fundamentals of microwave radio communication for ip and tdm
DESCRIPTION
BASIC INTRODUCTION INTO MICROWAVE THEORY AND IP APPLICATIONSTRANSCRIPT
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1
BASIC INTRODUCTION INTO MICROWAVE THEORY AND IP
APPLICATIONS
FUNDAMENTALS OF MICROWAVE RADIO
COMMUNICATION FOR IP AND TDM
Presented by: Richard Laine / Ivan Zambrano
Silicon Valley, CA.
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Agenda
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Introduction……………………………………..………….…….A
What is Microwave……….…………………….………….…….B
• Spectrum……………………………………………………………….…..B.1
• A Terrestrial Microwave Link and Applications...……………………....B.2
• How Far can Microwave Go………………………………………..........B.3
• How Microwave Radios Communicate……………………………….....B.4
• How Repeaters Extend the Range……………………………………....B.5
• Microwave Tower Issues………………………………………………….B.6
• Causes of Microwave Disconnect Periods……………………………...B.7
L2 Radio Technology………..………………………………......C
Why Propagation…………………......…………..…………......D
Antennas and Feeder Systems.…………………….………….E
RF Protection……………………………………………………..F
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A. INTRODUCTION
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• The field of terrestrial microwave communications is constantly experiencing a steady
technological innovation to accommodate the ever-demanding techniques telecom
providers and private microwave users employ when deploying microwave radios in their
cloud networks.
• In the beginning of this wireless evolution, the ubiquitous DS1s/E1s and DS3s/E3s
crisscrossed networks transporting mainly voice communications, data, and video.
• With the advent of Carrier Ethernet and IP, new techniques had to be developed to
ensure the new Layer 2 radios were up to par with the new wave of traffic requirements
including wideband online-streamed media. These new techniques come in the form of
Quality of Service (QoS), Traffic Prioritization, RF Protection and Design, Spectrum
Utilization, and Capacity Enhancement.
• With Carrier Ethernet and IP, network design becomes more demanding and complex in
terms of RF, Traffic Engineering, and QoS. However, the propagation concepts remain
unchanged from TDM link engineering while the link’s throughput of L2 radios doubles,
triples, or quadruples employing enhanced DSP techniques.
Introduction
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B. WHAT IS TERRESTRIAL MICROWAVE?
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Flushing ANSI values
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Terrestrial Microwave?………..What is it?
A line-of-sight point-to-point wireless technology
for the transmission of Internet, voice, data, and
online-streamed media.
July 2013
Refracted Beam
Direct Beam
Reflected Beam
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Terrestrial Microwave?………..What is it? (cont'd)
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Terrestrial Microwave?………..What is it? (cont'd)
July 2013
60% F1
60% F1
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B.1 SPECTRUM
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Frequency Spectrum
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Some Standard Frequency Bands for Terrestrial Microwave
Band Radio Frequency Recommendations (MHz) FCC, NTIA, and ITU-R)
4 GHz 3,600 – 4,200 FCC Part 101 and Rec F.635-6 (2006)
U4 GHz 3,803.5 – 4,203.5 ITU-R Rec F.382-8 (2006)
5 GHz 4,400 – 5,000 ITU-R Rec F.1099-3 Annex-1 (2007)
5 GHz 4,400 – 4,990 U.S. Federal (NTIA)
L6 GHz 5,925 – 6,175 FCC Part 101, Rec F.383-7 (2007)
U6 GHz 6,525 – 6,875 FCC Part 101
U6 GHz 6,430 – 7,110 ITU-R Rec F.384-9 (2007)
7/8 GHz 7,125 – 8,500 U.S. Federal (NTIA)
L7 GHz 7,125 – 7,425 ITU-R Rec F.385-8 Annex-1 (2007)
U7 GHz 7,425 – 7,725 ITU-R Rec F.385-8 (2007)
7W GHz 7,110 – 7,750 ITU-R Rec F.385-8 (2007)
L8 GHz 7,725 – 8,275 ITU-R Rec F.386-7 Annex-6 (2007)
10 GHz 10,550 – 11,680 FCC Part 101, Rec F.747 (1992)
11 GHz 10,700 – 11,700 FCC Part 101, Rec F.387-10 (2010)
13 GHz 12,750 – 13,250 ITU-R Rec F.497-6 (2007)
July 2013
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RF Atmospheric Attenuation
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B.2 A TERRESTRIAL MICROWAVE LINK
AND APPLICATIONS
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Data
Equipment
Outdoor RF/Antenna
Gigabit
Ethernet NxDS1/E1
PABX
Equipment
Data
Equipment
Outdoor RF/Antenna
Gigabit
Ethernet NxDS1/E1
PABX
Equipment
6 to 360 Mbit/s
QPSK to 256 QAM
July 2013
One "hop" of Microwave
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Radio Node Hardware Example - Eclipse
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Cellular Site MSC-BSC-BTS IP/TDM Interconnectivity
MSC (MTSO) - Switching Office (POP)
BTS - Base Station
BSC - Base Station Controller
BSC
18/23 GHz (NxDS1/E1)
23/38 GHz (NxDS1/E1)
18 GHz (NxDS1/E1) 18 GHz (DS3/E3) Eclipse Eclipse
BTS
BSC
Eclipse
MSC
(MTSO)
Eclipse
BTS BTS
BTS
Eclipse IRU 600 Self-Healing STM-1/OC-3/Ethernet /IP Ring
Typical TDM Capacity Requirements
OC-3/STM-1 to
OC-12/STM-4
16xDS1/E1 to
OC-3/STM-1 BSC to MSC
2-16xDS1/E1 1-2xDS1/E1 BTS to BSC
3G 2G Hops
BTS to BTS 1-2xDS1/E1 2-16xDS1/E1
July 2013
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Mobile RAN and Backhaul Transport
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IEEE, Oct. 2010
Carrier Ethernet MPLS-TP
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Outdoor Networked Radio (4-QAM through 1024-QAM)
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B.3 HOW FAR CAN TERRESTRIAL
MICROWAVE GO?
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Typical Relative Path Lengths with Clear Line of Sight (LOS)
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Path Length, mi (km)
6/7/8 GHz
11 GHz
18 GHz
23/38 GHz
100(160) 5(8) 10(16)
• Path lengths in the different RF
bands are estimates only
• A path analysis is required to
calculate the reliability and
availability criteria.
Maximum EIRP (Effective
Isotropic Radiated Power) =
+55 dBW = +85 dBm
3(5)
July 2013
80 GHz
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21
Examples of Very Long IP Microwave Links for Air Traffic Control
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B.4 HOW MICROWAVE RADIOS
COMMUNICATE
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Adaptive Coding and Modulation for IP Backhaul
Throughput
[Mbit/s @ 7 MHz Ch BW]
(QPSK) 10
(16QAM) 20
(64QAM) 30
Example: 99.990% 99.995% 99.999% Rain Availability or Path Reliability
Fade Margin: 24 dB (20%) 31 dB (55%) 40 dB (25%)
Time
Fast Multipath or Slow Rain Fade
Best Effort Traffic Less Critical
Traffic Critical Traffic
(256QAM) 40
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Coding Gain in AWGN Channels
• Coding gain in AWGN (Additive White Gaussian Noise) channels is defined as
the amount that the bit energy or S/N power ratio can be reduced under the coding
technique for a given Pb (bit error probability) or Pbl (block error probability)
Shannon Limit: Threshold, Eb/N0, below which
reliable communication can not be maintained! This
ratio can be considered a metric that characterizes the
performance of one system vs. another. The smaller
the ratio, the more efficient is the modulation and
detection process for a given Pb.
Pb
10-2
10-4
10-6
Uncoded
Coded
-1.6 dB -8 dB 16 dB
X dB of Coding Gain depending on modulation and BW
Eb/N
0
mNoEbNC log10//
With concatenated coding, the coded curve is steeper
than with Reed-Solomon alone.
Example: The C/N of a p-t-p radio featuring
4DS1/16QAM and Eb/N0 = 11.9 dB @ 10-6
equals: 11.9 dB + 10 log4 = 17.9 dB
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MLCM Signal Constellation d
√ 2 d 1 0
Level 1
1 0
2d
1 0
Level 2
A set of 64 symbols is divided into subsets B0 & B1 with
increased minimum square distance. Error performance
of level 1 is determined by the minimum square distance
of the original partition. Then in order to increase “free
Euclidean distance,” coding (combination of block or
convolutional) is performed to the lower level. Hence the
total error performance is improved. Example (16QAM):
Code rate, R = (1/2+3/4+23/24+1)/4=3.2/4
B1 B0
C2 C0 C1 C3
Level 3
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B.5 HOW REPEATERS EXTEND THE
RANGE
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Passive Reflector
"Billboard"
Site A
Single
Reflector
Site B
Terrain
Obstruction
Passive Repeater Arrangements
Site B
Site A
Terrain
Obstruction
Terrain
Obstruction
Double
Reflector
Double Reflector
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Site A Beam Bender
(Back-To-Back
Parabolics)
Terrain
Obstruction
Site B
Beam Bender
Back-To-Back Parabolic Antennas
"Beam Bender"
Other Passive Repeater Arrangements
July 2013
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B.6 MICROWAVE TOWER ISSUES
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Twist and Sway
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A B C
Antennas: HSX12-77 Antennas: HSX12-77
Beamwidth: ±0.35o Beamwidth: ±0.35o
425ft/130m
200ft/60m
425ft/130m
Daytime Tower Twist: ±10
±0.50 deflection angle
at 10 dB point
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B.7 CAUSES OF MICROWAVE
DISCONNECT PERIODS
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Causes of Traffic Disconnect - Outage
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• Rain outage (predictable and therefore acceptable) in access links above
about 10 GHz
• Equipment failure within the MTBF (Mean Time Between Failure) period
• Maintenance error or manual intervention (e.g., failure of a locked-on
module or path)
• Infrastructure failure (e.g., antenna, batteries, towers, power system)
• Low fade margin in non-diversity links
• Power fade (long-term loss of fade margin) in paths above about 6 GHz
July 2013
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C. SOME EXAMPLES OF L2 RADIO
TECHNOLOGY
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Eclipse Intelligent Node Unit
• The most compact nodal
solution on the market
• Single indoor unit
supporting multiple radio
paths
• Hot-swappable radio and
data access modules
• Support for all traffic types
• Cable-less traffic
connections
• Complete solution in one
box
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• Lower Losses than Couplers • More ODUs per Antenna feed
• Fewer Antennas
• Increased system gain • Reduces antenna sizes
• Less Tower Loading
• Radios’ features • 5 to 38 GHz licensed operation
• Fully transparent to payload
• Up to 500 Mbit/s of TDM, Hybrid TDM/Ethernet/IP, or all-IP throughput
• QPSK to 256-QAM
Networked Radios
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D. WHY PROPAGATION?
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Radio Wave Propagation
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GEO, MEO,
and LEO
Satellites
Sky Wave
(MF, HF only)
REFRACTED WAVE
NON-REFRACTED (k=1) WAVE Transmitting
Antenna
Receiving
Antenna
Troposphere
Ionosphere
Microwave link propagation is
influenced by REFRACTION,
REFLECTION, and DIFFRACTION
(not shown) wave propagation.
Ground Wave
(LF/MF only)
True Earth’s Curvature
MULTIPATH RAYS
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Ray Tracing Along a Profile
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• Not unlike outbound ripples from a pebble
tossed into a quiet pond, the outgoing microwave
wave front is circular. However, the only part of
the wave of interest is equal to the diameter
(aperture) of the antenna. Beyond the antenna’s
near field, and into the far field, the wave front is
flat, as shown. The ray(s), one direct (shown)
plus multipath rays (if any), are always
perpendicular (90o) to the wave front - thus only
one ray is assigned to each direct or multipath
route. All path profiles and engineering are based
upon ray analysis.
• Antennas serve only to provide maximum
coupling of the direct ray energy into the
waveguide feeder, to the exclusion of multipath
rays. Thus, optimum dish alignment is crucial
for minimum fading.
k = 1 (True Earth’s Radius)
Superrefraction (k>3)
Wavefront Ray 90o
Substandard Refraction (k<1)
Possible
Obstruction
Possible
Decoupling,
Defocusing, or
Entrapment
Dry and High Valleys
Humid Wetlands
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Carrier Ethernet Link Design Parameters
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Flushing ANSI values
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• NETWORK LAYOUT
• FIELD VERIFICATION
• MICROWAVE EQUIPMENT (Backhaul
Capacity, Link Aggregation, RF Band,
Diversity)
• LINK ANALYSIS (Google Map Study, Field
Survey, Geometry, Weather Patterns)
• LINK PERFORMANCE CALCS (ITU, Vigants)
• LINK AVAILABILITY CALCS (RF Protection,
Rain Outage)
• ACTIVE NODES and PASSIVE REPEATERS
• FREQUENCY STUDY (Interference,
Licensing, Antenna Selection)
• INFRASTRUCTURE (Shelter, AC/DC Power,
Site Security, Towers, Ice Shield, Air Con, etc.)
• ANTENNA FEEDER SYSTEM, (Structures,
Aesthetics, Transmission Lines)
• GROUNDING AND SAFETY
Towers >200ft (60-m)
Require Lighting,
Painting
Sections:
20-ft guyed,
25-ft Self Supp Shelter
Elliptical
Waveguide, Coax
Atmospheric
Multipath
Millimeter Wave
Rain Attenuation
Refraction, k-Factor
Variations
Antenna Sizes,
Types, Alignment
Diversity
Type, Ant.
Spacing, XPIC
Path
Clearance
July 2013
Dust Cloud
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Multipath Propagation
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Excessive Path
Clearance
Elevated Super-refractive
Layer
Specular Reflection
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E. ANTENNAS AND FEEDER SYSTEMS
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Reflector Antennas
Photos courtesy of Andrew Corporation
July 2013
Standard parabolic
Standard parabolic
(with radome) Shielded with radome
(high performance)
Higher F/B ratio
Spillover Effect Scattering Effect Diffraction Effect
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43 July 2013
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Antennas
• Used to efficiently radiate/receive the energy towards/from
the far-end of the link
• Important characteristics
– Gain / directivity / beamwidth
– Side lobe level
– Front-to-back ratio (F/B)
– Polarization (linear V/H, circular, dual V/H)
– Cross-polar discrimination
– VSWR
– Frequency operating range
– Mounting, weight, and wind loading
– Aesthetics
July 2013
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Antenna Alignment Issues
Antenna aligned on a side-lobe
Correct antenna alignment
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Antenna Decoupling
• Angle of arrival may vary by as much as 1° on long paths
in humid areas at night; therefore larger antennas are
typically slightly uptilted during daytime periods
• Such variations may cause power fades and degraded
performance (loss of fade margin, increased outage) if
antennas are very directive
Variation in arrival angle
K=
K=4/3
K=-2
July 2013
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47 AVIAT NETWORKS |
PRESSURIZED (AIR)
COAXIAL CABLE
UNPRESSURIZED (FOAM)
COAXIAL CABLE
ELIPTICAL
WAVEGUIDE
RECTANGULAR (RIGID)
WAVEGUIDE
CIRCULAR (RIGID)
WAVEGUIDE
Transmission Lines
July 2013
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48 AVIAT NETWORKS |
Transmission Lines (Feeder Systems)
• Coaxial cable
• Air dielectric (lower loss)
• Foam dielectric (higher loss)
• Works from DC, but losses increase very rapidly above 2GHz
• Waveguide
• Elliptical (very common)
• Circular (very low loss)
• Rectangular (now rarely used)
• Flexible/twistable waveguide
• Frequencies below cut-off do not propagate through waveguide
July 2013
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F. RF PROTECTION
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Definitions
50 AVIAT NETWORKS |
• Protection Schemes provide a level of security from long-
term (>10 CSES/event – Consecutive Severely Errored
Seconds) outages and loss of data throughput, and
therefore improve Availability and reduce traffic
disconnects.
• Diversity Arrangements reduce the number and duration
of short-term (<10 CSES/event) outages (no traffic
disconnects) and therefore improve Performance.
July 2013
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F.1 MONITORED HOT STANDBY
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1+1 Monitored Hot Standby Outdoor Node (cont’d)
July 2013 52 AVIAT NETWORKS |
Tribs 1-20
Protection
Cable
ODU 600sp/hp/ep
Y-Cables
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1+1 Monitored Hot Standby Outdoor Node
July 2013 53 AVIAT NETWORKS |
Equal split (3dB)
RF Splitter is also
possible with the
consequence of a
2dB link gain
penalty which
translates into a
58% degradation in
the hop’s error
performance and
perhaps larger
antennas!
ANTENNA
DATA
OUT
DATA IN
-1.6dB
-6.6dB
Tx A
Rx A
Tx B
Rx B
Asymmetric
RF
Coupler
INU/IDU errorless data
selection is frame-by-frame
-1.6dB
-1.6dB
Tx A or Tx B is on line
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H.2 MONITORED HOT STANDBY WITH
SPACE DIVERSITY
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July 2013 55 AVIAT NETWORKS |
Space Diversity with Horizontal Offset
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1+1 Monitored Hot Standby Space Diversity - Outdoor Node
July 2013 56 AVIAT NETWORKS |
Multipath forms essentially
in the vertical plane;
consequently, the antennas
should always be placed
vertically to achieve de-
correlated paths !
Main ANTENNA
DATA
OUT
DATA IN
Tx A
Rx A
Tx B
Rx B
INU errorless data
selection is frame-by-frame
Diversity ANTENNA
300 ms
Vertical antenna spacing from 3 – 23m
ITU-R P.530-13
RSLM
RSLD
-40 dB fade
-20 dB fade
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THANKS YOU AND SUGGESTIONS
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Suggestions
58 AVIAT NETWORKS | July 2013
• Professional Affiliations News Websites • IEEE
• LinkedIn www.bbc.com
www.foxnews.com
• Movies www.elpais.es
• The Pirates of Silicon Valley
• Social Network
• The Internship
• The Greatest Game Ever Played
• Flash of Genius
• Countries
• Spanish English • Chile Australia
• Argentina New Zealand
Dubai
Canada
USA