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This PDF file contains the front matter associated with SPIE
Proceedings Volume 7620, including the Title Page, Copyright
information, Table of Contents, and the Conference Committee listing.
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Mobile networks and services have gone further than voice-only communication services and are rapidly developing
towards data-centric services. Emerging mobile data services are expected to see the same explosive growth in demand
that Internet and wireless voice services have seen in recent years. To support such a rapid increase in traffic, active
users, and advanced multimedia services implied by this growth rate along with the diverse quality of service (QoS) and
rate requirements set by these services, mobile operator need to rapidly transition to a simple and cost-effective, flat, all
IP-network. This has accelerated the development and deployment of new wireless broadband access technologies
including fourth-generation (4G) mobile WiMAX and cellular Long-Term Evolution (LTE). Mobile WiMAX and LTE
are two different (but not necessarily competing) technologies that will eventually be used to achieve data speeds of up
to 100 Mbps. Speeds that are fast enough to potentially replace wired broadband connections with wireless. This paper
introduces both of these next generation technologies and then compares them in the end.
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The investigation of next-generation optical access network (NG-OAN) systems as well as the corresponding
standardization activities has been steadily progressing. In the near future, whenever such a NG-OAN system is deployed
to meet the bandwidth demands, the smooth migration from the existing system is indispensable because current PON
systems such as 1G-EPON/G-PON have been massively deployed all over the world. NGA systems should be deployed
so as not to interrupt existing system operation or degrade in-service user availability. I introduce recent technical topics
related to co-existence with 1G/10G-EPON as an example. In particular, a 1G/10G dual-rate dynamic bandwidth
allocation (DBA) technique and a 1G/10G dual-rate burst-mode transceiver are key technologies enabling 1G- and 10Gdata
to be handled simultaneously. Furthermore, from the CAPEX/OPEX reduction viewpoint, longer lifetime system is
preferable. NGA systems will, therefore, be more flexible to meet later bandwidth demands, wide coverage requirement,
and energy-efficient operation. WDM technology is an attractive approach to meeting these goals.
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Passive Optical Network (PON) and Mobile Worldwide Interoperability for Microwave Access (WiMAX) are two
emerging broadband technologies for the next-generation (NG) access networks. Integration of PON and Mobile
WiMAX might be an efficient solution to broadband network access that can take advantage of the bandwidth benefit of
fiber communications, and the mobile and non-line-of-sight features of wireless communications. By leveraging the
advantages of both of these access technologies combined on an integrated architecture platform, NG converged-access
solutions can meet the demand for mobility, bandwidth, reliability, security, and flexibility. By combining the practically
unlimited capacity of optical fiber networks with the ubiquity and mobility of wireless networks, NG Fiber-Wireless
(FiWi) networks will enable the support of a wide range of emerging and unforeseen fixed-mobile applications and
services independent of the access infrastructure. PON and 4G Mobile WiMAX integrated architecture enables
differentiated bandwidth allocation to end users that can provide more network capacity at reduced operational cost as
compared to other existing technologies.
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Fiber architecture solutions for providing wireless network coverage by radio-over fiber feeding in buildings
are discussed. The focus is on very high wireless data rate applications (>>100 Mb/s) with short wireless
distances (typ. <10m). Up to 20 Gb/s signal transmission at 60 GHz is demonstrated.
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We demonstrate the superior RF spectrum characteristics of an ultra-linear modulator. This modulator
exhibits excellent linearity (Spurious Free Dynamic Range, SFDR ~ 133 dB at 1Hz bandwidth), wider
linearization bandwidth (an order of magnitude wider), and flatter RF modulation frequency dependence
characteristics (linearized 3dB bandwidth ~ 20% of central RF frequency) when compared with Resonator-
Assisted Mach Zehnder (RAMZ) modulators. The modulator is based on a traveling-wave electrode design, in
which a phase modulator (PM) is on the upper arm of a Mach Zehnder (MZ) interferometer and a ring resonator
(RR) is located on the lower arm. This modulator design is also shown to have flexible control of the power
split ratio of an RF input to both the PM and the RR, in addition to the RF phase bias between the RR and PM -
which enables better manufacturing tolerance.
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In this work we report the photonic generation of microwave signals for distributing point to point analog TV signals by
using microstrip antennas. The experimental setup is based on optical heterodyne technique where two optical waves at
different wavelengths are mixed and applied to a photodetector. The microwave signal obtained by using this technique
is used in a wireless communication system for transmitting and receiving analog TV signals.
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In typical radio-over-fiber (RoF) systems, sub-carrier multiplexing is achieved by using directly modulated laser diode
(LD). However, the conventional LD for optical communication system has non-linear characteristics such as, 3rd order
intermodulation distortion (IMD3), which degrade overall analog RoF system performance. In addition, when the
multi-channel input signals are modulated directly, 5th order intermodulation distortion (IMD5) signals act as a noise on
overall systems. In this paper, we experimentally demonstrate an opto-electrical predistortion optical transmitter to
enhance IMD3 & IMD5 for radio-over-fiber systems. To reduce the 3rd and 5th order intermodulation (IM3 & IM5),
master laser diode (MLD) and slave laser diode (SLD) with similar performance are used, and the matching circuits of
two LDs are designed with equal properties. The amplitude and phase balances as well as bias current of two LDs are
carefully considered for the enhancements. The experimental results show that reductions of about 30 dB in the IM3
and about 12 dB in the IM5 are achieved at 2.2 GHz.
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The generation, distribution and processing of microwave signals in the optical domain is a topic of research
due to many advantages such as low loss, light weight, broadband width, and immunity to electromagnetic
interference. In this sense, a novel all-optical microwave photonic filter scheme is proposed and experimentally
demonstrated in the frequency range of 0.01-15.0 GHz. A microwave signal generated by optical mixing drives the
microwave photonic filter. Basically, photonic filter is composed by a multimode laser diode, an integrated Mach-
Zehnder intensity modulator, and 28.3-Km of single-mode standard fiber. Frequency response of the microwave
photonic filter depends of the emission spectral characteristics of the multimode laser diode, the physical length
of the single-mode standard fiber, and the chromatic dispersion factor associated to this type of fiber. Frequency
response of the photonic filter is composed of a low-pass band centered at zero frequency, and several band-pass
lobes located periodically on the microwave frequency range. Experimental results are compared by means of
numerical simulations in Matlab exhibiting a small deviation in the frequency range of 0.01-5.0 GHz. However,
this deviation is more evident when higher frequencies are reached. In this paper, we evaluate the causes of
this deviation in the range of 5.0-15.0 GHz analyzing the parameters involved in the frequency response. This
analysis permits to improve the performance of the photonic microwave filter to higher frequencies.
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This paper reviews recent research activities on the applications and technical issues of WDM-PON. First, we describe
two candidate applications of WDM-PON: one is a long-reach WDM-PON based on wavelength routing for
metro/access integration, and the other is a short-reach WDM-PON for co-existence with current PON systems. We
identify that the realization of colorless optical network units (ONUs) is an important technical issue for both
applications, and an effective protection function is another important issue, especially for the long-reach WDM-PON.
We introduce several 'colorless-ONU' approaches as well as introduce our recent research results to resolve the issues
raised by some colorless-ONU approaches. In the second half of this paper, we describe two application: one is the
wide-area optical/wireless hybrid access network based on long-reach WDM-PON with loop-back type colorless ONUs,
and the other is the optical and wireless access based on short-reach WDM-PON coexisting with a current PON
infrastructure with tunable-type colorless ONUs.
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In this research paper we propose a novel Passive Optical Network (PON) based Mobile Worldwide Interoperability for
Microwave Access (WiMAX) access network architecture to provide high capacity and performance multimedia
services to mobile WiMAX users. Passive Optical Networks (PON) networks do not require powered equipment; hence
they cost lower and need less network management. WiMAX technology emerges as a viable candidate for the last mile
solution. In the conventional WiMAX access networks, the base stations and Multiple Input Multiple Output (MIMO)
antennas are connected by point to point lines. Ideally in theory, the Maximum WiMAX bandwidth is assumed to be 70
Mbit/s over 31 miles. In reality, WiMAX can only provide one or the other as when operating over maximum range, bit
error rate increases and therefore it is required to use lower bit rate. Lowering the range allows a device to operate at
higher bit rates. Our focus in this research paper is to increase both range and bit rate by utilizing distributed cluster of
MIMO antennas connected to WiMAX base stations with PON based topologies. A novel quality of service (QoS)
algorithm is also proposed to provide admission control and scheduling to serve classified traffic. The proposed
architecture presents flexible and scalable system design with different performance requirements and complexity.
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The main objective of the presented research is to characterize an indoor wireless optical communication channel. Until
recently, there have not been any comprehensive published measurements results presenting characteristics of this
channel for high data rates, e. g. 1Gbit/s. To this end, a measurement setup is implemented, with a high-power laser
diode acting as the optical transmitter and an avalanche photodiode acting as the receiver. Using a network analyzer, the
laser is modulated by CW frequencies up to 1 GHz, which is the bandwidth of the receiver, as limited by the intrinsic
capacitance and the response-time of the avalanche photodiode. A single collimated optical spot with a small elliptical
shape on the ceiling is tested. The impacts of receiver orientation and configuration on the channel frequency response
are investigated. These measurements will enable us to explore the possibility of higher data transmission rates,
potentially beyond 1 Gbps, on indoor optical wireless channels. These channels can be a viable alternative to inherently
insecure and interference-prone RF wireless channels, and therefore, could be the basis of next-generation high data rate
wireless local area networks.
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Free Space Optical (FSO) communications is the only practical candidate for realizing universal network coverage
between ground and airborne nodes, satellites, and even moon and other nearby planets. When atmosphere (be it the
earth or Mars) is a part of the optical channel, attributes of scattering and turbulence bring about amplitude attenuation,
and scintillation, as well as beam wander and phase aberrations at the receiving aperture. Phase screens are usually used
in order to simulate the atmospheric fading channel and phase fluctuations. In this paper, different methods of generating
phase screens are compared based on their accuracy and computational complexity, as in most computer simulations, a
large ensemble of phase screens are required for averaging purposes.
To combat the focal plane intensity fading, caused by amplitude and phase variations in the received wave-front, it is
possible to replace the Single Input-Single Output (SISO) communications system with its Multiple Input Multiple
Output (MIMO) equivalent, which has the same total transmit power and receiving aperture area. Another alternative is
to equip the receiver with a state of the art Adaptive Optics (AO) correction system. Using average Bit Error Rate (BER),
as a performance metric, effectiveness of these two approaches are compared and it is shown that while a MIMO
configuration outperforms a basic AO system capable of only tilt corrections, an ideal AO system, which is able to
remove higher orders of Zernike modes can asymptotically perform as well as an equivalent MIMO configuration.
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This paper presents empirical probability density functions (p.d.fs) of variance and fluctuation speed of scintillation,
through analyzing a number of experimental data measured in Japan by a statistical model. The model enables us to treat
scintillation speed by one parameter of cut-off frequency in the power spectral density (PDS). By using the model and
based on the two p.d.fs, we also present simulation results on the level crossing rate (LCR) and average fade duration
(AFD). Combined the two results, an outage probabilities corresponding to a threshold optical intensity can be derived.
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