The present invention relates to an optical transmission system, and more particularly to an optical transmission system arranged to transmit high optical powers.
When high optical powers are transmitted in an optical fibre, the peak optical power within the fibre is reduced by non-linear processes. One such non-linear process is stimulated Raman scattering (SRS). In SRS, part of the energy of the incident light is transferred to a different frequency to that of the incident light. The energy transferred is mainly to the Stokes light having a lower frequency than the incident light. If the Stokes light is of high enough power, second or higher order Stokes light is produced.
In silica based optical fibre the frequency difference between incident and the first Stokes light is generally about 13 THz. For example, when light at a wavelength of 1064 nm is propagated through conventional optical fibre, the first Stokes light occurs at around 1120 nm.
The suppression or removal of Stokes light is important in the laser processing industry where high optical powers are sometimes used. The energy transfer caused by SRS may result in peak power depletion of incident light and deterioration of the capacity of laser processing.
Hollow-core photonic bandgap fibres (PBGFs) which can guide the light in an air core have been proposed for suppression of non-linear processes including SRS (J. D. Shephard et al., Opt. Express, 12 (2004), 717). However, their complex structure is an obstacle to realize commercial fabrication at present. As alternative methods, dual-hole assisted fibre (L. A. Zenteno et al., Opt. Express, 13 (2005), 8921), filter fibre (J. M. Fini et al., Optics Letters, 31 (2006), 2550), and W-type fibre (J. Kim et al., Opt. Express, 14 (2006), 5103) have been demonstrated. These fibres use mode coupling between the core guided mode and lossy cladding mode to eliminate the unwanted Stokes light. The intensity of light in the cladding mode decays due to the lossy nature of the cladding mode. Generally, the intensity of coupling from the core mode to cladding mode is affected by bending in these fibres. Moreover, the bandwidth over which light is coupled from core to cladding will change if the fibre is bent randomly. Therefore, the application of these SRS suppression schemes to delivery fibre is not practical. Hence, it is desirable to provide fibres which can suppress SRS and whose properties are stable against random bending in practical use.
The present invention provides an optical transmission system comprising: a laser light source arranged to emit light having a frequency ω; and an optical transmission line adapted to guide the light, wherein said optical transmission line includes a photonic bandgap optical fibre which guides light at a frequency ω and attenuates light at a frequency of ω-13 THz. The attenuation band or high loss band at a 13 THz offset from the transmission frequency is used to suppress Raman gain or light resulting from SRS.
The high loss band may be provided by the photonic bandgap fibre having a band edge between the frequency ω and the frequency ω-13 THz. The band edge may be provided by the edge of the third order transmission band of the photonic bandgap fibre.
The photonic band gap fibre may have a transmission loss at a frequency ω-13 THz that is 10 dB greater than the transmission loss at a frequency ω.
The photonic bandgap fibre may be an all-solid photonic bandgap fibre including a cladding having a periodic array of elements, each element having higher refractive index than the surrounding background material. The elements may have a peak refractive index difference of 3% to the background material. The elements may be formed from high index rods of diameter d and spaced apart in the background material on a pitch Λ, wherein d/Λ is 0.6. Optionally, the frequency ω may be the frequency of light at the wavelength of 1064 nm.
The present invention also provides a photonic bandgap optical fibre for use in suppressing stimulated Raman scattering, the fibre comprising: a core adapted to guide light at frequency ω, and to attenuate light at a frequency of ω-13 THz. The photonic bandgap optical fibre may have a transmission loss at a frequency ω-13 THz that is 10 dB greater than the transmission loss at a frequency ω.
The present invention also provides a method of suppressing stimulated Raman scattering in an optical transmission system, comprising: providing a laser light source emitting light having a frequency ω; and coupling the emitted light into an optical transmission line, wherein said optical transmission line includes a photonic bandgap fibre having a core guided mode at frequency ω and a high loss band at a frequency of ω-13 THz.
a shows a cross-section of the all-solid photonic bandgap fibre used in the present invention.
b is a schematic illustration showing the diameters and pitch of the high index elements in the cladding of the fibre.
In contrast to hollow-core photonic bandgap fibres, silica based all-solid photonic bandgap optical fibres (PBGFs) provide the possibility of economical commercial manufacture. This is because they have a structure which can be accurately controlled to achieve a fibre with the desired properties in good agreement between design and experiment. These fibres also offer design flexibility and can achieve low loss.
In addition, all-solid PBGFs have strong attenuation bands which are an intrinsic property of the bandgap fibre. The attenuation band can be used to suppress stimulated Raman scattering (SRS).
An all-solid photonic bandgap fibre was prepared as shown in
As shown in
From the preform, two fibres were drawn representing different embodiments. The parameters of each fibre are listed in table 1.
The fibres were designed for use with a laser source operating at 1064 nm. In silica fibre, the Raman shift is around 13 THz, resulting in the first Stokes light occurring at around 1120 nm. The diameters of the two fibre were adjusted during manufacture to provide bandgap edges close to the wavelength of the Stokes light. Fibre #1 was adjusted to have an outer diameter of 165 μm and a core diameter of 9.7 μm, which provides a red bandgap edge located at 1100 nm. For Fibre #2, the outer diameter of the fibre was 172 μm and the core diameter was 10.1 μm, which provides a red bandgap edge located at 1140 nm. The calculated effective area of the design is around 50 m2.
The position of the bandgap edges of the two fibres is shown in more detail in
Transmission spectra were also measured when fibre #1 was wound around a small diameter mandrel. Diameters of 20 mm and 30 mm were used, and the transmission spectra are shown in
An experiment confirming that the fibre is capable of suppressing SRS, that is, reducing the optical power of the Stokes light will now be described. The experimental set up is shown in
Fibre #2 was used as a reference fibre and has a band edge at 1140 nm. Hence, the first Stokes light is seen at around 1120 nm as this is within the transmission band of that fibre. Fibre #1 has a band edge at 1100 nm. In this fibre, the first Stokes light at around 1120 nm is significantly suppressed. Some spectral broadening is observed in fibre #1, perhaps due to weak continuum. For both fibres, the output spectra around the red edge of the third bandgap are identical to the spectra shown in
The above experiments confirm that PBGF can be used in suppressing Raman gain in optical transmission systems. The all-solid PBGF described is fabricated such that the core of the fibre does not support optical modes at the wavelength of the first Stokes light. Hence, first Stokes light is coupled from the core to cladding modes. Cladding modes are inherently very lossy and rapidly decays any Stokes light in the cladding mode. The all-solid PBGF provides the advantage over conventional SRS suppression techniques in that the bandgap edges are more stable and are particularly tolerant to bending of the fibre.
The person skilled in the art will readily appreciate that the above described invention may be changed in many ways without departing from the scope of the appended claims. For example, different fibres and fibre materials may be used, or the wavelengths of the core optical mode may be changed.
Number | Name | Date | Kind |
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6728439 | Weisberg et al. | Apr 2004 | B2 |
7072553 | Johnson et al. | Jul 2006 | B2 |
20020164137 | Johnson et al. | Nov 2002 | A1 |
20030031407 | Weisberg et al. | Feb 2003 | A1 |
Number | Date | Country | |
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20090252452 A1 | Oct 2009 | US |