Abstract:
A circuit arrangement for actuating semiconductor lasers with the transmitted optical power being controlled with the aid of a photodiode optically coupled to the laser radiation, whose amplified photoelectric current controls the current of the laser in such a way that its radiation capacity remains constant, is to be improved, in particular, such that the circuitry expenditure is low, the band width large and the operating point of the laser easy to set, and, furthermore, such that a digital or HF signal for modulation of the laser radiation can be coupled without difficulty.

Description:
BACKGROUND OF THE INVENTION 
     Modern semiconductor lasers are suitable as radiation sources in CW operation up to high modulation frequencies (several GHz). 
     CW semiconductor lasers are operated in such a manner that in the current radiation capacity characteristic curve of the laser, preferably above the threshold current I th , a certain DC operating point is set by a preliminary current I F . As required, a digital or HF signal is then modulated, or the laser is simply used as DC radiation source. In each case, it is necessary for various reasons (ageing, temperature dependence, etc.) to keep constant or stabilize the optical power of the laser. 
     A photodiode which is optically coupled to the laser radiation and is mostly arranged on the same base as the laser chip is primarily used for the stabilization. The photoelectric current of the photodiode, amplified via a control circuit, then controls the current I F  of the laser in such a way as to keep the radiation capacity constant. 
     SUMMARY OF THE INVENTION 
     The object underlying the invention is to improve a circuit arrangement for actuating semiconductor lasers, with the optical power transmitted being controlled with the aid of a photodiode optically coupled to the laser radiation such that the circuitry expenditure is very low, the band width large, and the operating point of the laser easy to set, and such that the circuit arrangement, furthermore, necessitates basically only one supply voltage and enables easy coupling of a digital or HF signal for modulation of the laser radiation. 
     This object is attained in accordance with the invention in that the photodiode operates as signal source for a transimpedance amplifier which is comprised of (at least) two transistors and whose output current is simultaneously the control current of the semiconductor laser. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will now be explained with reference to some circuitry examples. 
     FIG. 1 shows a laser actuating arrangement in the basic form according to the invention; 
     FIG. 2 shows a circuit arrangement which has been modified with respect to the modulation of the laser radiation by use of an additional transistor; 
     FIG. 3 shows a circuit arrangement with setting of the operating point of the laser with the aid of a reference voltage and with an additional transistor for modulation of the laser radiation with a digital or HF signal; 
     FIG. 4 shows a variant of the basic circuit arrangement according to FIG. 1 with an additional transistor which forms with the first transistor of the transimpedance amplifier a current mirror circuit; 
     FIG. 5 shows a modified circuit arrangement wherein the resistors provided in the circuit arrangement according to FIG. 1 for determining the laser current are replaced by a current mirror circuit comprised of two transistors. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The laser actuating circuit is illustrated in its basic form in FIG. 1. It consists of the two transistors Q 1 , Q 2 , the photodiode FD and four resistors R E , R F , R O  and R V , with R V  being in the form of an adjustment resistor. 
     The diode SD is connected as a protective diode antiparallel to the laser L a  and has no function other than that of protecting the laser from negative voltages. It should, therefore, be a rapid switching diode. 
     The transistors Q 1  and Q 2  form a transimpedance amplifier with the photodiode FD as signal source. The output current of the amplifier, i.e., the collector current of Q 2 , is simultaneously the control current I F  of the semiconductor laser L a . 
     Accordingly, the laser current I F  is directly related to the photoelectric current I P  through the current amplification V i  of the amplifier. 
     Approximated: 
     
         V.sub.i ≈R.sub.F /R.sub.E =I.sub.F /I.sub.P 
    
     or 
     
         I.sub.F =-I.sub.P ·V.sub.i. 
    
     The photoelectric current I P  is proportional to the optical power P emitted from the laser: 
     
         I.sub.P =S·P. 
    
     S represents the sensitivity of the photodiode. 
     It therefore follows that: 
     
         I.sub.F =-SV.sub.i P. 
    
     Accordingly, for every change ΔP in the power, there occurs the current change ΔI F  =-S·V i  ·ΔP which displaces the operating point on the laser characteristic curve such that the change in the power is decreased and disappears. 
     Since the transimpedance amplifier which effects the countercoupling is a definite wide band amplifier with high limit frequency, the optical countercoupling and control also remain effective up to very high frequencies, more precisely, up to the limit frequency f g  of the amplifier with the photodiode as source. 
     For frequencies larger than the limit frequency f g  of the controlled system, the control causes the optical power to be stabilized to a certain mean value. If HF transistors are used for Q 1 , Q 2 , the limit frequency f g  of the transimpedance amplifier is, in approximated terms, inversely proportional to the product R F  ·C F , 
     
         f.sub.g ˜(1/2π·R.sub.F ·C.sub.P), 
    
     with C P  being the capacitance of the photodiode and R F  the countercoupling resistance of the amplifier. 
     With low-capacitance rapid photodiodes, f g  reaches very high values. On the other hand, it is very often desired to stabilize to a mean value of the optical power. In this case, the limit frequency is reduced to the desired value by connecting external capacitors C e  to the input of the amplifier. 
     The laser radiation may be modulated with a signal at point A or point B via a capacitor C. 
     Another possibility of modulating the laser radiation with a digital or HF signal is shown in FIG. 2 and FIG. 3. Here, an additional transistor Q 3  which is connected with its emitter to point B, FIG. 3, or with its collector to point A, FIG. 2, is used, with, in this case, the emitter being connected via a resistor R 3  to the negative pole of the supply voltage source. In both cases, the laser L a  can then be modulated with the effective signal via the base of the transistor Q 3 . 
     The circuit variant shown in FIG. 5 is also suitable for modulation of the laser radiation with an external signal at point B. Here, an additional transistor Q 3 , connected to the resistor R B  parallel to the resistor R E  is likewise used. 
     The transistor Q 3 , may also be the output of a TTL gate with open collector outputs. 
     The connection of Q 3  in FIG. 3 corresponds to the output of an ECL gate. Accordingly, at point B the laser may also be directly modulated with a gate of this rapid logic. 
     In the case of FIGS. 1, 2 and 4, the operating point and the operating range of the laser in the current power characteristic curve are set roughly with the resistor R E  and precisely with the resistor R V . With predetermined resistances R F  and R E , the resistor R O  determines the maximum currrent I Fmax  and the sum R O  +R Vmax  the minimum current I Fmin  through the laser L a . 
     Two further possibilities of setting the operating point of the laser are shown in FIGS. 3 and 5. In the circuit arrangement according to FIG. 3, the operating point is fixed with the aid of a reference voltage U REF  at the base of the transistor Q 3 . In this case, the resistor R V  is eliminated with the result that only the resistor R O  is located between the base of the first transistor Q 1  and the positive pole of the supply voltage source. 
     In the circuit arrangement shown in FIG. 5, the resistors R V , R O  are replaced by a current mirror circuit Q 4 , Q 5 . Here, the operating point is set precisely with the variable resistor R P . In this case, the adjustment resistor R V  of FIG. 1 is placed between the negative pole and the collector base contacts of the transistor Q 5  which are connected to one another. 
     The advantage of the circuit arrangement of FIG. 5 over that shown in FIG. 1 is that in the case of FIG. 5, the collector of Q 4  is now connected as current source to the collector of Q 1 . This current source (collector of Q 4 ) corresponds, almost independently of the current, to a large load resistance for the transistor Q 1  so that the internal amplification of the transimpedance amplifier comprised of the transistors Q 1  and Q 2  remains large and stable in a wide dispersion range. 
     The characteristics of the transimpedance amplifier therefore also become dependent on the set operating point and current to a minor degree. The emitters of the PNP transistors Q 4  and Q 5  are each conductively connected via a resistor R 4  and R 5 , respectively, to the cathode of the photodiode FD which is connected to the positive pole of the voltage source. 
     A further variant of the basic circuit arrangement of FIG. 1 is shown in FIG. 4. Here, an additional transistor Q 0  which forms with the transistor Q 1  a current mirror circuit is used. Q 1  and Q 2  are still connected as transimpedance amplifier. 
     This circuit has the advantage of having very good temperature stability in the event that the transistors Q 1  and Q 0  are thermally coupled to one another. 
     If suitable HF or UHF transistors are used, the limit frequency of the control circuit according to the invention reaches values of several 100 MHz and is primarily only limited by the limit frequency of the photodiode FD. If necessary, the circuit may also be connected to two supply voltages.