KR100254744B1 - Optical wave safty circuit of laser diode in wave-length division multiplexing system - Google Patents

Abstract

PURPOSE: An apparatus for stabilizing light wavelength of a laser diode is to automatically stabilize the light wavelength of the laser diode using a simple circuit when turning on a WDM(wavelength division multiplexing) system, thereby simplifying a structure of the system. CONSTITUTION: An FBG(fiber bragg grating)(21) generates a reference wavelength for stabilizing a light signal. A tap coupler(22) taps a difference between light wavelength of a laser diode and the reference wavelength of the FBG into a desired percentage. A photo-detecting portion(23) detects the light wavelength tapped by the tap coupler and then converts into an electric signal. A differentiator(24) differentiates the electric signal with respect to time. An amplifying portion(25) amplifies the differentiated value generated from the differentiator. The first comparing portion(26) generates a pulse according to polarity of the amplified value. A window comparing portion(27) generates a pulse according to whether an initial light wavelength of the laser diode is included in a dead zone which is a limit value of the wavelength of the laser diode. An adding portion(28) adds the pulse generated from the first comparing portion and the window comparing portion.

Description

Optical Wavelength Stabilizer of Laser Diode in WDM System

The present invention relates to a WDM system (Wave-length Division Multiplexing System), in particular a simple circuit configuration in the laser diode in the WDM system to automatically stabilize the optical wavelength of the laser diode to the desired wavelength when the system is powered on It relates to an optical wavelength stabilization device of.

Conventionally, a method of dithering a wavelength generated by a laser diode and stabilizing it to a desired wavelength has been common, but recently, the WDM system is turned off and then turned on as an additional function to the wavelength dethering method. Even if it was turned on, the system added a function to search for a desired wavelength, but it was applied to a system, but an additional device was complicated.

Then, referring to the configuration of the optical wavelength stabilization device of the laser diode in the conventional WDM system, as shown in Figure 1, the oscillator (Oscillator 11) for oscillating the frequency signal to provide a dethering current and a reference signal value, and A laser diode 12 outputting a deserialization current applied from the oscillator 11 and an optical signal compensated by a wavelength correction control signal or a digital control signal applied to control wavelength stabilization, and a corresponding laser diode ( 12, a light filter (Fabry-Perot filter) 13 that detects an optical signal applied from the optical signal and outputs an error of the wavelength of the optical signal, and an error optical signal applied from the optical filter 13 A photo detector 14 for converting the signal into an electrical signal, an amplifier 15 for amplifying and outputting a signal applied from the photo detector 14, A lock-in amplifier (16) for comparing the amplified error signal applied through the amplifier 15 with a reference signal value applied from the oscillator 11 to generate a corresponding wavelength calibration control signal; The digital control unit 17 which generates a digital control signal by performing a cool start function for adjusting the laser wavelength by receiving the error signal amplified through the program by a program and the control of the digital control unit 17. According to the present invention, the control unit 18 includes a switching unit 18 for switching the digital control signal applied from the digital control unit 17 or the wavelength calibration control signal applied from the lock-in amplifier 16 to the laser diode 12.

In addition, the cool start function refers to a function for immediately performing an operation immediately when the power is turned on when power is supplied to a system.

In the WDM system configured as described above, the optical wavelength stabilization apparatus of the laser diode performs the operation as follows. First, the oscillator 11 oscillates a frequency signal, and the desired wavelength of the optical signal generated from the laser diode 12 is performed. In order to stabilize, the dethering current is applied to the laser diode 12 and the reference signal value set for the stabilization of the optical signal is applied to the lock-in amplifier 16.

Accordingly, the laser diode 12 generates an optical signal by compensating for the dethering current applied from the oscillator 11, outputs the generated optical signal to the optical filter 13, and the optical filter 13. Detects the wavelength of the light applied from the laser diode 12, and outputs the degree to which the wavelength of the optical signal generated by the laser diode 12 deviates from the desired wavelength to the photo detector 14.

The photo detector 14 detects the optical signal detected by the optical filter 13, converts the detected optical signal into an electrical signal, and outputs the electrical signal to the amplifier 15. The electric signal applied from the photo detector 14 is amplified and output to the lock-in amplifier 16 and the digital control unit 17.

Accordingly, the lock-in amplifier 16 compares an electric signal applied through the amplifier 15 with a reference signal value applied from the oscillator 11 and adjusts an optical signal wavelength of the laser diode 12. By returning the wavelength correction control signal for the corresponding laser diode 12 through the switching unit 18, the laser diode 12 is compensated by the wavelength correction control signal to output the optical signal.

However, when the power is turned on for the first time while the system is turned off, the above-described operation requires a long time to stabilize the wavelength, and the optical wavelength of the laser diode 12 is too far from the desired wavelength. Because they are separated, they should be roughly aligned with the desired wavelength range.

Thus, the digital control unit 17, which performs a cool start function for adjusting the laser wavelength by a program, receives an electrical signal through the corresponding amplifier 15, generates a digital control signal, and generates the digital control signal through the corresponding switching unit 18. Applied to the laser diode 12 to compensate for wavelength stabilization.

However, the operation of the digital controller 17 is quite limited, that is, not all the laser diodes 12 are wavelength stabilized, but only play a role of roughly matching the desired wavelength of the laser diode 12. In addition, the rest should be adjusted in detail by the above-described operation.

In other words, it was possible by the digital control unit 17 using a complicated computer performing a cool start function to roughly adjust the optical wavelength of the laser diode 12 to the desired wavelength when the system was first powered on. In addition, when the optical filter in the digital control unit 17 and the optical filter 13 are different from each other, the algorithm must be different, thereby increasing the installation space.

As described above, by using a complicated computer to adjust the laser wavelength to a desired wavelength when the system is powered on, there is a problem that the configuration is complicated, the reliability is low, the installation space is insufficient, and the cost is very high.

In order to solve the problems described above, the present invention relates to the stabilization of the optical wavelength of the laser diode used in the WDM system, a simple circuit configuration to automatically stabilize the optical wavelength of the laser diode to the desired wavelength when the system is powered on The aim is to simplify the configuration of the system at low cost without the need for complicated computers or fine tuning to meet the desired wavelength.

1 is a block diagram showing an optical wavelength stabilization device of a laser diode in a conventional WDM system.

2 is a block diagram illustrating an optical wavelength stabilization apparatus of a laser diode in a WDM system according to an exemplary embodiment of the present invention.

3 is a graph showing the transmission and filter characteristics of the optical wavelength in FIG.

Explanation of symbols on the main parts of the drawings

21: Fiber Bragg Grating (FBG) 22: Tap Coupler

23: Photo Detector 24: Differentiator

25 amplifier 26 first comparator

27: window comparator 28: summer

29: Toggle Flip-Flop

30: second comparator 31: integrator

The optical wavelength stabilization apparatus of a laser diode in a WDM system according to an embodiment of the present invention for achieving the above object is an FBG for generating a reference desired wavelength (λ ₀ ) of optical signal stabilization; A tap coupler for tapping a difference between a light wavelength of a laser diode and a desired wavelength generated by the FBG at a predetermined percentage; A photo detector for detecting the optical wavelength tapped by the tap coupler and converting the wavelength into an electrical signal; A differentiator for differentiating the electrical signal converted by the photo detector with respect to time; An amplifier for amplifying the differential value generated by the differentiator; A first comparator for generating a pulse according to the polarity of the amplified value of the amplifier; A window comparator for generating a pulse depending on whether the initial optical wavelength of the laser diode belongs to a dead zone which is an optical wavelength limit of the laser diode; A summer for summing two pulses generated by the first comparator and the window comparator; A toggle flip-flop for inverting polarity according to the levels of the pulses summed in the summer; A second comparator for generating a pulse inverted by the polarity inversion control of the toggle flip-flop; And an integrator configured to change the current direction according to the polarity of the pulse generated by the second comparator to increase or decrease the optical wavelength of the laser diode to be fixed to the desired wavelength.

Hereinafter, with reference to the accompanying drawings will be described as follows.

FIG. 2 is a block diagram illustrating a device for stabilizing an optical wavelength of a laser diode in a WDM system according to an exemplary embodiment of the present invention, and FIG. 3 is a graph illustrating transmission and filter characteristics of an optical wavelength in FIG. 2.

In the WDM system according to the embodiment of the present invention, an optical wavelength stabilization device of a laser diode includes a fiber bragg grating (FBG) 21, a tap coupler (22) of 3 (dB), Photo Detector 23, Differentiator 24, Amplifier 25, First Comparator 26, Window Comparator 27, Summer 28, Toggle Flip-Flop ( Toggle Flip-Flop; 29), a second comparator 30, and an integrator 31.

The FBG 21 generates a desired wavelength λ ₀ for stabilization of the optical signal generated by the laser diode and applies it to the tap coupler 22.

The tap coupler 22 taps the difference between the wavelength of light generated by the laser diode and the wavelength λ ₀ generated by the FBG 21 at a predetermined percentage, and the tapped optical wavelength is converted into the photo detector ( 23)

The photo detector 23 detects the tapped light wavelength output from the tap coupler 22, converts the detected light wavelength into an electrical signal, and applies it to the differentiator 24.

The differentiator 24 differentiates the electric signal value applied from the photo detector 23 with respect to time and applies the differentiated value to the amplifier 25.

The amplifier 25 inverts and amplifies the differential value applied from the differentiator 24, and applies the amplified value to the first comparator 26.

The first comparator 26 applies pulses of 'high' or 'low' level to the summer 28 according to the polarity of the amplified value applied from the amplifier 25.

The window comparator 27 sets a dead zone by calculation and measurement in advance to prevent the wavelength of the optical signal generated by the laser diode from continuously increasing or decreasing. When the initial light wavelength applied from the thermistor reaches the predetermined dead zone, a pulse of the 'high' level is generated and applied to the summer 28.

The summer 28 adds the pulses applied from the first comparator 26 and the pulses applied from the window comparator 27 and applies the summed pulses to the toggle flip-flop 29.

The toggle flip-flop 29 bounces a pulse according to the level of the summed pulse applied from the summer 28 and applies it to the second comparator 30.

The second comparator 30 changes the polarity when the toggle flip-flop 29 bounces a pulse and outputs the polarity to the integrator 31.

The integrator 31 changes the current direction of the control circuit according to the pulse applied from the second comparator 30 to fix the optical wavelength generated by the laser diode to the desired wavelength λ ₀ .

In the WDM system according to the embodiment of the present invention, the optical wavelength stabilization apparatus of a laser diode performs the following operation.

First, when the desired wavelength λ ₀ for stabilizing the optical signal generated by the laser diode is generated in the FBG 21 and applied to the tap coupler 22, the tap coupler 22 generates the desired wavelength λ ₀ . The difference between one light wavelength and the wavelength λ ₀ generated by the corresponding FBG 21 is tapped by a certain percentage, and the tapped light wavelength is output to the photo detector 23.

The photo detector 23 detects the wavelength of the tapping of the tap coupler 22, converts the detected wavelength into an electrical signal, and applies it to the differentiator 24. The electric signal value applied from the photo detector 23 is differentiated with respect to time, and if there is a difference between the wavelength of the light generated by the laser diode and the wavelength λ ₀ generated by the corresponding FBG 21, the differentiated value Is applied to the amplifier 25 having a negative polarity with a minus value.

Accordingly, the amplifier 25 amplifies the optical wavelength detected by the photo detector 23, and the amplified optical wavelength is a plus value by the differential minus value applied from the differentiator 24. The first comparator 26 applies the pulse of the 'high' level to the summer 28 by the amplified positive value applied from the amplifier 25.

Accordingly. The adder 28 applies a pulse applied from the first comparator 26 to the toggle flip-flop 29, so that the toggle flip-flop 29 bounces the pulse to change the polarity of the second comparator 30. The integrator 31 also changes the current direction of the control circuit due to the polarity inversion of the second comparator 30 so that the wavelength of the light generated by the laser diode is moved to the desired wavelength λ ₀ . Do it.

Then, when the WDM system is turned off and the power is turned on for the first time, the wavelength of the first light generated by the laser diode is too far from the desired wavelength. For example, referring to the graph shown in Figure 3 will be described as follows.

If the initial optical wavelength generated by the laser diode is one of the points 'A', 'B', 'C', and 'D', it should be stabilized to the desired wavelength λ ₀ .

For example, when the initial optical wavelength generated by the laser diode is a point 'A', and if the output of the integrator 31 is a positive value, the initial optical wavelength generated by the laser diode is a `A 'point. It will go to the point E ', whereby the output is continuously reduced by the filter characteristic and the output of the differentiator 24 has a negative value.

The negative output of the differentiator 24 also makes the polarity of the amplifier 25 negative, so that the input of the first comparator 26 becomes a positive value and the output of the first comparator 26 is reduced. By applying a positive value to the summer 28, the output of summer 28 causes a pulse to bounce on the toggle flip-flop 29.

Accordingly, when the toggle flip-flop 29 causes the pulse to bounce, the output polarity of the second comparator 30 is changed, thereby changing the current direction of the control circuit, and thus the wavelength of the light generated by the laser diode is' E. Move the object to the `B 'side.

Accordingly, when the wavelength of the light generated by the laser diode continues to move toward the 'C' side beyond the desired wavelength λ ₀ , the output of the differentiator 24 becomes a negative value and is the same as described above. In operation, since the optical wavelength generated by the laser diode moves toward the desired wavelength λ ₀ , the operation is repeated to fix the desired wavelength λ ₀ .

However, if the initial optical wavelength generated by the laser diode is not at the points 'A', 'B', 'C', or 'D' but at the point 'E' or 'F', the integrator 31 ) Is either a positive value or a negative value such that the initial light wavelength produced by the laser diode is unconditionally increased or decreased.

If the initial optical wavelength generated by the laser diode is at the point of 'E' and then decreases, the dead zone for preventing the wavelength of the optical signal generated by the laser diode from continuously increasing or decreasing in advance is calculated and When the initial optical wavelength applied from the thermistor of the laser diode in the window comparator 27 set by the measurement reaches the preset dead zone, a pulse of the 'high' level is generated and applied to the summer 28. do.

Accordingly, the summer 28 receives the pulse of the 'high' level from the window comparator 27 and causes the pulse to bounce in the toggle flip-flop 29 to change the polarity of the toggle flip-flop 29. .

In this way, the direction of movement of the initial optical wavelength generated by the laser diode is changed again, so that it is automatically fixed at the desired wavelength λ ₀ at any time.

As described above, in the optical wavelength stabilization of the laser diode used in the WDM system according to the present invention, the difference between the desired wavelength in the FBG and the optical wavelength of the laser diode is tapped by a tap coupler, detected by a photo detector, and differentiated in a differentiator. When the pulse generated through the first comparator and the initial optical wavelength of the corresponding laser diode approaches the dead zone, the pulse generated by the window comparator is polarized in the toggle flip-flop through the output of the adder and inverted in the second comparator. By applying a pulse to the integrator, the direction of the current is changed to fix the optical wavelength of the laser diode to the desired wavelength.At the same time as the system power is turned on, the optical wavelength of the laser diode is stabilized to the desired wavelength, requiring complicated computer or fine adjustment. Simplify system configuration at low cost The.

Claims (1)

An FBG 21 for generating a reference desired wavelength λ ₀ of optical signal stabilization; A tap coupler (22) for tapping the difference between the optical wavelength of the laser diode and the desired wavelength (λ ₀ ) generated by the FBG (21); A photo detector (23) for detecting the optical wavelength tapped by the tap coupler (22) and converting the wavelength into an electrical signal; A differentiator 24 for differentiating an electric signal converted by the photo detector 23 with respect to time; An amplifier (25) for amplifying the derivatives produced by the differentiator (24); A first comparator 26 for generating a pulse according to the polarity of the amplified value of the amplifier 25; A window comparator (27) for generating a pulse depending on whether the initial optical wavelength of the laser diode belongs to a dead zone which is the optical wavelength limit of the laser diode; A summer 28 for summing two pulses generated by the first comparator 26 and the window comparator 27; A toggle flip-flop (29) for inverting the polarity according to the level of the pulses summed by the summer (28); A second comparator (30) for generating a pulse inverted by the polarity inversion control of the toggle flip-flop (29); And an integrator 31 configured to change the current direction according to the polarity of the pulse generated by the second comparator 30 to increase or decrease the optical wavelength of the laser diode to be fixed to the desired wavelength λ ₀ . Optical wavelength stabilization device of a laser diode in a WDM system.

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