Free space optics (FSO)
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Oct 31, 2013
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About This Presentation
FSO! A new technology without using fiber cable..
Read this little awesome story on FSO....
Slide Content
FSO (Free Space Optics)
By,
Bhavik Trivedi
1 29 October 2013
By,
Bhavik Trivedi
1 29 October 2013
Outlines
•Concept
•Why Free Space Optics?
•Origin & Technology of FSO
•Working
•Challenges
•Applications
•Merits & Demerits
•References
2
•Concept
•Why Free Space Optics?
•Origin & Technology of FSO
•Working
•Challenges
•Applications
•Merits & Demerits
•References
2
Concept
[1]
•FSO - optical communication technology that
uses light propagating in free space to transfer
data.
•Line of sight technology.
•Bandwidth up to 2.5 Gbps.
•Uses LED or Laser as a light source.
3
[1]
•FSO - optical communication technology that
uses light propagating in free space to transfer
data.
•Line of sight technology.
•Bandwidth up to 2.5 Gbps.
•Uses LED or Laser as a light source.
3
FSO Transmitter FSO Receiver
4
Fig. 1 FSO Transmitter & Receiver images
[4]
4
Fig. 1 FSO Transmitter & Receiver images
[4]
Beam Divergence (Frequency) Effect
Fig. 2 Beam Divergence effect
[3]
5
Fig. 2 Beam Divergence effect
[3]
5
Why Free Space Optics?
[6]
Why Not Just Bury More Fiber?
With FSO, especially through
the window, no permits, no
digging, no fees
•Cost
•Rights of Way
•Permits
•Trenching
•Time
6
[6]
Why Not Just Bury More Fiber?
With FSO, especially through
the window, no permits, no
digging, no fees
•Cost
•Rights of Way
•Permits
•Trenching
•Time
6
Why Free Space Optics?
[6]
How FSO Works
7
[6]
How FSO Works
7
Why Free Space Optics?
[6]
Very Narrow and Directional Beams
•Beams only a few meters in diameter at a kilometer
•Allows VERY close spacing of links without interference
•No side lobes
•Highly secure
•Efficient use of energy
•Ranges of 20m to more than 8km possible
8
[6]
Very Narrow and Directional Beams
•Beams only a few meters in diameter at a kilometer
•Allows VERY close spacing of links without interference
•No side lobes
•Highly secure
•Efficient use of energy
•Ranges of 20m to more than 8km possible
8
Why Free Space Optics?
[6]
Deployment Behind Windows
•Rapid installations without trenching and
permitting
•Direct connection to the end user
•Bypasses the building owner
–No roof rights
–No riser rights
9
[6]
Deployment Behind Windows
•Rapid installations without trenching and
permitting
•Direct connection to the end user
•Bypasses the building owner
–No roof rights
–No riser rights
9
Origin
[1]
•Firstly used by Greeks in 8
th
century.
•According to them fire as the light source, the
atmosphere as transmission medium and an
eye as a receiver.
•19
th
century, Alexander Graham Bell – done
experiments - which were later called as
Photophone.
10
[1]
•Firstly used by Greeks in 8
th
century.
•According to them fire as the light source, the
atmosphere as transmission medium and an
eye as a receiver.
•19
th
century, Alexander Graham Bell – done
experiments - which were later called as
Photophone.
10
Origin (cont.)
[1]
•Bell converted voice sounds into telephone
signals and transmitted them between
receivers through free space along a beam of
light for a distance of some 600 feet.
•But Photophone never became commercial
reality.
•Though it demonstrated the basic principle of
optical transmissions.
11
[1]
•Bell converted voice sounds into telephone
signals and transmitted them between
receivers through free space along a beam of
light for a distance of some 600 feet.
•But Photophone never became commercial
reality.
•Though it demonstrated the basic principle of
optical transmissions.
11
Technology
[1]
•Uses a directed beam of light radiation
between transmitter and receiver.
•An FSO unit consists of
1) Optical transceiver
2) Laser transmitter and receiver
•Uses lens on transmitter and receiver.
•Maximum range is about 4 kms.
12
[1]
•Uses a directed beam of light radiation
between transmitter and receiver.
•An FSO unit consists of
1) Optical transceiver
2) Laser transmitter and receiver
•Uses lens on transmitter and receiver.
•Maximum range is about 4 kms.
12
Working
[2]
•FSO work on simple optical transmission
system.
•Modern Laser system provide network
connectivity speed from 660 Mbps onwards.
•Two beams are kept narrow.
•The receiver detectors are either PIN diodes or
Avalanche Photodiode.
•FSO transmits invisible light beams between
two beams.
13
[2]
•FSO work on simple optical transmission
system.
•Modern Laser system provide network
connectivity speed from 660 Mbps onwards.
•Two beams are kept narrow.
•The receiver detectors are either PIN diodes or
Avalanche Photodiode.
•FSO transmits invisible light beams between
two beams.
13
Working (cont.)
[2]
•It works in Tera Hertz (THz) spectrum.
•Wavelength:
•FSO can operate into two wavelengths:
1) 800 nm
2) 1550 nm
•1550 nm wavelengths are more preferred due
to its advantages over 800 nm.
14
[2]
•It works in Tera Hertz (THz) spectrum.
•Wavelength:
•FSO can operate into two wavelengths:
1) 800 nm
2) 1550 nm
•1550 nm wavelengths are more preferred due
to its advantages over 800 nm.
14
Working (cont.)
[2]
15
Fig. 3 Sub-systems used in a typical free-space optics unit
[2]
[2]
15
Fig. 3 Sub-systems used in a typical free-space optics unit
[2]
Challenges
[6]
Sunlight
Environmental factors
16
[6]
Sunlight
Environmental factors
16
Challenges
[6]
Atmospheric Attenuation - FOG
•Absorption or scattering of optical
signals due to airborne particles
•Primarily FOG but can be rain, snow,
smoke, dust, etc.
•Can result in a complete outage
•FSO wavelengths and fog droplets are
close to equal in size
–(Mie Scattering)
•Typical FSO systems work 2-3X further
than the human eye can see
•High availability deployments require
short links that can operate in the fog
17
[6]
Atmospheric Attenuation - FOG
•Absorption or scattering of optical
signals due to airborne particles
•Primarily FOG but can be rain, snow,
smoke, dust, etc.
•Can result in a complete outage
•FSO wavelengths and fog droplets are
close to equal in size
–(Mie Scattering)
•Typical FSO systems work 2-3X further
than the human eye can see
•High availability deployments require
short links that can operate in the fog
17
Challenges
[6]
Low Clouds, Rain, Snow and Dust
•Low Clouds
–Very similar to fog
–May accompany rain and snow
•Rain
–Drop sizes larger than fog and wavelength
of light
–Extremely heavy rain (can’t see through it)
can take a link down
–Water sheeting on windows
•Heavy Snow
–May cause ice build-up on windows
–Whiteout conditions
•Sand Storms
–Likely only in desert areas; rare in the
urban core
18
[6]
Low Clouds, Rain, Snow and Dust
•Low Clouds
–Very similar to fog
–May accompany rain and snow
•Rain
–Drop sizes larger than fog and wavelength
of light
–Extremely heavy rain (can’t see through it)
can take a link down
–Water sheeting on windows
•Heavy Snow
–May cause ice build-up on windows
–Whiteout conditions
•Sand Storms
–Likely only in desert areas; rare in the
urban core
18
Challenges
[6]
Scintillation
•Beam spreading and wandering due to propagation through air
pockets of varying temperature, density, and index of
refraction.
•Almost mutually exclusive with fog attenuation.
•Results in increased error rate but not complete outage.
19
[6]
Scintillation
•Beam spreading and wandering due to propagation through air
pockets of varying temperature, density, and index of
refraction.
•Almost mutually exclusive with fog attenuation.
•Results in increased error rate but not complete outage.
19
Applications
[1]
•Metro Area Networks (MAN)
•Last Mile Access
•Enterprise connectivity
•Fiber backup
•Backhaul
•Service acceleration
20
[1]
•Metro Area Networks (MAN)
•Last Mile Access
•Enterprise connectivity
•Fiber backup
•Backhaul
•Service acceleration
20
Merits
[1]
•Flexible network solution over conventional
broadband services.
•Straight forward deployment- no licenses
required
•Low initial investment
•Ease of installation
•Re-deployability
•High bit rates and low error rates
21
[1]
•Flexible network solution over conventional
broadband services.
•Straight forward deployment- no licenses
required
•Low initial investment
•Ease of installation
•Re-deployability
•High bit rates and low error rates
21
Demerits
[1]
•Fog
•Physical obstructions
•Scintillation
•Solar interference
•Scattering
•Absorption
•Building sway / Seismic activity
22
[1]
•Fog
•Physical obstructions
•Scintillation
•Solar interference
•Scattering
•Absorption
•Building sway / Seismic activity
22
References
[1] Free-space optical communication - Wikipedia, http://en.wikipedia.org/wiki/Free
space_optical_communication
[2] Vikrant Kaulgud, Free space optics Bridges the last mile, Electronics for U, June 2003 pp.
38-40. www.electronicsforu.com/electronicsforu/articles/hits.asp?id=822
[3] Hemmati, H., Free-space optical communications program at JPL, Jet Propulsion Lab.,
California Inst. of Technol., Pasadena, CA, USA, IEEE Lasers and Electro-Optics Society, pp.
106 - 107, vol.1, Nov. 1999.
[4] John Kaufmann, Free Space Optical Communications: An Overview of Applications and
Technologies, Boston IEEE Communications Society Meeting, December 1, 2011.
[6] John Schuster, Free Space Optics (FSO) Technology Overview, Chief Technology Officer,
Terabeam Corporation.
www.fcc.gov/realaudio/presentations/2002/.../technology_overview.ppt
[5] Andy Emmerson, Fiberless Optics, Everyday practical electronics, April 2003, pp. 248.
[6] www.fsona.com
[7] www.freespaceoptic.com
23
[1] Free-space optical communication - Wikipedia, http://en.wikipedia.org/wiki/Free
space_optical_communication
[2] Vikrant Kaulgud, Free space optics Bridges the last mile, Electronics for U, June 2003 pp.
38-40. www.electronicsforu.com/electronicsforu/articles/hits.asp?id=822
[3] Hemmati, H., Free-space optical communications program at JPL, Jet Propulsion Lab.,
California Inst. of Technol., Pasadena, CA, USA, IEEE Lasers and Electro-Optics Society, pp.
106 - 107, vol.1, Nov. 1999.
[4] John Kaufmann, Free Space Optical Communications: An Overview of Applications and
Technologies, Boston IEEE Communications Society Meeting, December 1, 2011.
[6] John Schuster, Free Space Optics (FSO) Technology Overview, Chief Technology Officer,
Terabeam Corporation.
www.fcc.gov/realaudio/presentations/2002/.../technology_overview.ppt
[5] Andy Emmerson, Fiberless Optics, Everyday practical electronics, April 2003, pp. 248.
[6] www.fsona.com
[7] www.freespaceoptic.com
23
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