Improvement of a Dynamic Frequency Hopping Optical Code Division Multiple Access System Using Power Control Method
In this thesis, adaptive power control method is proposed to improve the performance of dynamic frequency hopping-optical code division multiple access (DFH-OCDMA) communication system. This method is based on solving the near-far problem of power misdistribution among simultaneous users. The DFH...
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Main Author: | |
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Format: | Thesis |
Language: | English English |
Published: |
2009
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Online Access: | http://psasir.upm.edu.my/id/eprint/7840/1/ABS_%3D%3D%3D%3D_FK_2009_93.pdf http://psasir.upm.edu.my/id/eprint/7840/ |
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Summary: | In this thesis, adaptive power control method is proposed to improve the performance of
dynamic frequency hopping-optical code division multiple access (DFH-OCDMA)
communication system. This method is based on solving the near-far problem of power
misdistribution among simultaneous users. The DFH-OCDMA has an advantage of
supporting more users compared to other OCDMA techniques such as Hadamard code,
modified quadratic congruence code, modified frequency hopping code, and fast
frequency hopping system. Nevertheless, the bit error rate (BER) was found to
deteriorate rapidly with a slight change of received power compared to the other
techniques. With the change of the received power (i.e. from -10 dBm to -12 dBm), the
BER could be degraded from 10-9 to 10-6. This phenomenon is strongly related to nearfar
problem, where users at longer path lengths will suffer higher BER compared to
users at shorter path lengths. The unequal power distribution among users leads to
unequal performance for them. This may cause to not all users can be supported in the transmission system. Therefore, this study is aimed to search for a solution to increase
the number of users under the DFH-OCDMA system with near-far problem.
A distributed power control algorithm was proposed to enhance the performance of the
system and this was done by considering all possible noises such as the multiple access
interference, phase induced intensity noise, and shot noise. The performance of the
system was also observed at different issues of fibre impairments, including fibre
attenuation, and optical components. The results gathered from the simulations showed
that BER and signal-to-noise-ratio (SNR) for each user were significantly improved after
using the power control. In specific, it is observed that the best capacity increased was
51% when the random path lengths for 110 users was between 1 to 40 km. Thus, the
power control method is proven as an important enhancement to DFH-OCDMA
performance. Moreover, the number of users increased in the DFH-OCDMA system
with power control was 56 users while at prime code OCDMA and time hopping, only
20 users increment with power control. This result therefore shows better improvement
of capacity in DFH-ODCMA compared to other Power Controlled-OCDMA. |
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