New Frequency Quadrupling Techniques Based On Carrier Suppression For High-Quality 60 GHz Radio-over-Fiber Systems
Millimeter-wave (MMW) wireless networks in the 60 GHz unlicensed band have become a key technology for enabling multi-gigabit wireless access and provisioning of quality of service (QoS)-sensitive applications. However, numerous difficulties need to be solved in the 60 GHz wireless systems, the most...
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Format: | Thesis |
Language: | English |
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Online Access: | http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/59414/1/Page%201-24.pdf http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/59414/2/Full%20text.pdf |
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Summary: | Millimeter-wave (MMW) wireless networks in the 60 GHz unlicensed band have become a key technology for enabling multi-gigabit wireless access and provisioning of quality of service (QoS)-sensitive applications. However, numerous difficulties need to be solved in the 60 GHz wireless systems, the most important of which is the high air-link loss. This issue implies that many remote base stations (BSs)
need to be deployed to cover a large area. Radio-over-fiber (RoF) technology, the
integration of wireless and optical communication, has long been proposed as an ideal technology for solving these difficulties. Aside from numerous advantages, such as low
propagation loss, low cost, large bandwidth, and immunity to electromagnetic
interference, the RoF technology enables the shift of complexity from BSs to a central
office by a centralized provision of the MMW carrier. In an RoF system, the highquality
generation of MMW signals with simple implementation is a key technique.
Compared with the conventional electrical method, the optical method is preferable.
In this thesis, we propose two new frequency-quadrupling approaches for the optical
generation and downstream transmission of high-quality and data modulated 60 GHz
signals on the basis of two parallel dual-drive Mach–Zehnder Modulators (DD-MZMs)
and one integrated dual-parallel MZM (IDP-MZM). As a result of these proposed
approaches, two newly designed optical MMW generation schemes are proposed. The
first scheme uses two parallel DD-MZMs to generate a high-quality optical carrier
suppression (OCS) MMW signal, whereas the second scheme uses only one IDP-MZM
to generate a high-quality optical MMW signal without optical filter. A detailed
theoretical analysis of the proposed frequency-quadrupling approaches is conducted.
Moreover, explicit expressions of the optical sidebands suppression ratio (OSSR), radio
frequency spurious suppression ratio (RFSSRR), and MMW current are given and can
be utilized for the evaluation of the qualities of the generated optical and electrical
MWW signals in back-to-back (B-T-B) transmission, as well as the transmission
performance of the generated optical MMW signal over optical fiber. The simulation
software, OptiSystem (version 9.0), is utilized to evaluate the performance of the
proposed approaches. Good agreement is found between theory and simulation. By
using the first approach, the simulation results show that a 60 GHz MMW signal can be
generated from a 15 GHz RF oscillator with an OSSR of up to 39.4 dB and an RFSSRR
exceeding 35 dB without optical or electrical filter when the extinction ratios of the two
DD-MZMs are 25 dB. For the second approach, the simulation results show that the a
60 GHz MMW signal can be generated with an OSSR and an RFSSRR equal to 33.7 dB
and 33.4 dB, respectively, without optical or electrical filter when the extinction ratio of
the IDP-MZM is 30 dB. The influences of a number of non-ideal parameters, such as
imperfect extinction ratio, RF driving voltage deviation, and phase shifting, on the
performance of the proposed optical MMW generation schemes are examined through
simulations. Results indicate that a slight deviation from the ideal values would not
result in a significant degradation of the generated optical MMW signal. Finally, we
build a RoF system through simulation, and the transmission performance of the
generated optical MMW signals is presented. The eye pattern is clearly opened even
when the optical MMW signal is transmitted over 60 km. |
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