KR20030008725A - Opitical transmitter having control circuit for optical power/wavelength stability using integrated chip - Google Patents

Abstract

PURPOSE: An optical transmitter having an optical strength/wavelength stability control circuit using an integrated chip is provided to reduce its size by using elements composed in the optical strength/wavelength stability control circuit as the integrated chip. CONSTITUTION: A laser diode module(30) outputs a wavelength of a laser diode. An optical strength/wavelength stability control unit(34) performs a control operation for stably transmitting the wavelength outputted from the laser diode module(30), and elements for unifying an optical strength are composed as an integrated chip in the optical strength/wavelength stability control unit(34). A microprocessor(31) sets a reference voltage when the internal portion of the laser diode module(30) is at a normal temperature. The optical strength/wavelength stability control unit(34) compares a voltage of a thermistor which senses an increased/decreased temperature of the laser diode with the reference voltage set in the microprocessor(31) and outputs the compared result value. A TEC(Thermo Electric Cooling module) driving unit(32) adjusts a current quantity supplied to a TEC which cools and heats the laser diode according to the result value outputted from the optical strength/wavelength stability control unit(34), maintains a temperature of the laser diode as the normal temperature, and stabilizes the wavelength of the laser diode. The optical strength/wavelength stability control unit(34) compares a current quantity which flows in a photo detector with the reference voltage set in the microprocessor(31) and outputs the compared result value. A laser diode driving unit(33) controls a driving current supplied to the laser diode according to the compared result value outputted from the optical strength/wavelength stability control unit(34), and uniformly maintain the optical strength of the laser diode.

Description

Optical transmitter having control circuit for optical power / wavelength stability using integrated chip

The present invention relates to an optical transmitter, and more particularly, to an optical transmitter having an optical intensity / wavelength stabilization control circuit using an integrated chip.

In general, an optical transmitter is used to modulate a desired signal by turning on / off the laser diode itself in case of direct modulation, and modulating a signal by turning on / off light generated by the laser diode using an external modulator. Therefore, it consists of a light emitting element, an electric signal generating element and an amplifying element for modulating light.

In particular, the optical transmission device of the wavelength division multiplexing system (WDM) should be transmitted while the wavelength of each channel is stably transmitted and the light intensity is kept constant.

However, if the wavelength is not transmitted stably in the WDM optical transmission device, a change in the light intensity occurs when passing through the optical device, and the intensity of the output light source of the multi-channel optical amplifier for wavelength division multiplexing changes to cause nonlinearity in the optical fiber. This reduces the signal-to-noise ratio of the optical signal, which affects the performance of the system.

Therefore, in order to prevent a change in the wavelength of the light source, the optical transmitter should basically have a control circuit and a light intensity control circuit for stabilizing the wavelength.

Hereinafter, a control circuit and a light intensity control circuit for stabilizing wavelengths conventionally used will be described.

1 is a block diagram showing a conventional control circuit for wavelength stabilization.

First, as shown in FIG. 1, the conventional control circuit 100 for wavelength stabilization includes a laser diode module 10 for outputting a wavelength of a laser diode; A reference voltage generator (11) for setting a reference voltage which is a voltage when the temperature of the laser diode becomes room temperature; A comparator (12) for comparing the reference voltage set by the reference voltage generator (11) with a voltage when the temperature of the laser diode rises / falls from room temperature; According to the output of the comparator 12 is composed of a TC drive unit 13 for driving the TEC (thermoelectric cooling module) of the laser diode.

Also, a detailed block diagram of the laser diode module 10 is shown in FIG. 3, which is a laser diode 101 used as a light source of an optical transmitter and a photo detector (PD) for monitoring the wavelength of the laser diode. detector 102; A thermistor (103) for sensing the temperature of the laser diode; The thermistor is configured by a TC (104) for detecting when the laser diode rises / falls below room temperature, and adjusts the laser diode to room temperature.

In order for the control circuit 100 to stabilize the wavelength configured as described above to operate, first, the temperature of the laser diode 101 when the wavelength is stably transmitted must be sensed.

The thermistor 103 located inside the laser diode module 10 is used to sense the temperature.

The voltage value NORTHM measured by the thermistor 103 and the generated voltage value of the reference voltage generator 11 are set using the variable resistor.

The operation of the control circuit 100 to stabilize the wavelength after the above process will be described.

If the temperature of the laser diode 101 rises or falls below room temperature by the internal and external environment during the process of transmitting the wavelength in the laser diode 101 of the optical transmitter, the cavity refractive index inside the laser diode is changed to oscillate. The wavelength changes and eventually the wavelength cannot be transmitted stably.

Therefore, the temperature of the laser diode 101 should be at room temperature. The above-mentioned means that the thermistor 103 inside the laser diode module 10 senses that the laser diode 101 rises / falls below room temperature. The voltage value THM of the sensed temperature is output.

The output voltage value THM and the reference voltage NORTHM set in the reference voltage generator 11 are input to the comparator 12 and compared.

Therefore, the voltage value output from the comparator 12 is input to the TC driver 13, and the amount of current supplied to the TSC 104 of the laser diode varies according to the voltage value, so that the temperature of the laser diode 101 is varied. By keeping at room temperature, the wavelength can be stably output.

2 is a block diagram showing a control circuit 200 for making a conventional light intensity constant.

As shown in FIG. 2, the control circuit 200 for keeping the light intensity constant includes a laser diode module 20 for outputting a wavelength of the laser diode; The same reference voltage generator 21 as that used in the control circuit used for stabilizing the wavelength; A comparison unit 22 for comparing the reference voltage generated by the reference voltage generator 21 with the amount of current flowing through the photodetector inside the laser diode 10; The laser diode driver 23 controls the driving current supplied to the laser diode 20 according to the voltage value output through the comparator 22.

In order to operate the light intensity control circuit configured as described above, first, the current value flowing through the photo detector 102 when the light intensity becomes constant is monitored. Monitored The amount of current is converted into a voltage value NORPD, and the voltage generated by the reference voltage generator 11 is set according to the value.

It will be described that the light intensity control circuit 200 operates after the above process.

When the wavelength is transmitted from the laser diode 101 of the optical transmitter, a time when the intensity of the light generated by the laser diode 101 may not be constantly output may occur.

At this time, the current value PD flowing through the photo detector 102 for detecting light intensity and the reference voltage NOR PD generated by the reference voltage generator 21 are compared through the comparator 22.

Therefore, the voltage value output from the comparator 22 is input to the laser diode driver 23, and the driving current supplied to the laser diode 101 varies according to the voltage value, so that the light intensity can be made constant. have.

However, as described above, the control circuit and the light intensity control circuit for stabilizing the wavelength require a large amount of operational amplifiers and passive elements (resistors, capacitors) and the like, which causes a problem of increasing size.

In addition, the method of changing the light intensity / wave length in the light intensity / wavelength stabilization control circuit has been inconvenient for work because it sets the reference voltage by manually adjusting by the user.

Accordingly, an object of the present invention to solve such a problem is to provide a device provided in the wavelength stabilization control circuit and the light intensity control circuit for wavelength stabilization in an integrated chip.

In addition, the method of changing the light intensity / wavelength used in the light intensity / wavelength stabilization control circuit is connected to a microprocessor to provide digital adjustment.

1 is a block diagram showing a control circuit for wavelength stabilization in a conventional optical transmitter.

2 is a block diagram showing a light intensity control circuit in a conventional optical transmitter.

3 is a block diagram of the laser diode module shown in FIGS. 1 and 2;

4 is a block diagram showing an optical intensity / wavelength stabilization control circuit using a chip integrated in the optical transmitter of the present invention.

* Description of the symbols for the main parts of the drawings *

30: laser diode module 31: microprocessor

32: TC driver 33: laser diode driver

34: light intensity / wavelength stabilization control unit

The present invention for achieving the above object is a laser diode used as a light source of the optical transmitter, a photo detector for monitoring the wavelength of the laser diode, a thermistor for sensing the temperature inside the laser diode, the laser by the thermistor A laser diode module configured to control the temperature of the diode to room temperature and outputting the wavelength of the laser diode; a device for controlling the transmission of the wavelength output from the laser diode to be stable and having constant light intensity. An optical intensity / wavelength stabilization unit composed of chips; A microprocessor in which a reference voltage, which is a voltage when the laser diode is at room temperature, is set; The laser diode is cooled / heated according to the output value by comparing the voltage of the thermistor detecting the rising / falling temperature of the laser diode with the reference voltage set by the microprocessor in the light intensity / wavelength stabilizer. A T-C driver for controlling the amount of current to be supplied to the T-C, to stabilize the wavelength by maintaining the temperature of the laser diode at room temperature; The laser which makes the light intensity constant by controlling the driving current supplied to the laser diode according to the output value by comparing the amount of current flowing through the photodetector with the reference voltage set by the microprocessor in the light intensity / wavelength stabilizer It consists of an optical intensity / wavelength stabilization control circuit using an integrated chip composed of a diode driver.

In the present invention, the optical intensity stabilizer / wavelength stabilizer (DAC) converts a reference voltage input as a digital signal from the microprocessor into an analog signal to be input to the wavelength stabilizer / light intensity controller. Consists of

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 shows a block diagram of an optical intensity / wavelength stabilization control circuit using an integrated chip.

In addition, the same laser diode module 30 as a conventional component of the present invention will be described using the block diagram of FIG.

First, the light intensity / wavelength stabilization control circuit 300 includes a laser diode module 30 that outputs the wavelength of the laser diode 101, and a TC for driving the TCI 104 located in the laser diode module 30. The driver 32, the laser diode driver 33 for controlling the laser diode driving current supplied to the laser diode 101, and a reference voltage which is a voltage when the temperature of the laser diode 101 is room temperature are set. The microprocessor 31 and the light intensity / wavelength stabilization control section 34 are constituted by integrated chips of elements for stabilizing wavelength and light intensity.

3, the laser diode module 30 includes a laser diode 101 used as a light source of an optical transmitter, a photo detector 102 for monitoring a wavelength of the laser diode 101, and the laser diode ( Thermistor 103 for detecting the temperature of the 101, and the temperature of the laser diode 101 by the thermistor 103 detects when the temperature rises above room temperature, the TC 104 to adjust the laser diode 101 to room temperature It is composed of

The inside of the light intensity / wavelength stabilization control unit 34 converts a digital signal which is a reference voltage input from the microprocessor 31 into an analog signal for input to the light intensity / wavelength stabilization control section 34. There is a seed 330.

The operation of the light intensity / wavelength stabilization control circuit using the integrated chip will be described below.

Before describing the wavelength stabilization control operation of the light intensity / wavelength stabilization control circuit configured as described above, it is necessary to sense the temperature of the laser diode 101 when the wavelength is transmitted stably.

5 The thermistor 103 located inside the laser diode module 10 is used to detect the above temperature.

The voltage value NOR THM measured by this thermistor 103 is set by the microprocessor 31.

It will be described that the control circuit for stabilizing the wavelength after the voltage value NOR THM when the wavelength is stably transmitted is set in the microprocessor.

If the temperature of the laser diode 101 is increased / decreased from room temperature by the light generated by the laser diode 101 during the process of transmitting the wavelength in the laser diode 101 of the optical transmitter, the wavelength is not transmitted stably. .

Therefore, the temperature of the laser diode 101 should be at room temperature. The above-mentioned means that the thermistor 103 inside the laser diode module 30 senses that the laser diode rises / falls below room temperature, and the detected temperature Output the voltage value THM.

Here, the output voltage value THM and the reference voltage NOR THM set by the microprocessor 31 in the process of setting the reference voltage are input to the light intensity / wavelength stabilizer 34 and compared.

At this time, since the reference voltage NOR THM set in the microprocessor 31 is a digital signal, the light intensity / wavelength stabilizer 34 is input to the light intensity / wavelength stabilizer 34 integrated with analog elements. Via the ADC 330 located at the entrance of the change to the analog signal should be input to the light intensity / wavelength stabilizer (34).

As described above, the voltage value output from the light intensity / wavelength stabilizer 34 is input to the TC driver 32, and the amount of current supplied to the TSC 104 varies according to the voltage value, so that the laser diode ( The temperature of 101) can be adjusted so that the wavelength can be stably output.

In addition, before explaining the light intensity control operation of the light intensity / wavelength stabilization control circuit configured as described above, the current value flowing through the photo detector 102 when the light intensity becomes constant is monitored.

The monitored current amount is converted into a voltage value NOR PD and set in the microprocessor 31.

It will be described that the light intensity control circuit operates after the above process.

When the wavelength is transmitted from the laser diode 101 of the optical transmitter, a time when the intensity of the light generated by the laser diode 101 may not be constantly output may occur.

At this time, the current value PD flowing through the photo detector 102 for detecting light intensity and the reference voltage NOR PD generated by the microprocessor 31 are compared through the light intensity / wavelength stabilizer 34.

At this time, as in the wavelength stabilization control operation, the DC 330 is used to convert the digital signal into an analog signal.

Thus, the voltage value compared in the light intensity / wavelength stabilizer 34 is input to the laser diode driver 33, and the driving current supplied to the laser diode 101 is changed according to the voltage value, thereby controlling the light intensity. You can do it.

When the above process is performed, the light intensity can be controlled constantly.

As described above, the size of the transmitter can be reduced by using a chip in which the light intensity / wavelength stabilization control circuit is integrated, and digital adjustment can be made by using a microprocessor to adjust the wavelength / light intensity.

Therefore, as described above, the present invention has the effect of reducing the size of the optical transmitter by using the devices provided in the wavelength stabilization control circuit and the light intensity control circuit as integrated chips.

In addition, the present invention has an effect that the method of changing the wavelength / light intensity used in the light intensity / wavelength stabilization control circuit can be digitally adjusted in connection with the microprocessor.

Claims (2)

A laser diode used as a light source of an optical transmitter, a photo detector for monitoring the wavelength of the laser diode, a thermistor for sensing the temperature inside the laser diode, and a T.C. A laser diode module configured to output a wavelength of the laser diode; An optical intensity / wavelength stabilization unit configured to control the transmission of the wavelength output from the laser diode module in a stable manner and to form an integrated chip with elements having a constant optical intensity; A microprocessor in which a reference voltage, which is a voltage at room temperature, is set in the laser diode module; In the light intensity / wavelength stabilization unit, a voltage of the thermistor which senses the rising / falling temperature of the laser diode is compared with a reference voltage set by the microprocessor, and the TSI cools / heats the laser diode according to the output value. A TC driver controlling the amount of current to be supplied and stabilizing the wavelength by maintaining the temperature of the laser diode at room temperature; The laser which makes the light intensity constant by controlling the driving current supplied to the laser diode according to the output value by comparing the amount of current flowing through the photodetector with the reference voltage set by the microprocessor in the light intensity / wavelength stabilizer An optical transmitter having an optical intensity / wavelength stabilization control circuit using an integrated chip comprising a diode driver. According to claim 1, wherein the light intensity stabilized / wavelength stabilized unit And an optical intensity / wavelength stabilization control circuit using an integrated chip having a DC for converting a reference voltage input as a digital signal from the microprocessor into an analog signal for input to the wavelength stabilization / light intensity controller.