Claims
- 1. A semiconductor laser module comprising:
a semiconductor laser device having an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current; an optical fiber configured to guide the multiple mode laser beam to an output of said laser module; and an optical attenuation device configured to attenuate said multiple mode laser beam by an amount sufficient to provide a predetermined output power from said output of the laser module.
- 2. The semiconductor laser module of claim 1, wherein said optical attenuation device comprises an optical coupling lens offset from an optimum coupling position by an amount sufficient to provide said predetermined output power.
- 3. The semiconductor laser module of claim 2, wherein said optical coupling lens is a lens offset from the optimum coupling position in at least one of a direction of an optical axis of the laser beam and a direction perpendicular to said optical axis.
- 4. The semiconductor laser module of claim 3, wherein said coupling lens comprises a lens substantially offset from the optimum coupling position only in a direction of the optical axis.
- 5. The semiconductor laser module of claim 2, wherein said semiconductor laser device comprises a laser with said driving current being at least 50 mA.
- 6. The semiconductor laser module of claim 2, wherein said semiconductor laser device comprises a laser with said driving current being at least 100 mA.
- 7. The semiconductor laser module of claim 2, wherein said semiconductor laser device comprises a laser with said driving current being at least 150 mA.
- 8. The semiconductor laser module of claim 1, wherein said optical attenuation device comprises an optical attenuator interrupting said optical fiber and configured to attenuate said multiple mode laser beam by an amount sufficient to provide said predetermined output power.
- 9. The semiconductor laser module of claim 8, wherein said semiconductor laser device comprises a laser with said driving current being at least 50 mA.
- 10. The semiconductor laser module of claim 8, wherein said semiconductor laser device comprises a laser with said driving current being at least 100 mA.
- 11. The semiconductor laser module of claim 8, wherein said semiconductor laser device comprises a laser with said driving current being at least 150 mA.
- 12. The semiconductor laser module of claim 1, wherein
said semiconductor laser device comprises a laser with said driving current being a predetermined current sufficient to reduce relative intensity noise (RIN) of said laser module; and said optical attenuation device comprises a device configured to attenuate said multiple mode laser beam by an attenuation amount sufficient to provide said predetermined output power at a power level that is sufficient to avoid stimulated Brillouin scattering (SBS) in a signal fiber that the output power is injected into.
- 13. The semiconductor laser module of claim 12, wherein said optical attenuation device comprises a device configured to provide an attenuation amount corresponding to said predetermined current.
- 14. The semiconductor laser module of claim 1, wherein said optical attenuation device comprises said semiconductor laser device having a cavity length of no more than 800 μm.
- 15. A method for providing light from a semiconductor laser module comprising:
providing a driving current to a semiconductor laser device having an integrated diffraction grating so as to emit a multiple mode laser beam; providing an optical fiber for guiding the multiple mode laser beam to an output of said laser module; and providing an optical attenuating device for attenuating said multiple mode laser beam by an amount sufficient to provide a predetermined output power from the output of said laser module.
- 16. The method of claim 15, wherein said providing an optical attenuating device comprises providing an optical coupling lens offset from an optimum coupling position by an amount sufficient to provide said predetermined output power.
- 17. The method of claim 15, wherein said providing a driving current comprises providing a driving current of at least 50 mA to said semiconductor laser device.
- 18. The method of claim 15, wherein said providing an optical attenuating device comprises providing an optical attenuator interrupting said optical fiber and configured to attenuate said multiple mode laser beam by an amount sufficient to provide said predetermined output power.
- 19. The method of claim 18, wherein said providing a driving current comprises providing a driving current of at least 50 mA to said semiconductor laser device.
- 20. The method of claim 15, wherein
said providing a driving current comprises providing a predetermined driving current sufficient to reduce relative intensity noise (RIN) of said laser module; and providing an optical attenuation device comprises providing a device for attenuating said multiple mode laser beam by an attenuation amount sufficient to provide said predetermined output power at a power level that is sufficient to avoid stimulated Brillouin scattering (SBS) in a signal fiber that the output power is injected into.
- 21. The method of claim 20, wherein said providing an optical attenuation device further comprises providing a device for producing an attenuation amount corresponding to said predetermined current.
- 22. The method of claim 15, wherein providing an optical attenuation device comprises providing said semiconductor laser device with a cavity length of no more than 800 μm.
- 23. A semiconductor laser module comprising:
means for providing a multiple mode light beam from an integrated diffraction grating semiconductor laser device; means for guiding the multiple mode laser beam along an optical fiber to an output of said laser module; and means for optically attenuating said multiple mode laser beam by an amount sufficient to provide a predetermined output power from the output of said laser module.
- 24. The semiconductor laser module of claim 23, further comprising:
means for providing a predetermined driving current sufficient to reduce relative intensity noise (RIN) of said laser module; and means for providing a device for attenuating said multiple mode laser beam by an attenuation amount sufficient to provide said predetermined output power at a power level that is sufficient to avoid stimulated Brillouin scattering (SBS) in a signal fiber that the output power is injected into.
- 25. The semiconductor laser module of claim 24, further comprising means for producing an attenuation amount corresponding to said predetermined current.
- 26. An optical fiber amplifier comprising:
a semiconductor laser module comprising:
a semiconductor laser device having an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current, an optical fiber configured to guide the multiple mode laser beam to an output of said laser module, and an optical attenuation device configured to attenuate said multiple mode laser beam by an amount sufficient to provide a predetermined output power from said output of said laser module; and an amplifying fiber coupled to said optical fiber and configured to amplify a signal by using said output of said laser module as a forward excitation light.
- 27. A Raman amplifier comprising:
a semiconductor laser module comprising:
a semiconductor laser device having an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current, an optical fiber configured to guide the multiple mode laser beam to an output of said laser module, and an optical attenuation device configured to attenuate said multiple mode laser beam by an amount sufficient to provide a predetermined output power from said output of said laser module; and an amplifying fiber coupled to said optical fiber and configured to amplify a signal by using said output of said laser module as a forward excitation light.
- 28. A wavelength division multiplexing system comprising:
a transmission device configured to provide a plurality of optical signals having different wavelengths; an optical fiber amplifier coupled to said transmission device and including a semiconductor laser module comprising:
a semiconductor laser device having an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current, an optical fiber configured to guide the multiple mode laser beam to an output of said laser module, and an optical attenuation device configured to attenuate said multiple mode laser beam by an amount sufficient to provide a predetermined output power from said output of said laser module; and a receiving device coupled to said optical fiber amplifier and configured to receive said plurality of optical signals having different wavelengths.
- 29. A Raman amplifier comprising:
a signal fiber configured to carry a signal light; a super large area (SLA) amplifying fiber coupled to said signal fiber; a second amplifying fiber coupled to said signal fiber downstream from said SLA amplifying fiber in a direction of propagation of said signal light; a first semiconductor laser module configured to provide a forward excitation light to said first amplifying fiber, said first semiconductor laser device comprising an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current; and a second semiconductor laser module configured to provide a backward excitation light to said second amplifying fiber, wherein said SLA fiber has a relatively high stimulated Brillouin scattering (SBS) threshold in order to suppress Brillouin scattering of said forward excitation light.
- 30. The Raman amplifier of claim 29, wherein said SLA fiber has a predetermined length sufficient to attenuate the forward excitation light to a level below an SBS threshold of said second amplification fiber.
- 31. The Raman amplifier of claim 29, wherein said second amplification fiber comprises an inverse dispersion fiber configured to compensate for dispersion in said SLA fiber.
- 32. The Raman amplifier of claim 29, wherein said first semiconductor laser module further comprises:
an optical fiber configured to guide the multiple mode laser beam to an output of said laser module; and an optical attenuation device configured to attenuate said multiple mode laser beam by an amount sufficient to provide a predetermined output power from said output of the laser module.
- 33. The Raman amplifier of claim 29, wherein the second semiconductor laser module comprises a FP laser with fiber Bragg grating (FBG).
- 34. The Raman amplifier of claim 29, further comprising:
a second super large area (SLA) amplifying fiber coupled to said signal fiber and disposed between the second amplifying fiber and the second semiconductor laser module.
- 35. The Raman amplifier of claim 34, wherein the second semiconductor laser module comprises a semiconductor laser device having an integrated diffraction grating and is configured to output a multiple mode laser beam in the presence of a driving current.
- 36. A Raman amplifier comprising:
a signal fiber configured to carry a signal light; a super large area (SLA) amplifying fiber coupled to said signal fiber; a second amplifying fiber coupled to said signal fiber upstream from said SLA amplifying fiber in a direction of propagation of said signal light; and a semiconductor laser module configured to provide a backward excitation light to said super large area amplifying fiber, wherein said SLA fiber has a relatively high stimulated Brillouin scattering (SBS) threshold in order to suppress Brillouin scattering of said forward excitation light and the semiconductor laser module comprises a semiconductor laser device having an integrated diffraction grating and configured to output a multiple mode laser beam in the presence of a driving current.
- 37. The Raman amplifier of claim 37, wherein said second amplifying fiber comprises an inverse dispersion fiber configured to compensate for dispersion in said SLA fiber.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2001-304510 |
Sep 2001 |
JP |
|
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application contains subject matter related to U.S. patent application Nos. 09/832,885 filed on Apr. 12, 2001, 09/983,175 filed on Oct. 23, 2001, 09/983,249 filed on Oct. 23, 2001. The entire content of each of these applications is incorporated herein by reference.