JP2000019335A - Multi-wavelength light source unit for multi- wavelength optical communication - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and inexpensively manufacture a multi-wavelength light source used for a multi-wavelength optical communication. SOLUTION: This multi-wavelength light source unit uses a wide spectrum light source 10 containing at least plural use wavelength ranges in an emitted wavelength range, and is used in the wavelength multiple optical communication combining a filter means selectively taking out many narrow spectrum beams. The filter means is a fiber grating 14 or a grating formed on an optical waveguide substrate. Since the grating reflects a beam at a narrow band in the vicinity of a resonant wavelength, the reflected narrow spectrum beam is taken out from an optical circulator by assembling the optical circulator 12 between the light source and many gratings. As the light source, a natural emission beam of a super-luminescent diode or an erbium dope fiber is used.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light source used in wavelength-division multiplexed optical communication. The present invention relates to a multi-wavelength light source unit for wavelength-division multiplexing optical communication, which extracts a large number of narrow-spectrum light having a desired wavelength from a wide-spectrum light including a plurality of operating wavelength ranges.

[0002]

2. Description of the Related Art As is well known, a wavelength multiplexing technique (WDM:
Optical communication using Wavelength Division Multiplexing is an optical communication method for transmitting a large number of optical signals of different wavelengths in one optical fiber, and has attracted attention as a technology for increasing the capacity. Conventionally, wavelength multiplexing of 8 to 32 waves has been attempted, and wavelength multiplexing of many waves has been studied.

As a light source used in the wavelength division multiplexing optical communication, a laser diode oscillating at each wavelength and having the number of multiplexed wavelengths (for example, 8 to 32) is used. According to the standards of the Telecommunication Union, it is an integral multiple of 0.8 nm (100 GHz).

[0004]

As described above, conventionally, in order to realize wavelength-division multiplexed optical communication, it is necessary to prepare light sources (laser diodes) corresponding to multiple wavelengths only for the multiplicity. Very high control accuracy of the oscillation center wavelength is also required. Therefore, specifically, individual laser diodes were manufactured, and after manufacturing, characteristics were sorted out.
Further tuning (wavelength adjustment) by controlling current
It is carried out.

Therefore, the construction of the optical communication system is technically difficult, and the cost is extremely disadvantageous.

An object of the present invention is to provide a technique capable of easily and inexpensively manufacturing light sources of a large number of wavelengths used in wavelength division multiplexing optical communication.

[0007]

SUMMARY OF THE INVENTION The present invention is a multi-wavelength light source unit used in wavelength division multiplexed optical communication. In the present invention, the emission wavelength range uses a broad spectrum light source including at least a plurality of operating wavelength ranges, and the broad spectrum light source,
It is combined with a filter means for selectively extracting a large number of narrow spectrum lights. That is, the present invention has been realized by changing from a conventional method of independently generating and bundling light of many wavelengths to a method of cutting out light of several wavelengths.

In the present invention, a plurality of light intensity modulating means for respectively modulating the light intensity of the narrow spectrum light selectively extracted may be combined. Thus, on / off output control can be independently performed on the light of each wavelength selectively extracted.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The filter means for selectively extracting narrow spectrum light is preferably, for example, a fiber grating or a grating formed on an optical waveguide substrate. In particular, in the case of a grating formed on an optical waveguide substrate, optimization of a selected wavelength of a heat generation source or a current / voltage supply source on an optical waveguide substrate made of quartz glass, multi-component glass, electro-optic crystal, or the like. It is also possible to provide a wavelength adjusting means for achieving this, and to adjust the selected wavelength using the thermo-optical effect or the electro-optical effect of the substrate.

Incidentally, a grating is a Bragg grating having a constant refractive index modulation in the length direction. For example, a fiber grating functions as a filter because it reflects light in a narrow band near a resonance wavelength determined by the modulation pitch and the effective refractive index of the fiber mode. Therefore, a large number of gratings are arranged for a broad spectrum light source, and an optical circulator is incorporated between the light source and the grating. Thereby, the narrow spectrum light reflected from each grating can be extracted from the optical circulator.

As the broad spectrum light source, for example, a superluminescent diode (SLD) may be used, or spontaneous emission light (ASE light) of an erbium-doped fiber (EDF) may be used.

[0012]

FIG. 1 is an explanatory view showing an embodiment of a multi-wavelength light source unit for wavelength division multiplexing optical communication according to the present invention, which is an example of an optical fiber type. This light source unit is a combination of a broad-spectrum light source 10, an optical circulator 12, and an optical fiber 16 having a large number of fiber gratings 14 (only three are shown here for simplicity of description) in a core portion. Consists of

The broad spectrum light source 10 is a light source having a broad emission spectrum whose emission wavelength range includes at least a plurality of operating wavelength ranges. For example, a device using spontaneous emission light (ASE light) of a super luminescent diode (SLD) or erbium-doped fiber (EDF) may be used. Since this type of light source has an oscillation wavelength of about 15 to 30 nm, it can be sufficiently used for wavelength division multiplexed optical communication. The optical circulator 12 is of a three-port type and couples the input light from the broad spectrum light source 10 to the first port to the optical fiber 16 of the second port, and the reflected light from the optical fiber 16 of the second port is directed to the light source side. Is output from the third port without returning. Therefore, no matter how many wavelengths are required, only one light source 10 and one optical circulator 12 are required.

The fiber grating 14 is formed by irradiating a core portion of an optical fiber made of, for example, photosensitive glass with ultraviolet rays from two directions using a phase mask and utilizing interference. When a Bragg grating with a constant refractive index modulation is formed in the length direction of the core in this way, light is reflected in a narrow band near the resonance wavelength determined by the pitch of the modulation and the effective refractive index of the fiber mode. I do. Here, light having a wavelength lambda ₁ in the first fiber grating reflects, in the second fiber grating to reflect light of wavelength lambda _2, designed to reflect light of wavelength lambda ₃ in the third fiber grating (Λ ₁ ≠ λ ₂ ≠ λ ₃ ).

The broad spectrum light source 10 emits light having a broad emission spectrum as shown in FIG. In (a), the horizontal axis indicates the wavelength λ, and the vertical axis indicates the light intensity P. The output light enters the optical fiber 16 through the optical circulator 12. Each fiber grating 14 of the optical fiber 16 reflects light of a corresponding wavelength. That is, the light of the wavelength lambda ₁ in the first fiber grating, the light of the wavelength lambda ₂ in the second fiber grating, the third fiber grating light of wavelength lambda _3, is reflected respectively. The reflected lights return to the optical circulator 12 and exit from the output side (third port). The spectrum of the emitted light is shown in FIG. In this manner, a number of narrow spectrum lights (wavelengths λ ₁ , λ ₂ , λ ₃ ) corresponding to the number of fiber gratings can be selectively extracted. The transmitted light of the optical fiber 16 is
As shown in (c), the remaining spectrum light is obtained by subtracting the narrow spectrum light of (b) from the broad emission spectrum light of (a).

As can be seen from the above description, if a greater number of fiber gratings having different selected wavelengths are arranged in series, a multi-wavelength light source corresponding to the number can be obtained.
This multi-wavelength light source can be used for wavelength multiplexed optical communication.

FIG. 2 is an explanatory view showing another embodiment of the multi-wavelength light source unit for wavelength division multiplexing optical communication according to the present invention.
It is an example of an optical waveguide type. This light source unit also includes a combination of a broad spectrum light source 10, an optical circulator 12, and an optical waveguide substrate 26 on which a number of gratings 24 are shown (only three are shown here for simplicity of explanation). The optical waveguide substrate 26 is made of glass or the like.

The function of the grating in this optical waveguide type and the mechanism by which the multi-wavelength output is obtained are the same as those of the above-mentioned fiber type, so that the description thereof will be omitted. Also in this case, as in the case of the fiber grating, multi-wavelength light sources corresponding to the number of gratings are obtained, and can be used for wavelength-division multiplexed optical communication.

FIG. 3 is an explanatory view showing still another embodiment of the multi-wavelength light source unit for wavelength division multiplexing optical communication according to the present invention, which is an example of an optical waveguide type. This light source unit also
It comprises a combination of a broad spectrum light source 10, an optical circulator 12, and an optical waveguide 36 on which a number of gratings 34 are shown (only three are shown here for simplicity of explanation). In this embodiment, a thin film heater 38 is further formed in a portion near each grating 34 of an optical waveguide substrate 36 made of glass or the like and having a thermo-optic effect. The thin film heater 38 is, for example, a vapor-deposited or sputtered film of titanium or the like, and has a configuration provided with terminals. Then, a power supply 39 is connected between the terminals of each thin film heater 38.
This is the wavelength adjusting means for optimizing the selected wavelength.

When heat is applied by supplying a current to the thin film heater 38, the refractive index of the optical waveguide substrate changes due to the thermo-optic effect of the glass which is the optical waveguide substrate, and the light transmitted through the optical waveguide is expressed by ( The wavelength shifts by Δλ as shown in d). Therefore, the wavelength of the light reflected by the grating (the light emitted from the optical circulator) also shifts. In this manner, tuning of the selected wavelength can be performed by controlling the temperature of the substrate.

FIG. 4 is an explanatory view showing another embodiment of the multi-wavelength light source unit for wavelength division multiplexing optical communication according to the present invention, which is an example of an optical waveguide type. This light source unit also comprises a combination of a broad spectrum light source 10, an optical circulator 12, and an optical waveguide substrate 46. In this embodiment, a branching / coupling portion 47 is sequentially formed in one optical waveguide of an optical waveguide substrate 46, divided into a total of four optical waveguides, and a light intensity modulating means 48 and a grating 44 are provided respectively. . A selective wavelength adjustment mechanism including a thin film heater or the like as in the above embodiment may be incorporated near the grating 44.

The light intensity modulating means may be an MZ type (Mach-Zehnder type) as shown in FIG. 5A or a DC type (directional coupler type) as shown in FIG. A in FIG.
In this case, the current can be made in-phase or out-of-phase by controlling the current or voltage to the electrode 50, thereby controlling the return light to be “on” or “off”. In FIG. 5B, the optical path of the return light can be controlled by controlling the current or voltage to the electrode 52, and similarly, the “on” or “off” control of the return light can be performed. These are performed using lithium niobate or glass as a substrate material and utilizing their electro-optical effect or thermo-optical effect.

[0023]

As described above, the present invention is constructed so that light of a required wavelength is extracted from a light source having a broad emission spectrum by a filter function element. A multi-wavelength light source unit used for wavelength-division multiplexing optical communication can be easily manufactured at low cost without requiring a (laser diode).

Further, in the present invention, by using the optical waveguide substrate, it is easy to add a selected wavelength adjusting function or a light intensity modulation function to the light source of each wavelength.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing one embodiment of a multi-wavelength light source unit according to the present invention.

FIG. 2 is an explanatory view showing another embodiment of the multi-wavelength light source unit according to the present invention.

FIG. 3 is an explanatory view showing still another embodiment of the multi-wavelength light source unit according to the present invention.

FIG. 4 is an explanatory view showing another embodiment of the multi-wavelength light source unit according to the present invention.

FIG. 5 is an explanatory diagram showing an example of the light intensity modulation means.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Broad spectrum light source 12 Optical circulator 14 Fiber grating 16 Optical fiber 24 Grating 26 Optical waveguide substrate

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification code FI Theme coat ゛ (Reference) H04J 14/02 (72) Inventor Tatsushi 5-36-11 Shimbashi, Minato-ku, Tokyo Fuji Electric Chemical Co. (72) Inventor Tomonori Ichikawa 5-36-11 Shimbashi, Minato-ku, Tokyo Fuji Electric Chemical Co., Ltd.F-term (reference) 2H047 AA03 AA12 BB19 DD02 HH08 2H050 AC82 AC84 AD00 5K002 BA05 BA21 CA03 CA05 CA16 DA02

Claims (11)

[Claims] 1. A light source for use in wavelength-division multiplexing optical communication, wherein a wide-spectrum light source having an emission wavelength range including at least a plurality of use wavelength ranges is used, and the wide-spectrum light source and a large number of narrow-spectrum lights are selectively used. A multi-wavelength light source unit for wavelength-division multiplexing optical communication, comprising a combination of a filter means for extracting light. 2. A light source for use in wavelength division multiplexing optical communication, wherein a broad spectrum light source whose emission wavelength range includes at least a plurality of use wavelength ranges is used, and the wide spectrum light source and a large number of narrow spectrum lights are selectively used. A multi-wavelength light source unit for wavelength division multiplexing optical communication, comprising a combination of a filter means for extracting light and a plurality of light intensity modulation means for modulating light intensity of narrow spectrum light of each wavelength. 3. The multi-wavelength light source unit for wavelength division multiplexing optical communication according to claim 1, wherein the filter means for selectively extracting the narrow spectrum light is a fiber grating. 4. The multi-wavelength light source unit for wavelength division multiplexing optical communication according to claim 1, wherein the filter means for selectively extracting the narrow spectrum light is a grating formed on an optical waveguide substrate. 5. The multi-wavelength light source unit for wavelength division multiplexing optical communication according to claim 4, further comprising a wavelength adjusting means for optimizing a selected wavelength on the substrate. 6. The optical waveguide substrate is made of quartz glass or multi-component glass, and the wavelength adjusting means for optimizing the selected wavelength is a heat generating source, wherein the wavelength is selected by utilizing the thermo-optic effect of the substrate. 6. The multi-wavelength light source unit for wavelength division multiplexing optical communication according to claim 5, wherein the adjustment is performed. 7. The optical waveguide substrate is an electro-optic crystal, and the wavelength adjusting means for optimizing the selected wavelength is a current or voltage supply source, and uses the electro-optic effect of the substrate to adjust the selected wavelength. 6. The multi-wavelength light source unit for wavelength-division multiplexing optical communication according to claim 5, wherein the adjustment is performed. 8. The multi-wavelength light source unit for wavelength division multiplexing optical communication according to claim 2, wherein the light intensity modulating means is of a Mach-Zehnder type or a directional coupler type utilizing a thermo-optic effect of the optical waveguide substrate. 9. The multi-wavelength light source unit for WDM optical communication according to claim 2, wherein the light intensity modulating means is of a Mach-Zehnder type or a directional coupler type utilizing an electro-optic effect of the optical waveguide substrate. 10. The wavelength multiplexing apparatus according to claim 3, wherein an optical circulator is incorporated between the broad spectrum light source and the filter means for selectively extracting narrow spectrum light, and the narrow spectrum light is extracted from the optical circulator. Multi-wavelength light source unit for optical communication. 11. The multi-wavelength light source unit for WDM optical communication according to claim 1, wherein a spontaneous emission light of a super luminescent diode or an erbium-doped fiber is used as the broad spectrum light source.