be operated at low power and which suitable for dimensional reduction. The EA modulator absorbs carrier light according to an applied voltage, so as to be intensity modulated To generate signal light. A practical EA modulator is as a semiconductor chip provided, which produced by a semiconductor layering technique becomes. This semiconductor chip can be easily used with a laser diode Be integrated light source, thus the realization of a greatly reduced optical transmitter allows.

In a fiber optic communication system, which has an optical Transmitter with such an integrated semiconductor chip as an EA modulator and a laser diode is used, a transmission length is limited by Wavelength chirping due a residual reflection in the semiconductor chip used as EA modulator. That means that in one Working range in which the voltage applied to the EA modulator is low, the operation of the laser diode is unstable, which is easy leads to the occurrence of a waveform deterioration. To solve this problem have been conventionally different measures taken, including an anti-reflection coating for the semiconductor chip. Present are such measures but no drastic measures against the waveform deterioration.

Out US 5 077 619 For example, a driver circuit for a light-emitting component is known. The driver circuit includes tunable distortion means having an input for a data signal and inputs for reference signals. The tunable distortion circuit serves to pre-distort the electrical data signal to achieve a linear response in conjunction with the non-linear characteristic of the light-emitting component. The driver circuit also includes feedback including mean value detectors and a control circuit which generates the reference signals which in turn drive the circuitry of tunable distortion. The signal for the feedback is obtained by means of a photodiode from the optical output signal.

Out Electronic Dictionary, edited by Dr. med. Walter Baier, Franckh'sche Verlagshandlung Stuttgart, 2nd revision and extended edition, 1982, pages 284 and 609, It is known that the inverted pulse ratio, i.e., at periodic recurring pulses, the quotient of pulse duration and period duration, duty cycle is called.

Out DE 41 38 661 C1 a circuit arrangement for a driver circuit is known which comprises first and second differential amplifier stages and first and second adjustable offset voltage sources. The first offset voltage source is connected to an input of the first differential amplifier stage, so that the duty cycle of a differential signal generated by the differential amplifier stage by changing a first offset voltage is variable and the second offset voltage source is connected in an analogous manner to the input of the second differential amplifier stage ,

It An object of the present invention is a driver circuit for one to provide optical electroabsorption modulator, which is suitable is to prevent a waveform deterioration.

According to the present The invention will be a drive circuit for an optical electroabsorption modulator provided for receiving carrier light from a light source and for absorbing the carrier light according to a voltage applied to it so as to emit intensity modulated signal light, wherein the driver circuit comprises: a duty cycle varying circuit with a first input terminal, which is a digital signal supplied and a second input terminal to which a reference signal is applied, for generating a signal related to the duty cycle, that by changing of the duty cycle the digital signal according to the reference signal is obtained; a modulation signal generating means having input terminals, which that converted with respect to the duty cycle Signal supplied according to which the modulation signal generating means generates a modulation signal which is a change with respect to the offset voltage applied to the optical electroabsorption modulator is applied to this, and with an output terminal for outputting an inversion signal formed by inverting modulation signal; a mean value detector which detects the inversion signal receives for detecting an average value of the inversion signal and outputting of the detected Average; and a control circuit that detects the detected average receives for so controlling the reference signal supplied to the duty cycle changing circuit, that the detected Mean assumes a constant value.

Alternatively, according to the present invention, there is provided an optical electroabsorption modulator driving circuit for receiving carrier light from a light source and absorbing the carrier light according to a voltage applied thereto so as to output intensity-modulated signal light, the driver circuit comprising:
a duty cycle changing circuit having a first input terminal to which a digital signal is supplied and a second input terminal to which a reference signal is supplied for generating a duty ratio converted signal by changing the duty ratio of the digital signal according to the reference signal is obtained;
a modulation signal generating means to which the duty ratio converted signal is applied, according to which the modulation signal generating means generates a modulation signal applied thereto as a change in the offset voltage applied to the optical electroabsorption modulator;
mean value detecting means which receives the current generated in the optical electroabsorption modulator by the absorption of carrier light, detects its average value and outputs the detected average value; and a control circuit receiving the detected average value for controlling the reference signal supplied to the duty cycle changing circuit so that the detected average value becomes a constant value.

Further is alternatively according to the invention a driver circuit for one optical electroabsorption modulator provided for receiving of carrier light from a light source and for absorbing the carrier light according to a applied voltage, so as to deliver intensity modulated signal light, wherein the driver circuit comprises: a termination resistor, which is connected to the optical electroabsorption modulator is to generate the applied voltage by a voltage drop in the conclusion resistance; and a source ground circuit including a field effect transistor with a gate connection, which fed a digital signal is, and with a drain connection, with the optical electroabsorption modulator and the termination resistor operatively connected; wherein a characteristic of the field effect transistor, the one relationship between its drain current and its gate / source voltage shows in is substantially opposite to a characteristic of the optical Electroabsorption modulator, which is a ratio between its optical Output size and its applied voltage shows, so that the duty cycle of the signal light the duty cycle corresponds to the digital signal.

The above and other objects, features and advantages of the present invention Invention and the manner of its realization become apparent and the invention itself will be better understood from a study of following description and the appended claims with reference to the attached drawings, which some preferred designs of the invention show.

1 Fig. 10 is a block diagram showing the basic configuration of an optical transmitter according to the present invention;

2 Fig. 10 is a block diagram of an optical transmitter showing a preferred embodiment of the present invention;

3 is a diagram showing a characteristic operation of the in 2 shown optical transmitter;

4 Fig. 10 is a circuit diagram showing a first preferred embodiment of a drive circuit according to the present invention;

5 Fig. 10 is a circuit diagram showing a second preferred embodiment of the driver circuit;

6 Fig. 10 is a circuit diagram showing a third preferred embodiment of the driver circuit;

7 Fig. 10 is a circuit diagram showing a fourth preferred embodiment of the driver circuit;

8th Fig. 12 is a graph showing the relationship between a current generated in an EA modulator and a voltage applied to the EA modulator;

9 Fig. 10 is a view showing the configuration of a MI-LD (modulator-integrated laser diode);

10 is an equivalent circuit diagram in 9 shown MI-LD;

11 Fig. 10 is an equivalent circuit diagram showing a first preferred embodiment of an improved MI-LD according to the present invention;

12 Fig. 10 is an equivalent circuit diagram showing a second preferred embodiment of the improved MI-LD;

13 Fig. 10 is a block diagram of an optical transmitter characterized by APC according to the present invention;

14 Fig. 10 is a diagram for illustrating changes in the duty ratio of an input signal and signal light;

15 Fig. 10 is a block diagram showing a fifth preferred embodiment of the driver circuit;

16 Fig. 10 is a block diagram showing a sixth preferred embodiment of the driver circuit;

17 is a diagram illustrating the operating principle in 16 ;

18 Fig. 10 is a diagram showing a modulation signal generating circuit using an operating characteristic of an FET;

19 is a diagram illustrating the operating principle in 18 ; and

20 Fig. 10 is a block diagram of an optical transmitter to which direct modulation is applied.

Some preferred embodiments The present invention will now be described in detail with reference to FIG on the attached Drawings.

1 Fig. 10 is a block diagram showing the basic configuration of an optical transmitter according to the present invention. This optical transmitter has a light source 2 For example, configured as a laser diode, an EA modulator 4 , configured as a semiconductor chip, for example, and a driver circuit 6 for supplying an applied voltage to the EA modulator 4 , The light source 2 is supplied with a drive current for generating carrier light which has an intensity corresponding to the drive current. The carrier light becomes the EA modulator 4 entered. The EA modulator 4 absorbs the carrier light in accordance with the applied voltage so as to output intensity-modulated signal light. The driver circuit 6 includes a bias circuit 8th and a modulation signal generation circuit 10 , The bias circuit 8th supplies an offset voltage to the I / O modulator 4 so that the to the EA modulator 4 applied voltage enters a range in which the generation of the carrier light in the light source 2 is stable. The modulation signal generation circuit 10 receives an input signal and superimposes a modulation signal corresponding to the input signal on the offset voltage.

2 Fig. 10 is a block diagram of an optical transmitter showing a preferred embodiment of the present invention. A laser diode 12 which are considered the ones in 1 shown light source 2 used has a front surface 12A and a back surface 12B , That of the laser diode 12 emitted carrier light includes forward light 14 which is from the front surface 12A is broadcast and reverse light 16 which is from the back surface 12B is emitted. The reverse light 16 is in a photodiode (photodetector) 18 converted into an electrical signal having a level corresponding to the intensity of the backward light 16 Has. An automatic power control circuit (APC) 20 controls the drive current in the laser diode 12 so that the level of the photodiode 18 output electric signal is constant. The control object of the APC circuit 20 can the temperature of the laser diode 12 be.

The forward light 14 which is from the front surface 12A the laser diode 12 is emitted in an EA modulator 4 converted into intensity modulated signal light, and this signal light is then passed through an optical isolator 22 in an optical fiber 24 fed. The reference number 26 denotes a terminating resistor for generating an applied voltage in the EA modulator 4 according to one of the driver circuit 6 fed Signal. The impedance of the termination resistor for microwave adaptation for high-speed modulation is, for example, 50 ohms. The photodiode 18 , the laser diode 12 , the EA modulator 4 , the optical isolator 22 and the terminator 26 are in a package or a housing 28 accommodated. The APC circuit 20 and the driver circuit 6 are provided on a printed circuit board on which the housing 28 is mounted.

3 is a graph showing an operating characteristic of the in 2 shown optical transmitter shows. The by reference numeral 30 The curve referred to represents the relationship between the intensity (power) P _OUT of the EA modulator 4 output signal light and the on the EA modulator 4 applied voltage V _EA . It can be seen. a change in the output power P _OUT is substantially proportional to the square of a change in the applied voltage V _EA . In a conventional general driving method for an EA modulator, a modulation signal which varies between a value representing the maximum of the output power P _OUT and a value representing the minimum of the output power P _{OUT is} supplied to the EA modulator as by a dashed line 32 in which an intensity-modulated signal light is output from the EA modulator, as by a dashed line 34 shown.

The by reference numeral 36 designated curve represents the ratio between the drive current I _LD in the laser diode 12 and the voltage applied to the EA modulator voltage V _EA when the in 2 shown APC circuit 20 is in operation. In a work area in which the applied voltage V _{EA is} low, the drive current I _{LD is} in the laser diode 12 unstable, as indicated by the reference number 36A shown. The phenomenon that caused by the APC circuit 20 controlled drive current I _LD in the laser diode 12 itself with a change in the to the EA modulator 4 applied voltage V _EA changes, means that the intensity of the laser diode 12 emitted carrier light changes according to the absorption strength of the carrier light in the EA modulator 4 , This is attributed to the fact that light coming from a signal light output end face of the EA modulator 4 is reflected to the laser diode 12 returns and that this phenomenon is chirping in the oscillation of the laser diode 12 causing resulting waveform degradation.

In this embodiment, which addresses this problem, the EA modulator becomes 4 operated to avoid the area 36A in which the generation of the carrier light in the laser diode 12 is unstable. That is, an offset voltage V _OFF is preparatory to the EA modulator 4 applied, and a modulation signal, as denoted by reference numeral 38 is shown, the offset voltage V _{OFF is} superimposed, whereby intensity-modulated signal light is obtained, as indicated by reference numeral 40 is shown. Accordingly, the chirping in the laser diode 12 are suppressed, thereby minimizing the waveform deterioration of the signal light.

• (1) Die Vorspannschaltung 8 (siehe 1) beinhaltet eine variable Spannungsquelle oder eine variable Stromquelle, welche operativ verbunden ist mit dem EA-Modulator 4.
• (2) Das Eingabesignal an die Modulationssignal-Erzeugungschaltung 10 umfaßt ein erstes Signal und ein zweites Signal als ein Inversionssignal des ersten Signals.
• (3) Die Modulationssignal-Erzeugungsschaltung 10 beinhaltet ein differentielles Paar von Schaltelementen, welche erste und zweite Anschlüsse haben, welchen die ersten und zweiten Signale jeweils zugeführt werden, und welche einen Ausgangsanschluß haben, der operativ verbunden ist mit dem EA-Modulator 4, und eine Konstantstromquelle, welche operativ verbunden ist mit dem differentiellen Paar.

Now, some preferred embodiments of the driver circuit for applying the above-mentioned offset voltage to the EA modulator will be described. The common features permitting high speed modulation in the first to third preferred embodiments of the driver circuit are as follows:

• (1) The bias circuit 8th (please refer 1 ) includes a variable voltage source or a variable current source operatively connected to the EA modulator 4 ,
• (2) The input signal to the modulation signal generation circuit 10 comprises a first signal and a second signal as an inversion signal of the first signal.
• (3) The modulation signal generation circuit 10 includes a differential pair of switching elements having first and second terminals to which the first and second signals are supplied, respectively, and having an output terminal operatively connected to the EA modulator 4 and a constant current source operatively connected to the differential pair.

These Features will now be described in more detail.

4 Fig. 12 is a circuit diagram showing the first preferred embodiment of the driver circuit. The EA modulator 4 is configured of a semiconductor chip having a diode characteristic and the termination resistance 26 is between the anode and the cathode of the EA modulator 4 connected. The cathode of the EA modulator 4 is grounded and the anode of the EA modulator 4 is about an inductor 42 with the negative terminal of a variable voltage source 44 connected. The positive connection of the variable voltage source 44 is grounded.

The differential pair consists of FETs (Field Effect Transistors) 46 and 48 , The gates of the FETs 46 and 48 are with an input connection 50 for the first signal and an input terminal 52 connected for the second signal respectively. The sources of the FETs 46 and 48 are with a constant current source 54 connected. The drain of the FET 46 is about a resistance 56 grounded, and the drain of the FET 48 is with the anode of the EA modulator 4 connected.

According to this circuit can be connected to the EA modulator 4 applied voltage through the variable voltage source 44 be managed. Further, a modulation signal which becomes "high" or "low" according to a level difference between the first input signal and the input terminal 50 is supplied, and the second input signal, which the input terminal 52 is superimposed as a potential of the drain of the FET 48 to the offset voltage. In this case, the sign of the right side of in 3 V _EA axis shown negative.

5 Fig. 10 is a circuit diagram showing the second preferred embodiment of the driver circuit. Unlike the in 4 The first preferred embodiment shown in FIG 5 shown circuit characterized in that a variable voltage source 58 is selected for the offset of an output level of the differential pair (for the bias setting of the differential pair), and accordingly the drain of the FET 48 and the anode of the EA modulator 4 AC coupled through a capacitor 60 , The positive connection of the variable voltage source 58 is grounded and the negative terminal of the variable voltage source 58 is through an inductor 62 with the drain of the FET 48 connected.

6 Fig. 10 is a circuit diagram showing the third preferred embodiment of the driver circuit. Unlike the in 5 the second preferred embodiment shown in FIG 6 circuit shown characterized in that a gate ground circuit including a FET 64 is added. The source of the FET 64 is with the drain of the FET 48 connected, and the gate of the FET 64 is with the negative terminal of a constant voltage source 66 connected. The positive terminal of the constant voltage source 66 is grounded. A modulation signal, which is considered to be a change in the potential of the drain of the FET 64 is obtained on the Offssetspannung through the capacitor 60 superimposed. The addition of such a gate ground circuit allows the drain / source voltage of the FETs to be reduced 46 and 48 , For example, in the first to third preferred embodiments, the amplitude of the modulation signal superimposed on the offset voltage may be adjusted by the magnitude of that of the constant current source 54 delivered electricity.

7 Fig. 10 is a block diagram showing a fourth preferred embodiment of the driver circuit. In this preferred embodiment, the driver circuit has 6 a control signal input terminal 68 for adjusting the offset voltage which is applied to the I / O modulator 4 is created. numeral 70 denotes an input terminal for the input signal to the driver circuit 6 , There is also a resistance 72 for current detection connected in series with the EA modulator 4 for detecting the mean value of one in the EA modulator 4 current generated by absorption of carrier light. For this purpose, an averaging circuit is provided 74 with a connection point between the EA modulator 4 and the resistance 72 connected, and an output of the average detection circuit 74 becomes a control circuit 76 fed. The control circuit 76 supplies to the control signal input terminal 68 the driver circuit 6 a control signal for controlling the offset voltage, so that the detected average value becomes a constant value.

8th is a graph showing the relationship between that in the EA modulator 4 shown by the absorption of carrier light generated current I _EA and the applied voltage V _EA . As with reference to 3 described, the output power P _{OUT of} the signal light changes with a change of the applied voltage V _EA (see reference numeral 30 ). The one in the EA modulator 4 generated current I _EA increases with a decrease in the output power P _{OUT of} the signal light, that is, with an increase in the absorption amount of the carrier light as denoted by reference numeral 78 shown. This phenomenon means that when a given I / O modulator is provided, the current I _EA generated in the I / O modulator and the applied voltage V _{EA make} a one-to-one correspondence. Accordingly, by detecting the average value of this current and controlling the offset voltage so that the detected average value becomes a constant value, the offset voltage can be obtained with an always constant condition.

9 shows the configuration of a modulator-integrated laser diode (MI-LD) applicable to the present invention. This MI-LD is provided as a semiconductor chip having a directly coupled waveguide structure, including, for example, a multiple quantum well (GaQ) layer of GaInAs. The laser diode 12 has first and second connections 80 and 82 for supplying a drive current. The EA modulator 4 is configured of a semiconductor chip, which third and fourth terminals 84 and 86 for supplying an applied voltage. The laser diode 12 and the EA modulator 4 are monolithically integrated with each other, and in this case shown are also the second and fourth ports 82 and 86 integrated together.

First and second individual supply lines 88 and 90 are with the first and third connections 80 and 84 each connected, and a common supply line 92 is with the second and fourth connections 82 and 86 connected. The by reference numeral 94 designated arrow shows a propagation direction of the laser diode 12 radiated and through the EA modulator 4 directed forward light.

10 is an equivalent circuit diagram in 9 shown MI-LD. Reference numerals L88, L90, and L92 denote the inductances of the individual leads 88 and 90 and the common supply line 92 , Reference numerals C88 and C90 denote the parasitic capacitances of the individual leads 88 and 90 , In the equivalent circuit diagram shown, the cathodes are the laser diodes 12 and the EA modulator 4 through the common supply line 92 grounded. The anode of the laser diode 12 is through the individual supply line 88 with a drive power source 96 connected, and the anode of the EA modulator 4 is through the individual supply line 90 with a modulation signal source 98 connected. The drive power source 96 acts to supply a constant or APC controlled DC drive current to the laser diode 12 , The modulation signal source 98 acts to supply a high speed modulation signal to the EA modulator 4 ,

In the in 10 shown MI-LD, the inductance L92 through the common feed 92 provided between each cathode of the laser diode 12 and the EA modulator 4 and the earth. As a result, a high-frequency modulation signal leaked only to the EA modulator 4 is to be supplied to the laser diode 12 What a tiny modulation of the laser diode 12 caused by this leaking signal. As a result of this tiny modulation is the spectrum of the laser diode 12 emitted carrier light widens to cause a waveform distortion of the EA modulator 4 output signal light, thus making long distance transmission difficult. Another important problem due to the leakage of the high frequency signal into the laser diode 12 inside is that into the laser diode 12 guided high-speed signal the individual feeder 88 the laser diode 12 affected. This means that the signal light resonates in the inductance L88 and the capacitance C88 of the individual lead 88 causing signal distortion of the signal light. To address these problems, improvements to the MI-LD are envisaged, as described in the 11 and 12 are shown.

11 Fig. 12 is an equivalent circuit diagram showing a first preferred embodiment of the improved MI-LD. This MI-LD is characterized in that a capacitor 100 parallel to the laser diode 12 connected. According to this configuration, this can be done to the laser diode 12 leaking high frequency signal through the capacitor 100 be bypassed, thus broadening the spectrum of the laser diode 12 emitted carrier light suppressed and, accordingly, the waveform of the EA modulator 4 output signal light improved.

12 Fig. 12 is an equivalent circuit diagram showing a second preferred embodiment of the improved MI-LD. This MI-LD is characterized in that resistance 102 and a capacitor 104 , which are connected in series, are provided between the individual supply line 88 the laser diode 12 and the earth. The resistance 102 and the capacitor 104 are connected between the ground and an LD bias current input terminal (not shown), which may be used, for example, in US Pat 2 shown pack 28 is provided. The use of resistance 102 and the capacitor 104 allows the resonant frequency of a resonant circuit, which the individual lead 88 the laser diode 12 includes shifting to a range in which the influence of the signal component is avoided, eg the shift to a low frequency range. In addition, a Q value of the resonance can be reduced. Accordingly, the waveform of the signal light can be improved.

Thus, in accordance with the present invention, there is provided an optical transmitter having an in 11 or 12 has shown MI-LD, for the purpose of improving the waveform of the signal light.

The means that in accordance with an aspect of the present invention, an optical transmitter is provided, which comprises a laser diode, the first and second terminals for feed a drive current has, for generating a carrier light, which is an intensity in accordance with the drive current; an optical electroabsorption modulator, which comprises a semiconductor chip which monolithically integrates is with the laser diode and which has third and fourth ports, for absorbing the carrier light according to a created Voltage which is supplied is between the third and fourth terminals, thus an intensity modulated To emit signal light; first and second individual supply lines, which are respectively connected to the first and third terminals; a common Supply line which is connected to the second and fourth terminals is; and a capacitor, which is between the first and both connections connected.

Further, in accordance with another aspect of the present invention, there is provided an optical transmitter comprising a laser diode having first and second driving current supply terminals for generating a carrier light having an intensity corresponding to the driving current; an optical electroabsorption modulator comprising a semiconductor chip monolithically integrated with the laser diode and having third and fourth terminals for absorbing the carrier light according to an applied voltage supplied between the third and fourth terminals so as to output an intensity-modulated signal light; first and second individual feeds connected to the first and third terminals, respectively; a common supply for connecting the second and fourth terminals to the ground; and a resistor and a capacitor connected in series and provided between the first individual lead and the ground.

13 is a block diagram of an optical transmitter characterized by an APC for the laser diode 12 as a carrier light source. In the in 2 The preferred embodiment shown is the photodiode 18 for receiving the back light from the laser diode 12 used to perform the APC for the laser diode 12 with the backlight. In contrast, according to the in 13 shown preferred embodiment, the photodiode for receiving the reverse light omitted. This means that the mean value of one in the EA modulator 4 generated current, and a drive current in the laser diode 12 is controlled so that the above detected average takes a constant value. The configuration of this preferred embodiment will now be described in more detail.

From the in 8th shown graph can be concluded that the intensity of the laser diode 12 in the 13 reflected carrier light emitted is reflected in the middle of one in the EA modulator 4 current generated by the absorption of the carrier light. Accordingly, the optical transmitter in this embodiment uses the resistor 72 for current detection and in 7 shown average detection circuit 74 , An output signal from the average detection circuit 74 becomes an APC circuit 20 ' fed. The APC circuit 20 ' controls a drive current in the laser diode 12 so that in the averaging circuit 74 detected average current value assumes a constant value. The in the in 13 In the preferred embodiment shown, APC can not only be used when an offset voltage is applied to the EA modulator 4 but also if no offset voltage is applied to the EA modulator 4 ,

As previously related to in 3 Described operating characteristic, a change in the power P _OUT of the output from the EA modulator signal light is proportional to the square of a change in the voltage applied to the EA modulator voltage V _EA . In the case where the input signal is a digital signal, the duty cycle of the input signals (the first and second input signals) is, for example, the terminals 50 and 52 in the in 4 shown preferred embodiment, equal to the duty cycle of the modulation signal, which from the drain of the FET 48 the anode of the EA modulator 4 is supplied. However, the duty cycle of the modulation signal becomes different from the duty cycle of the signal light emitted by the EA modulator 4 is delivered.

14 Fig. 12 is a diagram specifically illustrating such a change in the duty ratio. The reference number 30 denotes a characteristic curve showing the relationship between the output power P _{OUT of} the signal light and the applied voltage V _EA , similar to that in FIG 3 . shown To simplify the description, it is assumed that the in 4 shown variable voltage source 44 is neglected and accordingly no offset voltage to the EA modulator 4 is created. If the duty cycle of the modulation signal is 100% as indicated by reference numeral 106 the duty cycle in the output waveform of the signal light becomes less than 100% as indicated by reference numeral 108 shown, due to the fact that the characteristic curve 30 a parable is.

In the above description, the 100% duty ratio means that the crossing point between an ascending line and a descending line in a digital signal coincide with the midpoint between a high level and a low level. Further, a duty ratio of less than 100% means that the cross point is shifted to the low level, whereas a duty ratio of more than 100% means that the cross point is shifted to the high level. In the case where the system is designed to obtain a duty ratio of 100%, the change in the duty ratio in the output signal form of the signal light results in a deterioration in the reception sensitivity. To make the duty ratio in the output waveform of the signal light equal to 100% as indicated by reference numeral 110 1, it is desirable to preliminarily set the duty ratio of the modulation signal to more than 100% as indicated by reference numeral 112 shown.

Now will be some preferred designs the driver circuit, which prepares the duty cycle of the Modulation signals can be set to any value to so the duty cycle in the output waveform of the signal light equal to a desired one Value (e.g., 100%).

15 Fig. 10 is a block diagram showing a fifth preferred embodiment of the driver circuit to which the present invention is applied. One of the features in the preferred embodiment is that the modulation signal generating circuit 10 a connection 114 for outputting an inversion signal of the modulation signal supplied from the drain of the FET 48 to the anode of the EA modulator 4 , This inversion signal is taken out as a change in the potential of the drain of the FET 46 , The driver circuit in this preferred embodiment also includes an averaging circuit 116 , a control circuit 118 , and a duty cycle changing circuit 120 in addition to the bias circuit 8th and the modulation signal generating circuit 10 ,

The duty cycle changing circuit 120 has a connection 120A for entering a reference signal, a connection 120B for inputting a digital input signal, and connections 120C and 120D for outputting signals appropriately changed in the duty cycle. In this preferred embodiment, those of the terminals 120C and 120D output signal inversion signals so that they match the differential pair (FETs 46 and 48 ) in the modulation signal generating circuit 10 to match. The duty cycle changing circuit 120 generates a duty ratio converted input signal obtained by changing the duty ratio of the input signal according to the level of the terminal 120A supplied reference signal. The averaging circuit 116 detects the mean value of the connection 114 output inversion signal, and supplies the detected average value to the control circuit 118 , The control circuit 118 controls the connection 120A in the duty cycle changing circuit 120 to be supplied reference signal so that in the averaging circuit 116 detected average assumes a constant value.

With this configuration, make the duty cycle of the of the drain of the FET 48 to the anode of the EA modulator 4 supplied modulation signal and the duty cycle of the inversion signal of this modulation signal has a one-to-one correspondence, so that the duty cycle of the modulation signal can be maintained at a desired constant value. Further, the duty ratio of the modulation signal can be set to an arbitrary value by appropriately setting the level of the duty cycle changing circuit 120 to be supplied reference signal, so that the duty cycle of the of the EA modulator 4 output signal light can be stabilized at 100%, for example. In other words, the target of the averaging circuit becomes 116 detected average value adjusted so that the duty cycle of the of the EA modulator 4 outputted signal light coincides with the duty ratio of the duty cycle changing circuit 120 supplied digital input signal.

The Idea in this preferred embodiment, the Waveform deterioration due to a difference between the duty cycle the input signal and the duty cycle of the signal light to prevent can also be applied to the case where no offset voltage is applied to the EA modulator.

Consequently will be in accordance with a further aspect of the present invention, a driver circuit created for an optical electroabsorption modulator for receiving carrier light from a light source and for absorbing the carrier light according to one applied voltage, so as to deliver intensity modulated signal light, comprising a device having first and second input ports, which a digital input signal and a reference signal respectively supplied is converted to produce a duty cycle converted Input signal obtained by changing a duty cycle the digital input signal corresponding to the reference signal; one Modulation signal generating device for generating a modulation signal according to a relative of the duty cycle converted input signal, wherein the modulation signal as a change applied in the voltage applied to the optical modulator and outputting an inversion signal of the modulation signal; an averaging circuit for receiving the inversion signal, for detecting an average of the inversion signal, and outputting the detected Average; and a device operatively connected with the averaging device and the second input port, for control the reference signal, so that the detected Mean assumes a constant value.

16 Fig. 10 is a block diagram showing a sixth preferred embodiment of the drive circuit to which the present invention is applied. The averaging circuit 74 detects the average of a current generated in the EA modulator by absorption of carrier light. A duty cycle changing circuit 120 ' is provided for generating a duty ratio converted input signal obtained by changing the duty ratio of one in the terminal 120B input digital input signal according to one in the terminal 120A input reference signal les, and for supplying the duty cycle converted input signal from a terminal 120E to the modulation signal generating circuit 10 , A control circuit 122 is provided for controlling the reference signal, which the connection 120A the duty cycle changing circuit 120 ' so that the detected average in the averaging circuit 74 assumes a constant value. Preferably, this target value is set so that the duty cycle of the of the EA modulator 4 outputted signal light coincides with the duty ratio of the terminal 120B the duty cycle changing circuit 120 ' supplied digital input signal.

17 is a diagram for illustrating the operating principle of the in 16 shown driver circuit. The by reference numeral 30 The curve shown in FIG. 2 shows the relationship between the output power P _{OUT of} the signal light in the EA modulator 4 and the applied voltage V _EA , and by reference numeral 78 designated curve shows the relationship between that in the EA modulator 4 flowing current I _EA and the applied voltage V _EA (see 8th ). In the case where the duty ratio of the signal is 100% as indicated by reference numeral 124 1, the applied voltage V _{EA is} equal to V1 according to the mean power of the signal light and the characteristic curve 30 , and in the EA modulator 4 flowing current I _EA is at this Zeiptunkt I ₁ according to the characteristic curve 78 , When the duty cycle of the signal light is reduced as indicated by reference numeral 126 shown, the applied voltage V _EA and the current I _EA accordingly change to V ₂ and I ₂ . Accordingly, to obtain a constant value, eg 100%, for the duty cycle of the signal light, the control is performed so that the detected average current in the averaging circuit 74 (please refer 16 ) becomes I ₁ .

While an offset voltage from the bias circuit 8th to the EA modulator in the in 16 The control according to the principle of 17 also be applied in the case in which no offset voltage is applied to the EA modulator.

Consequently will be in accordance with a further aspect of the present invention, a driver circuit created for an optical electroabsorption modulator for receiving carrier light from a light source and absorbing the carrier light according to a applied voltage, so as to an intensity modulated signal light comprising an apparatus having first and second input terminals, which each have a digital input signal and a reference signal supplied be used to generate a re of the duty cycle converted input signal, which is obtained by changing a duty cycle the digital input signal according to the reference signal; one Modulated signal generating device for generating a modulation signal according to the duty cycle converted input signal and the application of the modulation signal as a change in the voltage applied to the optical modulator; an averaging device for detecting an average value of one in the optical modulator by absorption of the carrier light generated electricity; and a device which is operatively connected is with the average value detecting device and the second input terminal for control the reference signal so that the Mean assumes a constant value.

18 FIG. 12 is a diagram showing the modulation signal generating circuit using the operation characteristic of an FET (Field Effect Transistor). In this preferred embodiment, the duty cycle of the signal light may be matched with the duty cycle of the input signal without the use of a duty cycle varying circuit. The modulation signal generating circuit in this preferred embodiment includes a source ground circuit including a FET 128 Has. The gate of the FET 128 is connected to a connection 130 for inputting a digital input signal, and the drain of the FET 128 is connected to a connection point between the EA modulator 4 and the terminator 26 , The source of the FET 128 is connected to a power supply line Vss.

19 is a diagram illustrating the operating principle of the in 18 shown modulation signal generating circuit. numeral 134 denotes a characteristic curve representing the relationship between a drain current ID and a gate / source voltage V _{GS of} the FET 128 shows. In a FET, it is known that a change in the drain current is substantially proportional to the square of the change of the gate / source voltage.

Assuming that the duty cycle of the digital input signal coming from the port 130 the gate of the FET 128 100% is as indicated by reference numeral 136 shown, the duty cycle in the output current waveform of the FET 128 less than 100% as indicated by reference number 138 shown. This is called the anode of the EA modulator 4 in the drain of the FET 128 flowing current as I. In this case, the current magnitude in the output current waveform changes between 0 and I, and accordingly changes those on the EA modulator 4 applied voltage between 0 and -IR, where R is the resistance of the terminating resistor 26 represents. Accordingly, the output voltage waveform of the FET becomes 128 by the reference number 140 which indicates that the duty cycle is greater than 100%. A change in the output voltage of the FET 128 means a the EA modulator 4 supplied modulation signal. Accordingly, the output waveform of the signal light obtained by the reference numeral 142 shown in accordance with the characteristic curve 30 of the EA modulator 4 , It is from the output waveform 142 obviously, the duty cycle is reduced to almost 100%.

While only the modulation signal generating circuit in FIG 18 2, a bias circuit for applying an offset voltage to the EA modulator 4 be added, similar to the previous preferred embodiments.

Consequently, in accordance With another aspect of the present invention, a driver circuit is provided for one optical electroabsorption modulator created to receive carrier light from a light source and for absorbing the carrier light according to a applied voltage so as to output an intensity-modulated signal light, comprising a terminator, which connected to the optical modulator for generating the applied Voltage by a voltage drop in the termination resistor; and a source ground circuit having a field effect transistor, which has a gate to which a digital input signal is applied, and a drain which is operatively connected to the optical Modulator and terminator; wherein a characteristic representing a relationship between a drain current and a gate / source voltage in the field effect transistor, is substantially opposite to a characteristic which a relationship between an optical output and an applied voltage in the optical modulator shows.

20 Fig. 10 is a block diagram of an optical transmitter to which direct modulation is applied.

A driver circuit 148 supplies a laser diode 146 serving as a light source, a drive current obtained by superimposing a modulation signal on a bias voltage. The modulation signal is generated according to an input signal supplied from a terminal 149 to the driver circuit 148 , An intensity modulated signal light coming from the laser diode 146 is discharged passes through an optical electroabsorption (eg EA modulator) 150 and is then fed to an untranslated optical transmission line.

A peak detection circuit 152 and an average detection circuit 154 are provided for detecting respectively the peak and the average value of one in the optical electroabsorption element 150 current generated by absorption of the signal light. A calculation circuit 156 performs a calculation according to the peaks and mean values detected above, and couples the result of the calculation to the drive current in the laser diode 146 back so that the waveform of the signal light becomes stable. The anode of the optical electroabsorption element 150 is with a connection of a resistor 158 connected. The other connection of the resistor 158 is about an inductor 160 with the negative terminal of a constant voltage source 162 connected. The positive terminal of the constant voltage source 162 is grounded. A capacitor 164 is between the earth and a connection point between the resistor 158 and the inductor 160 intended. A change in the potential of the anode of the optical electroabsorption element 150 becomes the peak detection circuit 152 and the average detection circuit 154 fed.

Preferably, that includes in the calculation circuit 156 The calculation performed is to determine a difference between the double value of the average detection circuit 154 detected average and that of the peak detection circuit 152 detected peak value. With this configuration, the vertical symmetry and the extinction ratio of the optical output waveform can be kept constant, and the amplitude of the optical output waveform can be controlled to a constant value. The details of the operating principle in the in 20 The illustrated optical transmitter will be readily understood in accordance with the operation principle of an optical output waveform stabilizing circuit well known from Japanese Patent Laid-Open No. 6-164049; therefore, its description is omitted here.

The The present invention is not limited to the details of those described above preferred embodiments limited. The scope of the invention is defined by the appended claims and all changes and modifications resulting in the equivalence of the scope of claims are thus covered by the invention.

Claims (4)

Driver circuit for an optical electroabsorption modulator ( 4 ) to receive Trä from a light source and absorbing the carrier light in accordance with a voltage applied thereto so as to emit intensity modulated signal light, the driver circuit comprising: a duty ratio varying circuit ( 120 ) with a first input terminal ( 120B ), to which a digital signal is supplied, and a second input terminal ( 120A to which a reference signal is supplied for generating a duty ratio converted signal obtained by changing the duty ratio of the digital signal according to the reference signal; a modulation signal generator ( 10 ) with input connections ( 50 . 52 ) to which the duty cycle converted signal is applied according to which the modulation signal generating means (14) 10 ) generates a modulating signal which, as a change with respect to the optical electro-absorption modulator ( 4 ) is applied to this offset, and with an output terminal ( 114 ) for outputting an inversion signal formed by inverting the modulation signal; a mean value detection device ( 116 ) receiving the inversion signal for detecting an average value of the inversion signal and outputting the detected average value; and a control circuit ( 118 ) receiving the detected average for controlling the duty cycle changing circuit (FIG. 120 ) supplied reference signal that the detected average assumes a constant value. Driver circuit for an optical electroabsorption modulator ( 4 ) for receiving carrier light from a light source and for absorbing the carrier light according to a voltage applied thereto so as to emit intensity modulated signal light, the driver circuit comprising: a duty ratio varying circuit (US Pat. 120 ' ) with a first input terminal ( 120B ), to which a digital signal is supplied, and a second input terminal ( 120A to which a reference signal is supplied for generating a duty ratio converted signal obtained by changing the duty ratio of the digital signal according to the reference signal; a modulation signal generator ( 10 ) to which the duty-ratio converted signal is supplied according to which the modulation signal generating means (Fig. 10 ) generates a modulating signal which, as a change with respect to the optical electro-absorption modulator ( 4 ) applied to this offset voltage; a mean value detection device ( 74 ) corresponding to those in the optical electroabsorption modulator ( 4 ) receives current generated by the absorption of carrier light, detects its mean and outputs the detected average value; and a control circuit ( 122 ) receiving the detected average for controlling the duty cycle changing circuit (FIG. 120 ' ) supplied reference signal that the detected average assumes a constant value. Driver circuit according to claim 1 or 2, characterized characterized in that constant value is set so that the duty cycle of the Signal light the duty cycle corresponds to the digital signal. Driver circuit for an optical electroabsorption modulator ( 4 ) for receiving carrier light from a light source and for absorbing the carrier light in accordance with an applied voltage so as to emit intensity modulated signal light, the driver circuit comprising: a terminator ( 26 ), which with the optical electroabsorption modulator ( 4 ) for generating the applied voltage by a voltage drop in the termination resistor; and a source ground circuit ( 128 ) comprising a field effect transistor with a gate connection ( 130 ), to which a digital signal is supplied, and having a drain connected to the optical electroabsorption modulator ( 4 ) and the terminating resistor ( 26 ) is operatively connected; wherein a characteristic of the field effect transistor showing a relationship between its drain current and its gate / source voltage is substantially opposite to a characteristic of the optical electroabsorption modulator (FIG. 4 ) showing a relationship between its optical output and its applied voltage so that the duty ratio of the signal light corresponds to the duty ratio of the digital signal.