Методы измерений, контроля, диагностики 
 
116  Приборы и методы измерений, № 2 (3), 2011 
УДК 535.31, 621.372.8 
 
BROADBAND METHOD FOR GROUP VELOCITY DISPERSION  
MEASUREMENTS IN THE MID-INFRARED 
 
Klimentov D.S.
1,2
, Tolstik N.A.
1
, Dvoyrin V.V.
1,3
, Sorokina I.T.
1 
 
1
Department of Physics, Norwegian University of Science and Technology, Trondheim, Norway  
2
Natural Sciences Center, General Physics Institute of Russian Academy of Sciences, Moscow, Russia 
3
Fiber Optics Research Center, Russian Academy of Sciences, Moscow, Russia 
 
A setup for broadband measurements of dispersion parameter in optical fibers based on the 
Mach–Zehnder interferometer is developed. Tm-doped fiber pumped at 1.61 μm was used as a 
source of broadband emission, that allowed to achieve the measurement spectral range of 1700 
to 2000 nm. The method is applicable for comparatively short pieces of optical fiber with 
lengths of less than 1 meter. The method was successfully tested for the standard telecommuni-
cation SMF-28 fiber. (E-mail : nikolai.tolstik@ntnu.no) 
 
Key Words: optical fiber, dispersion measurements, mid infrared. 
 
Introduction 
 
Solid-state and fiber lasers working at 2-μm 
wavelength are of great interest because of several 
favorable characteristics. Owing to the strong ab-
sorption by liquid water, the 2-μm laser is an ideal 
light source for bio-medical applications. The 2-
μm laser can also be used for range finding, cohe-
rent laser LIDAR and atmospheric sensing since it 
is in the eye-safe spectral range. In addition, high-
power 2-μm lasers are preferable as pump sources 
for optical parametric oscillators (OPOs) and opti-
cal parametric amplifiers (OPAs) in the mid-
infrared region than 1-μm lasers since they provide 
higher quantum efficiency. Based on these consi-
derations, solid-state and fiber lasers operating 
around the 2-μm waveband have been intensively 
investigated recently [1–4]. 
However, only few demonstrations of mode-
locked subpicosecond fiber lasers operating at 2 
μm have been reported to date, mainly due to lack 
of proper pulse initiative components and large 
anomalous dispersion of conventional optical fi-
bers at 2 μm [5–8]. Precise cavity design or disper-
sion management of active as well as passive opti-
cal fibers became essential for generation and de-
livery of ultrashort pulses in this spectral range. 
Measuring of dispersion in fibers is also important 
since it became possible to produce special micro-
structured optical fibers (photonic crystal fibers - 
PCF) with controllable group-velocity dispersion 
[9, 10]. Such fibers with precisely positioned zero-
dispersion wavelength are used as sources of su-
perbroadband emission (supercontinuum) [11, 12], 
which are important for spectroscopic applications, 
detection of gases etc.  
Several methods were developed for measu-
ring of dispersion parameter of optical fibers since 
1980’s [13–17]. Most of the techniques are inter-
ferometric and require the source of low-coherent 
emission to be used in the setup. The most chal-
lenging task on the way of adopting these methods 
for mid-IR spectral range is the lack of the broad-
band sources of low-coherent light in this spectral 
region.  In this work we present a setup for mea-
surements of dispersion parameter in optical fibers 
in the wavelength range from 1.7 to 2.0 microns. 
The setup is distinguished from the existing similar 
measurement systems by using the broadband 
high-power superluminescent fiber source, allo-
wing to achieve broad spectral coverage with a 
high signal-to-noise ratio. For the demonstration of 
capabilities of the setup we present dispersion pa-
rameter measurement of standard telecommunica-
tion fiber. 
 
Description of the method 
 
The experimental setup is presented in figure 
1. The setup is based on Mach-Zender interferome-
ter. As a source of superluminiscent emission a 
high numerical aperture 5-m long Tm-doped fiber 
was used. The luminescence in the fiber was exci-
ted by CW Er-fiber laser emitting at 1610 nm. To 
prevent lasing in Tm-fiber its output end was 
cleaved to 7 degrees and excitation power was lim-
 Методы измерений, контроля, диагностики 
 
Приборы и методы измерений, № 2 (3), 2011  117 
ited to 600 mW. The spectrum of the superlumi-
nescence is presented in figure 2. The optical pow-
er of the amplified spontaneous emission with 
about 50 nm FWHM reached 5 mW. This power 
level exceeds, to our knowledge, the optical 
power of the best commercially available super-
luminescent semiconductor lasers at this wave-
length. 
 
 
Figure 1 – Experimental setup for measurements of dispersion parameter in optical fibers  
in mid-IR spectral region 
 
 
Figure 2 – Spectrum of superluminescence of 5-m long Tm-doped fiber. The narrow band at 1610 nm is the 
emission of erbium fiber laser used as excitation source 
 Методы измерений, контроля, диагностики 
 
118  Приборы и методы измерений, № 2 (3), 2011 
The luminescence emission produced in the 
fiber was collimated and divided to two equal parts 
by 50/50 dielectric beamsplitter (at 2000 nm, 45°). 
The fiber under test was placed into the sample 
arm and the air arm is used as the reference arm 
with variable length. The fiber in the sample arm 
was modulated. As a modulator «M» we used elec-
tromagnetic system that induced periodical longi-
tudinal tension of the fiber and thus provided si-
nusoidal change in optical path length of the sam-
ple arm. The modulation amplitude was equal to 
several micrometers. The electromagnetic modula-
tor was connected to the frequency generator and 
operated at about 190 Hz. The optical length of the 
reference arm was tuned to be equal to the optical 
length of the sample arm. After the propagation 
through reference and sample arms, the beams 
were recombined by another dielectric beamsplit-
ter. If the difference between optical lengths of the 
arms is lower than coherence length of the light 
source, than periodically changing interference 
pattern arises. After recombination the resulting 
beam was passed through the double-prism Carl 
Zeiss monochromator with sensitive extended-
InGaAs photodetector installed on the output slit. 
The monochromator allowed to filter out the cer-
tain narrow band and to scan over the spectrum.  
In the experiment we measured the depen-
dence of beam path difference between the sample 
and the reference arms of the interferometer on the 
wavelength. The signal from the detector was pre-
amplified and directed to selective amplifier in or-
der to filter out the interference signal from the 
noise. The intensity of the signal was measured by 
the AC voltmeter. The shape and amplitude of in-
terference signal was additionally controlled by the 
oscilloscope.  
Based on these data, the dependence of the 
path difference ∆l on the wavelength λ  was plot-
ted. Dispersion parameter D(λ) and path difference 
∆l(λ) are related through [18]: 
 
,
л
)]л([1
)л(
d
ld
Lc
D  (1) 
 
where L is the length of the fiber under test; c is the 
speed of light.  
 
 
Experimental verification 
 
 
In order to verify the measurement technique 
described above the dispersion parameter of stand-
ard telecommunication fiber SMF-28 was meas-
ured with the setup shown in figure 1. The piece of 
fiber under test had the length of 80 cm. The spec-
tral resolution of the measurements was defined by 
the spectral bandwidth of the monochromator slit 
and was equal to about 35 nm in the current meas-
urements. The data points were taken every 15 nm.  
The signal to noise ratio was estimated to be about 
7 at 1820 nm wavelength and 2 at the limits of our 
spectral range. 
 
 
 
Figure 3 – The results of dispersion measurements in SMF-28 standard telecommunication fiber (solid line) 
in comparison with investigation results of SMF-28 from Fiber optics research center, Russian academy of 
sciences (dashed line) 
 Методы измерений, контроля, диагностики 
 
Приборы и методы измерений, № 2 (3), 2011  119 
The results of the measurements are presented 
in figure 3 and compared to the results of the in-
vestigation of the same fiber, performed in the Fi-
ber Optics Research Center, Russian Academy of 
Sciences. It can be seen that the measurement error 
generally do not exceed 10 % and reaches 30 % at 
the limits of the available spectral range only, 
where the signal to noise ratio is quite low. Con-
siderable advantage of the described technique is 
possibility to perform measurements on short fiber 
samples – in the current setup the allowable fiber 
lengths is 0.5 to 2.5 meters. Mentioned feature 
makes the developed method promising for inves-
tigation of novel special optical fibers, where the 
length of the sample could be critical.  
 
Conclusion 
 
In conclusion, we introduced interferometric 
setup for measurements of dispersion parameter of 
optical fibers, particularly prospective for specialty 
short-length fibers for infrared applications. The 
characteristic feature of the setup is that it is based 
on a broadband and rather intensive superlumines-
cent Tm-fiber source, allowing making measure-
ments in a broad wavelength range, at least 300 nm 
around 1,82 microns. Further optimization of the 
setup will help us to reduce the currently present 
measurement errors, thus, allowing obtaining dis-
persion curves with high accuracy. 
  
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120  Приборы и методы измерений, № 1 (2), 2011 
 
 
 
Климентов Д.С., Толстик Н.А., Двойрин В.В., Сорокина И.Т. 
 
Методика измерений дисперсии групповой скорости в широком спектральном диапазоне    
в инфракрасной области спектра 
 
Разработана широкополосная методика измерений показателя дисперсии в оптических волокнах, 
основанная на схеме интерферометра Маха–Цендера. В качестве источника излучения широкого 
спектрального диапазона использовано оптическое волокно, легированное ионами Tm3+, накачивае-
мое на длине волны 1,61 мкм, что позволило достичь спектрального диапазона измерений от 1700 до 
2000 нм. Метод может применяться для относительно небольших образцов оптических волокон с 
длиной менее 1 метра. Методика была успешно протестирована для стандартного телекоммуникаци-
онного волокна SMF-28. (E-mail : nikolai.tolstik@ntnu.no) 
 
Ключевые слова: оптическое волокно, измерения дисперсии, средний ИК-диапазон. 
 
Поступила в редакцию 19.09.2011.