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Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International
Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622
www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707
1703 | P a g e
Performance Optimization of Long Haul High Bit Rate Optical
Fiber System with Dispersion Compensating Fiber
Vineet Mubai1
, A. K. Jaiswal2
, Mukesh Kumar3
, Rohini Saxena4
, Neelesh
Agrawal5
1
PG Student, 2
Professor & H.O.D, 3, 4, 5
Assistant Professor (ECE, Deptt.)
1, 2, 3, 4, 5
Department of Electronics and Communication Engineering, SHIATS-DU, ALLAHABAD
ABSTRACT
In this paper the comparison of the
performance characteristic of pre and post
compensation is done to reduce the chromatic
compensation. The transmission behavior of
return-to-zero (RZ) and non return-to-zero is
compared numerically and experimentally. Data
at the rate of 10 Gb/s were transmitted over 2000-
km standard single-mode fiber using an
alternative compensation scheme in a
recirculation loop with more than 100 km
amplifier spacing. The pre-compensation and
post-compensation scheme is proposed using DCF
to reduce the chromatic dispersion at the
transmitter end. This method improves the Q-
factor in single wavelength of 1550 nm.
Keywords-BER, Dispersion Compensation,
Dispersion Compensating Fiber, Fiber transmission,
NRZ Modulation, RZ Modulation, Single Mode Fiber.
I. INTRODUCTION
Single-mode fiber (SMF) network are
subject to stringent limitations in fiber length due to
the linear chromatic dispersion when the high
capacity fiber optic transmission system is operated
at 1.55µm [1]. Passive dispersion compensation using
dispersion compensating fibers (DCF) is one of the
most powerful approaches to
overcome this limitation and has been investigated
intensively during the past few years [1]-[3].
One of the most promising methods of
installing high capacity all-optical network on the
already existing SMF base is the use of dispersion
compensating fiber so as to reduce or compensate for
the dispersion slope directly. Reverse dispersion fiber
and an inline dispersion slope compensator with
arrayed waveguides (AWGs) and DCFs can be used
to achieve this compensation of dispersion.
To date network design is aiming to achieve
SMF amplifier spacing above zz= 100 km in order to
reduce the number of repeater stations. Higher input
powers are required due to these extended lengths of
SMF sections, thus increasing the effect of
nonlinearities [2], [4].
Work has been carried out for Pre-
compensation and post-compensation of chromatic
dispersion at the transmitter end. This has brought in
improved Q-factor and results the BER in the desired
range in single wavelength. Data at the rate of 10-
Gb/s is transmitted using NRZ and RZ transmission
over 2000-km SMF with increased amplifier spacing
of more than 100 km in a recirculation loop [5], [6]
has been demonstrated experimentally and system
behavior has been explained by numerical
simulations. As it is obvious from theory that for
higher data rates return-to-zero (RZ) modulation
format is better than that to NRZ, hence the
transmission of a 10-Gb/s RZ data signal through the
transmission line and comparison of the performance
to the NRZ system has been done.
The RZ pulse occupies just a part of the bit
slot, so it has a duty cycle smaller than 1 and a broad
spectrum. The RZ signal has amplitude between
adjacent 1’s returns to zero. A RZ signal has
spectrum peak power twice the larger than that of the
NRZ signal with the same average power. The main
characteristic of RZ modulated signals is a relatively
broad optical spectrum, resulting in a reduced
dispersion tolerance and a reduced spectral
efficiency. The RZ pulse shape enables an increased
robustness to fiber nonlinear effects. The RZ
performs better than NRZ because the energy is
confined in the center of each bit-slot in the case of
RZ case and thus more differential group delay
(DGD) is required before the energy leaks out the bit-
slot to result in inter-symbol interference.
II. EXPERIMENTAL SETUP
The experiments are performed in a
recirculation span (Fig 1 and Fig 2) in which there is
PRBS generator with the 10Gbps bit rate and pattern
length also a continuous wave laser source has been
used to generate carrier wave at 1550 nm wavelength.
Machzehnder modulation as an external
modulator is used and 80 km single mode fiber
(SMF) having positive dispersion coefficient is used
with total dispersion of +1358 ps/nm/km In order to
compensate the transmitting fiber dispersion we
inserted DCF 20 km with negative dispersion slope
of -67.69ps/nm/km. An EDFA amplifier is also used
with 30GHz bandwidth in the system.
Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International
Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622
www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707
1704 | P a g e
Fig. 1 Pre-compensation of chromatic dispersion
Fig. 2 Post-compensation of chromatic dispersion
III. EXPERIMENTAL RESULT
In the pre-compensation scheme, total
negative dispersion generated by DCF is -1358
ps/nm/km, which is compensated through 80 km
SMF of positive dispersion slope. BER is measured
at data packets after 20 round trips corresponding to
2000 km SMF length. In the case of NRZ, at very
low power 0.5mW the Q-factor is 16.16dB and at
1mW power level the Q-factor becomes 14.76dB
which is below the desired value of 15.56dB. Also by
the numerical simulation, it thus enable us to achieve
BER<10-9
. For RZ modulation format on the other
hand, at 1mW power the Q-factor has maximum
value of 22.31dB and BER is 2.792×10-39
. As we
increase the power above 1mW, Q-factor decreases.
In post compensation DCF reduces the
dispersion which is generated by the 80 km SMF. In
this compensation scheme, NRZ modulation is
applicable below 2mW signal power to get the
desired range of BER and Q factor but RZ
modulation has a large range of signal power. Hence
at 10mW power Q-factor is 16.077dB for RZ
modulation and BER is 9.709×10-11
, which is
appropriate for optical communication.
Fig 3 Eye diagram of post-compensation of
chromatic dispersion with NRZ
Fig. 4 Eye diagram of pre compensation of chromatic
dispersion with NRZ
Figure 3 shows the eye diagram of post-
compensation of chromatic dispersion with NRZ
modulation. This figure has been taken at 1 mW
power. At the time of maximum eye opening,
sampling of the signal is best, that is the transmission
of signal will be error free. In this transmission
system, the eye opening is best at the time of signal
transmission. The width of the eye opening defines
the time interval over which the received signal can
be sampled without error from intersymbol
interference.
In pre-compensation of the same
transmission system, the eye diagram as shown in
Figure 4 contains some distortion in the signal. Some
noise seen in the diagram and eye opening is also less
Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International
Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622
www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707
1705 | P a g e
in this as compared to the post compensation of
chromatic dispersion.
Fig. 5 Eye diagram of post compensation of
chromatic dispersion with RZ modulation
Fig. 6 Eye diagram of pre compensation of
chromatic dispersion with RZ
On the transmission of RZ signal in post
compensation scheme, BER is find very low as
compared to desired system BER (10-9
to 10-12
) and
also the quality factor is very high as compare to
desired quality factor (15 to 17) of the system. From
figure 5 and figure 6 it is clear that the eye opening is
very poor at the time of transmission.
From the analysis of eye diagram NRZ modulation is
better perform in the post compensation of the
chromatic dispersion as compared to the RZ
modulation format.
On the transmission of RZ signal in pre
compensation technique, the eye opening of the
system is very less as compared to the NRZ
modulation format. BER is very low as compare to
desired value of the system and also Q (dB) is very
high as compared to desired value of system value.
Fig. 7 Dispersion map in the Post Compensation of
the Chromatic Dispersion
Figure 7 shows the dispersion map for the
post compensation scheme in which it is clear that the
total dispersion created after the 80 km SMF is 1368
ps/nm/km and then after passing it through the 20 km
DCF the dispersion reduces towards zero. The
received signal is then amplified by the EDFA
(erbium doped fiber amplifier) and then it is
transmitted to next 100 km span [7].
Fig. 8 Dispersion map for Pre-Compensation of
Chromatic Dispersion
In Figure 8, dispersion map of the pre
compensation scheme is shown, from which it is
evident that the total dispersion passes through the 20
km DCF reduces the dispersion towards -1200
ps/nm/km. Then the total dispersion created after the
Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International
Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622
www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707
1706 | P a g e
80 km SMF is 1368 ps/nm/km which compensates
the dispersion through the DCF towards zero. The
received signal is then amplified by the EDFA
(erbium doped fiber amplifier) and transmitted over
the next 100 km span.
IV. CONCLUSION
10 Gb/s data transmission over 2000-km
SMF at 1.55 µm with more than 100 km amplifier
spacing with an alternating dispersion compensation
scheme in a recirculation span is demonstrated
experimentally.
At 10Gbps bit rate, 1550 nm wavelength pre-
compensation is better than the post compensation. In
the Pre compensation Q-factor and BER improves as
compared to the post compensation. Also it has been
analyzed and investigated that the NRZ Modulation
is better than the RZ modulation although in the RZ
modulation, for large power we get the BER less than
10-9
, which is suitable for optical communication at
1550 nm wavelength.
REFERENCES
[1] D. Breuer, K. Ennser, and K. Petermann ,
“Comparison of NRZ- and RZ modulation
format for 40 Gb/s TDM standard-fiber
systems,” presented at ECOC’96, Oslo,
Norway, vol. 2, 1996, paper TuD.3.3..
[2] D. Breuer, K. J¨urgensen, F. K¨uppers, A.
Mattheus, I. Gabitov, and S. K.
Turitsyn,“Optimal schemes for dispersion
compensation of standard monomode fiber
based links,” Opt. Commun., vol. 140, pp.
15–18, July15, 1997.
[3] D. M. Rothnie and J. E. Midwinter,
“Improved standard fiber performance by
positioning the dispersion compensating
fiber,” Electron. Lett., vol. 32, no. 20, pp.
1907–1908, Sept. 1996.
[4] N. Smith, F.M. Knox, N.J. Doran, K.J.
Blow, I. Bennion, Electron. Lett. 32 (1996)
55.
[5] N. Kikuchi, S. Sasaki, and K. Sekine, “10
Gb/s dispersion-compensated transmission
over 2245km conventional fibers in a
recirculatiing loop,” Electron. Lett., vol. 31,
no. 5, pp. 375–377, Mar. 1995.
[6] N. Kikuchi and S. Sasaki, “Fiber
nonlinearity in dispersion-compensated
conventional fiber transmission,”
Electron. Lett., vol. 32, no. 6, pp. 570–572,
Mar. 1996.
[7] S. Artigaud, M. Chbat, P. Nouchi, F.
Chiquet, D. Bayart, L. Hamon, A. Pitel, F.
Goudeseune, P. Bousselet, J.-L.
Beylat,Electron. Lett. 32(1996) 1389.
Vineet Mubai was born in Allahabad, U.P,
India in 1984. He received B.Tech from the
department of Electronics and Communication from
B.B.S College of Engineering and Technology,
Allahabad in 2006. He is perusing M.Tech from the
Department of Electronics and Communication
Engineering from S.H.I.A.T.S, Allahabad. His main
research interest includes Optical Fiber
Communication System.
Email-ec.mvineet@gmail.com,
Mobile:+91-9695063167
Prof. Arvind Kumar Jaiswal was born in
1942. He is M.Sc in Science and M.Sc (Tech.) in
Electronic and Radio Engineering from Allahabad
University. He has 33 years of industry experience
and 10 years of teaching experience. Prof. A.K
Jaiswal is working as Professor and Head of
Electronics and Communication department in
SHIATS-DU, Allahabad. He guided many
Undergraduates and Post Graduates Students in their
projects and Research work. He has 3 publications on
various platforms. His research interests includes
Optical Fiber Communication and Control Systems.
Email: arvind.jaiswal@shiats.edu.in
Mukesh Kumar is working as a Asst. Prof.
in the Department of Electronics & Communication
Engineering in SHIATS, Allahabad. He received his
M.Tech. Degree in Advanced Communication
System Engineering from SHIATS, Allahabad in
2010. His research is focused on Signal processing,
Wireless Sensor Network and Computer Networks
,Microwave Engineering, as well as Optical fiber
communication.
Email-mukesh044@gmail.com,
Mobile:+91-9935966111
Rohini Saxena is working as a Asst. Prof.
in the Department of Electronics & Communication
Engineering in SHIATS, Allahabad. She received her
Degree of M.Tech in Advanced Communication
Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International
Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622
www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707
1707 | P a g e
System Engineering from SHIATS-DU, Allahabad in
2009. Her research is focused on Digital
Communication, Microwave Engineering, Wireless
Sensor Network and Computer Networks and Mobile
communication.
Email-rohini.saxena@gmail.com,
Mobile:+91-9208548881
Neelesh Agrawal is working as a Asst.
Prof. in the Department of Electronics &
Communication Engineering in SHIATS, Allahabad.
He received his M.Tech. Degree in Advanced
Communication System Engineering from SHIATS-
DU, Allahabad in 2009. His research is focused on
Signal Processing, Microwave Engineering, Wireless
Sensor Network and Computer Networks, Mobile
communication and Optical Communication.
Email- agrawalneelesh@gmail.com

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Jl3417031707

  • 1. Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622 www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707 1703 | P a g e Performance Optimization of Long Haul High Bit Rate Optical Fiber System with Dispersion Compensating Fiber Vineet Mubai1 , A. K. Jaiswal2 , Mukesh Kumar3 , Rohini Saxena4 , Neelesh Agrawal5 1 PG Student, 2 Professor & H.O.D, 3, 4, 5 Assistant Professor (ECE, Deptt.) 1, 2, 3, 4, 5 Department of Electronics and Communication Engineering, SHIATS-DU, ALLAHABAD ABSTRACT In this paper the comparison of the performance characteristic of pre and post compensation is done to reduce the chromatic compensation. The transmission behavior of return-to-zero (RZ) and non return-to-zero is compared numerically and experimentally. Data at the rate of 10 Gb/s were transmitted over 2000- km standard single-mode fiber using an alternative compensation scheme in a recirculation loop with more than 100 km amplifier spacing. The pre-compensation and post-compensation scheme is proposed using DCF to reduce the chromatic dispersion at the transmitter end. This method improves the Q- factor in single wavelength of 1550 nm. Keywords-BER, Dispersion Compensation, Dispersion Compensating Fiber, Fiber transmission, NRZ Modulation, RZ Modulation, Single Mode Fiber. I. INTRODUCTION Single-mode fiber (SMF) network are subject to stringent limitations in fiber length due to the linear chromatic dispersion when the high capacity fiber optic transmission system is operated at 1.55µm [1]. Passive dispersion compensation using dispersion compensating fibers (DCF) is one of the most powerful approaches to overcome this limitation and has been investigated intensively during the past few years [1]-[3]. One of the most promising methods of installing high capacity all-optical network on the already existing SMF base is the use of dispersion compensating fiber so as to reduce or compensate for the dispersion slope directly. Reverse dispersion fiber and an inline dispersion slope compensator with arrayed waveguides (AWGs) and DCFs can be used to achieve this compensation of dispersion. To date network design is aiming to achieve SMF amplifier spacing above zz= 100 km in order to reduce the number of repeater stations. Higher input powers are required due to these extended lengths of SMF sections, thus increasing the effect of nonlinearities [2], [4]. Work has been carried out for Pre- compensation and post-compensation of chromatic dispersion at the transmitter end. This has brought in improved Q-factor and results the BER in the desired range in single wavelength. Data at the rate of 10- Gb/s is transmitted using NRZ and RZ transmission over 2000-km SMF with increased amplifier spacing of more than 100 km in a recirculation loop [5], [6] has been demonstrated experimentally and system behavior has been explained by numerical simulations. As it is obvious from theory that for higher data rates return-to-zero (RZ) modulation format is better than that to NRZ, hence the transmission of a 10-Gb/s RZ data signal through the transmission line and comparison of the performance to the NRZ system has been done. The RZ pulse occupies just a part of the bit slot, so it has a duty cycle smaller than 1 and a broad spectrum. The RZ signal has amplitude between adjacent 1’s returns to zero. A RZ signal has spectrum peak power twice the larger than that of the NRZ signal with the same average power. The main characteristic of RZ modulated signals is a relatively broad optical spectrum, resulting in a reduced dispersion tolerance and a reduced spectral efficiency. The RZ pulse shape enables an increased robustness to fiber nonlinear effects. The RZ performs better than NRZ because the energy is confined in the center of each bit-slot in the case of RZ case and thus more differential group delay (DGD) is required before the energy leaks out the bit- slot to result in inter-symbol interference. II. EXPERIMENTAL SETUP The experiments are performed in a recirculation span (Fig 1 and Fig 2) in which there is PRBS generator with the 10Gbps bit rate and pattern length also a continuous wave laser source has been used to generate carrier wave at 1550 nm wavelength. Machzehnder modulation as an external modulator is used and 80 km single mode fiber (SMF) having positive dispersion coefficient is used with total dispersion of +1358 ps/nm/km In order to compensate the transmitting fiber dispersion we inserted DCF 20 km with negative dispersion slope of -67.69ps/nm/km. An EDFA amplifier is also used with 30GHz bandwidth in the system.
  • 2. Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622 www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707 1704 | P a g e Fig. 1 Pre-compensation of chromatic dispersion Fig. 2 Post-compensation of chromatic dispersion III. EXPERIMENTAL RESULT In the pre-compensation scheme, total negative dispersion generated by DCF is -1358 ps/nm/km, which is compensated through 80 km SMF of positive dispersion slope. BER is measured at data packets after 20 round trips corresponding to 2000 km SMF length. In the case of NRZ, at very low power 0.5mW the Q-factor is 16.16dB and at 1mW power level the Q-factor becomes 14.76dB which is below the desired value of 15.56dB. Also by the numerical simulation, it thus enable us to achieve BER<10-9 . For RZ modulation format on the other hand, at 1mW power the Q-factor has maximum value of 22.31dB and BER is 2.792×10-39 . As we increase the power above 1mW, Q-factor decreases. In post compensation DCF reduces the dispersion which is generated by the 80 km SMF. In this compensation scheme, NRZ modulation is applicable below 2mW signal power to get the desired range of BER and Q factor but RZ modulation has a large range of signal power. Hence at 10mW power Q-factor is 16.077dB for RZ modulation and BER is 9.709×10-11 , which is appropriate for optical communication. Fig 3 Eye diagram of post-compensation of chromatic dispersion with NRZ Fig. 4 Eye diagram of pre compensation of chromatic dispersion with NRZ Figure 3 shows the eye diagram of post- compensation of chromatic dispersion with NRZ modulation. This figure has been taken at 1 mW power. At the time of maximum eye opening, sampling of the signal is best, that is the transmission of signal will be error free. In this transmission system, the eye opening is best at the time of signal transmission. The width of the eye opening defines the time interval over which the received signal can be sampled without error from intersymbol interference. In pre-compensation of the same transmission system, the eye diagram as shown in Figure 4 contains some distortion in the signal. Some noise seen in the diagram and eye opening is also less
  • 3. Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622 www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707 1705 | P a g e in this as compared to the post compensation of chromatic dispersion. Fig. 5 Eye diagram of post compensation of chromatic dispersion with RZ modulation Fig. 6 Eye diagram of pre compensation of chromatic dispersion with RZ On the transmission of RZ signal in post compensation scheme, BER is find very low as compared to desired system BER (10-9 to 10-12 ) and also the quality factor is very high as compare to desired quality factor (15 to 17) of the system. From figure 5 and figure 6 it is clear that the eye opening is very poor at the time of transmission. From the analysis of eye diagram NRZ modulation is better perform in the post compensation of the chromatic dispersion as compared to the RZ modulation format. On the transmission of RZ signal in pre compensation technique, the eye opening of the system is very less as compared to the NRZ modulation format. BER is very low as compare to desired value of the system and also Q (dB) is very high as compared to desired value of system value. Fig. 7 Dispersion map in the Post Compensation of the Chromatic Dispersion Figure 7 shows the dispersion map for the post compensation scheme in which it is clear that the total dispersion created after the 80 km SMF is 1368 ps/nm/km and then after passing it through the 20 km DCF the dispersion reduces towards zero. The received signal is then amplified by the EDFA (erbium doped fiber amplifier) and then it is transmitted to next 100 km span [7]. Fig. 8 Dispersion map for Pre-Compensation of Chromatic Dispersion In Figure 8, dispersion map of the pre compensation scheme is shown, from which it is evident that the total dispersion passes through the 20 km DCF reduces the dispersion towards -1200 ps/nm/km. Then the total dispersion created after the
  • 4. Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622 www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707 1706 | P a g e 80 km SMF is 1368 ps/nm/km which compensates the dispersion through the DCF towards zero. The received signal is then amplified by the EDFA (erbium doped fiber amplifier) and transmitted over the next 100 km span. IV. CONCLUSION 10 Gb/s data transmission over 2000-km SMF at 1.55 µm with more than 100 km amplifier spacing with an alternating dispersion compensation scheme in a recirculation span is demonstrated experimentally. At 10Gbps bit rate, 1550 nm wavelength pre- compensation is better than the post compensation. In the Pre compensation Q-factor and BER improves as compared to the post compensation. Also it has been analyzed and investigated that the NRZ Modulation is better than the RZ modulation although in the RZ modulation, for large power we get the BER less than 10-9 , which is suitable for optical communication at 1550 nm wavelength. REFERENCES [1] D. Breuer, K. Ennser, and K. Petermann , “Comparison of NRZ- and RZ modulation format for 40 Gb/s TDM standard-fiber systems,” presented at ECOC’96, Oslo, Norway, vol. 2, 1996, paper TuD.3.3.. [2] D. Breuer, K. J¨urgensen, F. K¨uppers, A. Mattheus, I. Gabitov, and S. K. Turitsyn,“Optimal schemes for dispersion compensation of standard monomode fiber based links,” Opt. Commun., vol. 140, pp. 15–18, July15, 1997. [3] D. M. Rothnie and J. E. Midwinter, “Improved standard fiber performance by positioning the dispersion compensating fiber,” Electron. Lett., vol. 32, no. 20, pp. 1907–1908, Sept. 1996. [4] N. Smith, F.M. Knox, N.J. Doran, K.J. Blow, I. Bennion, Electron. Lett. 32 (1996) 55. [5] N. Kikuchi, S. Sasaki, and K. Sekine, “10 Gb/s dispersion-compensated transmission over 2245km conventional fibers in a recirculatiing loop,” Electron. Lett., vol. 31, no. 5, pp. 375–377, Mar. 1995. [6] N. Kikuchi and S. Sasaki, “Fiber nonlinearity in dispersion-compensated conventional fiber transmission,” Electron. Lett., vol. 32, no. 6, pp. 570–572, Mar. 1996. [7] S. Artigaud, M. Chbat, P. Nouchi, F. Chiquet, D. Bayart, L. Hamon, A. Pitel, F. Goudeseune, P. Bousselet, J.-L. Beylat,Electron. Lett. 32(1996) 1389. Vineet Mubai was born in Allahabad, U.P, India in 1984. He received B.Tech from the department of Electronics and Communication from B.B.S College of Engineering and Technology, Allahabad in 2006. He is perusing M.Tech from the Department of Electronics and Communication Engineering from S.H.I.A.T.S, Allahabad. His main research interest includes Optical Fiber Communication System. Email-ec.mvineet@gmail.com, Mobile:+91-9695063167 Prof. Arvind Kumar Jaiswal was born in 1942. He is M.Sc in Science and M.Sc (Tech.) in Electronic and Radio Engineering from Allahabad University. He has 33 years of industry experience and 10 years of teaching experience. Prof. A.K Jaiswal is working as Professor and Head of Electronics and Communication department in SHIATS-DU, Allahabad. He guided many Undergraduates and Post Graduates Students in their projects and Research work. He has 3 publications on various platforms. His research interests includes Optical Fiber Communication and Control Systems. Email: arvind.jaiswal@shiats.edu.in Mukesh Kumar is working as a Asst. Prof. in the Department of Electronics & Communication Engineering in SHIATS, Allahabad. He received his M.Tech. Degree in Advanced Communication System Engineering from SHIATS, Allahabad in 2010. His research is focused on Signal processing, Wireless Sensor Network and Computer Networks ,Microwave Engineering, as well as Optical fiber communication. Email-mukesh044@gmail.com, Mobile:+91-9935966111 Rohini Saxena is working as a Asst. Prof. in the Department of Electronics & Communication Engineering in SHIATS, Allahabad. She received her Degree of M.Tech in Advanced Communication
  • 5. Vineet Mubai, A. K. Jaiswal, Mukesh Kumar, Rohini Saxena, Neelesh Agrawal / International Journal of Engineering Research and Applications (IJERA) ISSN: 2248-9622 www.ijera.com Vol. 3, Issue 4, Jul-Aug 2013, pp.1703-1707 1707 | P a g e System Engineering from SHIATS-DU, Allahabad in 2009. Her research is focused on Digital Communication, Microwave Engineering, Wireless Sensor Network and Computer Networks and Mobile communication. Email-rohini.saxena@gmail.com, Mobile:+91-9208548881 Neelesh Agrawal is working as a Asst. Prof. in the Department of Electronics & Communication Engineering in SHIATS, Allahabad. He received his M.Tech. Degree in Advanced Communication System Engineering from SHIATS- DU, Allahabad in 2009. His research is focused on Signal Processing, Microwave Engineering, Wireless Sensor Network and Computer Networks, Mobile communication and Optical Communication. Email- agrawalneelesh@gmail.com