Multi-wavelength Erbium-doped Fiber Laser with Tunable
Wavelength Spacing
Xing Luo, Tong Hoang Tuan, Than Singh Saini, Hoa Phuoc Trung Nguyen,
Takenobu Suzuki and Yasutake Ohishi
Research Center for Advanced Photon Technology, Toyota Technological Institute,
2-12-1 Hisakata, Tempaku, Nagoya 468-8511, Japan
Keywords: Multi-wavelength, Erbium-doped Fiber Laser, Michelson Interferometer, Tunable Wavelength Spacing.
Abstract: We demonstrate a stable multi-wavelength ring cavity erbium-doped fiber laser in this paper. A fiber
Michelson interferometer is inserted into the ring laser cavity acting as a multi-wavelength filter to realize
multi-wavelength operation. The optical path difference of the two arms of the fiber Michelson
interferometer is tunable by changing the optical delay line. Thus, the wavelength spacing of the multi-
wavelength laser is tunable by tuning the optical delay line in the Michelson interferometer. Eventually, the
tunable range of the wavelength spacing is realized from 0.045 nm to 0.7 nm in our experiments. More than
60 wavelengths within 3 dB flatness with wavelength spacing of 0.0474 nm can be achieved.
1 INTRODUCTION
Multi-wavelength laser has found a lot of
applications in many filed, such as optical
communication, optical fiber sensing, laser
measurement, optical component testing and so on
(Liu et al., 2011; Salvadé et al., 2008), and many
efforts have been made to obtain high-quality multi-
wavelength laser. There are two issues to deal with
to obtain stable multi-wavelength laser with erbium-
doped fiber as the gain medium. Firstly, the erbium-
doped fiber laser suffers from homogenous line
broadening and cross-saturation in the room
temperature which could lead the unstability of the
multi-wavelength laser (Yao et al., 2004). Many
approaches have been developed to suppress the
homogenous line broadening in erbium-doped fiber
to obtain stable multi-wavelength laser. For
example, cooling the erbium-doped fiber in the
liquid nitrogen was proved to be an effective method
(Yamashita and Hotate, 1996); Utilizing the
nonlinear effects, like stimulated Brillouin scattering
or four wave mixing in the fiber, has achieved good
results in obtaining multi-wavelength erbium-doped
fiber laser (Al-Mansoori et al., 2005, Pan et al.,2006;
Xu et al., 2008). Secondly, in the multi-wavelength
erbium-doped fiber laser, the multi-wavelength filter
is a very important component. Many kinds of multi-
wavelength filters are adopted in the multi-
wavelength lasers, such as multi fiber Bragg grating
(Han et al.,2006), Fabry-Perot cavity (Al-Alimi et
al., 2018; Qin et al.,2006), programmable optical
filter (DeMiguel-Soto et al.,2014), Lyot-Saganc loop
with polarization maintaining fiber (Kim and Kang,
2004; Sugavanam et al., 2014), chirped fiber Bragg
grating (Dong et al., 2006) and so on. In some
applications, like upgradable optical communication
systems, tunability of multi-wavelength laser is very
important. For the most widely studied multi-
wavelength fiber laser using Lyot-Saganc loop filter
consisting of a piece of birefringence fiber, the
wavelength spacing is fixed once the length of the
birefringence fiber is selected (Wang et al., 2013,
Zhang et al., 2008). For the Brillouin-erbium multi-
wavelength laser, the wavelength spacing is still
fixed by the Brillouin shift and the narrow Brillouin
gain bandwidth. Although a wavelength spacing
switchable multi-wavelength Brillouin erbium fiber
laser was realized utilizing cascaded Brillouin gain
fibers, the wavelength spacing is limited by the
narrow bandwidth of the stimulated Brillouin
scattering (Wang, et al., 2016). A wavelength
spacing tunable multi-wavelength laser was
demonstrated by using superimposed chirped fiber
Bragg grating (Dong et al., 2006). Mach-Zehnder
optical fiber interferometer is also demonstrated to
be useful in a wavelength spacing tunable multi-
wavelength laser (Chen et al., 2007).
Luo, X., Tuan, T., Saini, T., Nguyen, H., Suzuki, T. and Ohishi, Y.
Multi-wavelength Erbium-doped Fiber Laser with Tunable Wavelength Spacing.
DOI: 10.5220/0006886302410245
In Proceedings of the 15th International Joint Conference on e-Business and Telecommunications (ICETE 2018) - Volume 1: DCNET, ICE-B, OPTICS, SIGMAP and WINSYS, pages 241-245
ISBN: 978-989-758-319-3
Copyright © 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
241
In this paper, we demonstrate a new multi-
wavelength erbium-doped fiber laser with tunable
wavelength spacing. A tunable Michelson fiber
interferometer consisting of an optical delay line is
inserted into the ring laser cavity to act as a
continuous tunable multi-wavelength filter.
Meanwhile, a nonlinear polarization rotation (NPR)
structure combined with a piece of long dispersion
shift fiber is introduced into this laser to suppress
longitudinal mode competition based on its
intensity-dependent loss feature. By tuning the
optical delay line, the tunability of the wavelength
spacing can be realized from 0.045 nm to 0.7 nm
continuously. More than 60 wavelengths within 3
dB flatness with wavelength spacing of 0.0474 nm
can be achieved.
2 EXPERIMENTAL SETUP
Figure 1(a) shows the schematic configurations of
the spacing-adjustable multi-wavelength erbium-
doped fiber laser. A 1480 nm laser diode (LD) is
connected to a wavelength division multiplexer
(WDM) to pump a piece of 2.1 m erbium-doped
fiber. The maximum output power of the 1480 nm
LD is ~283 mW. A piece of 5 km dispersion shift
fiber (DSF) is inserted into the laser cavity to
enhance the nonlinear effect. The 10% arm of a 10
dB coupler is used as the output port of the multi-
wavelength laser. A polarization dependent isolator
and two polarization controllers (PCs) constitute a
Nonlinear Polarization Rotation structure (NPR). A
fiber Michelson interferometer is inserted into the
laser cavity to act as the multi-wavelength filter and
realize multi-wavelength operation of the laser. The
schematic configuration of the spacing-adjustable
Michelson interferometer is shown in the red dashed
box in Fig.1 (a). The Michelson interferometer
consists of a 3 dB coupler, a tunable optical delay
line (ODL) and two wide band optical reflectors
(ORs). The mechanism of the Michelson
interferometer can be understood as following: The
input laser splits into two parts with the same
amplitude in the 3dB coupler; The two laser beams
propagate forward and are reflected back by the
wideband optical reflectors and then interfere with
each other in the 3 dB coupler. The interference
results in the comb filtering effect due to the
different optical path of the two arms. There is a
tunable ODL inserted into one arm of the fiber
Michelson interferometer, which makes the optical
path difference tunable. The Schematic
diagram of
the optical delay line is shown in Fig.1 (b). The ruler
of the ODL marks the position of the corner cube
mirror in the ODL. When changing the ODL ruler
reading to a position that makes the two arms of the
Michelson interferometer have the same length, the
optical path difference is zero. The wavelength
spacing of the transmission peaks of the Michelson
interferometer can be calculated by:
1480 nmLase
r
EDF
ISO
PD-ISO
PC
PC
ODL
OR
OR
1480/1550 WDM
10%
90%
10dB coupler
DSF
3dB coupler
(a)
cube mirror
Ruler
Fiber
Fiber
cube mirror position
(b)
Figure 1: (a) Schematic diagram of the tunable multi-
wavelength laser with Michelson interferometer. EDF:
erbium-doped fiber; DSF: dispersion shift fiber; ODL:
optical delay line; OR: optical reflector; PD-ISO:
polarization dependent isolator; PC: polarization
controller. (b) Schematic diagram of the optical delay line.
1546 1548 1550 1552 1554
-10
-8
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-4
-2
0
Transmission,dB
Wavelength,nm
Figure 2: A typical measured transmission spectrum of the
fiber Michelson interferometer.
OPTICS 2018 - International Conference on Optical Communication Systems
242
22
=
1
1
2
2
1
22
22
*
1
nL nL
mm
mm
nL
mm
nL nL
nL nL
mm
(1)
Where λ is the central wavelength, n is the refractive
index of air which is near to 1 in our case; ΔL is the
optical path difference introduced by the ODL. As
the laser propagates through the ODL twice, there is
a coefficient 2 in the formula. A typical measured
transmission spectral of the Michelson
interferometer using an ASE source is shown in Fig.
2. The value of the transmission peak is -0.9 dB
which can be attributed to the loss of the two arms.
The transmission spectrum of the Michelson
interferometer indicates its great potential to be used
as a multi-wavelength filter. The optical path
difference of the two arms can be continuously
adjusted by tuning the ODL. Therefore, we can
realize wide range tuning of the wavelength spacing
of multi-wavelength fiber laser by changing the
ODL in the Michelson interferometer. The ruler of
the ODL marks the position of the corner cube
mirror in the ODL. The changing of the optical path
introduced by the ODL can be calculated by the
reading of the ruler of the ODL. In the measurement
of the transmission spectra of the Michelson
interferometer, it was found that when the ODL ruler
reading is set to ~30 mm the transmission peak
spacing become very wide. It means that in this case
the optical path difference of the two arms is about
zero. When changing the ODL ruler reading to a
position that makes the two arms of the Michelson
interferometer have the same length, the optical path
difference is zero. Moving the ODL ruler reading
away from 30 mm leads to the increasing of the
optical path difference and the narrowing of the
transmission peak spacing. So the ODL ruler reading
30 mm can be deemed as the zero point. As the ruler
reading is the position of the corner cube mirror in
the ODL, the optical path difference ΔL introduced
by the ODL is twice of the difference between the
ruler reading and the zero point.
3 RESULTS
In the experiments, wideband, flat and stable multi-
wavelength laser can be obtained with correct setting
of the polarization controllers and suitable pump
power. Once the pump power reaches the threshold,
the multi-wavelength output can be achieved by
correct setting of polarization controllers.
1556 1558 1560 1562 1564 1566
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0
Intensity,dB
Wavelength,nm
28mm
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0
Intensity,dB
Wavelength,nm
26mm
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Intensity,dB
Wavelength,nm
24mm
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Intensity,dB
Wavelength,nm
22mm
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6
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0
Intensity,dB
Wavelength,nm
18mm
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-70
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-10
0
Intensity,dB
Wavelength,nm
20mm
Figure 3: Output spectra of the multi-wavelength laser
with different ODL ruler reading when the pump power is
fixed at 280 mW.
Multi-wavelength Erbium-doped Fiber Laser with Tunable Wavelength Spacing
243
1556 1558 1560 1562 1564 1566
-70
-60
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0
Intensity,dB
Wavelength,nm
17mm
1558.0 1558.5 1559.0 1559.5 1560.0
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Intensity,dB
Wavelength,nm
17mm
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-50
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Intensity,dB
Wavelength,nm
17mm
Figure 4: Output spectra of the multi-wavelength laser
with ODL ruler reading of 17 mm. (a) Overall spectrum
measured by the OSA. (b) and (c) Detailed spectra
measured by the HRS.
As we mentioned above, the wavelength spacing
of the multi-wavelength laser can be tuned
continuously by adjusting the ODL according to
formula (1). Figure 3 shows the output spectra of the
multi-wavelength laser with different ODL ruler
reading. For instance, as shown in Fig. 3(e), the
multi-wavelength spacing is ~0.0607 nm. In this
case, the ODL ruler reading is 20 mm, the optical
path difference ΔL equal to 2*(30mm-20mm)
=20mm. When the central wavelength of the laser is
about 1560 nm and the optical path difference is 20
mm, from formula (1), the calculated wavelength
spacing is ~0.061 nm. The experiment results are in
good agreement with the theoretical values. As
shown in Fig.3, with different ODL ruler reading,
the wavelength spacing of the multi-wavelength
laser is different. The larger the ODL ruler reading
deviates from 30 mm, the narrower the wavelength
spacing is. It can be found that the contrast of the
multi-wavelength peaks to the background decreases
with the narrowing of the wavelength spacing. We
believe it is due to the limited resolution (0.05 nm)
of the optical spectral analyzer (OSA, Yokogawa
AQ6375B). When the ODL ruler reading is 18 mm,
the measured output spectrum of the multi-
wavelength laser is shown in Fig. 3(f). In this case,
the output spectrum seems very flat and the spectral
peaks of the multi-wavelength almost cannot be
recognized. When the ODL ruler reading is 17 mm,
the measured output spectrum is shown in Fig 4.(a)
and the theoretical wavelength spacing calculated
with formula (1) is ~0.047 nm. In order to obtain
more information about the output spectrum, we
used a high resolution spectrometer (HRS, Agilent
83453B) to measure the output of the multi-
wavelength laser. The measured spectra are shown
in Fig. 4(b) and Fig. 4(c). Obvious spectral peaks
with wavelength spacing 0.0474 nm can be observed.
About 60 wavelengths are obtained with 3 dB
flatness. We believe that increasing the deviation of
the ODL ruler reading of the ODL further, the
wavelength spacing will become narrower and more
wavelengths can be obtained. By tuning the ODL
carefully, the wavelength spacing can be adjusted
continuously and we can obtain multi-wavelength
laser output with any wavelength spacing within the
range. We believe that with proper ODL setting and
pump power, it is feasible to realize multi-
wavelength output with spacing of 0.8 nm which is
standard in telecommunication. In the experiment,
no obvious power and wavelength fluctuation were
observed when all the fibers are fixed well on the
optical table. On the other hand, as the NPR
structure is sensitive to the polarization status, we
found that the central wavelength of the laser would
change if we bend the fibers in the laser.
4 CONCLUSION
A multi-wavelength fiber laser with tunable
wavelength spacing is demonstrated. A Michelson
interferometer consist of an optical delay line was
used as a tunable multi-wavelength filter. A NPR
structure with a long piece of dispersion shift fiber
was used to the equalize multi-wavelength and
suppress wavelength competition. Finally, a multi-
wavelength ring fiber laser with flat spectra was
obtained with continuously tunable wavelength
spacing. The wavelength spacing can be tune
continuously from 0.045 nm to 0.7 nm. More than
60 wavelengths within 3 dB flatness with spacing of
0.0474 nm can be achieved.
OPTICS 2018 - International Conference on Optical Communication Systems
244
ACKNOWLEDGEMENTS
This work was supported by the JSPS KAKENHI,
grant No.15H02250, 17K18891 &18H01504 and by
JSPS and CERN under the JSPS-CERN joint
research program.
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