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This PDF file contains the front matter associated with SPIE Proceedings Volume 8282, including the Title Page, Copyright information, Table of Contents, the Conference Committee listing, and the introduction.
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This paper reviews optical coherent technologies in next generation access networks with the use of radio over fiber
(RoF), which offer key enabling technologies of wired and wireless integrated and/or converged broadband access
networks to accommodate rapidly widespread cloud computing services. We describe technical issues on conventional
RoF based on subcarrier modulation (SCM) and their countermeasures. Two examples of RoF access networks with
optical coherent technologies to solve the technical issues are introduced; a video distribution system with FM
conversion and wired and wireless integrated wide-area access network with photonic up- and down-conversion.
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Advanced Signal Processing: Joint Session with Conference 8284
Millimeter-wave bands are attracting attention because of the availability of wideband for high-speed transmission.
However, due to the limitation of the performance of electric signal processing, it is rather difficult to modulate and
demodulate millimeter-wave signals with high-speed baseband modulation. In this paper, we describe optical signal
processing for high-speed modulation of millimeter-wave, based on high-speed and precise lightwave control. In optical
fiber communication systems, various types of modulation formats, such as quadrature-amplitude-modulation, are
reported to achieve high-speed transmission. Optical two-tone signals can be converted into millimeter-wave signals by
using high-speed photodetectors. This technique can be used for distribution of stable reference signals in large-scale
antenna arrays for radio astronomy. By using the millimeter-wave signal generation technique and the optical advanced
modulation formats, we can achieve high-speed modulation of millimeter-waves, where the carrier frequency and bit rate
can be over 90GHz and 40Gb/s, respectively.
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All-optical techniques for microwave and radio frequency (RF) signal processing has attracted considerable attention in
recent years. An important optical component in these all-optical signal processing techniques is the optical filter.
Tunable optical filters with a variety of transfer functions have been proposed. However, adjustability of the optical
filter transfer function is required to provide an extra degree of control. This adjustability of the shape of the transfer
function has not been addressed adequately in the literature. In this paper, we report on the theoretical basis for an all-fiber
based adjustable transfer function optical filter. In particular, we model the optical filter using FO-circuit transfer
matrices and Jones matrices to fully describe the state of polarization changes of the optical signals through the optical
filter. The filter is based on an all fiber Michelson Gires-Turnois interferometer (MGTI). The Gires-Turnois resonators
(GTRs) required for the formation of the MGTI are realized by pairs of fiber-loop mirrors (FLMs) in the two arms of the
Michelson interferometer. The optical reflectivity of the GTRs is control via adjustment of the polarization in the fiber
loop mirrors. We show that arbitrary transfer functions can be realized by adjusting the reflectivity of the FLMs as well
as the cavity length of the fiber based GTRs.
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High-Capacity Coherent Optical Technologies: Joint Session with Conference 8284
Coherent optical code division multiple access (OCDMA) technique, where encoding and decoding are based on the
phase and amplitude of optical field instead of its intensity, is receiving much attention for the overall superior
performance over incoherent OCDMA and the development of compact and reliable en/decoders (E/D) such as spatial
light phase modulator (SLPM), superstructured fiber Bragg grating (SSFBG) and multi-port array waveguide grating
(AWG)-type E/D. In this paper, we will discuss several recent progresses in coherent OCDMA: a. Novel coding
technology such as multi-phase-level SSFBG encoder, 50x50 multiport en/decoder and reconfigurable time domain
spectral phase en/decoding; b. New signal modulation formats in OCDMA including DPSK, DQPSK, CSK and M-ary
CSK; and c. Field trials of high capacity WDM/OCDMA systems.
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We present here a low cost, small form factor, optical transceiver module composed of a CMOS IC transceiver, 850 nm
emission wavelength VCSEL modulated at 25 Gb/s, and an InGaAs/InP PIN Photo Diode (PD). The transceiver IC is
fabricated in a standard 28 nm CMOS process and integrates the analog circuits interfacing the VCSEL and PD, namely
the VCSEL driver and Transimpedance Amplifier (TIA), as well as all other required transmitter and receiver circuits
like Phase Locked Loop (PLL), Post Amplifier and Clock & Data Recovery (CDR). The transceiver module couples into
a 62.5/125 um multi-mode (OM1) TX/RX fiber pair via a low cost plastic cover realizing the transmitter and receiver
lens systems and demonstrates BER < 10-12 at the 25 Gb/s data rate over a distance of 3 meters. Using a 50/125 um laser
optimized multi-mode fiber (OM3), the same performance was achieved over a distance of 30 meters.
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Next-Generation Devices and Components: Joint Session with Conferences 8283 and 8284
IMPACC (Interferometric Modulator with Phase-modulating and Cavity-modulating Components) is ultra-linear
optical consisting of a phase modulator and a ring resonator on different arms of a Mach Zehnder
interferometer (MZI). External control of the RF power split ratio from an input radio frequency (RF) signal
into the two separate arms of the interferometer has been shown to add (1) design flexibility, (2) the ability to
achieve high spurious free dynamic range (SFDR) of more than 130 dB, when compared to the single-ring
RAMZI (Resonator-assisted MZI) and (3) compensate parameter deviation due to manufacturing imperfection.
Our previous reports have assumed that the Optical power split ratio of the input optical signal into the two arm
of MZI is balanced with a 50:50 split ratio due to the optical splitter or optical coupler. Here, we investigate
three issues. First, we report the negative effect of unbalanced power of the input optical signal on the SFDR
performance of IMPACC. Second, we utilize the inherent compensate technique of IMPACC to counteract this
effect. Third, the power unbalanced effect is reported at high RF modulation frequency (23GHz) for three
different conditions of the ring resonator (RR) namely, critical coupling (CC), over coupling (OC), and under
coupling (UC). Lastly, we compare the performance of IMPACC to the single-ring RAMZI with traveling-wave
electrode design under sub-octave operations.
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Special Session on Optical Technologies for Mobile Microwave Access
A flexibly configurable radio access network architecture is expected to provide low-cost mobile broadband services.
The radio access network architecture has changed drastically thanks to the evolution in optical fiber communication
technologies. This paper describes optical transport technologies that contribute to the efficient deployment of broadband
radio access systems.
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The concept of the transportation of a microwave environment over networks using a digitized Radio-on-Fibre (DRoF)
technique as well as the concept of in-network microwave processing, which could make the concept of "wired and
wireless network virtualization" into a reality, is discussed. The new applications to a radio-on-demand service (RoD),
software-defined radio-aware network (SDRAN), and microwave environments cloud are introduced. 10-Gbps Ethernet
based microwave-to-network interface converter (MiNIC) are developed and the transportation of multiple digital TV
broadcasting signals is demonstrated. It is shown that the MiNIC should use more than 8-bits resolution in digitization of
a microwave environment when 7 channels of TV signals are included in it. The concept of remote microwave
environments observation over networks is demonstrated, where the frequency channel and received signal strength
indication (RSSI) of the detected digital TV broadcasting signals are remotely monitored.
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Wireless Internet usage is doubling every year. Users are using more of high bandwidth data applications, and the
heavy usage concentrates on several peak hours in a day, forcing ISPs to overprovision their networks accordingly.
In order to remain profitable, ISPs have been using pricing as a congestion management tool. We review many
of such pricing schemes in practice today and argue that they do not solve ISPs' problem of growing data traffic.
We believe that dynamic, time-dependent usage pricing, which charges users based on when they access the
Internet, can incentivize users to spread out their bandwidth consumption more evenly across different times of
the day, thus helping ISPs to overcome the problem of peak congestion. Congestion pricing is not a new idea
in itself, but the time for its implementation in data networks has finally arrived. Our key contribution lies in
developing new analysis and a fully integrated system architecture, called TUBE (Time-dependent Usage-based
Broadband price Engineering) that enables ISPs to implement the proposed TDP plan. The theory, simulation,
and system implementation of TUBE system is further complemented with consumer surveys conducted in India
and the US, along with preparations for a field trial that is currently underway.
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In this paper we describe an analog microwave photonic link system used to transmit simultaneously two TV signals.
The experimental setup is composed mainly by two distributed feedback (DFB) laser diodes emitting at 1500 nm. When
DFB lasers are operated in the low laser threshold current region, relaxation oscillation frequencies are obtained.
Relaxation oscillations in the laser intensity can be seen as sidebands on both sides of the main laser line. The optical
emissions generated in each laser are combined and amplified by using an Erbium-Doped Fiber Amplifier (EDFA).
Next, the amplified optical signal is detected by a fast photo-detector using direct detection method and as result of this
photo-detection microwave signals are generated. Microwave signals obtained by this technique are used as electrical
carriers to transmit analog TV signals over 30 km of standard optical fiber by using a Mach-Zehnder modulator (MZM).
At the end of the optical link the modulated light is photo-detected in order to recover efficiently and successfully the
analog TV signals.
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A 60GHz wireless over fiber indoor system is proposed and evaluated, using a microwave/optical/wireless converged
analysis. In order to promote a cost-efficient deployment multimode fiber indoor infrastructure is employed, and a
photonic integrated patch antenna combined with a LiNbO3 modulator scheme for all-optical frequency up-conversion
are studied. Using, a 3Gb/s Orthogonal Frequency Division Multiplexing (OFDM) based IEEE 802.15.3c prestandard,
and OM-4 graded index multimode fiber (GI-MMF) transmission of 100m, an acceptable performance, in terms of Error
Vector Magnitude (EVM) is calculated for a wireless coverage in the order of 10m. A possible system topology is
proposed which apart from fulfilling the wired-wireless and low cost requirements, utilizing a FTTB single mode fiber
(SMF) feeding and MMF indoor deployment, is appropriate for future green system scenarios through λ-reuse and
photonic integrated antenna scheme without post amplification.
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An emerging theme in next-generation access research includes seamless wireline-wireless convergence addressed by
Radio-over-Fiber (RoF) technologies. Optical cabling solutions offer the possibility for semi-transparent transport
through the access network microwave to mm-wave radio carriers commonly employed for creating high-capacity
picocell wireless networks, attending present demands from the wireless technologies, with portable/mobile devices
converging with photonics. Advanced RoF techniques can efficiently generate and transport such carriers, and deliver
them to simplified antenna stations or radio access points (RAPs). Thus, they can convey high data rates in
comprehensive modulation formats on multiple-GHz carriers in MMF networks.
Selective mode-launching schemes combined with the use of narrow linewidth optical sources are experimentally
demonstrated to enable broadband RF, microwave and mm-wave transmission in short- and middle-reach distances over
silica-based multimode optical fibers (MMFs); and are reviewed in this paper. However, arbitrary operating conditions,
such as the temperature dependence in the fiber link, impose a great challenge for the extension of the RoMMF
technology. Temperature impairment characterization is analyzed over the broadband transmission bands that are
present, under certain operating link conditions, in the frequency response performance of MMF to support multiple GHz
carrier delivering schemes, thus contributing to fault link prevention.
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Metro and Alternative Access Technologies (Visible Light Communication): Joint Session with Conference 8283
Visible Light Communication (VLC) is a wireless communication method using LEDs. LEDs can respond in high-speed
and VLC uses this characteristics. In VLC researches, there are two types of receivers mainly, one is photodiode receiver
and the other is high-speed camera. A photodiode receiver can communicate in high-speed and has high transmission
rate because of its high-speed response. A high-speed camera can detect and track the transmitter easily because it is not
necessary to move the camera. In this paper, we use a hybrid sensor designed for VLC which has advantages of both
photodiode and high-speed camera, that is, high transmission rate and easy detecting of the transmitter. The light
receiving section of the hybrid sensor consists of communication pixels and video pixels, which realizes the advantages.
This hybrid sensor can communicate in static environment in previous research. However in dynamic environment, high-speed
tracking of the transmitter is essential for communication. So, we realize the high-speed tracking of the transmitter
by using the information of the communication pixels. Experimental results show the possibility of communication in
dynamic environment.
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As Light-Emitting Diode (LED)'s increasingly displace incandescent lighting over the next few years, general
applications of Visible Light Communication (VLC) technology are expected to include wireless internet access,
vehicle-to-vehicle communications, broadcast from LED signage, and machine-to-machine communications. An
objective in this paper is to reveal the influence of system parameters on the power distribution and communication
quality, in a general plural sources VLC system. It is demonstrated that sources' Half-Power Angles (HPA), receivers'
Field-Of Views (FOV), sources layout and the power distribution among sources are significant impact factors. Based on
our findings, we developed a method to adaptively change working status of each LED respectively according to users'
locations. The program minimizes total power emitted while simultaneously ensuring sufficient light intensity and
communication quality for each user. The paper also compares Orthogonal Frequency-Division Multiplexing (OFDM)
and On-Off Keying (OOK) signals performance in indoor optical wireless communications. The simulation is carried out
for different locations where different impulse response distortions are experienced. OFDM seems a better choice than
prevalent OOK for indoor VLC due to its high resistance to multi-path effect and delay spread. However, the peak-to-average
power limitations of the method must be investigated for lighting LEDs.
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Recent developments in visible light communication (VLC) technology have solidified utilizing light-emitting diodes
(LEDs) for not only illumination, but also optical wireless communication. This paper presents a novel optical access
point transceiver that features addressable arrays of LEDs and photodetectors. The transmitter array enables combined
illumination control and serial data transmission for an array of 16 LEDs producing an aggregate data rate of 100 Mb/s.
The receiver consists of a 16-element array of broadband receiver channels. Designed in a 0.5 μm CMOS process to
enable miniaturization and VLC system integration, the transceiver is capable of processing multiple user requests.
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A simple, accurate, secure, long-lasting, and portable hybrid positioning system is proposed and designed in this paper. It
consists of a lighting LED that generates visible light data corresponding to position information of a target and a Zigbee
wireless network communication module with low power, security, and service area expansion characteristics. Under an
indoor environment where there is 23.62m distance between an observer and the target, the presented hybrid positioning
system is tested and is verified with the functions of Zigbee three hop wireless networking and visible light
communication (VLC) scheme. The test results are analyzed and discussed.
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