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HIGH CAPACITY OPTICAL FIBER TRANSMISSION EXPERIMENTS USING MULTIPLE MODES Dr. V.A.J.M. Sleiffer MSc
May 13th 2015
11:30-11:55
Communication networks beyond the capacity crunch - further discussion The Royal Society at Chicheley Hall, home of the Kavli Royal Society International Centre, Buckinghamshire
ACKNOWLEDGEMENTS
• Dr. Maxim Kuschnerov (Coriant)
• Dr. Yongmin Jung (ORC)
• Paolo Leoni (Universität der Bundeswehr München)
• Dr. Haoshuo Chen (Formerly TU/e, now with Bell Labs)
• Dr. Huug de Waardt (TU/e)
• Prof. David Richardson (ORC)
• All partners from the MODEGAP project
OVERVIEW
Introduction
Few-mode fiber (FMF) experiments
Hollow-core photonic bandgap fiber (HC-PBGF)
Field demonstration of MDM upgrade scenarios
Conclusions and remarks
INTRODUCTION
• Increasing data traffic (~2 dB/year)
• Current transmission medium, the single mode fiber, is reaching its limits
– Fiber nonlinearity limits maximum received OSNR
– Higher-order modulation formats have high OSNR requirements AND are more sensitive to nonlinear effects
– Limitation of maximum capacity for a certain reach
• Cost per bit and energy efficiency important drivers for new technology
R.J. Essiambre et al., “Capacity limits of Optical Fiber Networks,” JLT 28, pp. 662-700 (2010)
INTRODUCTION
• Capacity? Fiber nonlinearity, number of cores/modes, transmission window
• Reach? Fiber attenuation and nonlinearity, amplification technologies
• Cost/energy efficiency? Higher-order modulation, information density
• Amplification
• Routing
• Space-division multiplexing (SDM) and mode-division multiplexing (MDM)
Single-mode fiber ribbon
= Single-mode fiber
Multi-core fiber/ Coupled-core fiber
Few-/Multi-mode fiber
THE MODEGAP PROJECT
• Advantages w.r.t. other space-division multiplexing (SDM) technologies
– Highest information density per µm2 allows for a high level of integration
– Lowest expected overall system costs and highest energy efficiency (integrated amplifiers and ROADMs)
– Easy handling/splicing
• Hollow-core photonic band gap fiber (HC-PBGF):
– Lowest nonlinearity
– Lowest potential loss @2µm
– Highest available bandwidth @2µm
– Multi-mode?
F. Poletti et al., “Hollow-core photonic bandgap fibers: technology and applications,” Nanophotonics, vol. 2, no. 5-6, pp. 315–340, Nov. 2013.
×2.5
×4
×10
OVERVIEW
Introduction
Hollow-core photonic bandgap fiber (HC-PBGF)
Field demonstration of MDM upgrade scenarios
Conclusions and remarks
FMF experiments
FEW-MODE FIBER EXPERIMENTS
DAC
DAC
ODD
AWG
DAC
DAC
EVEN
AWG
2810
Symbols
4402
Symbols
Mode MUX
LP11B
LP11A
LP01
LP11A
Sco
pe
1S
co
pe
2Coherent
Rx
Coherent
Rx
Coherent
Rx
FM-EDFA
84km 35km
Span 2Span 1
357
SymbolsDAC
DAC
CUT
LO
1x4
48
48
WSS
0.4nm
0.4nm
0.4nm
Syn
c.
LP11B
LP01
Mode DEMUX
Mo
du
lati
on
DP
+W
DM
FMF-link MDM
Coherent reception and 6×6 MIMO-DSP
Here we only use 2 mode-groups / 3 modes: LP01, LP11A and LP11B
HIGH-CAPACITY TRANSMISSION OVER FMF
• Total 73.7 Tb/s (96 × 3 × 256) over 119 km of FMF
• Net datarate 57.6 Tb/s (taking into account FEC-overhead+Network protocols)
• Reach limitation due to mode (de)multiplexer loss
96 WDM channels FEC-limit
V.A.J.M. Sleiffer et al., “73.7 Tb/s (96 x 3 x 256-Gb/s) mode-division-multiplexed DP-16QAM transmission with inline MM-EDFA”, Optics Express 20 (26), B428-B438 (2013)
256 Gb/s
256 Gb/s
256 Gb/s
LONG-HAUL TRANSMISSION OVER FMF
• 3 MDM × 128-Gb/s DP-QPSK channel
• 60-km FMF (DMD minimized)
• 2 FM-EDFAs
V.A.J.M. Sleiffer et al., “An optical chopper based re-circulating loop for few-mode fiber transmission”, Optics Letters 39 (5), 1181-1184 (2014)
Tx
Rx
Beam diameter ≈ 0.6mm
Loop in
Loop o
ut
Tx
RxTim
ing
Contro
l
Chopper
3dB coupler
loop
60km
Spool 1 Spool 2
Length [km] 30 30
DGD [ps/m] -0.044 0.053
Average BER
Signal 1
Signal 2
Signal 3
FEC-limit
0 100 200 300 400 500 60010
-5
10-4
10-3
10-2
Transmission Distance [km]
Bit-e
rror
ratio
400 500 600 700 800 900 1000 1100 1200
10-4
10-3
10-2
Transmission Distance [km]
Bit-e
rror
ratio
10-5
FEC-Limit
LP01LP11bLP11a
Average BER 3 MDM × 128-Gb/s
DP-QPSK
Pol. X
Pol. Y
LP11a LP11b LP01
LONG-HAUL TRANSMISSION OVER FMF
V.A.J.M. Sleiffer et al., “An optical chopper based re-circulating loop for few-mode fiber transmission”, Optics Letters 39 (5), 1181-1184 (2014)
V.A.J.M. Sleiffer et al., “480 km Transmission of MDM 576-Gb/s 8QAM using a Few-Mode Re-circulating Loop”, IEEE Photonics Conference, Bellevue WA, PD6(2013)
Mode-selective launch Mode-mixed launch
LONG-HAUL TRANSMISSION OVER FMF
• Impulse response grows due to DGD/DMD!
– Important for DSP requirements
– Important for non-linear effects?
V.A.J.M. Sleiffer et al., “480 km Transmission of MDM 576-Gb/s 8QAM using a Few-Mode Re-circulating Loop”, IEEE Photonics Conference, Bellevue WA, PD6 (2013)
100 150 200 250 300 350 400
10-4
10-3
10-2
Number of TapsBit-e
rror
ratio
2 Loops (120km)
5 Loops (300km)
8 Loops (480km)
-120 -80 -40 0 40 80 120-60
-40
-20
0
Tap Number
Magnitude [
dB]
2 Loops (120km)
5 Loops (300km)
8 Loops (480km)
OVERVIEW
Introduction
Field demonstration of MDM upgrade scenarios
Conclusions and remarks
Hollow-core PBGF
FMF experiments
HC-PBGF EXPERIMENTS
• Light propagates in air meaning:
– Ultra low nonlinearities (>103 reduction over SMF)
– Ultra low Rayleigh scattering and potential for ultra-low overall transmission loss
• Low-loss can only be provided when overlap between the optical field and the glass is small
• Hard to achieve in reality! -> still actively being researched
– Ultimate low latency (99.7% the speed of light in vacuum)
HC-PBGF EXPERIMENTS (SINGLE-MODE)
• Highest capacity transmitted using coherent technology 24 Tb/s
– V.A.J.M. Sleiffer et al., “30.7 Tb/s (96 × 320 Gb/s) DP-32QAM transmission over 19-cell photonic band gap fiber”, Proc. OFC, OW1I.5 (2013)
• Longest distance transmitted using coherent technology and a re-circulating loop consisting of 6.2 km HC-PBGF -> 74.8 km
– M. Kuschnerov et al., “Data Transmission through up to 74.8 km of Hollow-Core Fiber with Coherent and Direct-Detect Transceivers”, Submitted to ECOC 2015
Interesting research topic!
HC-PBGF EXPERIMENTS (FEW-MODE)
V.A.J.M. Sleiffer et al., “High capacity mode-division multiplexed transmission in a novel 37-cell hollow-core photonic bandgap fiber”, Journal of Lightwave Technology 32 (4), p. 854-863 (2014)
HC-PBGF EXPERIMENTS (FEW-MODE)
• Total 73.7 Tb/s (96 × 3 × 256) over 310 m of 37-cell HC-PBGF
• Net datarate 57.6 Tb/s (taking into account FEC-overhead+Network protocols)
96 WDM channels
FEC-limit
V.A.J.M. Sleiffer et al., “High capacity mode-division multiplexed transmission in a novel 37-cell hollow-core photonic bandgap fiber”, Journal of Lightwave Technology 32 (4), p. 854-863 (2014)
-300 -200 -100 0 100 200 300-60
-40
-20
0
-300 -200 -100 0 100 200 300-60
-40
-20
0
4-5
ps/
m
12
-13
ps/
m
9-1
2 p
s/m
LP01 LP11 LP21 LP02
Tap Number
Mag
nit
ud
e [d
B]
Mag
nit
ud
e [d
B]
HC-PBGF EXPERIMENTS (FEW-MODE)
• Large DGD between modes
– Factor ~100 more than solid-core FMF
• (Not shown) Very large mode-dependent loss (MDL) of ~3-4 dB/km
LP01 LP01
LP11 LP11
V.A.J.M. Sleiffer et al., “High capacity mode-division multiplexed transmission in a novel 37-cell hollow-core photonic bandgap fiber”, Journal of Lightwave Technology 32 (4), p. 854-863 (2014)
Field demonstration of MDM upgrade scenarios
OVERVIEW
Introduction
Conclusions and remarks
FMF experiments
HC-PBGF
FIELD DEMONSTRATION OF MDM UPGRADE SCENARIO ON LEGACY NETWORKS
• All few-mode fiber work beside this is confined to laboratories
• Need to show backward compatibility of SDM technology with single mode technology
– No end-to-end FMF link immediately available
– Congested spans to be replaced first
FM-EDFA
FMF
MU
X
DE
MU
X
nxSSMF
m×ROADM Terminal
Terminal
Single-mode
Amplifiers
m×ROADM
n×SSMF
nxSSMF
n×SSMF
n×SSMF
n×SSMF
m×ROADM m×ROADM
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
DETAILED TRIAL LAY-OUT
1,2) Flexi-rate prototypes A) Live A1 Network (1,023 km)
3) Commercial 100G B) Dark A1 fiber (52.2 km)
4) Offline receiver FMF) Few-mode fiber
Legend:
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
DAC
EVEN
1
2
Salzb
urg
Klagenfurt
Bischofs-hofen
a
Vienna
Bb
Lin
k 3
Link 2
Link 1
1x4
DAC
ODD800
Symbols
1854 Sym.
5535 Sym.
8x8x1x8
1x8
193.95THz
193.95THz
100G
100G
optional
optionalW
SS
1
1
2
or
b
4
3
100G
Scope 1
Scope 2
Scope 3
Offlin
e D
SP
LO
LO
LO
CoherentRx 1
CoherentRx 2
CoherentRx 3
1x4
2
Salzb
urg
Bischofs-hofen
60km 60kmFMF FMF
FM-EDFA
Mode DEMUX
Mode MUX
b4
or
3
SCENARIO 1: SINGLE-MODE TRANSMISSION OVER FMF
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
SCENARIO 1: SINGLE-MODE TRANSMISSION OVER FMF
• Transmission over 1,247 km (1,023 km live network) with three fiber types (SSMF, NZDSF, FMF)
• Coriant 100G-HD commercial cards used
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
DAC
EVEN
1
260km 60kmFMF FMF
FM-EDFA
Mode DEMUX
Salzb
urg
Klagenfurt
Bischofs-hofen
a
Vienna
Bb
Lin
k 3
Link 2
Link 1
Mode MUX
1x4
DAC
ODD800
Symbols
1854 Sym.
5535 Sym.
8x8x1x8
1x8
193.95THz
193.95THz
100G
100G
optional
optional
WSS
1
1
2
or
b b
4
100G
Scope 1
Scope 2
Scope 3
Offlin
e D
SP
LO
LO
LO
CoherentRx 1
CoherentRx 2
CoherentRx 3
1x4
2
Salzb
urg
Bischofs-hofen
4
or
3
3
SCENARIO 1: SINGLE-MODE TRANSMISSION OVER FMF
• Most penalty from additional EDFAs
• Minimal penalty due to few-mode fibers (FMF)
• 100G commercial card was running for hours without post-FEC errors
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
-4 -2 0 2 4 6 8 1010
-3
10-2
PLaunch
[dBm]
16 18 20 22
Bit-e
rror
ratio
Pump power [dBm]
0 60 120 18010
-4
10-3
10-2
Time [s]
Bit-e
rror
ratio
1,247 km (Link 1 to 3 + 120 FMF )
1,023 km (Link 1 & 2)
100G Performance over
SCENARIO 2: MID-LINK MODE MULTIPLEXING AND DE-MULTIPLEXING OF THREE SIGNALS
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
SCENARIO 2: MID-LINK MODE MULTIPLEXING AND DE-MULTIPLEXING OF THREE SIGNALS
• Three single-mode signals transmitted over 52 km SMF and multiplexed onto FMF, de-multiplexed and transmitted again over three separate SMFs before detection and offline 6 × 6 MIMO-DSP
• Each fiber carrying either 16 WDM channels with 192-Gb/s DP-8QAM (total 7.2 Tb/s) or 256-Gb/s DP-16QAM modulation (total 9.6 Tb/s)
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
60km 60kmFMF FMF
FM-EDFA
Mode DEMUX
Mode MUX
b4
or
3
DAC
EVEN
1
2
Salzb
urg
Klagenfurt
Bischofs-hofen
a
Vienna
Bb
Lin
k 3
Link 2
Link 1
1x4
DAC
ODD800
Symbols
1854 Sym.
5535 Sym.
8x8x1x8
1x8
193.95THz
193.95THz
100G
100G
optional
optionalW
SS
1
1
2
or
b
4
3
100G
Scope 1
Scope 2
Scope 3
Offlin
e D
SP
LO
LO
LO
CoherentRx 1
CoherentRx 2
CoherentRx 3
1x4
2
Salzb
urg
Bischofs-hofen
SCENARIO 2: MID-LINK MODE MULTIPLEXING AND DE-MULTIPLEXING OF THREE SIGNALS
• Good performance over 224 km combined FMF and SMF
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
193.4 193.6 193.8 194 194.2 194.410
-7
10-6
10-5
10-4
10-3
10-2
Frequency [THz]
Bit-e
rror
ratio
-30
-25
-20
-15
-10
-5
-0
Rela
tive p
ow
er
[dB]
3·256-Gb/s DP-16QAM Avg. BER
3·192-Gb/s DP-8QAM Avg. BER
DP-sig. 1 DP-sig. 2 DP-sig. 3
Pol. X
Pol. Y
Pol. X
Pol. Y
sig. 1 sig. 2 sig. 3
SCENARIO 3: MULTI-RATE, MULTI-DISTANCE TRANSMISSION
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
SCENARIO 3: MULTI-RATE, MULTI-DISTANCE TRANSMISSION
• 1 x 128 Gb/s DP-QPSK, 2 x 192 Gb/s DP-8QAM, different transmitters (lasers) running at the same wavelength
– Hybrid transmission in operation with live network
– 128-Gb/s DP-QPSK over 1,245 km, 192-Gb/s DP-8QAM over 224 km
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
60km 60kmFMF FMF
FM-EDFA
Mode DEMUX
b4
or
3
DAC
EVEN
1
2
Salzb
urg
Klagenfurt
Bischofs-hofen
a
Vienna
Bb
Lin
k 3
Link 2
Link 1
1x4
DAC
ODD800
Symbols
1854 Sym.
5535 Sym.
8x8x1x8
1x8
193.95THz
193.95THz
100G
100G
optional
optional
WSS
1
1
2
or
b
4
3
100G
Scope 1
Scope 2
Scope 3
Offlin
e D
SP
LO
LO
LO
CoherentRx 1
CoherentRx 2
CoherentRx 3
1x4
Salzb
urg
Bischofs-hofen
2
Mode MUX
SCENARIO 3: MULTI-RATE, MULTI-DISTANCE TRANSMISSION
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
0 2 4 6 8 1010
-7
10-6
10-5
10-4
10-3
10-2
Time [Min]
Bit-e
rror
ratio
Pol. X. Pol. Y.
192-Gb/s DP-8QAM 224 km:sig. 3sig. 2
128-Gb/s DP-QPSK 1,247 km sig. 1
FIELD DEMONSTRATION OF MDM UPGRADE SCENARIO ON LEGACY NETWORKS
We have successfully shown three possible upgrade scenarios for legacy networks with Space-Division-Multiplexing technology:
• Single-mode transmission over few-mode fiber with commercial 100G
– 1,127km single-mode fiber and 120 km few-mode fiber + few-mode EDFA
• 3 × SMF multiplexed onto FMF, de-multiplexed onto 3 × SMF again
– 3 mode-division multiplexed × 16 WDM × 192-Gb/s DP-8QAM (7.2 Tbit/s)
– 3 mode-division multiplexed × 16 WDM × 256-Gb/s DP-16QAM (9.6 Tbit/s)
• Multi-rate (QPSK, 8QAM), multi-distance (1,247 km and 224 km) transmission over 3 modes
– Different transmitter lasers
V.A.J.M. Sleiffer et al., “Field demonstration of mode-division multiplexing upgrade scenarios on commercial networks”, Optics Express 21 (25), p. 31036-31046 (2013)
Conclusions and remarks
OVERVIEW
Introduction
FMF experiments
HC-PBGF
Field demonstration of MDM upgrade scenarios
REMARKS ON COST AND ENERGY
• MIMO-DSP
– number of modes
– modal DGD
• Maybe able to minimize complexity by re-using information which affect all modes (carrier recovery/chromatic dispersion)
• FM-EDFA technology
– Higher energy efficiency?
– Cladding/core pumped?
• Coupled core fiber
– Minimize DGD
– Increase effective area
• Other network elements? ROADMs
M. Kuschnerov et al., “Energy efficient digital signal processing,” in Proc. OFC, paper Th3E.7 (2014).
Typical power dissipation distribution of the
different DSP processes in a 100-Gb/s DP-
QPSK line card
SD-FEC decoder
CD compensation
Other DSP modules
Carrier recovery
MIMO equalizer
CONCLUSIONS
• FMF/HC-PBGF is a potential transmission medium to increase the capacity per fiber system:
– Potential for capacity upgrade per fiber (57.6 Tb/s over FMF and PBGF)
– Long-haul reach achieved (1020 km over FMF)
– Interoperability with single-mode fiber technology demonstrated
• Important step to technology acceptance by telecom operators
• A lot of system tests still required, for instance to assess the fiber nonlinearity of FMFs
• Thesis available online: Towards petabit per second optical long-haul transmission links using space-division multiplexing technology
YACHT MAAKT WENDBAAR
THANK YOU FOR YOUR ATTENTION
