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Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Photonic Technologies for Next Generation Home and
Office Networks
Thomas Kamalakis, Georgia Dede, Katerina Margariti, Panagiotis Kanakis, Department of Informatics and Telematics, Harokopio University of Athens
Dimitris Alexandropoulos, Nikos Vainos Department of Materials Science, University of Patras
Research co-financed by the European Union & Greek national funds through the Operational Program "Education and Lifelong Learning" of the National Strategic Reference Framework Research Program: THALES
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Presentation Structure
Introduction
Home Network Requirements
Enabling Technologies
Network Architectures
Concluding Remarks
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Introduction
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Introduction
Distribution of online content through the web is expected to dominate video entertainment.
High definition video, telepresence applications are expected to put stringent requirements in the capacity of access networks.
High speed digital subscriber lines are expected to support an aggregate downstream and upstream data rate of up to 1Gbps at distances < 100m.
The advent of 4K video distribution will not be supported unless multigigabit data rates become available at the access network.
Driven need for Gbps!
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Introduction
FTTH is considered as a technology for the realization of broadband access networks.
PONs can support unrivaled access data-rates extending > 1Gbps.
Unprecedented data rates delivered in the home gateway.
How this broadband traffic can be distributed inside home or office???
Optical solutions, wireless or wireline may hold the key for overcoming this obstacle.
Review some of the architectures for realizing a smart optical local area network.
Examine network architectures to be realized using photonic technologies, pointing out the pros and cons.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Home Network Requirements
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Home Network Requirements
Since home networks are installed inside the customer premises, there be some very important bearing on the choice of optical components.
Recent socioeconomic studies point out the main home network driving factors:
Cost
Data Rate
Green Operation
Limited Household Disorder
Network Coverage
Usability
Design
Limited Interference with Legacy Systems
Safety Concerns
23,90%
20,38%
24,48%
31,24%
0%
5%
10%
15%
20%
25%
30%
35%
Inter-roomPerformance
BackbonePerformance
Economic SocialAcceptance
Weights
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Optical wireless Infrared
Optical communications without fiber: Light is transmitted in free space to enable wireless communication at high data rates.
Indoor, propagation length is a few meters, depending on the size of the room and the transceiver placement.
For good coverage conditions, the emitted optical beam should be wide enough implying increased geometric losses.
Transmitter board
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Optical wireless Infrared NLOS:
Transmitter beam is narrow and covers only a small portion of the room. Limited geometric losses and coverage.
Diffuse:
No direct LOS path. Communication achieved through beam reflections at the surfaces of the room.
WLOS:
Transmitter beam is wide enough to cover a relatively large portion of the room. Better coverage area, but higher optical losses.
Quasi diffuse:
Transmitter points towards the ceiling and terminals illuminated through reflection of the beam. Optical losses more pronounced.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Optical wireless Infrared
LOS configurations have a more relaxed power budget but they are susceptible to blocking and shadowing.
Radiation in this wavelength range cannot pass through walls, implying that
each room requires a dedicated optical hotspot, interconnected by a backbone network providing inter-room connectivity.
Early demonstrations of optical wireless systems relied on laser diodes as transmitters but in recent years super luminescent LEDs are also used.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Visible Light Communications
White LEDs considered as a major stakeholder for lighting applications.
Combine energy efficiency and long life in indoor and outdoor applications.
Can be modulated to transmit data
provide both illumination and data transmission at the same time (VLC).
VLC Transmitter
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Visible Light Communications
LED modulated at high frequencies so that the human eye does not perceive any flickering.
Simple Bias-T superimposes AC signal to DC-bias current that drives the LED.
At the receiver, TIA boosts the received current and convert it into voltage waveform.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Visible Light Communications
Major drawback: lighting LEDs are not generally designed with communication applications in mind.
They have small modulation bandwidths 5- 20MHz for single color or RGB LEDs, to 2MHz for phosphorescent white LEDs and ~100kHz for OLEDs. Extension needed.
OLED-based VLC links have been demonstrated with 10Mb/s capacity.
Inorganic VLC systems are more mature, extending in the multigigabit realm.
Achieving communication when LED lamps are dimmed is a tricky issue.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Plastic Optical Fibers
Commercialization of POFs based on polymethylmetacrylate (PMMA).
Have large core diameters of 1mm compared to the 50μm radius of conventional multimode fibers.
Considered in short range in-building networks with a range of ≤100m because of easy installation and maintenance features and high bending tolerance.
POF systems can extend well above 1Gbps.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Enabling Technologies
Plastic Optical Fibers
POF suffer from multimode dispersion
limits bandwidth at ~ 50MHz for a 100m distance.
VCSEL at the transmitter side provide transmission rates extending in multiGbps
GI-POFs are considered for extending the available bandwidth at GHz.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures
A variety of user devices are connected through the home network.
Data are distributed inside the HN through a number of access points, network extenders.
Many technologies can be considered such as
conventional and 60GHz radio systems
OW
UWB
PLC
not requiring new cable installations.
Home network, highlighting both inter and intra-room connections
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures
Many communication technologies claim a place inside the home or office network
possible future HN will be a collection of such technologies.
Conventional radio technologies (ex.WiFi) to provide connections to legacy devices or inter-room connectivity.
Hybrid home network
60GHz can provide high speed connections much like optical wireless.
VLC, having superior illumination can be used to broadcast data
Plastic fibers may also provide wireline connectivity.
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures
Coexistence of different physical layer technologies in one network
accomplished in MAC layer or the network layer
Autonomic network collecting knowledge of things to provide
Self-configuration
Self-healing
Self-optimization
Self-protection
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures Different arrangements evaluated for all optical house.
A5: All POF
A1 and A2 remain compatible with the no-new-wires approach.
PLC and POF are expected to achieve Gb/s.
A1: bidirectional IR LOS and PLC backbone A2: IR LOS and PLC backbone. VLC lamps for downstream
A3: bidirectional IR LOS and POF backbone A4: IR LOS and POF backbone. VLC lamps for downstream
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Network Architectures VLC and IR hotspots, with a PLC backbone
most favorable option, closely followed by IR hotspots with PLC backbone.
Advantages of PLC backbone in terms of ease of installation in older buildings.
0%
10%
20%
30%
Office 21.5% 22.4% 18.0% 17.8% 20.4%
Home 21.9% 22.7% 17.5% 17.0% 20.9%
PLC/ IR
LOS
PLC Hybrid
POF/ IR
LOS
POF Hybrid
All POF
0%
10%
20%
30%
40%
50%
PLC 43.9% 44.6%
POF 35.8% 34.5%
Office Home
Alternative Priorities for Office and Home scenarios Added PLC and POF wireless priorities
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Concluding Remarks
Cost is a restrictive factor and this points to alternative low cost technologies.
LEDs and VCSELs seem to be the technology of choice at the transmitter side.
Exciting prospect of lighting LEDs to provide communication & illumination through VLC.
Optical wireless are limited for intra-room communications
a POF or PLC network backbone to span connection across multiple rooms.
Wireline: POF provides an alternative to multimode fiber to deliver multiGbps rate
Future Home Networks will probably consist of Hybrid Solutions!
Department of Informatics and Telematics
18th Panhellenic Conference on Informatics, 2-3/10/2014, Harokopion University, Athens
Thank you!
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