Low Cost RF over Fiber Systems for Wireless LANs - MITcfp.mit.edu/publications/CFP_Presentations/Jun04/Penty... · 2004. 6. 22. · 256-QAM Transmission Fig: 256-QAM constellation
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Centre for Photonic Systems
UNIVERSITY OFCAMBRIDGE
Low Cost RF over Fiber Systems for Wireless LANs
Ian White, Richard Penty, Peter Hartmann and Xin QianPhotonic Communication Research, Department of Engineering, University of Cambridge,
Trumpington Street, Cambridge, CB2 1PZ, United Kingdom
Alwyn SeedsDepartment of Electronic and Electrical Engineering, University College London,
Torrington Place, London, WC1E 7JE, United Kingdom
Centre for Photonic Systems
UNIVERSITY OFCAMBRIDGE
OutlineOutline
1. Introduction1. Use of RF of fiber systems in antenna remoting
2. Review of RF over fiber advances in recent years1. Use of low cost uncooled lasers2. Successful transmission of RF signals over both
single and multimode optical fiber3. Multiservice distribution
3. Future challenges1. Hybrid fibre data/radio networks2. High bandwidth (~10 Gb/s) short haul wireless links
4. Conclusions and future work
Centre for Photonic Systems
UNIVERSITY OFCAMBRIDGE
Introduction: Distributed Antenna System (DAS)Introduction: Distributed Antenna System (DAS)
Customers: demand for 100% indoor mobile coverage, especially in office buildings but also in locations such as airports, shopping malls, …
Distributed Antenna System (DAS)
Coverage: Penetration from outdoor coverage is unreliable and insufficient, so installation of indoor system is inevitable.
Network operators: want to provide this coverage, but at low installation and maintenance cost.
!!!!Analogue fibre-optic DAS
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UNIVERSITY OFCAMBRIDGE
Introduction: FibreIntroduction: Fibre--optic DASoptic DAS
Analogue fibre-optic DAS
Low installation cost
• For d>100m, installation of fibre is preferred to coaxial cable
• Preinstalled fibre base may be used
• Directly transmitting RF signals significantly reduces cost and complexity of remote antenna units (RAU)
Low maintenance cost
• RAU is inherently transparent to transmitted signals
• Technology updates only have to be carried out at central distribution units (CDU)
• No need to modify or even replace RAU
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StateState--ofof--art Laser Performanceart Laser PerformanceFig: L-I characteristic for 25…85 °C Fig: Optical spectrum at 60mA and 85 °C
• Threshold current is 6mA at 25°C and 31mA at 85°C• Slope efficiency at 60mA is 0.143 W/A at 25°C and 0.054 W/A at 85°C• Single-mode operation over the 25°C - 85°C range, with typical SMSR of 45dB
1308 1310 1312 1314 1316 1318 1320 1322-80
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Waveleng th [nm]
Opt
ical
pow
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Bm
]
85 °C
45 dB
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Forward current [mA]
Opt
ical
pow
er fr
om fi
ber p
igta
il [m
W]
25 °C
45 °C
65 °C
85 °C
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Linearity Assessment: Frequency Response and IntermodulationLinearity Assessment: Frequency Response and Intermodulation
Two-tone setup: Tones separated by 1MHz, Centre frequency from 1GHz to 20GHz Power swept from –15dBm to +10dBmLaser biased at 60mA, package temperature of 25°C and 85°C
Fig: Fundamental and IM3 at 25°C Fig: Fundamental and IM3 at 85°C
1 2 3 4 5 6 7 8 9 10-100
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Ce ntre fre que ncy [GHz]
Out
put e
lect
rical
pow
er [d
Bm
]
Fundame ntal
Third-orde r inte rmodulation
85 °C
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0
Ce ntre frequency [GHz]
Out
put e
lect
rical
pow
er [d
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]
Fundame ntal
Third-orde r inte rmodulation
25 °C
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UNIVERSITY OFCAMBRIDGE
1 2 3 4 5 6 7 8 9 1070
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Ce ntre fre que ncy [GHz]
Spu
rious
-free
dyn
amic
rang
e [d
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z2/3
] 85 °C
2 4 6 8 10 12 14 16 18 2080
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Centre frequency [GHz]
Spu
rious
-free
dyn
amic
rang
e [d
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z2/3
]
25 °C
Linearity Assessment: SpuriousLinearity Assessment: Spurious--Free Dynamic Range (SFDR)Free Dynamic Range (SFDR)
Highest SFDR-values reported so far for uncooled DFB lasers
25°C SFDR is greater than 103dB·Hz2/3 over 1-20GHz range, max = 114dB·Hz2/3 (4GHz)SFDR decreases towards higher frequencies, because it incorporates link gain
85°C SFDR is greater than 90dB·Hz2/3 over 1-10GHz range, max = 104dB·Hz2/3 (2GHz)SFDR shows a minimum in the vicinity of the relaxation frequency
Fig: SFDR at 25°C Fig: SFDR at 85°C
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256256--QAM TransmissionQAM Transmission
Fig: 256-QAM constellation diagram after transmission over 15km SMF
Fig: EVM of DFB-laser as a function of SMF link distance
• Transmitted signal is 10MS/s 256-QAM, carrier amplitude of –10dBm• Fibre-optic link assessed for laser-temperatures of 20°C and 70°C and carrier
frequencies of 2GHz and 5GHz• EVM < 1.9%• Increase in EVM < 0.1% / km SMF• Elevated temperature results in only a small excess EVM
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SMF distance / km
EV
M /
%
2GHz, 20°C5GHz, 20°C2GHz, 70°C5GHz, 70°C
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Transmission of 3GPP WTransmission of 3GPP W--CDMACDMA
Fig: QPSK constellation diagram of single user-channel after transmission over 15km SMF
Fig: EVM of DFB-laser as a function of SMF link distance for 3GPP W-CDMA uplink and downlink signals
Standard test pattern no. 1• 16 QPSK modulated user-channels, each 30kb/s• Several low-rate synchronisation channels• carrier frequencies of 1.93GHz (uplink) and 2.14GHz (downlink)
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SMF distance / km
EV
M /
%
1.94GHz, 20°C2.13GHz, 20°C1.94GHz, 70°C2.13GHz, 70°C
• EVM requirement for 3GPP W-CDMA: 17%• EVM after transmission over 15km SMF: < 2.1%
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MultiMulti--Antenna Remoting using Single Mode FibreAntenna Remoting using Single Mode Fibre
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0 20 40 60 80 100 120 Number of antennae
EVM
[%]
QPSK16QAM32QAM64QAM
Bias T
35 mA
M-QAM
Splitter
Splitter
Splitter
PolarisationController SOA
Single Mode Fibre
O/E
O/E
O/E
O/E
Transmitter
Bias T
35 mA
M-QAM
PolarisationController SOA
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Long Haul Remoting using Amplifier SMF LinksLong Haul Remoting using Amplifier SMF Links
0
5
10
15
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25
0 20 40 60 80 100 120Fibre Length [km]
EVM
[%]
Without SOA
With SOA at the end ofthe linkWith SOA after 50km
SOA – Semiconductor Optical Amplifier
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Summary of SMF ResultsSummary of SMF ResultsTwo-tone intermodulation experiments• 25°C SFDR>100dB·Hz2/3 IIP3>20dBm for 1-20GHz range• 85°C SFDR>90dB·Hz2/3 IIP3>18dBm for 1-10GHz range
!Highest values reported so far
Transmission of wireless signals• If operation range of laser is properly chosen, the device adds only little
excess EVMSignal EVM requirement EVM after 15km SMF256-QAM N/A < 1.6% at 20°C,
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RF over MultiRF over Multi--mode Fibremode Fibre
frequency, GHz
rela
tive
resp
onse
, dB
0
-10
0 2 4 6
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MULTIMODE FIBRE RESPONSE (1km; 1300nm)
3G
802.
11b
802.
11a
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IEEE 802.11b WLAN MMF DemonstratorIEEE 802.11b WLAN MMF Demonstrator
Schematic of the WLAN demonstrator setup
-10dBLD DL PD DL
PD UL LD UL+30dB
+30dB
Uplink(MMF)
EthernetSwitch
AccessPoint
Downlink(MMF)
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Bias Current [mA]SN
R [d
B]
1m MMF100m MMF400m MMF700m MMF1000m MMF
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Multiservice Transmission of IEEE 802.11a/gMultiservice Transmission of IEEE 802.11a/g
+
Wired LAN
.11a
.11g
+
RF combiningnetwork
Local transceiverunit
Remote antennaunit
.11a.11a
.11g
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of 5
4Mbp
s O
FDM
sig
nal [
%]
20°C
70°C
CoaxComposite EVM of IEEE 802.11a signal from wireless access point within IEEE specification up to 1375m MMF link length
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Future OpportunitiesFuture OpportunitiesHybrid Optical/RF networks – an optimum scenario?
Fibre Core
Distributor
Transponder
Transponder
Fibre Radio Interface
Distributor500 Mb
it/s
1 Gbit
/s
30
250 m
100
300 m
104
m
100700
m
245 m
100700 m
245 m
100700 m
245 m
100
700 m 245 m
Distributor
...100 M
bit/s
100 Mbit/s
20 Mbit/s
1 Gbit/s
1 Gbit/s
30
300 m
500 Mbit/s100 Mbit/s
REACH architecture
10 Gbit/s
Fibre Radio Interface
1 Gbit/s
104m
Distributor
100 Mbit/s
...
- Use of core fibre network with 10 Gb/s link rates
- Use of directed UWB RF links to achieve low cost large bandwidth last drop to the user
-Use of RF over fibre techniques to allow raw transmission to the edge of the fibre network
-Particular interest in UWB or 20,40,60 GHz bands
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Future OpportunitiesFuture Opportunities
Scope of Hybrid Optical/RFNetwork
1. End-drop bit rate to the user of 100 or 500 Mb/s. 2. Achieved by demuxing a 10 Gbit/s fibre channel rate to
10 x 1 Gbit/s rates. 3. The 1 Gbit/s downstream rate is further split into two
500 Mbit/s streams. 4. Stream one delivers 500 Mbit/s over 300 m (radio free
space) distance to a single user. 5. Stream two at 500 Mbit/s provides 100 Mbit/s per user to
5 users through 5 beams; with 300 m range.
Fibre Core
Distributor 1 Gb
it/s50
300 m
104
m
1 Gbit/s
30
300 m
500 Mbit/s100 Mbit/s
1 Gbit/s
104m
Distributor
100 Mbit/s
..
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3G
+
+ RF combiner
Local unit
Remote unit
10GbE
10Gbit/s
Music
Movie
Data
Bias T
Bias
RF
Ultra-high speed wireless access
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UNIVERSITY OFCAMBRIDGE
0.40.0 0.8 1.2 1.6 2.0 2.4 2.8
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frequency / GHz
resp
onse
/ dB
• Good quality 200 Mb/s eye diagrams achieved for carrier frequencies up to 3.8 GHz i.e. 20 x F3dB
1.4 GHz 2.6 GHz 3.8 GHz
1.5ns/div
• Baseband channel transmission is limited by the bandwidth of the first null
• Propose to transmit several channels which are located in the passband regions of the fibre
Passband Transmission at 20x the Fibre Bandwidth
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5Gb/s Baseband Channel
5Gb/s SCM Channel
Back-Back (50mV/div, 150ps/div)
Back-Back (40mV/div, 150ps/div) After 300m (25mV, 150ps)
After 300m (50mV, 150ps)
• 5Gb/s signals are not adversely affected by transmission over 300m of 62.5µm MMF
10 10 Gb/sGb/s MMF Link DemonstrationMMF Link Demonstration
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• Subcarrier Multiplexing can be employed to achieve the ultra-high data rate
• 5Gbit/s/channel x 2 channels = 10Gbit/s• 2.5Gbit/s/channel x 4 channels = 10Gbit/s• 1.25Gbit/s/channel x 8 channels = 10Gbit/s
• M-QAM modulation schemes can also be utilised to improve the spectral efficiency and potentially further increase the capacity
• E.g. for 16QAM, 625MHz/channel x 4bit/Hz x 4 channels = 10Gbit/s
802.11b/g2G 3G
2GHz 2.5GHz1.5GHz
802.11a
5GHz 6GHz5.5GHz3GHz 10GHz 10.5GHz
UWB
-41.3dBm
Implementation using Ultra-wide Band Space
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0
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Channel 1 Channel 2 Channel 3 Channel 4
EVM
[%]
Fibre 1 16QAMFibre 2 16QAM
Reference Value
EVM of 10Gbit/s transmission over a typical MMF of 300m length
Output constellation and eye diagram of 16QAM
• Channel distribution • Channel 1: 4.0GHz
• Channel 2: 6.5GHz
• Channel 3: 7.8GHz
• Channel 4: 9.1GHz
Input constellation and eye diagram of 16QAM
Modelling results of SCM transmission characteristics
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ConclusionsConclusionsWe have shown that …
• … state-of-the-art uncooled DFB lasers show very high linearity performance at both high temperatures and high frequencies
• … few km transmission is possible over MMF and 100 km over SMF
We wish to study whether …… hybrid optical RF links will provide an optimum wireless distribution network
for broadband data… what are the limits to bandwidth… how dynamic bandwidth allocation is achieved... what impact may result from WDM… how can data and wireless networking be unified at the physical level
Centre for Photonic Systems
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AcknowledgementsAcknowledgements
• UK EPSRC/DTI LINK FRIDAY and WOWS projects
• Agilent Technologies and Bookham for providing some of the laser diodes used in these projects
• Amardeep Uppal of Agilent Technologies for providing the loan of the Agilent E4438C VSG and the Agilent 89640 VSA.
• Professor J M Elmirghani, University of Swansea for collaborations on the hybrid optical/RF architecture
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