KR100234042B1 - Wavelength fixing system using fiber bragg grating filter - Google Patents

Abstract

The present invention provides a fiber Bragg grating filter (Fiber Bragg Grating Filter) to improve the stability and reliability of the wavelength by automatically fixing the wavelength so that the laser diode can always operate at the reference wavelength (Fiber Bragg Grating Filter) Bragg Grating Filter).

Since the conventional WDM system does not have an absolute standard of light wavelength, there is a problem in that installation and maintenance / management are difficult because it can be operated sensitively by aging effects and external environment.

To solve this problem, the present invention provides an oscillator for applying an oscillation signal of a predetermined level to the bias current of the laser; A first waveform shaping unit for waveform shaping the oscillation signal output from the oscillator accordingly; A separation unit for separating a level of a predetermined value from the optical wavelength signal output from the laser diode module and sending it to the fiber Bragg grating filter; A fiber Bragg grating filter unit for reflecting only the reference wavelength [lambda] 0 at the level of a predetermined value output through the separation unit and passing other wavelength components as they are; A light detector for detecting the intensity of the light wavelength reflected by the fiber Bragg grating filter unit using the separator; An amplifier for amplifying and outputting the intensity value of the optical wavelength detected by the photodetector to a predetermined level; A second waveform shaping section for waveform shaping the optical wavelength signal amplified by the amplifying section accordingly; An adder for adding waveform-formed signals through the first waveform shaping section and the second waveform shaping section, respectively; An integrator for integrating the signal added by the adder to a predetermined value and generating a thermoelectric cooling drive control signal according to the result value; It consists of a laser diode module consisting of a thermoelectric cooler which is driven according to the thermoelectric cooling drive control signal output from the integrator and increases or decreases the optical wavelength of the laser diode.

Description

Wavelength Fixing Device Using Fiber Bragg Grating Filter

TECHNICAL FIELD The present invention relates to a WDM transmission system, and in particular, a fiber bragg grating filter is used to automatically fix a wavelength so that a laser diode can always operate at a reference wavelength. And it relates to a wavelength fixing device using a Fiber Bragg Grating Filter to improve the reliability.

As shown in FIG. 1, the conventional WDM system is driven according to a thermistor 1a for monitoring the temperature inside the laser, and a thermoelectric cooling drive control signal output from the comparator 2 so that the laser diode ( 1c) A laser diode module 1 composed of a thermoelectric cooler 1b for maintaining a constant internal temperature, and a temperature value monitored by a thermistor 1a in the laser module 1 and a temperature for maintaining the temperature of the laser diode. It consists of a comparator 2 which compares the set temperature value and generates a thermoelectric cooling drive control signal according to the comparison result.

The operation of the conventional WDM system configured as described above will be described with reference to the accompanying drawings.

First, the DFB laser used in the WDM system is very limited in its tunable capability, and among the many products, the temperature is controlled by selecting the lasers operating closest to the reference wavelength for each channel. It is intended to operate at the reference wavelength.

That is, the temperature inside the laser diode 1c is always monitored through the thermistor 1a in the laser diode module 1 and input to the comparator 2.

Then, the comparator 2 compares the temperature value monitored by the thermistor 1a with a preset temperature value for maintaining the temperature of the laser diode, and generates a thermoelectric cooling drive control signal when there is a difference.

Accordingly, the thermoelectric cooler 1b in the laser diode module 1 is driven in accordance with the thermoelectric cooling drive control signal output from the comparator 2 to keep the temperature inside the laser diode 1c constant.

As a result, adjusting the temperature reference allows the laser diode to be varied to operate at the desired wavelength.

However, since the conventional WDM system does not have an absolute standard of light wavelength, it may be operated sensitively by secular effects, external environment, etc., and thus there is a problem in that installation and maintenance / management are difficult.

Accordingly, the present invention provides a fiber Bragg grating filter (Fibre Bragg Grating Filter) to improve the stability and reliability of the wavelength by automatically fixing the wavelength so that the laser diode can always operate at the reference wavelength (Filber Bragg Grating Filter) The purpose is to provide a wavelength fixing device using a Fiber Bragg Grating Filter.

Technical means of the present invention for achieving this object, the oscillator for applying a predetermined level of oscillation signal to the bias current of the laser; A first waveform shaping unit configured to waveform-shape the oscillation signal output from the oscillator to rise thereto; A separation unit for separating a level of a predetermined value from the optical wavelength signal output from the laser diode module and sending it to the fiber Bragg grating filter; A fiber Bragg grating filter unit for reflecting only the reference wavelength [lambda] 0 and passing other wavelength components as they are at a level of a predetermined value output through the separation unit; A light detector for detecting the intensity of the light wavelength reflected by the fiber Bragg grating filter unit using the separator; An amplifier for amplifying and outputting the intensity value of the optical wavelength detected by the photodetector to a predetermined level; A second waveform shaping unit for waveform shaping the optical wavelength signal amplified by the amplifier; An adder for adding the waveform-formed signals through the first and second waveform-shaping sections, respectively; An integrator for integrating the signal added by the adder to a predetermined value and generating a thermoelectric cooling drive control signal according to the result value; The laser diode module is driven by a thermoelectric cooling driving control signal output from the integrator, and is configured of a laser diode module configured to increase or decrease the optical wavelength of the laser diode.

1 is a block diagram of a conventional WDM system.

2 is a block diagram of a wavelength fixing device using a Fiber Bragg Grating Filter according to the present invention.

3 is a spectrum of an optical signal reflected from a fiber Bragg grating filter applied to FIG.

4 to 6 are output waveform diagrams for each point of FIG.

<Explanation of symbols for main parts of drawing>

101: laser diode module 101a: thermoelectric cooler

102: oscillator 103: first waveform shaping unit

104: separating portion 105: fiber Bragg grating filter portion

106: light detector 107: amplifier

108: second waveform shaping unit 109: adder

110: integrator

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

Figure 2 shows a block diagram of a wavelength fixing device using a Fiber Bragg Grating Filter according to the present invention, the oscillator 102 for applying a predetermined level of oscillation signal to the bias current of the laser, A fiber Bragg grating filter by separating a level of a predetermined value from the first waveform shaping unit 103 for waveform shaping the oscillation signal output from the oscillator 102 and the optical wavelength signal output from the laser diode module 101. The fiber Bragg grating filter unit 105 which reflects only the reference wavelength λ 0 at the level of a predetermined value output through the separator 104 and other wavelength components as it passes through the separation unit 104 sent to the unit 105. ), A light detector 106 for detecting the intensity of the light wavelength reflected by the fiber Bragg grating filter unit 105 using the separator 104, and the light detector 106 The amplification unit 107 for amplifying and outputting the detected intensity value of the optical wavelength to a predetermined level, and the second waveform shaping unit 108 for waveform shaping the optical wavelength signal amplified by the amplifying unit 107 accordingly. And an adder 109 for adding the waveform-formed signals through the first waveform shaping unit 103 and the second waveform shaping unit 108, and the signal added by the adder 109 to a predetermined value. And an integrator 110 generating a thermoelectric cooling drive control signal according to the result, and a thermoelectric cooler 101a that is driven according to the thermoelectric cooling drive control signal output from the integrator 110 to increase or decrease the optical wavelength of the laser diode. It consists of a laser diode module 101 consisting of.

Referring to Figures 2 to 6 attached to the operation and effect of the present invention configured as described above are as follows.

First, since the optical wavelength oscillated by the laser diode module 101 changes minutely even by a slight change in the bias current, an AC signal of about ± 3 dB is applied to the bias current of the laser by using the oscillator 102 of 5 ㎑. Adopt.

Here, the sine wave as shown in (a) of FIG. 4 is output as the output (point ⓒ) of the oscillator 102, that is, the modulation signal.

Then, the first waveform shaping unit 103 waveform-forms the oscillation signal output from the oscillator 102 correspondingly and outputs the oscillation signal to the adder 109.

On the other hand, the separation unit 104 separates 1% of the wavelength output from the laser diode module 101 and sends it to the fiber Bragg grating filter unit 105.

Then, the fiber Bragg grating filter unit 105 reflects only the reference wavelength λ 0 at the wavelength separated by the separation unit 104 and passes other wavelength components as they are.

That is, the spectrum of the optical signal reflected by the fiber Bragg grating filter 105 is as shown in FIG.

Accordingly, the photodetector 106 detects the intensity of the optical signal reflected by the fiber Bragg grating filter 105 using the separator 104 again.

When the oscillation wavelength of the optical signal detected by the photodetector 106 is smaller than the reference wavelength λ 0 of the spectrum of the optical signal shown in FIG. 3, the wavelength will increase finely when the bias current increases finely ( i) In this case the optical power will increase slightly.

Therefore, the output current of the laser diode in the laser diode module 101 increases finely.

Also, as the current decreases, the wavelength and power will likewise decrease slightly (ii) and eventually the output current of the laser diode also decreases.

That is, the waveform as shown in Fig. 4B is output.

On the other hand, when the oscillation wavelength of the optical signal detected by the photodetector 106 is larger than the reference wavelength λ0 of the spectrum of the optical signal shown in FIG. 3, the optical power decreases when the current increases and eventually the output of the laser diode The current is reduced (in case of (iii)).

In addition, when the current decreases, the optical power increases (iv) and the output current of the laser diode increases.

That is, the waveform as shown in Fig. 4C is output.

Then, the amplifier 107 amplifies and outputs the intensity value of the optical wavelength detected by the photodetector 106 to a predetermined level.

Accordingly, the second waveform shaping unit 108 waveform-shapes the optical wavelength signal amplified by the amplifying unit 107 accordingly and outputs the waveform to the adder 109.

지점에서의 신호가 가산기(109)에 출력되는 것이다.That is, each shown in FIG.

The signal at the point is output to the adder 109.

Then, the adder 109 adds the waveform-formed signals from the first and second waveform shaping units 103 and 108 to output to the integrator 110.

Accordingly, the integrator 11 increases or decreases the optical wavelength of the laser diode by excluding the thermoelectric cooler 101a in the laser diode module 101 according to the result of integrating the signal added by the adder 109 to a predetermined value. It is to improve the stability and reliability.

As an example, when the wavelength is smaller than the reference wavelength lambda 0, the signal sent to the thermoelectric cooler 101a in the laser diode module 101 will be as shown in FIG.

Accordingly, the heater of the thermoelectric cooler 101a is operated to increase the light wavelength.

On the other hand, when the wavelength is larger than the reference wavelength λ0, the signal sent to the thermoelectric cooler 101a in the laser diode module 101 will be as shown in FIG.

Accordingly, the cooler of the thermoelectric cooler 101a is operated to reduce the wavelength.

On the contrary, when the wavelength coincides with the reference wavelength lambda 0, no signal needs to be sent to the thermoelectric cooler 101a in the laser diode module 101.

As described above, the present invention has an effect of improving the stability and reliability of the wavelength by automatically fixing the wavelength so that the laser diode can always operate at the reference wavelength.

Claims (1)

An oscillator 102 which applies an oscillation signal of a predetermined level to the bias current of the laser; A first waveform shaping section 103 for waveform shaping the oscillation signal output from the oscillating section 102 accordingly; A separating unit 104 for separating the level of a predetermined value from the optical wavelength signal output from the laser diode module 101 and sending it to the fiber Bragg grating filter unit 105; A fiber Bragg grating filter unit 105 for reflecting only the reference wavelength lambda 0 at the level of a predetermined value output through the separating unit 104 and passing other wavelength components as it is; A photodetector 106 for detecting the intensity of the light wavelength reflected by the fiber Bragg grating filter unit 105 using the separator 104; An amplifier 107 for amplifying and outputting the intensity value of the optical wavelength detected by the photo detector 106 to a predetermined level; A second waveform shaping part 108 for waveform shaping the optical wavelength signal amplified by the amplifying part 107 accordingly; An adder (109) for adding waveform-formed signals through the first waveform shaping section (103) and the second waveform shaping section (108); An integrator 110 for integrating the signal added by the adder 109 to a predetermined value and generating a thermoelectric cooling drive control signal according to the result value; Fiber Bragg grating, characterized in that it comprises a laser diode module 101 consisting of a thermoelectric cooler (101a) is driven in accordance with the thermoelectric cooling drive control signal output from the integrator 110 to increase or decrease the optical wavelength of the laser diode. Wavelength Fixing Device using Fiber Bragg Grating Filter.

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