JPH0638532B2 - Laser diode drive circuit - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a laser diode drive circuit that drives a laser diode based on a pulse signal so as to emit a light pulse.

[Prior art]

Conventionally, a laser diode drive circuit described below with reference to FIG. 4 has been proposed. That is, one end (anode) of the laser diode 1 is
One end (negative polarity end) is connected to the other end (positive polarity end) of the DC power supply 2 connected to ground, and the other end (cathode) is connected to ground through the DC bias current supply circuit 3 having a control end. As a result, the DC bias current supply circuit 3 supplies the current from the DC power supply 2 to the laser diode 1
And is supplied as a DC bias current I _B. Further, since the other end (cathode) of the laser diode 1 is connected to the ground through the switch circuit 5 and the pulse current supply circuit 6 which are on / off controlled by the pulse signal PS from the pulse signal source 4, current supply circuit 6, a current from the DC power source 2 to the ,, laser diode 1, through the switch circuit 5 is configured so as to supply the pulse current I _P. Further, the optical pulse L emitted from the laser diode 1
Photoelectric conversion element 7 such as a photodiode for receiving P
Is connected to the other end (positive end) of the DC power supply 2 described above, the other end is connected to the ground through the optical pulse power detection circuit 8, and the output end is derived from the optical pulse power detection circuit 8. The output terminal is connected to the control terminal of the DC bias current supply circuit 3 described above, so that the photoelectric conversion element 7 and the optical pulse power detection circuit 8 constitute the control signal generation circuit 9, and the control thereof is performed. The signal generation circuit 9
The above-mentioned DC bias current I _B supplied to the laser diode 1 from the above-mentioned DC bias current supply circuit 3 is
The control signal D for controlling the DC bias current supply circuit 2 is generated so that the electric power of the optical pulse LP emitted from the laser diode 1 can be obtained with a value that keeps the electric power constant. The above is the configuration of the conventionally proposed laser diode drive circuit. According to the laser diode driving circuit having such a configuration, the DC bias current supply circuit 3 supplies the laser diode 1 with the current from the DC power supply 2 as the DC bias current I _B and the pulse current supply circuit. 6, the power from the DC power supply 2 is supplied via the switch circuit 5 as the pulse current I _P superimposed on the DC bias current I _B , so that the optical pulse LP is emitted from the laser diode 1. can get. In this case, the light pulse LP emitted from the laser diode 1 receives the light receiving element 7 which constitutes the control signal generating circuit 9.
Since it is incident on, a current according to the power of the light pulse LP is
From the DC power supply 2 through the light receiving element 7, the light pulse power detection circuit 8 constituting the control signal generation circuit 9 flows, which is detected by the light pulse power detection circuit 8 and controlled based on the detection output. The signal D from the control signal generation circuit 9
It is supplied to the control end of the DC bias current supply circuit 3. For this reason, in general, the laser diode 1 makes the current supplied to it generally I, and the laser diode 1
The power of the light emitted from the laser diode is generally P, and the absolute temperature for the laser diode 1 is generally low T _1.
When the temperature is set to a high temperature T ₂ , the current I vs. power P characteristics having the temperatures T ₁ and T ₂ as parameters, as shown in FIG. 5, are provided, so that the laser diode 1 is switched by the pulse current supply circuit 6. The pulse currents I _P (when they are respectively I and _P) when the temperature T supplied to the laser diode 1 via the circuit 5 is low T ₁ and high T _2.
P1 and I _P2 ) both rise at the same time point t ₁ , fall at the next same time point t ₂ , rise at the next same time point t ₃ , and next same time point t _{4 as shown in FIG.} Then fall ...
... And assuming that the pulse currents have the same amplitude, the optical pulse LP when the temperature T for the laser diode 1 is a low temperature T ₁ and a high temperature T ₂ (they are referred to as LP ₁ and LP ₂ , respectively) However, as shown in FIG. 5, the temperature T for the laser diode 1 is low T
_Whether it is ₁ or high temperature T ₂ ,
When the value of the DC bias current I _B is obtained with a value I _B2 which is approximately equal to the threshold current I _t2 of the laser diode 1 when the temperature T for the laser diode 1 is a high temperature T ₂ , the temperature T for the laser diode 1 is Low temperature T ₂
In this case, a value I _B1 that is sufficiently lower than the threshold current I _t1 of the laser diode 1 is obtained, so that the laser beam is emitted with a constant power value P ₀ . Therefore, the optical pulse L emitted from the laser diode 1
P has a characteristic that it can be obtained at a constant power value P ₀ even if the temperature T for the laser diode 1 changes.

[Problems to be Solved by the Invention]

However, in the case of the conventional laser diode drive circuit shown in FIG. 4, even when the temperature T for the laser diode 1 supplied through the switch circuit 5 to the laser diode 1 is changed by the pulse current supply circuit 6,
Since the pulse current _IP has a constant amplitude,
When the optical pulse LP ₂ obtained when the temperature T for the laser diode 1 is the high temperature T ₂ is obtained by rising at the time points t ₁ , t ₃ ..., At which the pulse current I _P2 rises,
The light pulse LP ₁ obtained when the temperature T for the laser diode 1 is a low temperature T ₁ is a time t ′ ₁ , which is delayed from a time t ₁ , t ₃ ..., At which the pulse current I _P1 rises,
It obtained me rising at t _'3 .......... The reason is that the luminous efficiency η of the laser diode 1 is η = η ₀ · exp (−T / T ₀ ) ... (1) (where η ₀ is a constant, T is the absolute temperature of the laser diode, T ₀ is a characteristic temperature having a value of 100 ° K to 500 ° K)
Therefore, even though the luminous efficiency η has a temperature dependency that is large when the temperature T with respect to the laser diode 1 is high, even if the temperature T with respect to the laser diode 1 changes, Since the value of the bias current I _B is controlled so that the light pulse LP is emitted at the constant power value P ₀ , the DC bias current I _B is set when the temperature T for the laser diode 1 is a high temperature T _2.
When the value I _B1 of the DC bias current I _B is equal to the threshold current I _{t2 at} this time and the temperature T for the laser diode 1 is the low temperature T ₁ , the value I _B2 of the DC bias current I _B becomes _This is because the value becomes lower than _t1 and the laser diode 1 has an oscillation delay effect and a relaxation oscillation effect. Therefore, the present invention proposes a novel laser diode driving circuit which does not have the above-mentioned points.

[Means for Solving the Problems]

The laser diode drive circuit according to the present invention is similar to the case of the conventional laser diode drive circuit described above with reference to FIG. 4. (a) DC bias current supply for supplying the laser diode with the current from the DC power supply as the DC bias current. The circuit, the pulse current supply circuit for supplying the laser diode with the current from the DC power supply as a pulse current through the switch circuit, and the power of the optical pulse emitted from the laser diode are detected, and the detection output is also detected. As a result, the DC bias current supplied to the laser diode from the DC bias current supply circuit is
And a control signal generation circuit for generating a control signal for controlling the DC bias current supply circuit so that the power of the optical pulse emitted from the laser diode can be obtained with a value that reduces the power to a constant value. However, the laser diode drive circuit according to the present invention is a laser diode drive circuit having such a configuration, in which (b) the pulse current supply circuit connects the emitter to one end of the pulse current supply circuit through a constant current source, A first transistor having a collector connected to the other end of the pulse current supply circuit and a base connected to a first base voltage generating means for generating a first base voltage; and an emitter connected through the constant current source. A second base which is connected to one end of a pulse current supply circuit, a collector is connected to a constant voltage source, and a base produces a voltage having a positive temperature dependency when viewed as a difference voltage between the base and the first base voltage. A second transistor connected to second base voltage generating means for generating a voltage.

[Action / effect]

The laser diode drive circuit according to the present invention has the same configuration as the conventional laser diode drive circuit described above with reference to FIG. 4 except for the above-mentioned matters. The current from the power supply is supplied as a DC bias current, and the pulse current supply circuit supplies the current from the DC power supply as a pulse current by superimposing it on the DC bias current via the switch circuit. An optical pulse is emitted from the laser diode and obtained. Further, in this case, the DC bias current supply circuit supplies the laser diode from the DC bias current supply circuit to the laser diode by the control signal from the control signal generation circuit, as in the case of the conventional laser diode drive circuit described in FIG. The direct current bias current is controlled so that the power of the optical pulse emitted from the laser diode is obtained at a constant value. Therefore, as in the case of the conventional laser diode drive circuit described above with reference to FIG. The light pulse emitted from the laser diode can be obtained with a constant power value even if the temperature of the laser diode changes. However, according to the laser diode drive circuit of the present invention, since the pulse current supply circuit has the above-mentioned configuration (b), the difference between the first and second base voltages applied to the bases of the first and second transistors is increased. Can have a value corresponding to a change in temperature with respect to the laser diode, so that the current flowing through the first transistor and hence the pulse current flowing through the laser diode is
It is possible to make the amplitude value have temperature dependence. Therefore, even if the temperature of the laser diode changes, the rise time of the optical pulse emitted from the laser diode with respect to the pulse current does not change.

【Example】

Next, an embodiment of the laser diode drive circuit according to the present invention will be described with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed description thereof will be omitted. The laser diode drive circuit according to the present invention shown in FIG. 1 has the same configuration as the conventional laser diode drive circuit described above with reference to FIG. 4, except that the pulse current supply circuit 6 has the configuration described below. . That is, the pulse current supply circuit 6 connects the emitter to the ground, which is one end of the pulse current supply circuit 6, through the constant current source 11, and connects the collector to the switch circuit 5 side, which is the other end of the pulse current supply circuit 6. , An npn-type transistor 13 whose base is connected to the base voltage generation circuit 12
Have. In addition, the constant voltage source 1 in which the emitter is connected to the ground which is one end of the pulse current supply circuit 6 through the constant current source 11 described above, and the collector is connected to the ground at one end (negative polarity end)
4 is connected to the other end (the positive polarity end) and the base is connected to another base voltage generating circuit 12 '. In this case, in the base voltage generating circuit 12, a series circuit of a resistor 15, an npn-type transistor 16 and another resistor 17 is connected to both ends of the constant voltage source 14, and the base is connected to both ends of the constant voltage source 14 by a transistor. It has a configuration in which a series circuit of a level shift transistor 18, a level shift diode 19, and a constant current source 20 connected to a connection midpoint of 16 and a resistor 15 is connected. In the base voltage generating circuit 12 ', a series circuit of a resistor 15', an npn-type transistor 16 'and another resistor 17' is connected to both ends of the constant voltage source 14, and the constant voltage source 14 'is also connected.
The bases of the transistor 16 'and the resistor 15' are provided at both ends of the
Level shift transistor 18 ', level shift diode 19', and constant current source 2 connected to the connection middle point of
It has a configuration in which a series circuit with 0'is connected. Further, a series circuit of a constant current source 21, a transistor 22 having a base connected to the collector, and a transistor 23 having a base similarly connected to the collector is connected to both ends of the constant voltage source 14, and a constant current is supplied. The midpoint of connection between the source 21 and the transistor 22 is connected to the base of the transistor of the base voltage generating circuit 12, and the transistor 22
And 23 are connected to the base of the transistor 16 'of the base voltage generating circuit 12'. The above is the configuration of the embodiment of the laser diode drive circuit according to the present invention. With such a configuration, the difference voltage between the voltage applied from the base voltage generation circuit 12 to the base of the transistor 13 and the voltage applied from the base voltage generation circuit 12 'to the base of the transistor 13' becomes 23, the base-emitter voltage of the transistor used in the base voltage generating circuits 12 and 12 ', the voltage across the diodes 19 and 19', etc. have a negative temperature coefficient. It has a positive temperature dependency by, for example, making the emitter area of ′ ′ sufficiently larger than that of the transistor 23 and allowing a current having a value close to the current flowing in the constant current source 21 to flow in the transistor 16 ′. be able to. Therefore, the pulse current I _P supplied from the pulse current supply circuit 6 to the laser diode 1 through the switch circuit 5
Can be obtained as having a positive temperature dependence. Therefore, the value of the pulse current I _P can be changed according to the temperature for the laser diode 1 as shown in FIGS. 2 and 3. Therefore, as shown in FIG. 3, even if the temperature with respect to the laser diode 1 changes, the laser diode emits an optical pulse having a constant amplitude and having no change in the rise time with respect to the pulse current I _P. You can

[Brief description of drawings]

FIG. 1 is a connection diagram showing an embodiment of a laser diode drive circuit according to the present invention. FIGS. 2A and 2B are diagrams showing the relationship between the temperature (° C.) of the laser diode and the value I _P (mA) of the pulse current supplied to the laser diode with respect to the explanation. FIG. 3 is provided for explaining the operation of the laser diode drive circuit according to the present invention shown in FIG. 1, and the power P of the light emitted from the laser diode with respect to the current I supplied to the laser diode with the temperature for the laser diode as a parameter. FIG. 3 is a diagram showing the relationship between the pulse current supplied to the laser diode and the power of the optical pulse emitted from the laser diode with respect to the pulse current supplied to the laser diode. FIG. 4 is a systematic connection diagram showing a conventional laser diode drive circuit. FIG. 5 is a view similar to the case of FIG. 3 of the laser diode drive circuit shown in FIG. 1 ... Laser diode 2 ... DC power supply 3 ... DC bias current supply circuit 4 ... Pulse signal source 5 ... Switch circuit 6 ... Pulse current supply circuit 7 ... Photoelectric conversion element 8 ... Optical pulse power detection circuit 9 ... Control signal generating circuit 11 ... Constant current source 12, 12 '... Base voltage generating circuit 13, 13' ... Transistor 14 ... Constant voltage source 15, 15 '... Resistor 16, 16' ... Transistor 17, 17 '... Resistor 18, 18' ... Level shift transistor 19, 19 '... Level shift diode 20 ... Constant current source 21 ... Constant current source 22 ... Transistor 23 ... Transistor

Claims (1)

[Claims] 1. A DC bias current supply circuit for supplying a laser diode with a current from a DC power supply as a DC bias current, and a pulse for supplying the laser diode with a current from the DC power supply as a pulse current through a switch circuit. The DC bias current detected by the current supply circuit and the power of the light pulse emitted from the laser diode and supplied to the laser diode from the DC bias current supply circuit based on the detection output is the laser. A laser diode drive circuit having a control signal generation circuit for generating a control signal for controlling the DC bias current supply circuit so that the power of an optical pulse emitted from a diode can be obtained with a value that reduces the power to a constant value. The pulse current supply circuit causes the emitter to pass through the constant current source. Connected to one end of the scan current supply circuit, a collector connected to the other end of the pulse current supply circuit, the base first
A first transistor connected to a first base voltage generating means for generating a base voltage of, and an emitter connected to one end of the pulse current supply circuit through the constant current source,
A second base voltage generator that connects a collector to a constant voltage source and generates a second base voltage that produces a voltage having a positive temperature dependence when the base is viewed as a voltage difference between the first base voltage and the first base voltage. And a second transistor connected to the means.