JPH0560695B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an analog modulation circuit for a laser diode that modulates and outputs an analog signal into an optical signal.

[Conventional technology]

Figure 3 shows, for example, Japanese Unexamined Patent Publication No. 57-135535.
-14936) This is a circuit diagram of a conventional analog modulation circuit for a laser diode shown in the publication. In the figure, 1 is a laser diode whose cathode is grounded, and 2 is a laser diode whose output is connected to the anode of this laser diode 1. A laser diode drive circuit, 3 is an analog signal input terminal connected to the input of this laser diode drive circuit 2, 4 is a high frequency signal generator that generates a high frequency signal for modulation, and 5 is an output of this high frequency signal generator 4. A coupling capacitor 15 inserted between the anode of the laser diode 1 and the anode of the laser diode 1 is a light receiving element that is connected to a laser diode drive circuit and receives a part of the optical output of the laser diode 1.

The laser diode drive circuit 2 adds an analog signal current input from an analog signal input terminal 3 to a DC bias current below a threshold current and supplies the resultant to the laser diode 1, and also outputs an optical output signal received by a light receiving element 15. The optical output signal of the laser diode 1 is stabilized by performing negative feedback control using the monitor signal. The optical output signal stabilizing circuit described above is described in Japanese Patent Application Laid-open No. 81739/1983.

Next, the operation will be explained. Generally, when a longitudinal single-mode laser diode that oscillates at a single wavelength is modulated with an analog signal current and the signal is transmitted using a multimode optical fiber, the above-mentioned Interference between propagation modes within the optical fiber generates an inter-mode interference pattern, which fluctuates due to fluctuations in the oscillation wavelength of the light source, vibrations of the optical fiber, and the like. For this reason,
Modal noise caused by this causes distortion deterioration and S/N deterioration of the received signal. In order to prevent the above modal noise, it is necessary to make the laser diode oscillate at multiple wavelengths to reduce coherence. One effective method is to set the DC bias current of laser diode 1 to a threshold value. A method is known in which the analog signal current is set to a value equal to or lower than the analog signal current and a high frequency signal current of several 100 MHz is superimposed on the analog signal current. FIG. 4 is an explanatory diagram of the operation of the analog modulation circuit for the laser diode shown in FIG. 3 based on the above method. In FIG. 4, A is the current vs. optical output characteristic of the laser diode, B is the analog signal current, C is the threshold current, D is the DC bias current, and O is the optical output signal. Corresponding to the above-mentioned high-frequency signal current is a high-frequency current F on which the analog signal current A is superimposed, and this high-frequency current F is biased to the operating point of the laser diode 1 by the DC bias current E. As described above, the laser diode 1 oscillates in longitudinal multimode, suppressing deterioration of transmission characteristics during multimode fiber transmission due to the modal nozzle, and thereby realizing stable analog signal transmission.

[Problem that the invention seeks to solve]

Since the conventional analog modulation circuit of a laser diode is configured as described above, the output high frequency signal of the high frequency signal generator 4 is inputted to the laser diode 1 via the coupling capacitor 5. When using a diode, if you try to set the high-frequency current amplitude so as to obtain a predetermined optical output with the DC bias current set below the threshold current, in extreme cases the negative peak value of the superimposed high-frequency current may occur. There was a problem in that the laser diode could become reverse biased if it became less than 0, resulting in deterioration of characteristics and lifespan.

Furthermore, since the high-frequency current amplitude applied to the laser diode 1 is always constant, fluctuations in the differential quantum efficiency of the laser diode 1 due to changes in ambient temperature result in fluctuations in the average optical output, which is incorporated in the laser diode drive circuit 3. If an attempt was made to stabilize the optical output using the optical output stabilizing circuit, the DC bias current would change, resulting in the problem that the high frequency superimposition conditions could not be kept constant despite changes in ambient temperature.

This invention was made to solve the above-mentioned problems, and the negative peak value of the superimposed high-frequency current becomes 0 or less, so that the laser diode is not reverse biased, and the drive current of the laser diode is The object of the present invention is to obtain an analog modulation circuit for a laser diode that can drive the laser diode under stable and constant high-frequency superimposition conditions without being affected by changes in output characteristics due to ambient temperature changes or variations between elements.

[Means for solving problems]

The analog modulation circuit for a laser diode according to the present invention is provided with a high frequency amplitude limiting circuit to limit the negative peak value of the high frequency current so that it does not become less than a predetermined positive current value.

Further, the amplitude of the superimposed high-frequency current is controlled according to temperature changes in the differential quantum efficiency of the laser diode, and the amplitude is limited so that the negative peak value of the high-frequency current does not become less than a predetermined positive current value.

[Effect]

The high frequency amplitude limiting circuit in the present invention limits the amplitude so that the negative peak value of the high frequency current does not become less than a predetermined positive current value.

In addition, by detecting changes in the differential quantum efficiency of the laser diode and controlling the high-frequency current amplitude input to the laser diode according to the detection signal, the optical output amplitude after current-light conversion can be adjusted to the superimposed high frequency by changing the temperature. is kept constant.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings. In Figure 1, 1 to 4 and 15 are the third
This is equivalent to the conventional laser diode analog modulation circuit shown in the figure. 6 is an analog signal current monitor resistor connected between the output terminal of the laser diode drive circuit 2 and the anode of the laser diode 1; 7 is a differential amplifier that amplifies the difference in voltage across the analog signal current monitor resistor 6; 8 is a peak detector that detects the peak value of the output of the differential amplifier 7; 9 is a differential amplifier that amplifies the difference between the output signal of the peak detector 8 and a predetermined reference voltage Vr applied to the reference voltage input terminal 10; amplifier, 1
1 is a variable attenuator whose attenuation changes according to the output voltage of the differential amplifier 9; 12 is a high frequency amplitude limiting circuit that clips the high frequency voltage (current) input from the variable attenuator 11; 13 is a high frequency amplitude limiting circuit. 12
is a reference voltage (current) input terminal to which a predetermined clipping voltage (current) for performing clipping is input.

The monitor resistor 6, differential amplifier 7, peak detector 8, differential amplifier 9, and variable attenuator 11 constitute a high frequency signal amplitude control circuit 14.

Next, the operation of the laser diode analog modulation circuit of this embodiment configured as described above will be explained. Here, the laser diode drive circuit 2 includes a negative feedback control circuit using a monitor signal from the light receiving element 15 in order to keep the average optical output and analog signal output amplitude constant, as in the conventional example shown in FIG. The following explanation will be given assuming that the optical output stabilizing circuit is built-in. The optical output stabilizing circuit is as described in Japanese Patent Application Laid-Open No. 57-81739.
1 laser diode to 15 laser diodes
is provided, and the laser diode 15 detects the light from the laser diode 1.

The laser diode drive circuit 2 controls the amplitude of the analog signal current input to the laser diode 1 in order to control the amplitude of the analog signal light to always remain constant even if the differential quantum efficiency of the laser diode 1 changes due to temperature. will increase or decrease in inverse proportion to the change in differential quantum efficiency. Therefore, by monitoring the analog signal current, changes in the differential quantum efficiency of the laser diode 1 can be detected. The resistor 6 is a monitor resistor for this purpose, and the voltage across it is amplified by a differential amplifier 7 and then applied to a peak detector 8, and its peak value is detected and output to a differential amplifier 9. Ru. A differential amplifier 9 uses the output voltage of the peak detector 8 and a predetermined reference voltage input to a reference voltage input terminal 10.
The voltage difference with Vr is output to the variable attenuator 11 as an attenuation control voltage. The variable attenuator 11 changes the amount of attenuation according to the control voltage, thereby changing the amplitude of the high frequency current applied from the high frequency signal generator 4 to the laser diode 1.

Through the above series of operations, laser diode 1
Since the amplitude of the superimposed high-frequency optical signal output from the laser diode 1 is controlled to remain constant even if the differential quantum efficiency changes, the laser diode 1 can be operated under stable and constant high-frequency superposition conditions even when the ambient temperature changes. It becomes possible to drive.

On the other hand, the high frequency amplitude limiting circuit 12 is configured such that the peak value of the superimposed high frequency voltage (current) inputted from the variable attenuator 11 is higher than a predetermined positive clip voltage (current) inputted to the reference voltage (current) input terminal 13. It is output to the laser diode 1 after being clipped so as not to become small. As a result, even if the high-frequency current amplitude changes, its negative peak value will always remain below a predetermined positive current value, so even when using a laser diode with a low threshold current, there is no risk of a reverse bias state. This makes it possible to drive under stable high frequency superimposition conditions.

FIG. 2 is an explanatory diagram of the operation of the analog modulation circuit for a laser diode according to an embodiment of the present invention shown above. In the figure, A to A are the same as those shown in FIG. The key is the clip current set point. As the ambient temperature decreases, the threshold current C of the laser diode 1 generally decreases, as shown in FIG. 2, and the differential quantum efficiency, which corresponds to the slope of the current vs. optical output characteristic A, increases. By controlling the amplitude of the high frequency current, the optical output signal is kept constant over temperature changes. Further, since the negative peak of the high frequency current force is clipped at the clip current setting point key, application of a reverse bias current to the laser diode 1 is prevented.

In the above embodiment, the cathode of the laser diode is grounded, but the anode may be grounded. It goes without saying that the same effect can be obtained by using a variable gain amplifier instead of the variable attenuator 11.

〔Effect of the invention〕

As described above, according to the present invention, the high frequency signal amplitude control circuit controls the optical output amplitude of the superimposed high frequency to be constant with respect to changes in ambient temperature, and the high frequency amplitude limiting circuit controls the negative peak of the high frequency current. Since the value is clipped so that it does not fall below a predetermined positive current value, it is possible to operate under stable and constant high-frequency superimposition conditions without being affected by temperature changes in the drive current vs. optical output characteristics of the laser diode or differences between elements. This has the effect of providing an analog modulation circuit that can drive a laser diode.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of an analog modulation circuit for a laser diode according to an embodiment of the present invention, FIG. 2 is an explanatory diagram of the operation of the analog modulation circuit for a laser diode shown in FIG. 1, and FIG. 3 is a diagram of a conventional laser diode analog modulation circuit. FIG. 4 is an explanatory diagram of the operation of the conventional analog modulation circuit for a laser diode shown in FIG. 3. 1 is a laser diode, 2 is a laser diode drive circuit, 3 is an analog signal input terminal, 4 is a high frequency signal generator, 5 is a coupling capacitor, 6 is an analog signal current monitor resistor, 7 is a differential amplifier, 8 is a peak detector , 9 is a differential amplifier, 10 is a reference voltage input terminal, 11 is a variable attenuator, 12 is a high frequency amplitude limiting circuit, 13 is a reference voltage (current) input terminal, 14
1 is a high frequency signal amplitude control circuit, and 15 is a light receiving element. In addition, in the figures, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Claims] 1. A laser diode and a high-frequency signal generator that generates a high-frequency signal of a predetermined frequency or higher, superimposes an analog signal from an analog signal input terminal on the high-frequency signal, and generates the high-frequency superimposed signal. In the analog modulation circuit of the laser diode that inputs modulation, the optical signal converted by the laser diode is input, and the laser diode drive controls the amplitude of the analog signal from the analog signal input terminal based on the output value of this optical signal. The circuit inputs the output of this laser diode drive circuit, detects a change in the differential quantum efficiency of the laser diode based on the input analog signal, and changes the high frequency signal of the high frequency signal generator according to the detection result. a high frequency signal amplitude control circuit that controls the amplitude; a high frequency amplitude limit circuit that limits the amplitude so that the peak value of the output of the high frequency signal amplitude control circuit does not become less than a predetermined positive value; this high frequency amplitude limit circuit and the laser. 1. A laser diode analog modulation circuit comprising: a laser diode that inputs a signal on which an output from a diode drive circuit is superimposed and converts the superimposed signal into an optical signal.