CN101692521A - Laser diode driver for optical communication transmitter - Google Patents

Laser diode driver for optical communication transmitter Download PDF

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Publication number
CN101692521A
CN101692521A CN200910197321A CN200910197321A CN101692521A CN 101692521 A CN101692521 A CN 101692521A CN 200910197321 A CN200910197321 A CN 200910197321A CN 200910197321 A CN200910197321 A CN 200910197321A CN 101692521 A CN101692521 A CN 101692521A
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laser diode
circuit
current
optical communication
output
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CN101692521B (en
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易河清
潘素敏
刘尚新
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SHANGHAI BOWEI PHOTOELECTIC TECHNOLOGY Co Ltd
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SHANGHAI BOWEI PHOTOELECTIC TECHNOLOGY Co Ltd
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Abstract

The invention discloses a laser diode driver for an optical communication transmitter. The laser diode driver comprises an input shaping circuit, a laser diode modulated current control circuit which is provided with a modulated current switch and is connected with the output end of the input shaping circuit and a to-be-driven laser diode, a laser diode bias current control circuit which is provided with a bias current switch and is connected with the laser diode, a photoelectric switching circuit, a peak detection circuit in direct-current coupling with the photoelectric switching circuit to carry out quick detection of electric signals output by the photoelectric switching circuit to output a detection signal and a differential comparison amplifying circuit in direct-current coupling with the peak detection circuit, wherein the output end of the differential comparison amplifying circuit is connected with the laser diode modulated current control circuit and the laser diode bias current control circuit to form a negative feedback loop. The laser diode driver has the advantages that the driver is suitable for transmitting both burst signals and random balanced signal flows.

Description

The laser diode drive that is used for optical communication transmitter
Technical field
The present invention relates to a kind of optical communication field, particularly a kind of laser diode drive that is used for optical communication transmitter.
Background technology
The laser diode drive that is used for optical communication transmitter is that the voltage signal that will be transmitted changes light signal in the effect of optical communication system.Usually it is made up of a laser diode driver circuit, a laser diode (LD) and automatic power control circuitry.Wherein, laser diode driver circuit changes the voltage signal that is transmitted into corresponding current signal, this current signal driving laser diode, and laser diode changes this driving current signal into light signal output.Because the electric current/luminous power conversion efficiency of each laser diode all there are differences, and this conversion efficiency not only can strengthen with variation of ambient temperature, also can change with aging (in time promptly) of laser diode simultaneously.So often need an automatic power control circuitry in the laser diode drive, keep stable to guarantee the luminous power that transmitter sends, thereby make overall optical communication system working stability, and prolong the useful life of laser.Thereby laser diode drive is one of core component of optical communication system.
The conventional laser diode (led) driver, majority only is applicable to that the light of stochastic equilibrium code stream (being that light sends the code stream that average power approximates 1/2 peak power) sends, and the light of inapplicable burst (be that light sends the code stream that average power is not equal to 1/2 peak power, do not have stable quantitative relation between the average transmitting power of burst luminous signal and the peak power) sends.Reason is that traditional laser diode drive can only be controlled the average power that light sends, and controls the peak power of stochastic equilibrium signal indirectly by the quantitative relation that average power approximates 1/2 peak power.And for the transmission of burst, the direct peak power of control transmission signal then.Along with the development of Optical Access Network in recent years, the existing few technical products of quantity, the laser diode drive that uses burst to send is provided, they roughly are divided into two classes: a class is not have automatic control function of power, adopt the way of total temperature compensation to stablize transmitted power, shortcoming is that transmission peak power stability is not high, and can not compensate the aging transmitted power decline that causes of LD, shorten the useful life of LD, but the majority of applying at present is this series products; Second class is that automatic control function of power is arranged, but the prior art majority can only be applicable to and require relatively low EPON (Ethernet passive optical network) that perhaps control precision stability is still not enough, rarely applies at present just to suffice to show that its technology is immature.
Therefore providing a kind of laser diode drive with perfect automatic controlled function of transmission light signal peak power, is the demand that present optical communication technique development, especially Optical Access Network technology and other technical fields that relates to the burst optical transmission develop.
Summary of the invention
Technical scheme to be solved by this invention provides a kind of laser diode drive that is used for optical communication transmitter, to solve the deficiencies in the prior art.
For solving technique scheme, the invention provides a kind of laser diode drive that is used for optical communication transmitter, comprise: the input shaper circuit, be used for the waveform of differential voltage signal to input and carry out shaping and amplify, with the disequilibrium and the relaxation distortion of the differential signal of eliminating input; Laser diode modulated current control circuit with modulated current switch, the output, and the laser diode to be driven that connect described input shaper circuit, be used for the signal of described input shaper circuit output is converted into the modulated current signal with positive temperature coefficient, and make described modulated current signal send light pulse signal to drive described laser diode by described modulated current switch; Have the bias current switch laser diode bias current control circuit, connect described laser diode, be used for providing bias current with positive temperature coefficient to described laser diode; Photoelectric switching circuit is used for the light signal dorsad of described laser diode output is converted to the signal of telecommunication; Peak-detector circuit with described photoelectric switching circuit direct-current coupling, be used for the signal of telecommunication of described photoelectric switching circuit output is carried out quick detection with the output rectified signal, and its detection time constant detected the peak value of burst so that can realize much smaller than the retention time of rectified signal; With the differential ratio of described peak-detector circuit direct-current coupling than amplifying circuit, its can export send the relevant and voltage that is inversely proportional to of photopeak value power with described laser diode output with described laser diode modulated current control circuit, reach described laser diode bias current control circuit and be connected, to form negative feedback loop, realize control to described bias current and described modulation signal.
Preferable, described input shaper circuit comprises the attenuation network that described differential voltage signal is decayed and is connected the differential amplifier of described attenuation network output.
Preferable, the series circuit of described attenuation network for constituting, the turnover voltage that the peak-to-peak value of the differential signal of its output is put greater than the bipolar transistor difference by the resistance series connection.
Preferable, described differential amplifier comprises a differential pair tube, the constant-current source circuit of electric current is provided, is connected with described constant-current source circuit and is used to compensate the proportional current mirror of described constant-current source circuit temperature characterisitic, is connected described differential pair tube output and separately output signal is fed back to described constant-current source circuit to constitute two emitter followers of direct current negative feedback biasing respectively to described differential pair tube.
Preferable, described constant-current source circuit is made of transistor AND gate resistance, and described proportional current mirror is made of diode and resistance.
Preferable, described modulated current switch comprises that a transistor is to pipe, wherein, described transistor connects described laser diode to an output, the collector electrode that the base stage of one in the pipe connects described input shaper circuit, and described transistor connects power end to another output, the collector electrode that the base stage of another person in the pipe connects described input shaper circuit.
Preferable, described laser diode modulated current control circuit also comprises: with described transistor the emitter of the two transistor of pipe is connected and be used to provide modulated current the modulated current source circuit, to described modulated current source circuit provide bias voltage the negative feedback serial regulating circuit, and the output of described negative feedback serial regulating circuit is coupled to the emitter follower of described modulated current source circuit.
Preferable, described modulated current source circuit is drawn a laser diode modulated current monitoring side.
Preferable, the input of described emitter follower is drawn a laser diode modulated current and end is set by connecing the resistance of establishing the initial modulation electric current to be set.
Preferable, described laser diode modulated current control circuit also comprises: be connected described negative feedback serial regulating circuit output, and can make the bias voltage of described negative feedback serial regulating circuit output be lower than the required bias voltage of described modulated current source circuit and then cause described modulated current source circuit not export the drive current complete shut-down deenergizing of modulated current.
Preferable, described drive current complete shut-down deenergizing is the common emitter circuit of two-stage series connection, and described common emitter circuit is drawn drive current complete shut-down outage pressure input.
Preferable, described inclined to one side system current switch comprises that a transistor provides the base bias circuit of base bias voltage to pipe with to described transistor respectively to both of pipe, wherein, described transistor is higher than another person's base bias voltage to the base bias voltage of one in the pipe, and the high person's of base bias voltage collector electrode connects described laser diode, and low person's collector electrode connects power end.
Preferable, described laser diode bias current control circuit also comprises: with described transistor the emitter of the two transistor of pipe is connected and be used to provide bias current the bias current source circuit, to described bias current source circuit provide bias voltage the negative feedback serial regulating circuit, and the output of described negative feedback serial regulating circuit is coupled to the emitter follower of described bias current source circuit.
Preferable, described bias current source circuit is drawn a laser diode bias current monitoring side.
Preferable, the input of described emitter follower is drawn a laser diode bias current and end is set by connecing the resistance of establishing the initial bias electric current to be set.
Preferable, described laser diode bias current control circuit also comprises: be connected described negative feedback serial regulating circuit output, and can make the bias voltage of described negative feedback serial regulating circuit output be lower than the required bias voltage of described bias current source circuit and then cause the not bias current breaking circuit of output offset electric current of described bias current source circuit.
Preferable, described bias current breaking circuit is the common emitter circuit of two-stage series connection, and described common emitter circuit is drawn a bias current shutoff voltage input.
Preferable, described laser diode modulated current control circuit is drawn drive current complete shut-down outage pressure-controlled end, described bias current shutoff voltage control end is connected by a unidirectional isolating diode with described drive current complete shut-down outage pressure-controlled end, so that described bias current breaking circuit does not exert an influence to described modulated current complete shut-down deenergizing when turn-offing.
Preferable, described photoelectric switching circuit comprises a photodiode and and the trans-impedance amplifier of described photodiode direct-current coupling.
Preferable, described peak-detector circuit comprises: the emitter follower of the described photoelectric switching circuit output signal of direct-current coupling, the detector diode with described emitter follower direct-current coupling, the detection electric capacity that is connected with described detector diode and be connected and comprise the commonsource amplifier of field-effect transistor with described detection electric capacity.
Preferable, the charge constant that described detection electric capacity and described detector diode conducting resistance constitute is several ns orders of magnitude, the discharge time constant that the reverse off-resistances of described detection electric capacity and described detector diode constitutes is tens ms orders of magnitude.
Preferable, described differential ratio comprises than amplifying circuit: first emitter follower that is connected described peak-detector circuit output, be connected with the described first emitter follower output and comprise the differential comparator amplifier that differential pair tube constitutes, reach second emitter follower and the 3rd emitter-base bandgap grading follower that are connected respectively with two outputs of described differential pair tube, the input of one in the wherein said differential pair tube connects described first emitter follower, another person's input connects reference voltage, and the output that connects the reference voltage person can be exported voltage relevant with described laser diode transmission photopeak value power and that be inversely proportional to.
Preferable, in described differential pair tube, connect the reference voltage person and draw laser diode output photopeak value power setting end.
Preferable, in described differential pair tube, it draws laser diode transmission photopeak value power monitoring end by described second emitter follower to connect the described first emitter follower person.
Preferable, described differential ratio comprises also that than amplifying circuit negative pole is connected described the 3rd emitter-base bandgap grading follower and anodal first isolating diode and the negative pole that is connected described laser diode modulated current control circuit is connected described the 3rd emitter-base bandgap grading follower and anodal second isolating diode that is connected between the described laser diode bias current control circuit.
Preferable, the negative pole quiescent voltage working point of described second isolating diode is lower than the quiescent point of described first isolating diode, so that bias current is gone into control earlier than modulated current.
Beneficial effect of the present invention is: the automatic controlled function of emission peak luminous power is perfect, emission peak luminous power dynamic stability is better, the emission peak luminous power is not subjected to send the sign indicating number type to be influenced, be not subjected to the influence of LD bias current frame synchronization switch yet, thereby both be applicable to that burst sent, be applicable to that also the stochastic equilibrium signal flow sends.
Description of drawings
Fig. 1 is the laser diode drive preferred embodiment block diagram that is used for optical communication transmitter.
Fig. 2 is the laser diode drive preferred embodiment circuit diagram that is used for optical communication transmitter.
Embodiment
Describe the preferred embodiments of the present invention in detail below in conjunction with accompanying drawing.
Please refer to Fig. 1, the burst laser diode drive that is used for optical communication transmitter provided by the invention comprises that two differential signal inputs 1 and 2, input shaper circuit 3, modulated current switch 4, laser diode LD 5, laser diode modulated current control circuit 6, a laser diode modulated current are provided with end I MSET7, a laser diode modulated current is provided with resistance R IM8, laser diode modulated current monitoring side I MMON9, laser diode drive current shutoff voltage V DISABLEThe unidirectional isolating diode of input 10, one 11, one have the laser diode bias current control circuit 12 of bias current switch, a laser diode bias current is provided with end I BSET13, laser diode bias current is provided with resistance 14, a laser diode bias current monitoring side I BMON15, laser diode bias current shutoff voltage input V IBOFF16, relatively amplifying circuit 19, a laser diode send peak light power setting end APC for photodiode PD17, transimpedance amplifier TIA18, peak detection SET20, a laser diode sends peak light power setting resistance R APC21 and laser diodes send peak light power monitoring end PW MON22.Wherein, modulated current switch 4 and laser diode modulated current control circuit 6 constitute the laser diode modulated current control circuit with modulated current switch, peak detection comparison amplifying circuit 19 comprises that peak-detector circuit and differential ratio are than amplifying circuit two parts, LD among the figure promptly represents laser diode, laser diode modulated current control circuit 6 refers to same main body with LD modulated current control circuit 6, is applicable to that in like manner other employings " LD " replace the mode of laser diode.
To input shaper circuit 3, input shaper circuit 3 is eliminated possible asymmetric (positive and negative phase signals imbalance) and the possible relaxation distortion of input differential signal to differential input end 1 and 2 with input differential signal direct-current coupling.LD modulated current switch 4 is converted to switching current signal modulated laser diode 5 with the voltage signal of input shaper circuit 3 outputs, and laser diode 5 is converted to corresponding light signal feed-in transmission medium with modulated current signal.LD modulated current control circuit 6 provides modulated current for LD modulated current switch, its feedback voltage that provides according to peak detection comparison amplifying circuit 19, LD modulation circuit are provided with end 7, the outage of LD drive current complete shut-down presses the state of input 10 dynamically to control LD modulated current and LD bias current, and provide the normal light communication system that the function port that provides is provided.It comprises that the LD modulated current is provided with end 7, and input 10 (purpose is to guarantee the system maintenance personal security) is pressed in the outage of LD modulated current monitoring side 9 and LD drive current (comprising modulated current and bias current) complete shut-down.The LD modulated current is provided with resistance 8 and is set according to power/current curve (PI curve) and the system requirements of LD by the user.LD bias current sources and control circuit 12 provide bias current for laser diode 5, the feedback voltage that it provides according to peak detection comparison amplifying circuit, and the LD bias current is provided with end 13, LD bias current shutoff voltage input 16.11 unidirectional buffer actions of diode, its positive pole is connected with port one 6, negative pole is connected with port one 0, when port one 6 input low levels (≤0.7V) time, the LD bias current turn-offs, diode 11 is in cut-off state, do not influence port one 0, and when port one 0 input low level, diode 11 conductings, LD modulated current and LD bias current turn-off simultaneously.In addition, LD bias current sources and control circuit also provide the normal light communication system that the function port one 3,15 and 16 that provides is provided.The LD bias current is provided with resistance 14 and is set according to PI curve and the system requirements of LD by the user.Photodiode 17 and trans-impedance amplifier 18 with LD dorsad light signal be converted to voltage signal, 19 pairs of these voltage signals of peak detection comparison amplifying circuit carry out peak detection and compare and enlarge, thereby make its output voltage and LD send peak light power linear correlation, and should be fed to LD modulated current control circuit 6 and LD bias current sources and control circuit 12 by negative-feedback principle, thereby realize LD is sent the dynamic auto control of peak light power with LD transmission peak light power linear correlation voltage.In addition, the function port that peak detection comparison amplifying circuit 19 also provides the normal light communication system to require to provide is that LD transmitting optical power monitoring port 22 and LD transmitting optical power are provided with port 20, and the LD transmitting optical power is provided with resistance 21 and is set according to system requirements by the user.
Please refer to Fig. 2, it implements circuit diagram for the above-mentioned laser diode drive that is used for optical communication transmitter.
Resistor R 1, R2, R3 are connected in series successively, form a resistance decrement network, differential voltage signal is imported from the other end of R1 and R3 respectively, export the differential voltage that is attenuated from the two ends of R2, output differential signal peak-to-peak value after its decay is about 150mV~200mV, the turnover voltage of putting greater than the bipolar transistor difference (being about 80mV).
By above-mentioned connection, the resistance decrement network of being made up of R1, R2, R3 has effectively improved the return loss of input signal, has reduced the standing-wave ratio of input signal, prevents that simultaneously subsequent conditioning circuit from importing blasting.
The difference amplifier transistor is to pipe Q1, Q2, its collector electrode connects power supply VCC by resistance R 4, R5 respectively, its two base stage connects the two ends of above-mentioned R2 respectively, two emitter is connected with the collector electrode of transistor Q3, the emitter of Q3 is by resistance R 6 ground connection, constitute constant-current source circuit, its base stage is by a diode D1 and resistance R 0 series connection ground connection.Transistor Q4, Q5 constitute two emitter followers with resistance R 7, R8.Resistance R 9, R10 series connection back cross-over connection are in the emitter of Q4, Q5, and it is connected in series and a little is connected with the base stage of Q3, provides negative feedback bias voltage, wherein R9=R10 as the Q3 base stage.
Constitute a differential amplifier according to above-mentioned connection transistor Q1, Q2, Q3, Q4, Q5 and resistance R 4, R5, R6, R7, R8, R9, R10, R0 and diode D1, the constant source flowing transistor Q3 base stage of differential amplifier is put to export with difference by resistance R 9, R10 and is penetrated with being connected, because R9=R10, its AC signal amplitude that is connected in series a little is 0, thereby realize direct current negative feedback biasing, diode D1 and resistance R 0 constitute a proportional current mirror, temperature characterisitic in order to compensation Q3 makes the stability of described differential amplifier and equilibrium response good.Add the high return loss of above-mentioned input attenuation network, the output waveform that described difference is put keeps difference to amplify the approximate rectangular ripple of amplitude limit, eliminates the possible relaxation distortion of waveform input signal.
Transistor constitutes laser diode modulated current switch to Q6, Q7, two base stage is penetrated with being connected with two outputs of above-mentioned differential amplifier respectively, two emitter-base bandgap grading is connected with the collector electrode of constant source flowing transistor Q8, the collector electrode of Q6 is connected with laser diode LD, the collector electrode of Q7 connects power supply VCC, and the emitter of Q8 is by resistance R 11 ground connection.Transistor Q9, Q10 and resistance R 13, R14, R15, R16 constitute a negative feedback serial regulating circuit, draw output voltage from the collector electrode of transistor Q9, the emitter-base bandgap grading of transistor Q11 is by diode D2 and resistance R 17 series connection ground connection, its collector electrode connects power supply VCC, base stage is connected with the output of described serial regulating circuit, constitutes an emitter follower.D2 a little is connected with the base stage of Q8 with being connected in series of R17, for Q8 provides base bias voltage.Draw the LD modulated current from the collector electrode of transistor Q9 function port I is set MSET, draw LD modulated current monitoring port I by a resistance R 12 from the emitter of transistor Q8 MMON
Constant source flowing transistor Q8 and emitter resistance thereof constitute a modulated current source circuit, the LD modulated current switch that constitutes for transistor Q6, Q7 provides LD modulated current, described serial regulating circuit and output are penetrated with providing base bias voltage for constant source flowing transistor Q8, because the BE of transistor Q10 knot has-temperature coefficient of 2mV/C, so have a bigger positive temperature coefficient from the voltage of Q9 collector electrode output, this positive temperature coefficient has more been strengthened in the BE knot of transistor Q11 and diode D2 series connection.So the output current of constant source flowing transistor raises along with ambient temperature and increases, with electric current---the negative temperature coefficient of luminous power transfer ratio of compensation LD.When the base stage of transistor Q6 is a high level, when the base stage of transistor Q7 was low level, Q6 conducting, Q7 ended, and the electric current that Q8 provides is injected into laser diode LD, and LD sends light pulse signal, otherwise then Q6 ends, the Q7 conducting, and the LD modulated current is turned off.The user can pass through an earth resistance R IMConnect the LD modulated current end I is set MSETInitial LD modulated current is set.The resistance of known R11 is from LD modulated current monitoring port I MMONOutput voltage can make a matched curve (equation) and send into the monitoring module of system and detect the LD modulated current.
The common emitter circuit (two inverters) of the two-stage series connection that transistor Q12, Q13, resistance R 18, R19 form is as drive current complete shut-down deenergizing, the wherein grounded emitter of Q12, Q13, the collector electrode of Q12 is connected power supply VCC by resistance R 18, R19 respectively with base stage, the base stage of Q13 is connected with the collector electrode of Q12, and the base stage of Q13 and the voltage output end of above-mentioned series voltage regulator are that the collector electrode of transistor Q9 is connected.Draw the outage of LD drive current complete shut-down from the base stage of described transistor Q12 and press input DISABLE.
According to above-mentioned connection, described modulated current switch, described modulated current source circuit, described emitter follower, described negative feedback serial regulating circuit, be that described drive current complete shut-down deenergizing constitutes the laser diode modulated current control circuit with modulated current switch.When the input voltage of LD drive current shutoff voltage input DISABLE be low level (≤0.7V) time, above-mentioned transistor Q12 ends, the Q13 conducting is until current saturation, its collector voltage is reduced to≤0.3V, thereby above-mentioned LD modulation constant source flowing transistor Q8 is ended, turn-off the LD modulated current, and turn-off LD bias current described later.When LD drive current complete shut-down outage press input be high level (〉=1.8V) or during open circuit, above-mentioned transistor Q12 conducting is also saturated, Q13 ends, the bias voltage (control voltage) that is provided with of LD modulated current constant source flowing transistor is not exerted an influence.
Transistor constitutes the bias current switch to pipe Q14, Q15, and two emitter is connected with the collector electrode of transistor Q16, and the collector electrode of Q14 is connected with the negative pole of above-mentioned laser diode LD, and the collector electrode of Q15 connects power supply VCC.The emitter of described transistor Q16 constitutes the bias current source circuit by resistance R 25 ground connection.Resistance R 20, diode D3, D4, resistance R 21, resistance R 22, diode D5, D6 and resistance R 23 have constituted base bias circuit.Wherein, resistance R 20, diode D3, D4 and resistance R 21 are connected in series successively, and wherein the end of R20 connects power supply VCC, the end ground connection of R21, and the base stage of transistor Q14 connects being connected in series a little of R20 and D3, for Q14 provides base bias voltage; Resistance R 22, diode D5, D6 and resistance R 23 are connected in series successively, and an end of resistance R 22 connects power supply VCC, and an end of resistance R 23 connects ground, and being connected in series of diode D5, D6 a little is connected with the base stage of described transistor Q15, for Q15 provides bias voltage; Described resistance R 20=R22, R21=R23.Transistor Q17, Q18 and resistance R 27, R28, R29, R30 constitute a negative feedback serial regulating circuit, its output voltage is drawn and is passed through by penetrating with providing base bias voltage for above-mentioned transistor Q16 that transistor Q19 and diode D7, resistance R 24 constitute from the collector electrode of transistor Q17, wherein diode D7 and R24 are connected in series and penetrate with load as described, and the base stage of above-mentioned transistor Q16 connects being connected in series a little of diode D7 and resistance R 24.
Described serial regulating circuit comprises that the output voltage of described voltage output emitter follower has positive temperature coefficient, and it provides base bias voltage for described transistor Q16; Then the collector current of Q16 has positive temperature coefficient equally, compensates the negative temperature coefficient of laser diode threshold current slope with this.The collector current of described transistor Q16 is the bias current of laser diode LD, and this electric current is injected into the emitter of transistor Q14 and Q15.Because the base bias voltage of Q14 is than the high diode turn-on voltage of base bias voltage (about 0.8V) of Q15 in the normal state, so under the common state, Q14 conducting and Q15 ends.So the collector current of transistor Q16 is by Q14 feed-in laser diode LD.
Transistor Q20, Q21, resistor R 31, R32, R33, diode D8, D9, D10 form common emitter (inverter) circuit of a two-stage tandem as the bias current breaking circuit, wherein, the emitter of transistor Q20, Q21 is respectively by diode D8, D9 ground connection, the collector electrode of Q20 is connected power supply VCC by resistance R 31 respectively with base stage with R32, the positive pole of diode D10 is connected with the base stage of transistor Q20, and input V is pressed in the negative pole of D10 and the outage of above-mentioned LD drive current complete shut-down DISABLEConnect.The collector electrode of transistor Q21 is connected with the base stage of above-mentioned transistor Q14.In addition, draw the LD bias current from the collector electrode of above-mentioned transistor Q17 end I is set BSET, draw LD bias current monitoring side from the emitter of transistor Q16 by a resistance R 26, draw LD bias current shutoff voltage input port V from the base stage of transistor Q20 by resistance R 33 IBOFF
By above-mentioned connection, described bias current switch, described bias current source circuit, described base bias circuit, described negative feedback serial regulating circuit, and described bias current breaking circuit constitute LD bias current control circuit with bias current switch, as above-mentioned LD bias current shutoff voltage input V IBOFFOr (with) above-mentioned LD drive current complete shut-down outage pressure input V DISABLEFor low level (≤0.7V) time, transistor Q20 ends, transistor Q21 conducting is until saturated, thereby the base bias voltage that makes transistor Q14 is pulled down to and is about 0.8V, and Q14 is ended, and the Q15 conducting, the LD bias current is turned off, and the collector current of Q16 discharges by Q15.Wherein, wherein diode D10 plays unidirectional buffer action, as LD bias current shutoff voltage input V IBOFFBe low level, and input V is pressed in the outage of LD drive current complete shut-down IDSABLEDuring for high level or open circuit, diode D10 ends, and does not influence the LD modulated current.The effect of resistance R 33 is to guarantee LD drive current complete shut-down outage pressure input V DISABLEThe pressure turn-off function, even as LD bias current shutoff voltage input V IBOFFBe in high level state, as long as LD drive current shutoff voltage input V DISABLEBe low level, because diode D10 conducting this moment, the pressure drop that produces on R33 makes the base bias voltage reduction of transistor Q20 end until it, and the LD drive current comprises modulated current and bias current, is turn-offed fully.The purpose of described pressure turn-off function is the safety that guarantees the system maintenance personnel.The user can be provided with port at the LD bias current and be external to earth resistance R by one in addition IBThe LD bias current is set.
Photodiode PD and connected trans-impedance amplifier TIA constitute photoelectric switching circuit, the light signal dorsad of laser diode LD is converted to the signal of telecommunication, and a transistor Q22 is connected the pulse voltage signal of output after opto-electronic conversion with the emitter follower that a resistance R 34 constitutes with trans-impedance amplifier TIA direct-current coupling.The positive pole of a detector diode D11 is connected with the output direct-current coupling of described emitter follower.Its negative pole is by detection capacitor C 1 ground connection, a field effect transistor Q23 and a resistance R 35 constitute common-source circuits, the source ground of field-effect transistor Q23 wherein, its drain electrode connects power supply VCC by resistance R 35, and its grid is connected with the negative pole of diode D11.
By above-mentioned connection, described photoelectric switching circuit, described emitter follower, described detector diode, described detection electric capacity, and described commonsource amplifier constitute a comparatively desirable peak-detector circuit, its feature comprises that described trans-impedance amplifier penetrates the pulse voltage signal peak amplitude and described laser diode LD transmission light signal peak power linear correlation with output; Described emitter follower output end voltage quiescent point is lower than the conducting voltage (being about 0.6V) of described detector diode D11; Be that detector diode D11 static state is ended; When described photoelectric switching circuit voltage pulse output signal, its crest value of impulse voltage is superimposed on the quiescent voltage working point, when the two stack amplitude reaches the detector diode conducting voltage, and D11 conducting and to detection capacitor C 1 charging; When described detection capacitor C 1 charging voltage when being higher than the pinch-off voltage of described field effect transistor Q23, the Q23 conducting, its source voltage descends with the rising of detecting circuit input voltage peak amplitude.
By the above-mentioned above-mentioned peak-detector circuit that connects and composes, its feature also comprises: between each assembly of described peak-detector circuit, all adopt direct-current coupling mode (DC coupling), thereby eliminated drift fluctuation of base limit and baseline shift time delay that common employing AC coupled modes are brought; The differential resistance R that just is conducted of described detector diode D11 dBe 100~1000 Ω orders of magnitude, its anti-phase ohmic leakage R BckBe 10 11The Ω order of magnitude, the grid input resistance of described field-effect transistor Q23 is 10 13The Ω order of magnitude.Therefore, when peak-detector circuit applied signal voltage peak value was constant, described detection capacitor C 1 charging voltage maximum was Vs, its detection charge constant R d* C1 (capacitor C 1 voltage from 0V to the 0.68Vs required time) keeps (discharge) time R than detecting circuit Bck* (be detecting circuit when not having input signal, the voltage on the capacitor C 1 is from V for C1 sReduce to 0.68V sThe required time) little 8 orders of magnitude.For example, select C1=6pf, then the charging interval is the ns order of magnitude, and the retention time is the 100ms order of magnitude, thereby makes described peak-detector circuit realize quick detection, and keeps memory for a long time, make its peak detection efficient and input code type and frame structure irrelevant, promptly realize the peak detection of burst.And since its big discharge time constant, promptly big low-pass filtering time constant, and effectively the alternating current component of filtering detection output voltage makes circuit working stable.In fact, in order to be applicable to the peak detection of various frame structures (being various line codes) waveform, the detection charge constant should be less than or equal to about 1/10 of minimum subframe (packet) length, could guarantee to detect peak value, and can ignoring, so the more little approaching more ideal of charge constant with mark rate dependence in the subframe.The detecting circuit retention time then at least should be greater than maximum multi-frame length, and maximum multi-frame limiting length is 50ms, and 50ms is the real-time exchange protect networks time, so no matter under any speed, the retention time is equal to or greater than 50ms and gets final product.Can see that from above-mentioned explanation detection charge constant and detecting circuit retention time constant respectively have its independently requirement, there is no inevitable order of magnitude requirement ratio between the two.But since minimum subframe logical 1/10 usually much smaller than maximum multi-frame limiting length, the detection charge constant needs usually less than detecting circuit retention time 2 orders of magnitude.In the side circuit design,,, the two is difficult for accomplishing so taking into account owing to charging and keeping a shared capacitor.And the detection charging interval of setting in the present invention is several ns, and the retention time is tens to 100ms, has reached preferable effect.
Transistor Q24 and resistance R 36 constitute one first emitter follower, and its input is connected with the source electrode of above-mentioned field-effect transistor Q23.The difference amplifier transistor constitutes a differential comparator amplifier to pipe Q25, Q26 and resistance R 37, R38, R39, wherein the collector electrode of Q25 connects power supply VCC by resistance R 37, the collector electrode of Q26 connects power supply VCC by resistance R 38, and the emitter of Q25 and Q26 is by resistance R 39 ground connection.Two resistance R 40, R41 are connected in series between back cross-over connection power supply VCC and the ground mutually, constitute a resitstance voltage divider, reference voltage is provided, one of two inputs of described differential comparator amplifier be described transistor Q25 base stage with described penetrate with output be that the emitter of transistor Q24 is connected, peak detection voltage is penetrated with the described differential comparator amplifier of feed-in through described.Another input of described differential comparator amplifier is that the base stage of described transistor Q26 is connected with described resitstance voltage divider, to obtain comparison reference voltage (threshold voltage).
The collector electrode output voltage that above-mentioned differential comparator amplifier voltage output end is above-mentioned transistor Q26 sends photopeak value power linear correlation with described laser diode and is inversely proportional in setting range.Just when described laser diode LD sent the increase of photopeak value power, described differential comparator amplifier output voltage reduced, otherwise this voltage raises.
Transistor Q27, its base stage and the voltage output end of above-mentioned differential comparator amplifier are that the collector electrode of above-mentioned transistor Q26 is connected, and its collector electrode connects power supply VCC, and its emitter constitutes the 3rd emitter-base bandgap grading follower by resistance R 42 and R43 series connection ground connection.In addition, the emitter of transistor Q27 is connected with the collector electrode of above-mentioned transistor Q9 by one first isolating diode D12, wherein first negative poles of isolating two sharp pipe D12 are connected with the emitter of above-mentioned transistor Q27, and the positive pole of the first isolating diode D12 is connected with the collector electrode of above-mentioned transistor Q9.Being connected in series o'clock of resistance R 42 and resistance R 43 is connected to the collector electrode of above-mentioned transistor Q17 by one second isolating diode D13, wherein the negative pole of the second isolating diode D13 connects being connected in series a little of R42 and R43, and the positive pole of the second isolating diode D13 is connected with the collector electrode of above-mentioned transistor Q17.A transistor Q28, its base stage and the complementary output end of above-mentioned differential comparator amplifier are that the collector electrode of above-mentioned transistor Q25 is connected, its collector electrode connects power supply VCC, its emitter is by resistance R 44 ground connection, constitute second emitter follower, and draw laser diode transmission photopeak value power monitoring port PW from the emitter of Q28 MONDraw laser diode output photopeak value power setting port APC from the base stage of above-mentioned transistor Q26 SET, the user can arrive earth resistance R by external one of this port APCLaser diode LD is set sends photopeak value power.
By above-mentioned connection, described first emitter follower, described second emitter follower, described the 3rd emitter-base bandgap grading follower, and described differential comparator amplifier constitutes differential ratio than amplifying circuit, described differential ratio than amplifying circuit together with described peak-detector circuit, described photoelectric switching circuit, described laser diode modulated current control circuit with modulated current switch, described laser diode bias current control circuit with bias current switch, and described first and second isolated diode and constituted the transmission photopeak value power that the present invention is used for the optical communication transmitter laser diode drive and control (APC) feedback loop automatically.Its feature comprises: described peak detection comparison amplifier output voltage by penetrating of constituting by described transistor Q27 and resistance R 42, R43 with and diode D12, D13 feed back to described LD modulated current control circuit and described LD bias current control circuit, thereby modulated current and the bias current of control LD, reach the purpose that control LD sends photopeak value power with this, as mentioned above, this feedback voltage and LD send photopeak value power linear correlation and are inversely proportional to, thereby this feedback loop is the voltage negative feedback.The effect of wherein said diode D12 and D13 is the described peak detection comparison amplifier output moment high level pulse that may cause when being isolated in circuit supply power supply VCC switch and external rings interference, make the LD drive current not exceed the maximum of setting, thereby avoid laser diode LD to receive impact injury.Also have above-mentioned feedback control loop both to control the modulated current of laser diode, controlled the bias current of laser diode LD again, usually in most cases only realize the LD transmitted power method of control automatically by the control bias current, its control dynamic range is bigger.Have again, because the negative pole quiescent voltage working point of described diode D13 is lower than the quiescent point of described diode D12, thereby the LD bias current goes into control earlier than the LD modulated current, thereby avoids in control procedure the excessive control of LD modulated current is caused that LD sends light signal dynamic extinction ratio deterioration.
In sum, in the burst laser diode drive of a kind of new structure provided by the invention, an input shaper circuit is used for revising the asymmetric of input differential signal, eliminates the possible relaxation distortion of input signal and improves the standing-wave ratio of input signal.A LD modulated current switch changes voltage signal into current signal and modulated laser diode LD, and a laser diode LD is converted to corresponding light signal with above-mentioned modulated current signal and is sent to the optical transmission media.A LD modulated current control circuit provides modulated current and dynamically controls the LD modulated current according to whole feedback control loop state for LD modulated current switch; LD bias current control circuit with bias current switch provides bias current and dynamically controls the LD bias current according to the state of whole feedback control loop for laser diode LD; A photodiode PD and connected trans-impedance amplifier TIA are converted to voltage signal with the light signal (dorsad) that laser diode sends; Peak-detector circuit with trans-impedance amplifier TIA direct-current coupling detects the voltage signal that sends photopeak value power linear correlation with laser diode LD, its time constant that detects fast (charging interval) only is the ns order of magnitude, its discharge time constant (retention time) reaches the 100ms order of magnitude, and owing to all adopt direct-current coupling (DC coupling) mode between each assembly of this peak-detector circuit, overcome baseline shift fluctuation and the baseline shift that common AC coupling causes and stablized time delay, thereby the reliable and stable peak detection of circuit realization, its detecting circuit and LD send photopeak value power linear correlation and have nothing to do with modulation format and frame structure; A differential comparator amplifier compares and enlarges the output voltage of peak-detector circuit and the comparison reference voltage of setting, it relatively amplifies output voltage and LD and sends photopeak value power linear correlation and be inversely proportional to, this output voltage is fed back to LD modulated current control circuit and LD bias current control circuit, the variable quantity that also is about to LD output photopeak value power is converted into linear correlation and the voltage variety that is inversely proportional to feeds back to the voltage offset electric circuit of LD modulation current source and LD bias current sources, when LD sends the rising of photopeak value power, above-mentioned bias voltage is reduced, otherwise above-mentioned bias voltage is raise, thereby reaching LD transmission peak light power controls automatically, and it is remained in the setting range, the present invention not only is applicable to the optical transmitter of burst, is applicable to that also the light of stochastic equilibrium signal flow sends.
Above embodiment is the unrestricted technical scheme of the present invention in order to explanation only.Any modification or partial replacement that does not break away from spirit and scope of the invention all should be encompassed in the middle of the claim scope of the present invention.

Claims (26)

1. a laser diode drive that is used for optical communication transmitter is characterized in that, comprising:
The input shaper circuit is used for the waveform of differential voltage signal to input and carries out shaping and amplify, with the disequilibrium and the relaxation distortion of the differential signal of eliminating input;
Laser diode modulated current control circuit with modulated current switch, the output, and the laser diode to be driven that connect described input shaper circuit, be used for the signal of described input shaper circuit output is converted into the modulated current signal with positive temperature coefficient, and make described modulated current signal send light pulse signal to drive described laser diode by described modulated current switch;
Have the laser diode bias current control circuit of bias current switch, connect described laser diode, be used for providing bias current with positive temperature coefficient to described laser diode;
Photoelectric switching circuit is used for the light signal dorsad of described laser diode output is converted to the signal of telecommunication;
Peak-detector circuit with described photoelectric switching circuit direct-current coupling, be used for the signal of telecommunication of described photoelectric switching circuit output is carried out quick detection with the output rectified signal, and its detection time constant to the peak value of burst detects so that can realize less than retention time 2 orders of magnitude of rectified signal at least;
With the differential ratio of described peak-detector circuit direct-current coupling than amplifying circuit, it can be exported with described laser diode and send the signal that photopeak value power is relevant and be inversely proportional to, and its output and described laser diode modulated current control circuit, and described laser diode bias current control circuit be connected, to form negative feedback loop, realize control to described bias current and described modulated current.
2. the laser diode drive that is used for optical communication transmitter as claimed in claim 1 is characterized in that: described input shaper circuit comprises the attenuation network that described differential voltage signal is decayed and is connected the differential amplifier of described attenuation network output.
3. the laser diode drive that is used for optical communication transmitter as claimed in claim 2, it is characterized in that: the series circuit of described attenuation network for constituting, the turnover voltage that the peak-to-peak value of the differential signal of its output is put greater than the bipolar transistor difference by the resistance series connection.
4. the laser diode drive that is used for optical communication transmitter as claimed in claim 2 is characterized in that: described differential amplifier comprises a differential pair tube, the constant-current source circuit of electric current is provided, is connected with described constant-current source circuit and is used to compensate the proportional current mirror of described constant-current source circuit temperature characterisitic, is connected described differential pair tube output and separately output signal is fed back to described constant-current source circuit to constitute two emitter followers of direct current negative feedback biasing respectively to described differential pair tube.
5. the laser diode drive that is used for optical communication transmitter as claimed in claim 4 is characterized in that: described constant-current source circuit is made of transistor AND gate resistance, and described proportional current mirror is made of diode and resistance.
6. the laser diode drive that is used for optical communication transmitter as claimed in claim 1, it is characterized in that: described modulated current switch comprises that a transistor is to pipe, wherein, described transistor connects described laser diode to an output, the collector electrode that the base stage of one in the pipe connects described input shaper circuit, and described transistor connects power end to another output, the collector electrode that the base stage of another person in the pipe connects described input shaper circuit.
7. the laser diode drive that is used for optical communication transmitter as claimed in claim 6, it is characterized in that described laser diode modulated current control circuit also comprises: with described transistor the emitter of the two transistor of pipe is connected and be used to provide modulated current the modulated current source circuit, to described modulated current source circuit provide bias voltage the negative feedback serial regulating circuit, and the output of described negative feedback serial regulating circuit is coupled to the emitter follower of described modulated current source circuit.
8. the laser diode drive that is used for optical communication transmitter as claimed in claim 7 is characterized in that: described modulated current source circuit is drawn a laser diode modulated current monitoring side.
9. the laser diode drive that is used for optical communication transmitter as claimed in claim 7 is characterized in that: the input of described emitter follower is drawn a laser diode modulated current and end is set by connecing the resistance of establishing the initial modulation electric current to be set.
10. the laser diode drive that is used for optical communication transmitter as claimed in claim 7, it is characterized in that, described laser diode modulated current control circuit also comprises: be connected described negative feedback serial regulating circuit output, and can make the bias voltage of described negative feedback serial regulating circuit output be lower than the required bias voltage of described modulated current source circuit and then cause described modulated current source circuit not export the drive current complete shut-down deenergizing of modulated current.
11. the laser diode drive that is used for optical communication transmitter as claimed in claim 10, it is characterized in that: described drive current complete shut-down deenergizing is the common emitter circuit of two-stage series connection, and described common emitter circuit is drawn a drive current shutoff voltage input.
12. the laser diode drive that is used for optical communication transmitter as claimed in claim 1, it is characterized in that: described inclined to one side system current switch comprises that a transistor provides the base bias circuit of base bias voltage to pipe with to described transistor respectively to both of pipe, wherein, described transistor is higher than another person's base bias voltage to the base bias voltage of one in the pipe, and the high person's of base bias voltage collector electrode connects described laser diode, and low person's collector electrode connects power end.
13. the laser diode drive that is used for optical communication transmitter as claimed in claim 12, it is characterized in that described laser diode bias current control circuit also comprises: with described transistor the emitter of the two transistor of pipe is connected and be used to provide bias current the bias current source circuit, to described bias current source circuit provide bias voltage the negative feedback serial regulating circuit, and the output of described negative feedback serial regulating circuit is coupled to the emitter follower of described bias current source circuit.
14. the laser diode drive that is used for optical communication transmitter as claimed in claim 13 is characterized in that: described bias current source circuit is drawn a laser diode bias current monitoring side.
15. the laser diode drive that is used for optical communication transmitter as claimed in claim 13 is characterized in that: the input of described emitter follower is drawn a laser diode bias current and end is set by connecing the resistance of establishing the initial bias electric current to be set.
16. the laser diode drive that is used for optical communication transmitter as claimed in claim 13, it is characterized in that, described laser diode bias current control circuit also comprises: be connected described negative feedback serial regulating circuit output, and can make the bias voltage of described negative feedback serial regulating circuit output be lower than the required bias voltage of described bias current source circuit and then cause the not bias current breaking circuit of output offset electric current of described bias current source circuit.
17. the laser diode drive that is used for optical communication transmitter as claimed in claim 16 is characterized in that: described bias current breaking circuit is the common emitter circuit of two-stage series connection, and described common emitter circuit is drawn a bias current shutoff voltage input.
18. the laser diode drive that is used for optical communication transmitter as claimed in claim 17, it is characterized in that: described laser diode modulated current control circuit is drawn modulated current shutoff voltage control end, described bias current shutoff voltage control end is connected by a unidirectional isolating diode with described drive current complete shut-down outage pressure-controlled end, so that described bias current breaking circuit does not exert an influence to described drive current complete shut-down deenergizing when turn-offing.
19. the laser diode drive that is used for optical communication transmitter as claimed in claim 1 is characterized in that: described photoelectric switching circuit comprises a photodiode and and the trans-impedance amplifier of described photodiode direct-current coupling.
20. the laser diode drive that is used for optical communication transmitter as claimed in claim 1, it is characterized in that described peak-detector circuit comprises: the emitter follower of the described photoelectric switching circuit output signal of direct-current coupling, detector diode, the detection electric capacity that is connected with described detector diode and be connected and comprise the commonsource amplifier of field-effect transistor with described detection electric capacity with described emitter follower direct-current coupling.
21. the laser diode drive that is used for optical communication transmitter as claimed in claim 20, it is characterized in that: the charge constant that described detection electric capacity and described detector diode conducting resistance constitute is several ns orders of magnitude, and the discharge time constant that the reverse off-resistances of described detection electric capacity and described detector diode constitutes is tens ms orders of magnitude.
22. the laser diode drive that is used for optical communication transmitter as claimed in claim 1, it is characterized in that, described differential amplifier circuit comprises: first emitter follower that is connected described peak-detector circuit output, be connected with the described first emitter follower output and comprise the differential comparator amplifier that differential pair tube constitutes, reach second emitter follower and the 3rd emitter-base bandgap grading follower that are connected respectively with two outputs of described differential pair tube, the input of one in the wherein said differential pair tube connects described first emitter follower, another person's input connects reference voltage, and the output that connects the reference voltage person can be exported voltage relevant with described laser diode transmission photopeak value power and that be inversely proportional to.
23. the laser diode drive that is used for optical communication transmitter as claimed in claim 22 is characterized in that: in described differential pair tube, connect the reference voltage person and draw laser diode output photopeak value power setting end.
24. the laser diode drive that is used for optical communication transmitter as claimed in claim 22, it is characterized in that: in described differential pair tube, it draws laser diode transmission photopeak value power monitoring end by described second emitter follower to connect the described first emitter follower person.
25. the laser diode drive that is used for optical communication transmitter as claimed in claim 22 is characterized in that: described differential ratio comprises also that than amplifying circuit negative pole is connected described the 3rd emitter-base bandgap grading follower and anodal first isolating diode and the negative pole that is connected described laser diode modulated current control circuit is connected described the 3rd emitter-base bandgap grading follower and anodal second isolating diode that is connected between the described laser diode bias current control circuit.
26. the laser diode drive that is used for optical communication transmitter as claimed in claim 25, it is characterized in that: the negative pole quiescent voltage working point of described second isolating diode is lower than the quiescent point of described first isolating diode, so that bias current is gone into control earlier than modulated current.
CN2009101973214A 2009-10-16 2009-10-16 Laser diode driver for optical communication transmitter Expired - Fee Related CN101692521B (en)

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CN113644541B (en) * 2021-06-21 2022-07-12 义乌协同创新研究院 Direct modulation laser driving circuit for high-speed photoelectric interconnection

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