JPH09186388A - Stabilized wavelength light source - Google Patents

Abstract

PROBLEM TO BE SOLVED: To synchronize the frequency of emitted light by varying the magnitude of magnetostatic field being applied to an absorption cell depending on an external control signal thereby regulating the frequency of light emitted from a semiconductor laser diode. SOLUTION: Magnetostatic field of an absorption cell 5 is varied by applying a control signal externally to a coil 11 through a control signal input terminal 14 and thereby the resonance frequency of absorption cell 5 is varied. Consequently, the amplitude and phase of error signal in synchronism detection results from a lock-in amplifier 8 is varied. The error signal is applied to a PID controller 9 to produce a control signal for controlling the current level of a laser diode power supply 2 and the set temperature of a temperature controller 3 thus regulating the frequency of light emitted from a semiconductor laser diode 1. Consequently, the frequency of light emitted from semiconductor laser diode 1 can be synchronized.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light source in which the frequency (wavelength) of generated light is stabilized, and more particularly to a wavelength stabilized light source in which the generated frequency can be adjusted according to a control signal from the outside. is there.

WDM (Wave Division Multiplexing) for simultaneously transmitting a large number of optical information using one optical fiber
In communication and coherent optical communication, it is necessary to stabilize the frequency of transmitted light, that is, the wavelength, and to synchronize the transmitting and receiving stations.

Therefore, in the wavelength-stabilized light source used for such a purpose, it is necessary to synchronize the frequency of the generated light with an external control signal.

[0004]

2. Description of the Related Art As a technique for stabilizing optical frequency (wavelength), an absorption line of an atom or a molecule is used as an absolute reference frequency.
A method for stabilizing the wavelength of LD generated light by controlling the injection current and the ambient temperature of a semiconductor laser diode (LD) which is a light emitting source by a method such as synchronous detection is already known.

Further, in order to synchronize the light wavelengths, a frequency difference (beat signal) between the two lights is used by using a photodiode or the like.
Is detected and is fed back to the injection current and the ambient temperature of the controlled LD so that the beat signal becomes 0 in the case of the homodyne system and the beat signal frequency becomes a predetermined intermediate frequency in the case of the heterodyne system. OPLL (Optical Phas
e Locked Loop) technology is already known.

FIG. 11 shows an example of the structure of a conventional wavelength-stabilized light source, and shows the structure of a general wavelength-stabilized light source using absorption lines of atoms (molecules).

In FIG. 11, a semiconductor laser diode (LD) 1 emits light having a wavelength determined by an injection current from a laser diode current source 2 and an ambient temperature given by a temperature controller 3. At this time, the injection current from the laser diode current source 2 is added to the modulation oscillator 4
By applying a small modulation with the low frequency signal from
The light generated by the LD1 has been subjected to minute frequency modulation.

The light generated by the LD 1 enters the absorption cell 5 such as rubidium (Rb) through the lens 4 and is absorbed by resonance in the absorption line of a specific wavelength. The transmitted light of the absorption cell 5 is applied to a photodiode (PD) 6, converted into a current signal, amplified by a preamplifier 7, and then amplified.
An error signal that is added to the lock-in amplifier 8 and is synchronously detected by the low-frequency signal from the modulation oscillator 4 so that the amplitude and phase change according to the difference in frequency from the resonance frequency (wavelength) of the absorption line. To occur.

A control signal is generated by applying this error signal to the PID controller 9, and PID control is performed on the injection current from the laser diode current source 2 to the LD 1 and the ambient temperature based on the temperature controller 3. This stabilizes the wavelength of the light generated by the LD 1 so as to always follow the wavelength of the absorption line determined by the absorption cell 5.

Here, the PID controller 9 controls P (proportional) control, I (integral) control, and D based on the input error signal.
It is a well-known device that performs (differential) control to generate a control signal, and can perform stable control according to the control characteristics of the laser diode current source 2 and the temperature controller 3. In FIG. 11, the temperature controller 3 may not be controlled.

At this time, the wavelength of the absorption line of the absorption cell 5 changes depending on the static magnetic field applied to the absorption cell 5, so that a coil for generating a static magnetic field is provided around the cavity 10 around the absorption cell 5. 11 is configured to apply a stable voltage or current from a constant voltage source or a constant current source 12, and a magnetic shield 13 is provided around the coil 11.
The effect of the noise magnetic field is removed by applying.

As described above, in the conventional wavelength-stabilized light source, the wavelength of the generated light is fixed, so that the static magnetic field in the absorption cell 5 is fixedly set to a certain arbitrary value.

[0013]

In a coherent optical communication system or a WDM communication system, there are a method of installing a wavelength stabilizing light source on both the transmitting and receiving stations and a method of installing a wavelength stabilizing light source on only one of the transmitting and receiving stations. Are known. When the wavelength-stabilized light source is installed only in one station, the slave LD is placed in the station in which the wavelength-stabilized light source is not installed so as to synchronize with the light source of the master station. In this case, the above-mentioned OPLL technique is used as a method for achieving synchronization.

In the system in which the wavelength stabilizing light source is installed in the transmitting / receiving station, when the wavelength spacing of the multiplexed light is 100 GHz or more, the frequency difference is considered if the accuracy of the wavelength stabilizing light source is about several tens of MHz. Since it is small, it is not necessary to synchronize the wavelength stabilizing light source between the transmitting and receiving stations. On the other hand, when the wavelength interval of the multiplexed light becomes about 10 GHz, it becomes necessary to synchronize.

However, conventionally, the wavelength-stabilized light source is a reference device, and a method of synchronizing the reference device has not been known. Therefore, in a coherent optical communication system or a WDM communication system, it is not possible to sufficiently reduce the wavelength spacing of multiplexed light, and when the wavelength spacing is reduced,
There is a problem that high quality communication cannot be performed.

The present invention is intended to solve the problems of the prior art as described above, and makes it possible to adjust the wavelength of the generated light in a wavelength stabilized light source according to a control signal from the outside. Thus, it is an object of the present invention to provide a wavelength-stabilized light source that can synchronize the frequency of generated light.

[0017]

In order to solve such a problem, the present invention is provided with the following specific means.

(1) In the wavelength stabilizing light source for stabilizing the frequency of the light generated by the semiconductor laser diode 1 using the absorption cell 5, the magnitude of the static magnetic field applied to the absorption cell 5 according to the control signal from the outside. The frequency of the light generated by the semiconductor laser diode 1 can be adjusted by changing the.

(2) In the case of (1), the magnitude of the static magnetic field is controlled by adjusting the voltage or current of the static magnetic field generating coil 11 provided around the absorption cell 5.

(3) In the wavelength stabilizing light source that stabilizes the frequency of the light generated by the semiconductor laser diode 1 using the absorption cell 5, the input signal frequency is set in the path of the incident light from the semiconductor laser diode 1 to the absorption cell 5. The AOM 16 that shifts the frequency of the incident light in accordance therewith is inserted, and the frequency of the light generated by the semiconductor laser diode 1 can be adjusted by controlling the AOM 16 with an external control signal.

(4) In the case of (3), a V / f converter 15 for converting an external control signal voltage into a frequency signal is provided,
By controlling the AOM 16 by the output of the V / f converter 15, the frequency of the light generated by the semiconductor laser diode 1 can be adjusted.

(5) In the wavelength stabilizing light source for stabilizing the frequency of the light generated by the semiconductor laser diode 1 using the absorption cell 5, the ambient temperature of the absorption cell 5 is changed according to a control signal from the outside. Thus, the frequency of light generated by the semiconductor laser diode 1 can be adjusted.

(6) In the case of (5), it has an absorption cell temperature controller 20 for stabilizing the ambient temperature of the absorption cell 5,
The frequency of the light generated by the semiconductor laser diode 1 can be adjusted by changing the set temperature of the temperature controller 20 according to a control signal from the outside.

(7) In any one of (1) to (6), the semiconductor laser diode 1 is provided with a semiconductor laser diode temperature controller 3 for stabilizing the ambient temperature of the semiconductor laser diode 1. The laser diode current source 2 that supplies a current modulates the injection current with a modulation signal, and the semiconductor laser diode 1
Of the laser diode current source 2 and / or the semiconductor laser according to an error signal obtained by converting the light generated by the The diode temperature controller 3 is configured to control the temperature set value.

(8) In the laser diode current source 2 which supplies the injection current to the semiconductor laser diode 1, the injection current is modulated by the modulation signal, and the light generated by the semiconductor laser diode 1 is electrically converted into the light passing through the absorption cell 5. By controlling the current value of the laser diode current source 2 in accordance with an error signal obtained by converting the signal into a signal and performing synchronous detection with the modulation signal, wavelength stabilization that stabilizes the frequency of the light generated by the semiconductor laser diode 1 PGA 17 that generates a signal proportional to the injection current of the semiconductor laser diode 1 and proportional to the control signal from the outside,
An adder 18 for adding the output of the GA 17 and the electric signal obtained by converting the light passing through the absorption cell 5 is provided, and the output of the adder 18 is synchronously detected to generate an error signal.

(9) In the case of (7) or (8), a PID controller 9 for performing PID control is provided, and an error signal is added to the PID controller 9 to obtain a laser diode current source according to the control signal obtained. 2 and / or the temperature set value of the semiconductor laser diode temperature controller 3 is controlled.

(10) In a communication system in which both the transmitting and receiving stations connected via an optical fiber are provided with wavelength stabilizing light sources and the frequencies of the light generated by both wavelength stabilizing light sources are synchronized,
By equipping one or both of the transceiver stations with the wavelength-stabilized light source described in any one of (1) to (9), one of the transceiver stations is at the frequency of the output light of the other station, or Communication is performed mutually in synchronization with the frequency of the output light of the other station.

(11) In the case of (10), the beat signal between the output light of the wavelength stabilizing light source and the output light of the other station is detected, and the wavelength is adjusted so that the beat frequency becomes 0 or the set frequency. Controls the frequency of light generated by the stabilized light source.

(12) In the case of (11), the control time constant for controlling the frequency of the generated light in the wavelength-stabilized light source is calculated from the short-term frequency fluctuation cycle based on the disturbance of the communication line connecting the transmitting and receiving stations. Also lengthen.

As described above, according to the present invention, the frequency (wavelength) of the light generated by the wavelength stabilizing light source can be easily adjusted by a control signal from the outside. Therefore, according to the present invention, the frequency (wavelength) of the reference light source of the transceiver station can be synchronized by combining with the optical frequency synchronization technology such as the OPLL circuit.

[0031]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an embodiment (1) of the present invention, in which the same parts as those in FIG. 11 are designated by the same reference numerals, and 14 is an external control signal input terminal. is there.

In the embodiment (1) shown in FIG. 1,
Instead of connecting the coil 11 to a constant voltage source or a constant current source, an external control signal is applied via the control signal input terminal 14 to make the static magnetic field in the absorption cell 5 variable. According to this method, the static magnetic field in the absorption cell 5 can be easily changed.

FIG. 2 shows an example of changes in the resonance frequency (wavelength) of the absorption cell with respect to a static magnetic field. By changing the static magnetic field of the absorption cell 5, the resonance frequency (wavelength) of the absorption cell 5 changes according to this characteristic, so that the amplitude and phase of the error signal of the synchronous detection result from the lock-in amplifier 8 change.

By controlling the current value of the laser diode current source 2 and / or the temperature setting value of the temperature controller 3 by the control signal obtained by adding this error signal to the PID controller 9, the generated light of the LD 1 is controlled. Control is performed so that the frequency (wavelength) changes and the error signal of the synchronous detection result converges to zero.

Therefore, according to the embodiment (1), a slight deviation in the frequency (wavelength) of the light generated by the LD 1 can be easily finely adjusted. The operation of the other parts is the same as in the case of the conventional example shown in FIG.

FIG. 3 shows an embodiment (2) of the present invention, in which the same components as those in FIG. 11 are designated by the same reference numerals, and 15 denotes the voltage of a control signal from the outside converted to a frequency signal. Is a voltage / frequency (V / f) converter, 16 is an AOM (Acoustic) inserted in the light incident path to the absorption cell 5.
Optical Modulator).

In FIG. 3, the V / f converter 15 generates a signal having a frequency that changes according to the voltage of the control signal from the outside and inputs it to the AOM 16. The AOM 16 shifts the frequency of light passing therethrough by the frequency of the input electric signal.

FIG. 4 shows the input / output frequency characteristics of the AOM. As shown, the light of frequency f ₁
In addition, when the control frequency of the AOM is M, the output frequency of the AOM is f ₁ + M.

In FIG. 3, by adding the output light of the AOM 16 to the absorption cell 5, the amplitude of the error signal of the synchronous detection result from the lock-in amplifier 8 is adjusted according to the frequency difference from the resonance frequency of the absorption cell 5. The polarity changes.

By controlling the current value of the laser diode current source 2 and / or the temperature setting value of the temperature controller 3 by the control signal obtained by adding this error signal to the PID controller 9, the generated light of the LD 1 is controlled. Control is performed so that the frequency (wavelength) changes and the error signal of the synchronous detection result converges to zero.

Therefore, according to the embodiment (2), the frequency (wavelength) of the light generated by the LD 1 can be finely adjusted according to the control signal from the outside. The operation of other parts is as shown in FIG.
This is similar to the conventional case shown in FIG.

Generally, since it is easy to use a voltage signal as the control signal for controlling the wavelength of the wavelength stabilized light source, the V / f converter is used in the above embodiment, but the frequency is used. The input may be directly used as a control signal.

FIG. 5 shows an embodiment (3) of the present invention, in which the same parts as those in FIG. 11 are shown by the same numbers, and 17 is proportional to the injection current of the semiconductor laser diode 1 and is external. PGA (Prgramable GainAmplifier) 18 for generating an output proportional to the control signal from the adder 18 is an adder for adding the output of the preamplifier 7 and the output of the PGA 17.

FIG. 6 shows a general current-light intensity characteristic of the LD. The LD generally has an injection current-laser light intensity characteristic as shown in FIG. 6, and the light intensity (power) changes depending on the magnitude of the current. Then, in the portion exceeding the threshold value, the injection current and the laser light intensity are substantially proportional to each other.

FIG. 7 shows a general current-wavelength characteristic of an LD. The LD generally has an injection current-oscillation wavelength characteristic as shown in FIG. 7, and has a characteristic substantially proportional to the current-light intensity characteristic.

FIG. 8 shows the absorption characteristics of atomic (molecular) rays. The line width of the absorption line of an atom (molecule) is the time during which the atom (molecule) remains in a high energy level, that is, the lifetime (for rubidium atom, τ ≈
27 ns: 6 MHz 2πτ = 1 / γ).

However, since atoms are actively moving due to temperature energy under a certain temperature environment,
At room temperature (25 ° C), the Doppler width is as large as several hundred MHz, and the natural width determined by the life can be ignored.
Since the directions of atomic motion are irregular, the line width of the absorption line has a normal distribution.

FIG. 9 shows the intensity of the LD light transmitted through the absorption cell. Generally, in a wavelength stabilized light source using an LD, the light intensity after passing through the absorption cell has the characteristics shown in FIG. It is clear that this characteristic is obtained by superimposing the characteristic shown in FIGS. 6 and 7 and the characteristic shown in FIG.

From the characteristics of FIG. 9, it can be seen that the resonance frequency of the absorption cell shifts based on the slope of the current-light intensity characteristics. In the embodiment (3) of the present invention shown in FIG. 5, in consideration of the characteristics of FIG. 9, a DC component proportional to the injection current (or light intensity) flowing in the LD is added by the adder 18 to the photodiode. It is added to the output and input to the lock-in amplifier 8.

Then, in the lock-in amplifier 8, the proportional coefficient of the DC component proportional to the injection current (light intensity) is changed according to the control signal from the outside, and the obtained error signal is used as the PID controller. By controlling the current value of the laser diode current source 2 by the control signal obtained in addition to 9, the frequency (wavelength) of the light generated by the LD 1 changes, and the error signal of the synchronous detection result converges to 0. Is controlled.

In this way, the influence of the shift in the resonance frequency of the absorption cell due to the slope of the current-light intensity characteristic is eliminated, and the frequency of the light generated by the LD1 is controlled to the resonance frequency of the absorption cell, while A slight deviation in the frequency (wavelength) of the light generated by the LD 1 can be easily adjusted. The operation of the other parts is the same as in the case of the conventional example shown in FIG.

FIG. 10 shows an embodiment (4) of the present invention, in which the same components as those in FIG. 11 are designated by the same reference numerals, 19 is a thermostat for accommodating the absorption cell 5, and 20 is a thermostat. 19 is a temperature controller for stabilizing the temperature of 19.

The resonance frequency (wavelength) of the absorption cell 5 changes depending on the ambient temperature. Therefore, the set temperature of the constant temperature bath 19 in the temperature controller 20 that stabilizes the temperature of the constant temperature bath 19 that houses the absorption cell 5 is changed by a control signal from the outside. According to this method, the resonance frequency of the absorption cell 5 can be easily changed.

A change in the resonance frequency of the absorption cell 5 causes a change in the amplitude and phase of the error signal as a result of the synchronous detection from the lock-in amplifier 8. By controlling the current value of the laser diode current source 2 and / or the temperature set value of the temperature controller 3 by a control signal obtained by adding this error signal to the PID controller 9, the frequency of the light generated by the LD 1 (wavelength ) Changes, and control is performed so that the error signal of the synchronous detection result converges to zero.

Therefore, according to the embodiment (4), a slight deviation of the frequency (wavelength) of the light generated by the LD1 can be easily finely adjusted. The operation of the other parts is the same as in the case of the conventional example shown in FIG.

According to the embodiments (1) to (4), it is possible to easily adjust the frequency (wavelength) of the light generated by the LD 1 according to the control signal from the outside. Therefore, a coherent optical communication system or a WDM system, in which a wavelength-stabilized light source is provided in both transmitting and receiving stations connected via one optical fiber, and communication is performed by synchronizing the frequencies of light generated by both wavelength-stabilizing light sources, In the communication system, an OPL (not shown)
By the L circuit, the beat signals of the optical frequency (wavelength) of the master station and the slave station are detected by the photodiode or the like, and the obtained beat signal becomes 0 or the set frequency,
By changing and controlling the above-mentioned control signal,
Frequency (wavelength) of light generated by the wavelength-stabilized light source of one station
Can be synchronized with the light generated by the wavelength-stabilized light source of the other station.

In this case, one of the transmitting and receiving stations may perform communication in synchronization with the other station, or may perform communication in synchronization with each other.

In a system in which a wavelength-stabilized light source is installed in both the transmitting and receiving stations and one station communicates in synchronization with the other station, or in a mutually synchronized communication, Even if the synchronization clock line between them is cut off, each station can operate independently, so that there is an advantage that communication is not cut off immediately.

Further, in the control exchange on the synchronous line,
Due to the disturbance of the communication line (diurnal fluctuation of optical fiber propagation speed, temperature fluctuation, etc.), short-term (about 1 second to 1 hour) frequency (wavelength) fluctuation becomes large. In this case, by making the control time constant of the synchronous system sufficiently long (1 hour or more), high-quality light that follows the stability of the master station in the long term and the stability of the slave station in the short term You can get a signal.

[0060]

As described above, according to the present invention, the frequency (wavelength) of the light generated by the wavelength stabilizing light source can be easily adjusted. Therefore, according to the present invention, the frequency (wavelength) of the reference light source of the transmitting / receiving station can be synchronized in the coherent communication system and the WDM communication system by combining with the optical frequency synchronization technology such as the OPLL circuit, and therefore the quality is high. A communication system can be provided.

At this time, a high quality clock can be realized by setting the synchronization control time constant of the transmitting / receiving station to an appropriate time. If the wavelength stabilization light source synchronization method is realized by the present invention, since the wavelength stabilization light source is provided in the transmitting and receiving station, the communication line can be maintained even if the synchronization line is disconnected, and a highly reliable communication system is provided. Can be realized.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment (1) of the present invention.

[Fig. 2] Resonance frequency (wavelength) of an absorption cell with respect to a static magnetic field
It is a figure which shows an example of the change of.

FIG. 3 is a diagram showing an embodiment (2) of the present invention.

FIG. 4 is a diagram showing input / output frequency characteristics of an AOM.

FIG. 5 is a view showing an embodiment (3) of the present invention.

FIG. 6 is a diagram showing a general current-light intensity characteristic of an LD.

FIG. 7 is a diagram showing a general current-wavelength characteristic of an LD.

FIG. 8 is a diagram showing absorption characteristics of atomic (molecular) rays.

FIG. 9 is a diagram showing the intensity of LD light transmitted through an absorption cell.

FIG. 10 is a diagram showing an embodiment (4) of the present invention.

FIG. 11 is a diagram showing a configuration example of a conventional wavelength stabilized light source.

[Explanation of symbols]

 1 Semiconductor Laser Diode 2 Laser Diode Current Source 3 Semiconductor Laser Diode Temperature Controller 5 Absorption Cell 9 PID Controller 11 Static Magnetic Field Generation Coil 15 V / f Converter 16 AOM 17 PGA 18 Adder 20 Absorption Cell Temperature Controller

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication H04B 10/06 10/04

Claims (12)

[Claims] 1. A wavelength stabilizing light source for stabilizing the frequency of light generated by a semiconductor laser diode using an absorption cell, wherein the magnitude of a static magnetic field applied to the absorption cell is changed according to a control signal from the outside. Thus, the wavelength stabilized light source is characterized in that the frequency of light generated by the semiconductor laser diode can be adjusted. 2. The wavelength-stabilized light source according to claim 1, wherein the magnitude or magnitude of the static magnetic field is controlled by adjusting the voltage or current of a static magnetic field generating coil provided around the absorption cell 5. A wavelength stabilized light source. 3. A wavelength-stabilized light source for stabilizing the frequency of light emitted from a semiconductor laser diode by using an absorption cell, wherein the incident light is incident on a path of the incident light from the semiconductor laser diode to the absorption cell according to an input signal frequency. The wavelength stabilizing light source is characterized in that the frequency of the light generated by the semiconductor laser diode can be adjusted by inserting an AOM for shifting the frequency, and controlling the AOM by an external control signal. 4. The wavelength-stabilized light source according to claim 3, further comprising a V / f converter that converts a control signal voltage from the outside into a frequency signal, and outputs the AOM by the output of the V / f converter. A wavelength stabilized light source characterized in that the frequency of light generated by the semiconductor laser diode can be adjusted by controlling. 5. A wavelength-stabilized light source for stabilizing the frequency of light generated by a semiconductor laser diode using an absorption cell, by changing the ambient temperature of the absorption cell according to a control signal from the outside. A wavelength stabilized light source characterized in that the frequency of light generated by a semiconductor laser diode can be adjusted. 6. The wavelength stabilized light source according to claim 5, further comprising an absorption cell temperature controller for stabilizing the ambient temperature of the absorption cell, and setting the temperature controller according to a control signal from the outside. A wavelength-stabilized light source characterized in that the frequency of light generated by the semiconductor laser diode can be adjusted by changing the temperature. 7. A wavelength stabilized light source according to claim 1, wherein the wavelength stabilized light source has a temperature controller for a semiconductor laser diode that stabilizes an ambient temperature of the semiconductor laser diode. For modulating the injection current by a modulation signal in a laser diode current source that supplies the laser light, and converting the light generated by the semiconductor laser diode through an absorption cell into an electric signal for synchronous detection by the modulation signal. A wavelength-stabilized light source configured to control a current value of the laser diode current source and / or a temperature set value of the semiconductor laser diode temperature controller according to an error signal obtained by the method. 8. A laser diode current source that supplies an injection current to a semiconductor laser diode, modulates the injection current with a modulation signal, and converts light generated by the semiconductor laser diode through an absorption cell into an electrical signal. In the wavelength stabilizing light source for stabilizing the frequency of the generated light of the semiconductor laser diode by controlling the current value of the laser diode current source according to the error signal obtained by synchronous detection by the modulation signal PGA for generating a signal proportional to the injection current of the semiconductor laser diode and proportional to an external control signal
And an adder for adding the output of the PGA and an electric signal obtained by converting the light passing through the absorption cell, and the error signal is generated by synchronously detecting the output of the adder. A wavelength-stabilized light source. 9. The wavelength-stabilized light source according to claim 7, further comprising a PID controller for performing PID control, wherein the laser is responsive to a control signal obtained by adding the error signal to the PID controller. Current value of diode current source and /
Alternatively, the wavelength stabilized light source is characterized in that the temperature set value of the temperature controller for the semiconductor laser diode is controlled. 10. A communication system in which a wavelength stabilizing light source is provided in both of the transmitting and receiving stations connected via an optical fiber, and the frequency of light generated by the both wavelength stabilizing light sources is synchronized, one or both of the transmitting and receiving stations. A wavelength-stabilized light source according to any one of claims 1 to 9, wherein one of the transmitting and receiving stations has a frequency of output light of the other station or a frequency of output light of the other station. A communication system characterized in that communication is performed in synchronization with. 11. The communication system according to claim 10, wherein a beat signal between the output light of the wavelength stabilizing light source and the output light of another station is detected so that the beat frequency becomes 0 or a set frequency. A wavelength-stabilized light source characterized by controlling the frequency of light generated by the wavelength-stabilized light source. 12. The communication system according to claim 11, wherein the control time constant for controlling the frequency of the generated light in the wavelength stabilized light source is a short-term frequency fluctuation based on the disturbance of the communication line connecting the transmitting / receiving stations. A communication system characterized in that it is longer than the period.