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DIGITAL PULSE INTERVAL MODULATION (DPIM) AS AN ALTERNATIVE MODULATION SCHEME FOR FREE SPACE OPTICS (FSO). Fiber Optic Cable. Intro to FSO. Intra-city Fiber Optic Links. The Reasoning. High-speed Access The Last Mile Problem? - PowerPoint PPT Presentation
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DIGITAL PULSE INTERVAL MODULATION (DPIM) AS AN ALTERNATIVE MODULATION SCHEME FOR FREE SPACE OPTICS (FSO)
Intro to FSO Intra-city Fiber Optic Links
Fiber Optic Cable
The Reasoning High-speed Access
The Last Mile Problem?Picture taken from: I. I. Kim, B. McArthur, and E. Korevaar, Comparison of laser beam propagation @ 785nm and
1550nm in fog and haze for optical wireless communications, Optical Access Incorporated, San Diego
Free Space Optics
Picture taken from: I. I. Kim, and E. Korevaar, Availability of Free Space Optics (FSO) and hybrid FSO/RF systems, Optical Access Incorporated, San Diego
The Solution
High-speed Access (cont’d)
Picture taken from: I. I. Kim, B. McArthur, and E. Korevaar, Comparison of laser beam propagation @ 785nm and 1550nm in fog and haze for optical wireless communications, Optical Access Incorporated, San Diego
The Solution (cont’d)
The Solution (cont’d) Typical FSO Laser/Photodiode Systems
Photos taken from: http://www.systemsupportsolutions.com
FSO Limitations Power Link Budget Equation
PTX – Power Transmitted PRX – Power Received dTX – Transmit Aperture Diameter (m) dRX – Receive Aperture Diameter (m) D – Beam Divergence (mrad) R – Range (km) – atmospheric attenuation factor
(dB/km)
2)(2 1010
DRd
dPP
TXA
RXATXRX
R
Atmospheric Attenuation
Table taken from: I. I. Kim, and E. Korevaar, Availability of Free Space Optics (FSO) and hybrid FSO/RF systems, Optical Access Incorporated, San Diego
FSO Limitations (cont’d)
FSO Limitations (cont’d) TX/RX Alignment
TX/RX Misalignment
Picture taken from: TD. A. Rockwell, and G. S. Mecherle, Optical Wireless: Low-cost, Broadband, Optical Access,
Fsona Communication Corporation, Richmond, BC
Limitation Solutions RF Back-up (Hybrid FSO/RF)
Active Beam Tracking
Limitation Solutions (cont’d) Increase Laser Power
Higher power received Higher power per unit area Operating @ 1550nm instead of 800nm
Increase Average Power Efficiency (APE) Pulse Modulation Schemes can provide
higher average power efficiency at theexpense of higher BW requirement
Hence, increase Peak-APE
Limitation Solutions (cont’d)
On-Off Keying (OOK) Simplest solution based on intensity
modulation ‘0’ – zero intensity, ‘1’ positive intensity
Popular Pulse Time Modulation Schemes for OC Pulse Position Modulation (PPM) Pulse Interval Modulation (PIM)
Pulse Time Modulation PPM
Higher average power efficiency than OOK Increases system complexity due to symbol-level
synchronization. DPIM
Higher APE than OOK but a bit lower than PPM No symbol-level synchronization required Higher Information capacity Data encoded as a number of time intervals between
successive pulses Simplified receiver structure
Pulse Time Modulation (cont’d)
Table taken from: A.R. Hayes, Z. Ghassemlooy, and N.L. See, The Effect of Baseline Wander on the Performance of
Digital Pulse Interval Modulation, 1999 IEEE
Pulse Time Modulation (cont’d)
M = log2L
Picture Taken form: J. Zhang, Modulation Analysis for Outdoors Applications of Optical Wireless Communications, Nokia Networks Oy, Finland
Bandwidth and Power Efficiency Comparisons
Table Taken form: J. Zhang, Modulation Analysis for Outdoors Applications of Optical Wireless Communications, Nokia Networks Oy, Finland
Pulse Time Modulation (cont’d)
Conclusion Power Increased by DPIM @ the cost of
increased BW. Higher power means more power
received @ the receiver @ high levels of attenuation and misalignment between TX/RX
Major FSO benefit: reliable link connection and/or increased distance between TX/RX for certain cities
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