Satellite RF Fundamentals 1 Wireless Technologies Review: Satellite RF Fundamentals.
Wireless Networks in the Factory Introduction : Fundamentals of Wireless
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Transcript of Wireless Networks in the Factory Introduction : Fundamentals of Wireless
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Wireless Networks in the Factory
Introduction: Fundamentals of Wireless9-Apr-2012
Fanny MlinarskyoctoScope, Inc.
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Contents
Radio technologiesRadio propagationFrequency bands
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Standards based Proprietary
Flood/water detector
Motion detector
Alarm panel
Smoke detector
Cordless phone
Smart meter
Baby monitor
Wireless Technologies
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GSM, WCDMA, LTE
802.16 WiMAX
802.11 Wi-Fi
802.15BluetoothZigBee60 GHzUWB
802.22
LocalLocal
MetroMetro
RegionalRegional
PersonalPersonal
Wide (3GPP* based)Wide (3GPP* based)
TVWS
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802.802.11af11af
802.11ad
LAN = local area networkingPAN = personal area networkingMAN = metropolitan area networkingWAN = wide area networkingNAN = neighborhood area networkRAN = regional area networkingTVWS = television white spaces3GPP = 3rd generation partnership project
NAN
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White Space Technologies
DB 3
DB 2DB 1
Mode II Device
Mode I Device
GPS Satellite
Source: Neal Mellen, TDK
Geolocation
Available channels
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Near Field Communications (NFC)• Key benefit: simplicity of use
– No configuration by user; data stored in NFC tag automatically triggers application
• Use cases include – Poster
• NFC tag in the poster automatically triggers the appropriate application in the reading device (e.g. URL stored in poster opens browser on handset)
– Mobile payments• Pay with NFC phones at any POS terminal• Store vouchers and coupons in NFC
phones– Authentication, access control
• Unlock car doors • Secure building access • Secure PC log-in
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Poster
Point of Sale (POS) terminal for mobile payments
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Common Access Protocols
• TDMA (time division multiple access)– AMPS, GSM
• CDMA (code division multiple access)– CDMA, W-CDMA, CDMA-2000
• SDMA (space division multiple access)– MIMO, beamforming, sectorized antennas
• FDMA (frequency division multiple access)• OFDM (orthogonal frequency division multiplexing)• OFDMA (orthogonal frequency division multiple access)
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Courtesy of Suresh Goyal & Rich Howard
CDMA
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FDMA
…TDMA
Frequency
Pow
er OFDM
Multiple orthogonal carriers
Time
Pow
er
Channel
Frequency
User 1 User 2 User 3 User 4 User 5
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OFDM (Orthogonal Frequency Division Multiplexing)
• OFDM is the most robust signaling scheme for a hostile wireless channel– Works well in the presence of multipath thanks to multi-tone signaling and
cyclic prefix (aka guard interval)• OFDM is used in all new wireless standards, including
– 802.11a, g and draft 802.11ac, ad– 802.16d,e; 802.22– DVB-T, DVB-H, DAB
• LTE is the first 3GPP standard to adopt OFDM
Multiple orthogonal carriers
Frequency
Vol
tage
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DVB = digital video broadcastingDVB-T = DVB terrestrialDVB-H = DVB handheldDAB = digital audio broadcastingLTE = long term evolution
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FDMA vs. OFDMA• OFDMA is more frequency efficient
than traditional FDMA– Orthogonal subcarriers require no guard bands
FDMAFDMA OFDMAOFDMA
ChannelGuard band
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OFDMA
Frequency
Tim
e
Frequency allocation per user is continuous vs. time
Frequency per user is dynamically allocated vs. time slots
User 1 User 2 User 3 User 4 User 5Ti
me
OFDM is a modulation
scheme
OFDMA is a modulation and access scheme
OFDM = orthogonal frequency division multiplexingOFDMA = orthogonal frequency division multiple access
Multiple Access
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LTE
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User 1
User 2
User 3 User 1
User 3
User 3
User 2
User 2
User 1
User 3
User 2
User 2
User 1
User 1
User 3
User 3
User 2
User 2
User 2
User 1
Frequency
Tim
e
Resource Block (RB)
180 kHz, 12 subcarriers with normal CP
0.5 ms7 symbols with normal CP
OFDMA Resource Allocation
• Resources are allocated per user in time and frequency. RB is the basic unit of allocation.
• RB is 180 kHz by 0.5 ms; typically 12 subcarriers by 7 OFDM symbols, but the number of subcarriers and symbols can vary based on CP
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CP = cyclic prefix, explained ahead
LTE
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Resource Block
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1 slot, 0.5 ms
1 subcarrierResource Element1 subcarrierQPSK: 2 bits16 QAM: 4 bits64 QAM: 6 bits
Resource block 12 subcarriers
Time
Subc
arrie
r (fr
eque
ncy)
…
…
……v
A resource block (RB) is a basic unit of access allocation. RB bandwidth per slot (0.5 ms) is 12 subcarriers times 15 kHz/subcarrier equal to 180 kHz.
LTE
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Transmission bandwidth in RBs
Channel bandwidth in MHz
1.4 3 5 10 15 20
1.08 2.7 4.5 9 13.5 18
6 15 25 50 75 100
Channel bw
Transmission bw
# RBs per slot
MHz
Scalable Channel Bandwidth
RB = resource block
Center subcarrier (DC)
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LTE
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DLUL
DL
UL
FDD vs. TDD• FDD (frequency division duplex)
– Paired channels• TDD (time division duplex)
– Single frequency channel for uplink an downlink– Is more flexible than FDD in its proportioning of uplink vs. downlink bandwidth
utilization– Can ease spectrum allocation issues
TD-LTE
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Contents
Radio technologiesRadio propagationFrequency bands
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Wireless Channel• Frequency and time variable
wireless channel• Multipath creates a sum of
multiple versions of the TX signal at the RX
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Ch
ann
el Q
ual
ity
Frequency-variable channel appears flat over the narrow band of an OFDM subcarrier.
Frequency
……
OFDM = orthogonal frequency division multiplexing
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Wireless Channel
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Line of sight
Per path angular spread
Composite angular spread
Composite angular spread
Multipath clusters
Multipath and Doppler fading in the channel
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Path Loss and Multipath• In a wireless channel the signal
propagating from TX to RX experiences fading and multipath
• Free space loss (flat fading) increases vs. frequency
Fading can be ‘flat’ or it can have multipath components
Multipath can be caused by mobile or stationary reflectors.
Time
+10 dB0 dB
Multipath fading component
-15 dB flat fading component
Path loss in free spaceDistance 5.8 GHz 2.4 GHz 915 MHz160 feet 81 dB 74 dB 65 dB
Loss (dB) = 20 * Log10 (frequency in MHz) + 20 * Log10 (distance in miles) + 36.6
In ideal free space propagation, range doubles for every 6 dB of path loss.
Typically 6-9 dB of increase in link budget doubles outdoor range and 9-12 dB increase in link budget doubles indoor range.
Devices supporting antenna diversity or MIMO help mitigate
the effects of multipath.
MIMO = multiple input multiple output
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Cyclic Prefix ↔ Guard Interval
• The OFDM symbol is extended by repeating the end of the symbol in the beginning. This extension is called the Cyclic Prefix (CP) or Guard Interval (GI).
• CP is a guard interval that allows multipath reflections from the previous symbol to settle prior to receiving the current symbol. CP has to be greater than the delay spread in the channel.
• CP minimizes Intersymbol Interference (ISI) and Inter Carrier Interference (ICI) making the data easier to recover.
TS
copy
Guard interval > delay spread in the channelUseful data
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Multiple Antenna Techniques• SISO (Single Input Single Output)
Traditional radio
• MISO (Multiple Input Single Output)Transmit diversity (STBC, SFBC, CDD)
• SIMO (Single Input Multiple Output)Receive diversity, MRC
• MIMO (Multiple Input Multiple Output)SM to transmit multiple streams simultaneously; can be used in conjunction with CDD; works best in high SNR environments and channels de-correlated by multipathTX and RX diversity, used independently or together; used to enhance throughput in the presence of adverse channel conditions
• Beamforming SM = spatial multiplexingSFBC = space frequency block codingSTBC = space time block codingCDD = cyclic delay diversityMRC = maximal ratio combiningSM = Spatial MultiplexingSNR = signal to noise ratio
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NxM
MIMO systems are typically described as NxM, where N is the number of transmitters and M is the number of receivers.
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TX
RX
TX
RX
2x2MIMO radio
channel
TX
RX
TX
RX
2x2 radio 2x2 radio
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Fresnel Zone
• Fresnel zone is the shape of electromagnetic signal and is a function of frequency
• The higher the frequency the smaller the radius of the Fresnel zone
• Constricting Fresnel zone introduces attenuation and signal distortion
• Fresnel zone considerations favor higher frequencies, but path loss considerations favor lower frequencies of operation
r = radius in feetD = distance in milesf = frequency in GHz
Example: D = 0.5 miler = 30 feet for 700 MHzr = 16 feet for 2.4 GHzr = 10 feet for 5.8 GHz
D
rSource: Wikipediahttp://en.wikipedia.org/wiki/Fresnel_zone
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Contents
Radio technologiesRadio propagationFrequency bands
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Key Unlicensed ServicesIEEE 802.11 (Wi-Fi) operates in the ISM-2400 and ISM-5800 bands and in the 5800 UNII band; recently standardized for 3650-3700 contention band
IEEE 802.16 (WiMAX) operates in the UNII/ISM band and in the 3500-3700 MHz contention band
Cordless phones
ISM-900 traditionally used for consumer devices such as cordless phones, garage openers and baby monitors, now also used on smart meters
proprietary
Standards-based
FCC spectrum allocation charthttp://www.ntia.doc.gov/osmhome/allochrt.PDF
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UWB based WiMedia is a short-range network operating in the noise floor of other services
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Unlicensed Bands and ServicesFrequency range Bandwidth Band Notes
433.05 – 434.79 MHz 1.74 MHz ISM Europe
420–450 MHz 30 MHz Amateur US
868-870 MHz 2 MHz ISM Europe
902–928 MHz 26 MHz ISM-900 Region 2
2.4–2.5 GHz 100 MHz ISM-2400International allocations (see slides 7, 8 for details)
5.15–5.35 GHz 200 MHz UNII-1,2
5.47–5.725 GHz 255 MHz UNII-2 ext.
5.725–5.875 GHz 150 MHz ISM-5800UNII-3
24–24.25 GHz 250 MHz ISM US, Europe
57-64 GHz59-66 GHz 7 GHz ISM US
Europe
Emerging 802.11ad802.15.3c, ECMA-387WirelessHD
802.11b/g/n, Bluetooth802.15.4 (Bluetooth, ZigBee), cordless phones
802.11a/n, cordless phones
Smart meters, remote control, baby monitors, cordless phones
Medical devicesRemote control
Amer
icas
, Aus
tral
ia, I
srae
l
RFID and other unlicensed services
Euro
pean
ana
log
of th
e IS
M-9
00 b
and
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ISM = industrial, scientific and medicalUNII = unlicensed national information infrastructure
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ISM and UNII BandsBand Freq. Range
(MHz)Bandwidth
(MHz)Max Power Max EIRP
ISM-900 902-928 26 1 Watt 4 Watt (+36 dBm)ISM-2400 2400-2483.5 83.5 1 Watt 4 Watt for PtMP,
200 Watt for PtPISM-5800 5725-5850 125 1 Watt 200 W (+53 dBm)
UNII-1 5150-5250 100 50 mW 200 mWUNII-2 5250-5350 100 250 mW 1 Watt
UNII-2 ext 5470–5725 255 250 mW 1 WattUNII-3/ISM 5725-5825 100 1 Watt 200 Watt
EIRP = equivalent isotropically radiated powerPtMP = point to multipointPtP = point to point DFS = Dynamic Frequency Selection TPC = Transmitter Power Control
For frequency hopping services regulatory requirements also include dwell times, which impact the power spectrum.To operate in the 5 GHz bands radios must comply with the DFS and TPC protocol of 802.11h.
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UHF Spectrum
MHz
Low 700 MHz band
High 700 MHz band
US (FCC) White Spaces54-72, 76-88, 174-216, 470-692 MHz
European (ECC) White Spaces (470-790 MHz)
CH 52-59, 692-746 MHz
Acq
uire
d by
A
T&T
Band12
Band17
Band12
Band17
ECC = Electronic Communications Committee
A B C D E A B C
CH 60-69, 746-806 MHz
A B A B
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High 700 MHz BandD-Block
Public Safety Broadband (763-768, 793-798 MHz)Public Safety Narrowband (769-775, 799-805 MHz), local LMR
758 763 775 788 793 805MHz
Guard band Guard band
LMR = land mobile radio
Band 13 Band 13
Band 14 Band 14
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LTE Frequency Bands - FDDBand Uplink (UL) Downlink (DL) Regions
1 1920 -1980 MHz 2110 - 2170 MHz Europe, Asia
2 1850 -1910 MHz 1930 - 1990 MHz Americas, Asia
3 1710 -1785 MHz 1805 -1880 MHz Europe, Asia, Americas 4 1710 -1755 MHz 2110 - 2155 MHz Americas 5 824-849 MHz 869 - 894 MHz Americas
6 830 - 840 MHz 875 - 885 MHz Japan
7 2500 - 2570 MHz 2620 - 2690 MHz Europe, Asia
8 880 - 915 MHz 925 - 960 MHz Europe, Asia
9 1749.9 - 1784.9 MHz 1844.9 - 1879.9 MHz Japan
10 1710 -1770 MHz 2110 - 2170 MHz Americas
11 1427.9 - 1452.9 MHz 1475.9 - 1500.9 MHz Japan
12 698 - 716 MHz 728 - 746 MHz Americas
13 777 - 787 MHz 746 - 756 MHz Americas (Verizon)
14 788 - 798 MHz 758 - 768 MHz Americas (D-Block, public safety)
17 704 - 716 MHz 734 - 746 MHz Americas (AT&T)
18 815 – 830 MHz 860 – 875 MHz
19 830 – 845 MHz 875 – 890 MHz
20 832 – 862 MHz 791 – 821 MHz
21 1447.9 – 1462.9 MHz 1495.9 – 1510.9 MHz
Source: 3GPP TS 36.104; V10.1.0 (2010-12)
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LTE Frequency Bands - TDDBand UL and DL Regions
33 1900 - 1920 MHz Europe, Asia (not Japan)34 2010 - 2025 MHz Europe, Asia35 1850 - 1910 MHz 36 1930 - 1990 MHz 37 1910 - 1930 MHz 38 2570 - 2620 MHz Europe39 1880 - 1920 MHz China40 2300 – 2400 MHz Europe, Asia41 2496 – 2690 MHz Americas (Clearwire LTE)42 3400 – 3600 MHz43 3600 – 3800 MHz
Source: 3GPP TS 36.104; V10.1.0 (2010-12)
TD-LTE
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WiMAX Frequency Bands - TDD Band Class
(GHz)BW (MHZ)
Bandwidth Certification Group Code (BCG)
1 2.3-2.4 8.75 1.A 5 AND 10 1.B2 2.305-2.320, 2.345-2.360 3.5 2.A (Obsolete, replaced by 2.D) 5 2.B (Obsolete, replaced by 2.D) 10 2.C (Obsolete, replaced by 2.D) 3.5 AND 5 AND 10 2.D3 2.496-2.69 5 AND 10 3.A4 3.3-3.4 5 4.A 7 4.B 10 4.C5 3.4-3.8 5 5.A 7 5.B 10 5.C7 0.698-0.862
5 AND 7 AND 10 7.A8 MHz 7.F
WiMAX Forum Mobile Certification Profile v1.1.0
A universal frequency step size of 250 KHz is recommended for all band classes, while 200 KHz step size is also recommended for band class 3 in Europe.
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Band Class
(GHz)BW (MHZ) Duplexing Mode BS
Duplexing Mode MS
MS Transmit Band (MHz)
BS Transmit Band (MHz)
Certification Group Code
2 2.305-2.320, 2.345-2.360 2x3.5 AND 2x5 AND 2x10 FDD HFDD 2345-2360 2305-2320 2.E**5 UL, 10 DL FDD HFDD 2345-2360 2305-2320 2.F**
3 2.496-2.690 2x5 AND 2x10 FDD HFDD 2496-2572 2614-2690 3.B
5 3.4-3.82x5 AND 2x7 AND 2x10 FDD HFDD 3400-3500 3500-3600 5.D
6 1.710-2.170 FDD
2x5 AND 2x10 FDD HFDD 1710-1770 2110-2170 6.A2x5 AND 2x10 ANDOptional 2x20 MHz
FDD HFDD 1920-1980 2110-2170 6.B
2x5 AND 2x10 MHz FDD HFDD 1710-1785 1805-1880 6.C7 0.698-0.960 2x5 AND 2x10 FDD HFDD 776-787 746-757 7.B
2x5 FDD HFDD 788-793 AND 793-798 758-763 AND 763-768 7.C2x10 FDD HFDD 788-798 758-768 7.D5 AND 7 AND 10 (TDD), 2x5 AND 2x7 AND 2x10 (H-FDD)
TDD or FDD Dual Mode TDD/H-FDD
698-862 698-862 7.E*
2x5 AND 2x10 MHz FDD HFDD 880-915 925-960 7.G8 1.710-2.170 TDD
5 AND 10 TDD TDD 1785-1805, 1880-1920, 1910-1930, 2010-2025
1785-1805, 1880-1920, 1910-1930, 2010-2025
8.A
WiMAX Frequency Bands - FDD Source: WiMAX Forum Mobile Certification Profile R1 5 v1.3.0
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Global Unlicensed Bands SummaryFrequency Band Considerations
433 MHz Supported by most regions; < 2 MHz of bandwidth available; voice, video, audio and continuous data transmission are not allowed in US; commonly used for keyless entry systems and remote control
868 /915 MHz Single design takes care of 80% of the market, including Europe, US, Canada, Australia, New Zealand and other regions; long range and lower power consumption than in 2.4 GHz and higher frequency bands
2.4 GHz Popular international band; tends to be busy with interference from Wi-Fi, Bluetooth and cordless phones
5.8 GHz High cost and power consumption; low range compared to sub-1 GHz bands
60 GHz Suitable for emerging uncompressed video and high speed short range data networking applications; high power consumption and high cost expected
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Next Session
Part II: What You Need to Know about 802.11
•When: April 10th at 2 p.m.
Thank you!Please see more info and white papers at
www.octoscope.com
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