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Laser Communication
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5. The current fiber optic backbone runs to central offices in most of the
large population centers in the US. There has been much work done
to upgrade the fiber optic backbone by both extending its reach,
and increasing its bandwidth. The high bandwidth capability of the
fiber optic backbone of 2.5 Gbps to 10 Gbps has been achieved by
improvements in switching and optical components, and with the
implementation of technologies such as wavelength division
multiplexing (WDM). Most of the recent large effort of digging up
the ground and laying down new fiber has been directed towards
extending the fiber optic backbone to new central offices, and not
laying fiber directly to the customer. In fact, only 5% of all buildings
have a direct connection to the fiber optic backbone.
However, more than 75% of all businesses are within a mile of the fiber
optic backbone.
8. Light up optical bandwidth for your next generation wireless networks.
Wireless mult-gigabit Ethernet links up to 8km
Lasercom has taken Free Space Optical (FSO) and wireless optical communications
a quantum leap forward in bandwidth, and distance. When AOptix resolved the random
unpredictable light scattering distortions caused by scintillation, the clear focus turned to
straight attenuation factors related to weather. Using real-time beam pointing and
tracking for tower twist and sway and collimated beam control for extended reach,
availability is significantly improved in severe weather conditions.
Lasercom offers wireless networks the capacity equivalent of fiber cables. Whether it is
multi-gigabit terrestrial links or secure private networks, the unique set of product
features built into each of the AOptix products ensures top performance.
Key features:
•Long distance links for wireless backhaul up to 8km.
•Scalable capacity to 10 GigE & beyond.
•Real time compensation for tower twist & sway.
9. Breaking the Bandwidth Bottleneck
AOptix lasercom terminals provide solutions for backhaul aggregation hubs, loops, edge and metro
rings, as well as enterprise LAN's between buildings and sites. The bi-direction high capacity links can
also support fiber-backbones as extensions or as emergency back-up links. The interference-free
operation provides true fiber equivalent performance for multiple applications.
The low profile, long distance, high capacity attributes of Lasercom offers diversified solutions for low
profile pico-cells at street level, long distance backhaul aggregation hubs on towers, and high capacity
metro rings on building rooftops.
The outdoor unit (ODU) requires 1 linear foot of tower space regardless of the required capacity. As
network demands increase, this unique product will continue to provide the best value, cost per Mbit
solution year after year.
Availability is the performance measure for Lasercom:
Precision real-time active beam pointing ensures link stability under the worst case twist and sway
conditions for utility poles, towers and building rooftops
Pre + Post Correction for atmospheric distortions caused by scintillation
Collimated Beam control for longer distances in severe weather conditions
"Total Cost of Ownership" (TCO) is the financial measure for Lasercom:
Small lightweight ODU includes semi-automatic link alignment for ease of installation
Low profile configuration and energy efficient power rating ensures the lowest operating costs
Hitless capacity upgrades support new services without building additional infrastructure
The new wireless Lasercom links backhaul multi-gigabit Ethernet payloads in either direction. This cost
effective solution eliminates fees for leased fiber, spectrum licensing, as well as building permits and
construction costs for trenching fiber or additional wireless towers.
10. Laser Links 1.5 Mbps to 10 Gigabit speeds
What is a Laser Link or FSO? Free-Space Optics (also known as FSO,
Wireless Optics or Optical Wireless) is an optical data, voice and
video transmission system. Like fiber optic cable, wireless optics
communication systems use laser light to transmit a digital signal
between two transceivers. However, unlike fiber, the laser like is
transtmited through the air (free-space) instead of through a glass
strand. In order for the digital signal to be transmitted and received,
there must be clear line of site between each wireless optics unit. In
other words, there should be no obstructions such as trees or
buildings between the transceiver units.
Features of Laser Links
Leased line replacement
Cost Effective Fibre replacement
High bandwidths available up to 10 Gigabit
Licence free operation
Cost effective solution
Rapid deployment – less than a day
Immune from interference
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12. Technology provides broadband data transmission using infrared light
on stationary or moving platforms
› High Bbandwidth and un-detectability (compared to RF)
› Invisible and eye safe
Major Programs
› Dual Mode Optical Interrogator (DMOI) – NRL
› Dynamic Optical Tags System (DOTS) – DARPA
Performance and Accomplishments
› 10 Mbps at 3 km (retro-reflecting mode)
› Tracking system for mobile tactical comm links with automatic acquisition
› First deployed end-to-end fully-tracking retro-reflecting system
› 1-inch square, passive retro-reflecting optical tag for clandestine
interrogation
12NOVASOL PROPRIETARY
Optical Interrogator
13. 622 Mbps at 20 km (Direct Mode )
Develop Hand-held and Airborne interrogator
versions
Gimbal for fully-automatic tracking and
acquisition
Miniaturized to support special operations
Optical tags
Future applications
› Data download from unmanned sensors
› Direct air-to-air
› Direct ship-to-ship
› UGV hi-band communication
13NOVASOL PROPRIETARY
15. NOVASOL PROPRIETARY 15
Today: 2 Watts using EMSP Technology *
*: Cooperative Research and Development Agreement (CRADA) with NRL
Objective: 5 Watts
• Small Form Factor for embedded applications
• Computer Control and Monitoring (USB)
• Automatic shut-off
16. NOVASOL PROPRIETARY 16
Inner-
Clad
Outer-Clad (Buffer)
Double Clad Fiber
Single Mode Core (9um)
Multimode light
propagating
Electrical
Connections
Temporary short
for ESD
protection
Thermistor
connection Glass Substrate
Laser DiodeAnode Mount Cathode Mount
Fiber
125mm
21. 21NOVASOL PROPRIETARY
1. From 2W to 5W
Finding the optimum EDFA configuration using
Simulation and lab Experiment
Evaluation of non-linearities (Expected to be a limiting
factor)
Evaluating of different Double Clad Doped fibers
Proof of concept: Building a optical gain block with 5W
output power
2. Design the 5W EDFA
Final optical configuration
Control Electronics (with Monitoring and Computer
Control)
Mechanical and packaging
3. Implementation
Building the final EDFA
Testing
22. 22NOVASOL PROPRIETARY
Specifications
Ytterbium co-doped Double Clad Erbium Doped Fiber Amplifier
Saturated output power up to 37 dBm (5 Watts)
Bandwidth 1535-1570 nm
High rejection of 1064nm for Eye safety and un-detectability
Input and output monitor photodiodes
Isolated input
635nm input [1] for system alignment
Micro-Controller with USB interface for Control and monitoring
Automatic shut-off function in case of disconnection of input power[2]
Small form factor optimized for embedded applications
>5% wall plug efficiency