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01_Intro.pptx
02_SystemOverview.pptx
03_OpticalChannel.pptx
04_Lasers.pptx
05_Modulation.pptx
06_Receivers.pptx
07_Amplifiers.pptx
08_Filters.pptx
09_Systems.pptx
10_Simulation.ppt
11_Outlook.pptx
Lecture
Optical Communications
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Overview
• Organization
• History of Optical Communications
• Structure of the Lecture
• Goals
2
01 - Introduction
Contact
Slides of the lecture and excercises can be found
here:
http://www.tf.uni-kiel.de/etit/NT
Password: LNT
E-Mail: [email protected]
E-Mail (for the excercises):
[email protected]
3
01 - Introduction
Organization
• The lecture takes place each week on Monday
from 10:15 – 11:45
• Exercises are scheduled every second week on Tuesday
from 12:15 – 13:45 (starting 19.4.2016)
• Examination:
written examination (90 min) in the examination period after the
course (currently planned for 06.10.16 9.00-10.30)
4
01 - Introduction
Curriculum vitae
• Born in Dortmund, 1977
• Master studies at City University, London
Degree: MSc in Information Engineering, 2001
• Diploma studies at TU Dortmund
Degree: Dipl.-Ing., 2002
• PhD studies at TU Dortmund – Chair of High Frequency
Technology, funded by Siemens AG, Munich
Degree: Dr.-Ing., 2005
• Diploma studies at Fernuni, Hagen
Degree: Dipl.-Wirt.-Ing., 2005
5
01 - Introduction
CV (contd.)
• 2007-2011 Principal Engineer (Oberingenieur) at Chair of High
Frequency Technology, TU Dortmund
• 2011-2015 in various positions at ADVA Optical Networking SE
(last as Principal Engineer in the CTO Office)
•
•
•
Project leader and manager (also as consortium lead) of several EUfunded research projects in the area of next-generation optical access
networks and structural and functional convergence of fixed and
mobile networks
Development of novel system concepts for the second generation of
100 Gb/s transmission systems and next generation systems with
400 Gb/s data rate
Support of the standardization activities in FSAN and ITU-T
(Study Group 15, Question 2 and Study Group 15, Question 6)
• Since April 2016 Professor of Communications at ChristianAlbrechts-Universität zu Kiel
6
01 - Introduction
History
7
01 - Introduction
History of Optical Communications (1)
Smoke signals, light signals
1900
1925
1938
Analog transmission, one channel per telephone line
Vacuum tube  frequency division multiplexing
Coaxial cables
1960
Invention of the laser (Maiman)
8
01 - Introduction
History of Optical Communications (2)
1966
Proposal: Use of optical fibers for guiding of light
(Nobel prize for Charles Kao in 2009)
1970
Reduction of fiber losses to 17dB/km (Corning)
1977
1.3 µm InGaAsP laser (Fiber attenuation @ 1.3 µm: 1 dB/km)
1978
First installation of an optical transmission system
Multimode fiber, =0.8 µm, 50 Mb/s, 10 km regenerator distance
1980
Optimized optical transmission systems
Multimode fiber, =1.3 µm, 100 Mb/s, 20 km regenerator distance
9
01 - Introduction
History of optical communications (3)
1981
First demonstration of single-mode fiber (SSMF)
1987
Invention of the Erbium-Doped Fiber Amplifier (Univ. of Southampton)
1988
Further generations of optical transmission systems
SSMF, =1.3 µm, 1 Gb/s, 50 km regenerator distance
Reach limited by fiber attenuation (0.5 dB/km)
1990
10
Improved systems by use of single mode laser
SSMF, =1.3 or 1.55 µm, 2.5 Gb/s,
100 km regenerator distance
01 - Introduction
History of Optical Communications (4)
1992
1995
1996
1998
11
First work on optical transmission systems using fiber amplifiers and
wavelength division multiplexing (WDM)
First generation of optical WDM transmission systems
SSMF, =1.55 µm, 8x2.5 Gb/s, 1200 km regenerator distance
point-to-point transmission (static, manually configured)
First field trials with Optical Cross-Connects (OXC)
Availability of first commercial Optical Add-Drop Multiplexer (OADM)
01 - Introduction
History of Optical Communications (5)
2000
Second generation of optical WDM transmission systems
SSMF, =1.55 µm, 160x10.7 Gb/s,
1500 km regenerator distance
automatic reconfigurability by OADM/OXC
2001
2002
12
Introduction of Automatically Switched Transport Networks (ASTN)
standards by ITU-T
01 - Introduction
History of Optical Communications (6)
Introduction of phase modulated transmission systems
2004
Next generation of optical transmission systems
SSMF, =1.55 µm, 96x43 Gb/s,
1500 km regenerator distance
Introduction of coherent transmission systems
(electronic pre-distortion, equalizer, DSP…)
2006
2010
Future?
13
First field trials of 112 Gb/s WDM transmission systems
Next generation of optical transmission systems
SSMF, =1.55 µm, 96x112 Gb/s,
3000 km regenerator distance
Fiber-to-the-home (passive optical networks), Software-Defined Optics,
400 Gb/s WDM transmission systems, Optical Fronthauling (connection of mobile
phone antenna sites)
01 - Introduction
Bandwidth Increase
Source: DE-CIX
Internet Exchange
New services (e.g. video streaming), higher access data rates
(DSL, FTTH etc.) lead to exponential increase of the bandwidth.
Challenges: Affordable, dynamic, energy efficient networks
14
01 - Introduction
What happens in 1 min?
15
01 - Introduction
Network View
Edge
Metro Access
Core
Long Haul/Ultra Long Haul
Regional
Metro Core
Wavelength-Division Multiplexing (WDM)
Network Element
Time-Division Multiplexing (TDM)
Network Element
OXC
DWDM
mesh
OADM
Capacity
EDFA
Internet Service
Provider (ISP)
Metro
DWDM
Rings or Mesh
TDM
mesh
Rings or Mesh
Business User
Campus
EXC
ADM
Rings
Video
(O)ADM: (Optical) Add/Drop Multiplexer
OXC: Optical Crossconect
EDFA: Erbium-Doped Fiber Amplifier
EXC: Electrical Crossconnect
Data
Voice
Distance
16
01 - Introduction
Contents (1)
1.Introduction
1.1 Contents of the Course
1.2 Overview: Optical Communications
1.2.1 Review
1.2.2 Relevance of Optical Communications
1.3 Basic System Overview
1.3.1 Generic Block Diagram of Optical Transmission
1.3.2 Basic Properties of the Optical Fiber Channel
1.4 Basic Concepts in Optical Communications
1.4.1 Time division multiplexing (TDM)
1.4.2 Wavelength division multiplexing (WDM)
1.4.3 Optical Time Division Multiplex (OTDM)
1.5 Evolution of Optical Networks
17
01 - Introduction
Contents (2)
2. The Optical Transmission Channel
2.1 Optical Signals
2.2 Basic properties: Fiber Loss
2.3 Basic properties: Fiber Dispersion
2.4 Linear Channel Model of Optical Fiber
2.4.1 System Responses of Fiber
2.4.2 Influence of Dispersion on Data Transmission
2.4.3 Dispersion Compensation in Long Distance Links
2.5 Dispersion in Fibers
2.5.1 Polarisation Mode Dispersion
2.6 Nonlinear Fiber Effects
2.6.1 Linear and Nonlinear Fiber Properties
2.6.2 Optical Kerr-Effect
2.6.5 Influence of SPM on Signal Transmission
2.6.5 Soliton Transmission
2.7 Propagation Modes in Fibers, Characteristics of MMF and POF
18
01 - Introduction
Contents (3)
3. Optical Transmitters and Modulators
3.1 Semiconductor Lasers
3.1.1 Materials
3.1.2 Basic Principle
3.1.3 Bandgap Model of Semiconductor Lasers
3.1.4 Laser Beam Confinement
3.1.5 Recombination
3.1.6 Technical Implementation
3.1.7 Fabry-Perot Resonator, Lasing Condition
3.1.8 Single Mode Lasers
3.1.9 Rate Equations
3.1.10 Light-Power-Current Characteristics
3.1.11 Direct Modulation of a Laser
3.1.12 Laser-Chirp
3.1.13 Small-Signal Properties, Laser-Frequency Response
3.2 External Modulators
3.2.1 Electro-Absorption-Modulator (EAM)
3.2.2 Mach-Zehnder-Modulator (MZM)
19
01 - Introduction
Contents (4)
4. Optical Receivers
4.1 Block Diagram
4.2 Optical to Electrical Conversion
4.3 Noise Performance
4.3.1 Quantum Limit
4.3.2 Noise Performance of Practical Receivers
5. Optical Amplifiers
5.1 Overview, Basic Concepts
5.2 Semiconductor Laser Amplifiers
5.3 Fiber-Optic Amplifiers
5.3.1 Building Blocks of an Erbium-Doped Fiber Amplifier
5.3.2 Optical Amplification
5.3.3 EDFA Noise
6. Optical Filters
6.1 Fabry-Perot Filter
6.2 Fiber Gratings
6.3 Optical Delay Line Filters
6.3.1 Basics
6.3.2 Mach-Zehnder Filters
20
01 - Introduction
Contents (5)
7. Optical Transmission Systems
7.1 Modulation Formats
7.2 Transmitter and Receiver Design
7.3 Coherent Transmission
8. Simulation
8.1 Propagation Equation, Nonlinear Schrödinger Equation
8.2 Numerical Solution: Split-Step Fourier Method
9. Outlook
21
01 - Introduction
22
01 - Introduction
Literature
Fundamentals of Optical Communications
• E. Voges, K. Petermann, „Optische Kommunikationstechnik“
ISBN: 3-540-67213-3 (only in German)
• G. P. Agrawal, „Fiber-Optic Communication Systems“
ISBN: 0-471-21571-6
• I. P. Kaminow, T. Li, A. E. Willner, „Optical Fiber
Telecommunications V B: Systems and Networks“
ISBN: 0-12-374172-1
• M. Seimetz: “High-Order Modulation for Optical Fiber
Transmission”. Springer Series in Optical Sciences, 2009
23
01 - Introduction
Literature
Optical Networks
• R. Ramaswami, K. N. Sivarajan, „Optical Networks“
ISBN: 1-55860-655-6
• B. Mukherjee, „Optical WDM Networks“
ISBN: 0-387-29055-9
• S. Pachnicke, „Fiber-Optic Transmission Networks“
ISBN: 978-3642210549
24
01 - Introduction
Lecture
Optical Communications
Basic System Properties
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Click To Edit Master Title Style
Overview: Optical Communications
Review
Optical telegraph network in France 1830 – 1840
Source: V. Aschoff
2
02 – Basic System Properties
Click
To Edit
Master Network
Title Style
Optical
Telegraph
in France 1830-1840
"Transmitter"
3
"Receiver"
02 – Basic System Properties
Global Data Traffic (PB/Month)
Click To of
Edit
Master in
Title
Style
Increase
Capacity
Communication
Networks
Quelle:
R. Essiambre, et al, Proc. of IEEE, 2012.
Year
Exponential growth of traffic volume
4
02 – Basic System Properties
Click To Edit Master Title Style
Relevance of Optical Communications
Advantages of fiber optics:
• Very high usable bandwidth
• Electromagnetic compatibility (EMC)
Disadvantages:
• Cables/fibers necessary (compared to radio)
• Expensive optical components, lower price reduction (compared to electronics)
Applications:
• Long distance digital transmission at high capacity in wide area networks (WAN)
and metropolitan areas (MAN)
• Fiber to the home (FTTH), Fiber to the curb (FTTC) – used for VDSL, hybrid fibercable TV distribution systems (CATV) – used for DOCSIS
• Replacement of electrical lines, if EMC problems exist (optical cabling in cars,
airplanes, ships, big data centres, optical “bus" at back-plane cabling)
• "Radio over Fiber" RF-signal feeding of mobile radio base stations
• Optical wireless communications: Free space transmission, terrestrial (short) as
well as in space (very long distance), submarine, in-door visible light
communications
5
02 – Basic System Properties
Optical
Network
Deutsche Telekom
Click ToFiber
Edit Master
TitleofStyle
(Core Network)
D Ä N E M A R K
• Approx. 130,000 km of optical cables
• Approx. 40 fibers per cable (average)
5.2 Mio. km deployed fibers
• Mostly Standard Single Mode Fiber (SSMF)
• Data Rates (interface rates):
up to 100 Gb/s per fiber and WDM channel
NIEDERLANDE
• Typically WDM-links installed
(e.g. 96 wavelenghts @ 40Gb/s per fiber)
BELGIEN
LUX
G
BUR
EM
TSCHECHOSLOWAKEI
Offenbach/
Straßburg
Passau/
?
FRANKREICH
Traunstein/
Salzburg
SCHWEIZ
6
LIECHTENSTEIN
ÖSTERREICH
02 – Basic System Properties
Click
To EditOptical
MasterSubmarine
Title Style Network
Worldwide
Source: Telegeography
7
02 – Basic System Properties
Click
To Submarine-Systems
Edit Master Title Style
Optical
• Channel data rate 10 Gb/s … 100 Gb/s
• Maximum link-length: 9000 km
• Optical amplification: typ. 40km distance
• 25 years of continuous operation
Submarine-Cable
8
Trans-Pacific-System
02 – Basic System Properties
Click
MasterPremises/
Title StyleCurb (FTTx)
FiberTo
to Edit
the Home/
GPON
TDMA-PON
Passive
Splitter
Central
Office
NG-PON2
WDM-PON
Central
Office
WDM
Mux/Demux
+
1 fiber to the central office
+
1 transceiver in the central office
–
shared multi-point connection
–
low reach (ca. 10 km)
–
Bit rate / fiber = N x end-user bitrate
+
Physical point-to-point connection
+
Medium reach(ca. 40 km)
+
1 fiber in the central office
+
1 transceiver in the central office
+
Bit rate / fiber = end user bitrate
Acronyms:
TDMA=Time Division Multiple Access; WDM=Wavelength Division Multiplex
GPON=Gigabit capable passive optical networks; NG-PON2=Next Generation–PON2
•
•
•
•
9
lower data rates (up to 10Gb/s/l)
short distance (typ. ~ 20 km)
low cost required
passive optical networks (PON)
no electrically power components required in the field
02 – Basic System Properties
Click
To EditOverview
Master Title Style
Basic
System
Laser diode
A basic optical transmission system
Intensity modulation with digital
on-off keying at transmitter (TX)
opt.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Direct detection with photo diode
at receiver (RX)
Transmitter
A state of the art (high-end)
optical transmission system
QPSK-modulation, optical I/Qmodulator, dual polarizations (x/y)
at TX
Coherent detection, local laser,
balanced photo receivers, ADC
and digital signal processing at
RX
10
electr.
noise
02 – Basic System Properties
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Receiver
electronics
Receiver
Digital
sink
Generic
Diagram
of Optical
Click ToBlock
Edit Master
Title
Style Transmission
Using Intensity Modulation / Direct Detection
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Basic optical transmission link with transmitter, channel, and receiver.
Optical signals (thick, green) and electrical signals (thin, black).
Optical signals are carrier signals at optical frequency (~193 THz) modulated with the
digital data signal.
11
02 – Basic System Properties
Click
To Edit Master Title Style
Laser
Diode
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Laser diode: Generates (nearly) single frequency light with well defined wavelength =
carrier signal at frequency f C  c / lC (Electromagnetic wave). f C Lies
in the range of several hundred THz! (1 THz = 1012 Hz). The light signal, i.e.
the electromagnetic wave is usually simply called "electric field“ E(t)
12
02 – Basic System Properties
Click To Edit Master Title Style
Modulator
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Modulator: The digital data signal is modulated on the carrier (here light) by the modulator. Most
modulators have the capability to modulate the power of the light, i.e. the
instantaneous optical power (=light intensity) is proportional to the modulating data
signal of e.g. 10 Gb/s. The traditional basic modulation format is On-Off-Keying (OOK)
and Intensity Modulation (IM)
With binary signal: “1“ = Light on, “0“= Light (almost) off.
In some (low cost) applications with relatively low bit rates the modulator can be
omitted and the laser can be directly modulated by varying the input (injection) current
into the laser diode (directly modulated laser, DML)
13
02 – Basic System Properties
Click Fiber
To Edit Master Title Style
Optical
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Optical fiber: Guided wave propagation in silica glass fiber. Fiber typically measures 125 mm in
diameter with a "core" in center of ≈ 9 mm (single mode) or ≈ 50 mm (multi mode) in
diameter, where core and the outer cladding both are silica glass, the core has
slightly higher refractive index (through doping). Very low loss, huge bandwidth!
The fiber channel may be modeled as a linear system (to first order approx.!) with
transfer function H(f) of the electrical field E1(t) at the fiber input and E2(t) at the fiber
output.
14
02 – Basic System Properties
Click Amplifiers
To Edit Master
Title Style
Optical
and Filters
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Optical amplifiers: Broadband amplifiers for optical signals. At amplifier input, light of a pump laser
(high power) and the optical signal to be amplified are combined and coupled into
several meters of Erbium doped fiber (EDFA=erbium doped fiber amplifier).
This leads to amplification of the incident wave by stimulated emission.
But amplification of EDFAs is only possible in the wavelength range of
1530nm ...1570nm (191THz ... 197THz), i.e. in third optical window!
Opt. amplifiers are used as booster amplifiers (at transmitter), in-line amplifier (repeater
in long distance links), and pre-amplifier (at receiver input).
Optical filters: Applications (i) filtering of broadband optical noise produced e.g. by optical
amplifiers (ii) equalizers of optical signals e.g. dispersion compensation. Various
physical realizations, described by transfer functions, bandwidth, etc. (as usual)
15
02 – Basic System Properties
ClickDiode
To Edit Master Title Style
Photo
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
Photo Diode: Optical-to-electrical (o/e) conversion by detection of received optical power
(envelope detector). PIN (positive, intrinsic, negative)-diode (very fast, low
sensitivity) or APD = Avalanche Photo Diode. (high sensitivity, slower, more noise)
The received instantaneous light power results in a proportional electrical signal
(photo current), which drives a trans-impedance (TI)-amplifier so that a voltage can
be processed in the detector (clock and data recovery, CDR) where the bits are
retrieved.
Noise:
16
Is present in the optical domain (mainly from optical amplifiers) as well as in the
electrical domain (from electronics) and from o/e-conversion itself (shot noise)
02 – Basic System Properties
Click To Edit Master Title Style
Modelling
Laser diode
opt.
noise
electr.
noise
ok_1_optkanal.dsf
Digital
Source
Detector
Modulator
Transmitter
Remark:
opt. ampl. opt. filter
opt. fibre
Optical channel
Photo diode
Digital
sink
Receiver
electronics
Receiver
The generic transmitter / channel receiver configuration shown above uses intensity
modulation and direct detection (IM/DD configuration). In terms of communications
theory this is a pretty simple approach. However, it has been used widespread until
recently. Sufficient for data rates up to ~10 Gb/s.
Today much more advanced transmitter and receiver setups are under investigation
and are implemented in new (e.g. 100-400 Gb/s) systems. The full range of tools from
communications theory is used (like coding, equalisation, signal processing, multilevel
QAM, etc.)
17
02 – Basic System Properties
Click
ToCommunications:
Edit Master Title Style
Optical
Some Impressions…
Lab view (Coriant)
Lab view (NT Kiel)
Lab equipment with
several 100 km of
fiber spools
(Dt. Telekom)
Very high speed
photo diode
18
02 – Basic System Properties
High speed receiver
SiGe-chip
Click
Edit Master
TitleOptical
Style Fiber Channel
BasicTo
Properties
of the
Electromagnetic Spectrum
19
02 – Basic System Properties
Frequencies
and
Wavelengths
of
Click To Edit
Master
Title Style
Optical Signal Transmission
1000
Multimode Optical Fiber
900
Singlemode Optical Fiber
Polymer Optical Fiber
Frequency [THz]
800
700
f 
c
l
600
500
400
Visible Range
300
200
Infrared Light (IR)
100
300
400
500
600
700
800
900
1000
1100
Wavelength l [nm]
20
02 – Basic System Properties
1200
1300
1400
1500
1600
Loss
Single
Mode
ClickofToStandard
Edit Master
Title
StyleFibers (SSMF)
over Wavelength
1.4
C-Band L-Band
O-Band
Typical Values
1.2
Loss in dB/ km
1
0.4 dB/km @ 1310nm
0.2 dB/km @ 1550nm
OH-Absorption
0.8
SiO2 (IR)Absorption
RayleighScattering
0.6
0.4
0.2
0
1250
21
Bendinglosses
1300
1350
1400
1450
1500
Wavelength in nm
1550
02 – Basic System Properties
1600
1650
Chromatic
Dispersion
of Different
Click To Edit
Master Title
Style Single Mode Fiber
Types over Wavelength
25
O-Band
C-Band L-Band
Dispersion in ps/ (nmkm)
20
15
10
5
Dispersion Shifted Fiber
0
-5
-10
1250
22
1300
1350
1400
1450
1500
Wavelength in nm
1550
02 – Basic System Properties
1600
1650
Click To Edit Master Title Style
Basic Mathematical Model of Single Mode Fiber
Loss and dispersion  Linear system
Equivalent LP Transfer Function
 All-pass with quadratic phase response:
H LP
a
 dB L
( f )  10 20
23
c
DL  f 2


  e


loss
L:
l c:
adB:
D:
 j
lc2
dispersion
fiber length in km
wavelength
loss in dB/km
dispersion parameter
Response to a rectangular pulse
(25ps ≙ 40Gb/s data rate)
02 – Basic System Properties
Click
To Edit
Master
Title
Style
Multimode
and
Single
Mode
Silica Fibres
24
02 – Basic System Properties
Click
To Edit
Master
Title
Style
Standard
Single
Mode
Fiber
25
02 – Basic System Properties
Cross
Sections
of Commercial
Click To
Edit Master
Title Style Optical Fiber Cables
26
02 – Basic System Properties
Click
ToConcepts
Edit Master in
Title
Style Communications
Basic
Optical
Time division multiplexing (TDM)
Data streams of
• several bit rates (e.g. 64 kb/s,
2.048 Mb/s, 140 Mb/s) from
• several users
Principle of TDM Multiplexer
ok_1_optkanal.dsf
ch1
are aggregated to (very) high
speed data rates for
transmission in the network
ch2
MUX
ch3
ch4
clock
27
02 – Basic System Properties
Click
To Edit
Master Title Style
Increase
of Transmission
Capacity
(E)TDM (electrical) Time Division Multiplexing
2.5 Gb/s

10 Gb/s

40 Gb/s
 (100 Gb/s / 400 Gb/s)
steps in the SDH-Hierarchy. Each time factor of 4 starting from an STM-1 Container with
155 Mb/s data rate.
A single optical carrier with bandwidth according to data rate.
Problems: Availability of high speed electronics. Transmission problems due to high signal
bandwidth  Chromatic Dispersion (CD) and Polarisation mode dispersion (PMD).
Today: Data rate (here: the interface rate) is limited to approx. 400 Gb/s. The Baud rate (symbols
per sec.) is limited to approx. 100 GBaud
28
02 – Basic System Properties
Click To Edit Master Title Style
Wavelength Division Multiplexing (WDM)
Data streams of several light
paths from
• several transmitters with lasers
at different wavelengths
• each carrying a high speed
data signal
are combined to a
multiwavelength optical WDM
signal and transmitted over a
single fibre
Principle of WDM Multiplexer
l1
l2
l3
l4
ch1
ch2
ch3
ch4
WDMMUX
l1 l2 l3 l4
ok_1_optkanal.dsf
l1 l 2 l 3 l 4
29
02 – Basic System Properties
Click
To Edit
MasterAllocation
Title StyleGrid for WDM Networks
The ITU-T
Channel
ITU-T recommendation G.694.1 in 2002
Dense Wavelength Division Multiplexing
L-Band
C-Band
S-Band
186,00
…
190.90
191,00
…
195.90
196,00
…
200.90
1611.79
…
1570,42
1569.59
…
1530,33
1529.55
…
1492,25
Channel Spacing: 100GHz
200/50/25/12.5GHz also allowed
No. of channels:
96 in each band (at 50 GHz spacing)
Center frequency: 193.10THz = 1552.52nm
30
02 – Basic System Properties
A WDM Multi-Span Transmission Link with
Click To Edit Master Title Style
Gain- and Dispersion-Management
The transmission link is segmented in several "spans" where each span consists of transmission fiber
(typically 40…120km), an optical amplifier (loss compensation) and a dispersion compensator (e.g.
DCF=dispersion compensating fiber)
Data 1
ocn_7_wdm system.dsf
l1
Data 2
1 span
l2
M
U
X
Data 3
l3
Data 1
l1
Data N

lN
LD
MOD
optical amplifiers &
dispersion compensation
Data 2
D l
E 2
M
l
U 3
X
Data 3
lN
BP
LD: Laser Diode,
MOD: Modulator
31
BP: Band-pass,
PD: Photo Diode
02 – Basic System Properties
Data N
PD
Click
To Time
Edit Master
Title
Style
Optical
Division
Multiplexing
(OTDM)
an
ch nel
an 1
ch nel
an 2
ch ne
an l 3
ne
l4
ch
...
ch
an
ch nel
an 1
ne
l2
TDM in optical domain. Binary data (Bits) are represented as very short optical pulses within a
short time slot for each channel.
...
ok_124_systeme_wdm_und_otdm.dsf
100ps
time -->
Problems: Generation of short pulses. Timing jitter of pulses (phase fluctuations), very
high signal bandwidth (distortions by dispersion, PMD)
32
02 – Basic System Properties
Click To Edit Master Title Style
Wrap Up
What you should recall from this chapter:
•
•
•
•
•
•
•
•
•
•
•
•
33
Describe in detail the various multiplexing principles: WDM, OTDM, (E)TDM.
What kind of network elements are typically used in optical networks?
What is the meaning of “span” in optical communication links?
What are the dimensions of core and cladding in SMF and MMF?
Where is zero dispersion in SSMF; what is the value of the dispersion parameter at 1550 nm?
What is the centre wavelength of C- and L-bands; what are the related frequencies?
What are typical loss coefficients dB in the C-band and O-band?
What are the approximate wavelengths of red and violet visible light?
Plot the generic block diagram of optical transmission and explain each block in detail.
What is the typical span length in optical submarine systems?
What is the value for the vacuum speed of light?
Describe fiber optic applications in various parts of optical communication networks.
02 – Basic System Properties
Lecture
Optical Communications
Optical Channel
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
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The Optical Transmission Channel
Optical Signals
Physically the optical signal is an electromagnetic wave travelling through a wave
guide (i.e. the fiber). Wave propagation is described by Maxwell’s Equations (ME).
However, for communications purposes, we simplify and use a “signals & systems”
notation. This is exactly the same approach as e.g. in radio or electrical wire lines
communications!
In addition, for communication purposes we have to modulate the wave, either in
amplitude or in phase or both.
2
03 – Optical Channel
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Communications in a bandpass channel:

sBP (t )  a (t ) cos wc t +  (t ) +    Re a (t )e j (t )  e j (wct + )

(2.1-1)
In Optical Communications it is common use to denote sBP (t )  E (t ) and z (t )  A(t )

E (t )  a (t ) cos wc t +  (t ) +    Re a (t )e j (t )  e j (wct + )

(2.1-2)
wc  2 fc  2 c / c carrier frequency (from laser=carrier)  typically ≈ 200THz
A(t )
3
Complex envelope  typically a few GHz bandwidth
03 – Optical Channel
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Power, Intensity
Power, Intensity
It is relatively easy to exploit the intensity of an optical signal, whereas it is more
complicated to deal with the full optical signal, including carrier frequency and phase
(coherent optics)
Examples:
A photo diode “measures” the intensity because its output current is proportional to
the incoming light power ( optical receiver). Laser output light power is proportional
to the injection current ( optical intensity modulation)
The signal (i.e. the electric field) E(t) has instantaneous optical power (=intensity)
P (t )  A(t )  A* (t ) | A(t ) |2 | a (t ) |2
(2.1-3)
The intensity or instantaneous power is typically a time domain signal with GHz
bandwith and should not be mixed up with the mean optical power (to be measured
by a power meter)
4
03 – Optical Channel
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Optical Polarization
Two polarizations of an optical signal
If we look closer into wave propagation (resulting from Maxwell’s Equations), we find
that there exist two orthogonal polarization planes, namely a horizontal and a vertical
polarization plane, also called x- and y-polarization. It is possible to extract or
combine the signals from their individual polarization planes (polarization beam
splitter/combiner PBS or PBC). Thus we can extend our signal description
 E x (t )   a x (t ) Eˆ x cos wct +  x (t ) +  x  

E(t )  

ˆ
E
(
t
)


a
(
t
)
E
cos
w
t
+

(
t
)
+


 y   y
y
y
y  
 c
(2.1-4)
We have now two signals that propagate in the fiber. Each of these signals may be
modulated individually.  denotes the relative phase difference and Ê denotes the
relative amplitude difference of the x- and y-polarisation signals.
5
03 – Optical Channel
Wave To
Propagation
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Edit Master Title Style
In communications we are interested in the signals at the input and at the output of
the channel, here the fiber with length L. I. e. we observe the wave at fixed positions z
( z  0 at fiber input and z  L at fiber output). If we are interested how the wave
propagates along the fiber, we have to evaluate the wave equations resulting from
ME. It turns out (by solving the wave equation for the boundary conditions given by
the properties of the optical fiber and assuming a harmonic steady state solution and
considering one polarization and assuming lossless fiber) that the light wave signal
can be described as


E ( z , t )  Re Eˆ  e - j z  e jwC t  e j  Eˆ  cos  -  z + w0t +  

  Phase
(2.1-5)
This is a single frequency i.e. unmodulated, continuous wave (CW) signal at
frequency w0 [1/s] that travels along the z-axis, i.e. the longitudinal axis of the fibre
with propagation constant  [1/m].
6
03 – Optical Channel
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 For a fixed time instant t  t1 we see a cos-function vs. distance z with period n
 For a fixed location z  z1 we see a cos-function vs. time t with period T
t=t 1 t=t1 +Dt


Dz
z

E ( z , t )  Re Eˆ  e - j  z  e jwC t  e j  Eˆ  cos  -  z + w0t +  

  Phase
.
We observe the propagating wave at a fixed location on z-axis. During the time interval T 
(i.e. one period in time), the wave has moved a distance n 
2

2
w0
(i.e. one full cycle in space)
which is the wave’s wavelength. This distance n depends on the travelling speed of the wave. It
is n  v p  T , where v p is called the phase velocity of the light wave, which depends on the
refractive index n of the material within which the wave is travelling. We have:
7
n  1.00
for vacuum = free space ≈ air
n  1.45
for silica glass (fibre) at 3rd optical window, slightly depending on wavelength
03 – Optical Channel
Click To Edit Master Title Style
Actually the refractive index is calculated by dividing the speed of light c in a vacuum
by the speed of light v p in some other medium. The refractive index in vacuum is
therefore 1, by definition. Thus
vp 
c
n
(2.1-6)
Note:
Compared to light propagation in vacuum light travels through fiber ( n  1.45 ),
 with reduced speed ( c / n  200, 000 km / s )
 with reduced wavelength ( c / n )
 frequency remains unchanged!
Note:
Wavelengths are specified as vacuum (free space) wavelengths c
 e.g. a laser radiates at c  1550 nm  it’s frequency is f c 
8
03 – Optical Channel
c
c
 193.548 THz
Propagation
Click
To EditConstant
Master Title Style
The propagation constant is frequently used for characterising wave propagation

wc
w
2
 c n
 n  k  n  wc 0 0  r
vp
c
c
(2.1-7)
k  propagation constant in vacuum (also called wave number)
c
1
0 0
speed of light in vacuum
n   r relative electric field constant (relative permittivity) in lossless material
After travelling a distance L through the fiber we get (assume   0 in (2.1-5)):

L 
E ( L, t )  Re Eˆ  e - j  L  e jw0t  Eˆ  cos w0t -  L   Eˆ  cos  w0 (t )
w
0 



(2.1-8)
I.e. we observe a phase shift  L or equivalently a time delay of  L / wo

phase shift  L of the carrier wave (many millions of 2 cycles!)

propagation delay  L / wo of the carrier (a few ms per km fibre) sometimes called
"phase delay"
9
03 – Optical Channel
Click To Edit Master Title Style
Exercise:
Calculate the phase shift and the phase delay per km of fiber.
Calculate the “length” of a 100 ps bit duration
Note
As refractive index and thus propagation constant are slightly wavelength and thus
frequency dependent, each frequency component of a modulated optical signal
experiences a slightly different delay/phase shift.  fiber dispersion, phase distortions
due to fiber dispersion!
10
03 – Optical Channel
Other To
Light
Models
Click
Edit
Master Title Style

Geometrical optics = ray optics (objects/dimensions > )

Light as particle = quantum mechanic model emission and absorption

Wave optics (small Objects  )  electromagnetic waves
 Maxwell’s equations for electric and magnetic field (vectors)
Light propagation: = Change of field with time and space
 E x  x, y , z , t  


E  r , t    E y  x, y , z , t  


E
x
,
y
,
z
,
t


 z

11
(2.1-9)
03 – Optical Channel
Fiber Loss
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To Edit Master Title Style
12
03 – Optical Channel
Attenuation
Constant
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To Edit
Master Title Style
In a bandwidth up to several 10 GHz, attenuation is constant and thus not
wavelength or frequency dependent. (Remember: | Df | c | D | / C2 , i.e. 1nm
corresponds to 125 GHz at 1550nm!). Therefore, fiber loss reduces the optical signal
by a constant factor (we do not have to consider a frequency dependent attenuation
by a transfer function H (w ) )
Power of light decreases exponentially with fiber length L.
P
adB L  -10lg L
P0

a
- dB L
P ( L)  10 10 P (0)
also used: attenuation coefficient (in Neper)
a  (ln10) 
13
adB
10

P( L)  e- a L P(0)
03 – Optical Channel
Attenuation
Mechanisms
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To Edit
Master Title Style
In fibers we observe: (i) absorption loss, (ii) scattering loss, (iii) bending loss,
In a fiber communication link we have additional (iv) insertion loss
Absorption losses:
Dominates at high wavelengths (>1600nm). Light interacts with fiber material.
Impurities cause mechanical vibrations  heat  absorption of energy.
Impurities of water vapour (OH ions)  large absorption peaks at 1400nm, 1240nm,
950nm  "transmission windows" (peaks can be nearly eliminated in today's
extremely pure production processes  "all wave fiber™")
Scattering losses:
Dominant at low wavelengths (<100nm). Scattering losses arise from microscopic
variation in material density (structural inhomogeneities).
Rayleigh scattering is proportional to -4 (sharp decrease with ).
14
03 – Optical Channel
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Bending losses:
Energy is radiated out of the fiber due to macrobending (large curvature) and
microbending (random microscopic bends of fiber axis due to stress in cables or
irregularities of core/cladding boundary)
Insertion losses
determines the total fiber link loss, due to splices, connectors or components
(couplers, filters,...)
15
03 – Optical Channel
Fiber Dispersion
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To Edit Master Title Style
Dispersion is a major impairment in optical fiber transmission. The background is as
follows: We have seen that the fiber loss is not frequency dependent. This means
that the magnitude of the fiber’s frequency response | H ( f ) | is constant over the
frequencies of interest. Therefore we do not expect any filtering effects (LP or BP) on
the transmit data signal caused by magnitude response. The phase of the fiber’s
frequency response b( f )  - arg  H ( f ) , however, turns out to be frequencydependent and is not a linear function of frequency (not of linear phase). Thus due to
the nonlinear phase property we expect signal distortions caused by the phase
response.
From (2.1-5):

L 
E ( L, t )  Re Eˆ  e- j  L  e jw0t  Eˆ  cos w0t -  L   Eˆ  cos  w0 (t )
w0 



We know that an unmodulated wave with frequency w0 experiences a phase shift of
  L and a phase delay of   L / w0
16
03 – Optical Channel
Click To Edit Master Title Style
We assume now a modulation of the optical signal with carrier frequency wc .


j  (t ) -  L 
E ( L, t )  Re Eˆ  a (t )e 
 e jwC t  Eˆ  a(t ) cos wct +  (t ) -  L 
A modulated signal always has a spectrum of non-zero width, i.e. spectral
components in the vicinity of the carrier frequency. As  is frequency-dependent,
each spectral component experiences a different phase shift
 L 
w0
c
n(w )  L   (w )  L  b(w ) .
(2.3-1)
In frequency domain the phase response is described by the exp-function:
H (w )  e - j  (w )L  e- jb (w )
Thus we have a phase response b(w ) from which we can derive the group delay,
which is per definition:
 g  d b(w ) / dw .
17
(2.3-2)
03 – Optical Channel
Click To Edit Master Title Style
Note:
Unlike phase delay, which gives the propagation delay time (latency), group delay is
not a physical time delay. It is primarily used to describe the phase response. We
know that deviations from a linear shape of the phase response b(w ) result in signal
distortions (called phase distortions). Thus from the definition of group delay,
deviations from a constant value of the group delay  g (w ) result in these distortions.
It is simply more convenient to evaluate deviations from a constant than from a linear
function.
18
03 – Optical Channel
TaylorTo
Series
of the
Phase
Click
EditExpansion
Master Title
Style
Response
b(w )  L   (w )
For small deviations Dw  w - wc from (light) carrier frequency, i. e. for w  wc :
w

D

 (w )  c +
(w - wc ) +
w w w

c
 1
1 2
(w - wc )2
2 w 2
w w
c
+
 2
1 3
(w - wc )3 + ...
6 w 3
w w
c
 3
(2.3-3)
Therefore for small Dw :
1
1


b(Dw )  L   (Dw )  L   c + 1Dw +  2 Dw 2 + 3Dw 3 +  
2
6


const. linear squared
cubic
Lc
 constant phase shift of carrier  "phase dealy"
L1
 linear phase contribution  constant group delay"
L 2
 quadratic phase contribution
L3
 cubic phase contribution
19
03 – Optical Channel
(2.3-4)
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As group delay can be easily measured, it is common to define a dispersion
parameter D , which finally characterizes the influence of frequency-dependent
phase response on optical signal transmission.
D
1 d g
L d
(2.3-5)
D is given in ps (group delay variation)/nm (wavelength variation) per km (fiber
length). D is also called Chromatic Dispersion (CD) parameter or group velocity
dispersion parameter.
20
03 – Optical Channel
Dispersion
over
Wavelength
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Master
Title Style
@1310nm: D  0 ps/ (nm km)
2nd optical window
@1550nm: D  17 ps/ (nm km)
3rd optical window
Dispersion in ps/(nm km)
40
30
D
20
10
0
-10
-20
1,1
1,2
1,3
1,4
1,5
1,6
Wavelength in µm
21
03 – Optical Channel
1,7
Phase
Response
of the
Fiber
Click To
Edit Master
Title
Style
By zooming in, we find that D is constant over a reasonably wide -range (and thus
w-range) for a given c
D  const.   g  linear over    g  linear over w  b  quadratic over w
Now we calculate for small deviations D in the neighborhood of c
DL 
d g
d

 g (D )  DL  d D  DLD + c.
 c
c2
with D  Dw we find group delay as a function of Dw
2 c
 g (Dw )  - DL
c2
Dw + c.
2 c
The linear group delay term results in a quadratic phase term
b(Dw )    g (Dw )d Dw  - DL
22
c2 Dw 2
+ c.Dw + d .
2 c 2
03 – Optical Channel
Click To Edit Master Title Style
1
1


b(Dw )  L   (Dw )  L   c + 1Dw +  2 Dw 2 + 3Dw 3 +  
2
6


const. linear squared
(2.3-4)
cubic
From the Taylor series expansion, we find
D-
2 c
c2
2  -
2
c2
D
2 c
(2.3-6)
In third optical window:
c  1550nm ,
23
D  17 ps / ( nm  km ) ,
 2  -21.75 ps²/km
03 – Optical Channel
Dispersion
Slope
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Master Title Style
If we need to include an additional, cubic term in the Taylor series, we have to
consider dispersion slope
S
dD ( )
d   c
This is required, if we have a very wideband signal, or if the quadratic term is small
as e.g. at zero dispersion (1310nm for SSMF). Dispersion is then considered as a
linear function:
(2.3-7)
D ( D )  D1 + S D
We use D1 here to denote the constant dispersion and derive group delay over D
as above
1
2
 g (D )  L  D(D )d D  D1LD + SL(D )2 + c.
We use also a more accurate relationship D  f (Dw ) in order to find  g as a
function of Dw
D w  w - wc ,
24
D   - c ,

2 c
w
03 – Optical Channel
Click To Edit Master Title Style
1
2
 g (D )  L  D ( D )d D  D1LD + SL(D ) 2 + c.
We use also a more accurate relationship D  f (Dw ) in order to find  g as a
function of Dw
Dw  w - wc ,
D   - c ,

2 c
w
Using these relations
D 
 Dwc / (2 c) 
c
2 c
- c 
- c  -c 

Dwc
wc + Dw
1
+
D
w
/
(2

c
)
c


1+
2 c
 Dwc / (2 c ) 
c2
c3
 -c 
Dw +
Dw 2
2
2 c
(2 c )
1 + Dwc / (2 c ) 
Introducing D in the above  g (D ) and integrating for the phase we find finally:
2
 2  
2D 
3   T   S + 1 
 2 c  
T 


25
(2.3-8)
03 – Optical Channel
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To Editand
Master
TitleDispersion
Style
Anomalous
Normal
D> 0 = anomalous dispersion:
increasing   increasing delay   slower propagation
g
("blue faster than red")
D< 0 = normal dispersion:
increasing   decreasing delay   faster propagation ("red faster than blue")
g
Material and Waveguide Dispersion
Chromatic dispersion caused by

Material dispersion: refractive index of silica glass material

Waveguide dispersion: fiber waveguide properties (core geometry)
D  DM + DW
26
03 – Optical Channel
Click Types
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Other
of Master
Fiber Title Style
27
03 – Optical Channel
Click To Edit
Master
Overview
of Fiber
TypesTitle Style
25
O-Band
C-Band L-Band
Dispersion in ps/ (nmkm)
20
15
10
5
Dispersion Shifted Fiber
0
-5
-10
1250
28
1300
1350
1400
1450
1500
Wavelength in nm
1550
03 – Optical Channel
1600
1650
Click To Edit
Master Title
Style to
Dispersion
Parameter
According
ITU-T Standard
29
03 – Optical Channel
Measurement
ofMaster
the Dispersion
Parameter
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Title Style
30
03 – Optical Channel
Linear Channel Model
31
Transmission Model for Digital
Binary Intensity Modulation
Simple transmission schemes use intensity modulation with “on-off-keying”
("1"= light on, "0"= light off). Intensity of light = instantaneous power of light.
From (2.1-3)
P(t )  A(t )  A* (t ) | A(t ) |2 | a(t ) |2
TX: A directly modulated laser (DML) translates variations of the injection current in
proportional variations of the optical intensity P1 (t ) ~ v1 (t )
RX: A photo diode is able to detect the optical intensity and translates variations of
the optical intensity in proportional variations of the output current v2 (t ) ~ P2 (t )
Transmitter
Fibre
Receiver
ok _232_s ignalubertrag.ds f
v1(t)>0
const
P1(t)
P1(t)
Ain (t)
32
|...| 2
h TP(t)
Aout(t)
P2(t)
const
v2(t)
Click
ToChannel
Edit Master
Title
Linear
Model
of Style
Optical Fiber
From previous sections we conclude that the optical fiber channel is modeled as a
linear system, that can be described (w close to carrier frequency wc) by a transfer
function H (w ) | H(w ) | e - jb (w ) with constant magnitude | H(w ) | and a phase b (w ) ,
where the most important contribution is a quadratic function in w .
H (w )  10 - adB L / 20  e - j  (w ) L | H (w ) | e - jb (w )
Input and output signals are the optical fields at carrier frequency acc. to (2.1-2).
33
03 – Optical Channel
Click To Edit Master Title
Style
Bandpass-to-Lowpass
Transformation
It is common in communications to represent bandpass systems and bandpass
signals in lowpass domain.
H LP (w ) 
1 2 H BP (w + wc ) w  -wc

0
w  -wc
2
scaling factor 1/2 for preservation of energy
here:
H LP (w ) | H (w + wc ) | e - j  (w +wc ) L
for -wB  w  +wB
where wB is the bandwidth that is of interest for signal transmission
34
03 – Optical Channel
Click To Edit Master Title Style
1
1


b(Dw )  L   (Dw )  L  c + 1Dw +  2 Dw 2 + 3Dw 3 +  
2
6


With Taylor series expansion (eq. (2.3-3)) for  (w ) around w  wc we find with eq.
(2.3-4) for small w  Dw in the lowpass domain:
H LP (w ) | H |  e
- j c L
 e
- j 1 Lw

1
- j  2 Lw 2
e 2

1
- j 3 Lw 3
e 6

(2.4-1)
for -wB  w  +wB
Input and output signals are the complex envelopes of optical fields at input
A(t , z  0)  Ain (t ) and output A(t , z  L)  Aout (t )  Ain (t )  hLP (t ) of fiber (see (2.1-2))
35
03 – Optical Channel
Click To Edit Master Title Style
Oberservations

Phase b(w )   (w )  L is not an odd function  Lowpass impulse response
hLP(t) – • HLP(w) is complex valued!

Complex envelope Aout (t ) at fiber output is complex valued, i.e. has magnitude
and phase (or real and imaginary part), even if the fiber input is real valued

2
Impact of dispersion is proportional to Lw  High frequency components (high bit
rates) are extremely critical:
At twice the bit rate  transmission distance must be reduced to one quarter in
order to achieve the same impact (i.e. signal distortions) of dispersion.

Attention: input and output signals of fiber H(f) is electric field, not power or
intensity !
36
03 – Optical Channel
Click To
Edit Master
Style
System
Responses
of Title
the Fiber
Impulse response
regarding 1st order dispersion and non-causal representation we have
H LP
1
- j 4 2  2 Lf 2
2
(f)e
b2




D T2 L 2
+ j 2
f
2
2c
e
 e + j 2 b2 f
(2.4-2)
2
Define:
 L
b2  D T  - 2 L , b2  0 for D  0 (anomalous Dispersion)
2c
hLP (t )  F-1{H LP ( f )} 

| hLP (t ) |
1
e
2b2
1
 const.  t
2b2
j 2 ( -
t2 1
+ )
4b2 8
(2.4-3)
arg{hTP (t )}  Parabola
2
in time and frequency domain same functional relationship ( e - j x )! Compare
Gaussian function
see following figures (for all figures: D = 17ps/nm/km)
37
03 – Optical Channel
Click To Response
Edit Master
Style
Impulse
ofTitle
Fiber
with Dispersion
38
03 – Optical Channel
Step
and Rectangular
ClickResponse
To Edit Master
Title Style
Pulse Response
Step and rectangular pulse responses
can be computed from the impulse response
t
h-1 (t ) 

h( )d
-
hR (t )  h-1 (t ) - h-1 (t - Tb )
39
03 – Optical Channel
Click To Edit
Title Style
Response
to aMaster
Gaussian-Impulse
Model for an isolated "1" in binary transmission A(t )  a(t )e j (t )  g (t )  Gaussian
ok_231_gaussimpuls.dsf
g(t)
ok_231_gaussimpuls.dsf
G(f)
1
1
e- 2 =0,606
-T0
t
T0
-
g (t )  e
fbw=
- 1
2T0
t2
2T02
f
1
2T0
G ( f )  2 T0 e
-
1
2T0
T0 2
(2 f ) 2
2
at fibre output:
Aout ( f )  Ain ( f )  H LP ( f )  G ( f )  H LP ( f )
 2
T02
(2 f ) 2
2
2
T0e
e j 2 b2 f
-
-
Aout (t )  F-1{ Aout ( f )} 
T0
b2
e
b
t 2 (T02 + j 2 )
t2
2(T02 - j
b2

)
 ck e
T02 - j


40
ck  compl. const.
03 – Optical Channel

b
2[T04 + ( 2 )2 ]

Click To Edit Master Title Style
-
T0
Aout (t )  F-1{ Aout ( f )} 
b2
e
b
t 2 (T02 + j 2 )
t2
2(T02 - j
b2

)
 ck e
T02 - j


ck  compl. const.
-
| Aout (t ) || ck | e
41
t 2T02
b
2[T04 + ( 2 )2 ]

remains Gaussian!
03 – Optical Channel

b
2[T04 + ( 2 )2 ]

Click To Edit Master Title Style
Pulse width (decay by 1/ e ) at fiber output:
-
!
t 2T02
1
 b
2
2[T04 + ( 2 ) 2 ]
t2 


T1
b
 1 + ( 2 2 )2
T0
 T0
b
T 4 [1 + ( 2 2 ) 2 ]  T12
2 0
T0
 T0
1
2
 DL T2 
1+  2
  Pulse broadening !
 T0 2 c 


 2L
b D T
2
2c
Dispersion length:
Def.: Fiber length LD for which T1  2 T0
DL T2 !
1
T02 2 c
 L 
T1
 1+ 

T0
 LD 
L  LD 
T02 2 c
DT2
2
(2.4-4)
Example: T0=50ps (corresponding to Tb=100ps) LD=115.4 km
For L ~ LD Pulse broadening  Inter-symbol-interference  Bit errors  LD 
dispersion limited transmission length
42
03 – Optical Channel
Influence
of Dispersion
onStyle
Data
Click To Edit
Master Title
Transmission
Binary on-off keying transmission with on-off keying intensity modulation
2
Transitions "0"-"1" and "1"-"0" with smooth edges (cos -roll-off)
Eye diagram after 0 km (left)
and 6.25 km (right) at 40 Gb/s
and SSMF (D = 17 ps/nm/km)
43
03 – Optical Channel
Examples
of Eye
Distortions
Click To Edit
Master
Title Style
Eye diagrams and time signals at 10 Gb/s
transmission over standard single mode fiber
(SSMF) with D=17ps/nm/km.
Signals shown are instantaneous power signals
0 km
20 km
80 km
44
03 – Optical Channel
Dispersion
Limits
Click To Edit
Master Title Style
Dispersion limit is proportional to the square of the bit rate
D  Lmax 
c
4 2 fbit2
Dispersion compensation is required for transmission over (for NRZ-OOK modulation)
900 km SSMF @ 2.5 Gb/s (15000 ps/nm)
60 km SSMF @ 10 Gb/s (1000 ps/nm)
4 km SSMF @ 40 Gb/s
(65 ps/nm)
Alternative: Modulation formats (e.g. duobinary) with higher dispersion tolerances
45
03 – Optical Channel
Click To Edit
Master Title Style
Extinction
Ratio
from eye diagram (time signal on oscilloscope, trigger with bit clock) we find
Def.:
ex 
P ("0")
P ("1")
(2.4-5)
ex dB  10lg(ex)
typically:
ex dB  -10dB  - 16dB,
ex  0.1  0.025
P("1")
P("0")
46
03 – Optical Channel
Dispersion
Compensation
inStyle
Long
Click To Edit
Master Title
Distance Links
Transmission distance L >> Dispersion limit LD (wide area networks WAN
L >100km ... several 1000km)
Due to fiber loss, the received signal is attenuated
 optical amplifiers for loss compensation
Due to dispersion, the received signal is heavily distorted! However, as dispersion
results in linear distortions, we can compensate by applying equalization:
H equal ( f )  1/ H fibre ( f )
As the fiber transfer function is basically a phase filter with quadratic phase response,
we need an optical filter as equalizer with inverted sign quadratic phase shape.
 optical dispersion compensators (opt. filters or DCF)
47
03 – Optical Channel
Click To Edit Master Title Style
Optical Dispersion Management
Typically long distance fiber links are organised in several spans. In each span
optical amplifiers are used for loss compensation and DCF (Dispersion compensating
fiber) is used for dispersion compensation. DCF has an inverted dispersion
coefficient:
DDCF  -(5...15) DSSMF
 LDCF  LSSMF / (5...15)
For linear transmission (small optical power) full compensation of dispersion is
possible. Usually we use higher power (e.g. 10dBm)  non-linear transmission 
signal distortions due to both nonlinearity and chromatic dispersion
48
03 – Optical Channel
Click
To Edit
Master Title
Style
Electronic
Dispersion
Compensation
Can we apply electrical equalisers at RX (after optical/electrical conversion) for
dispersion compensation (electrical filters are cheaper and more flexible!)?

Yes, if phase distortions on the optical signal can be transformed in exactly the
same phase distortions in the electrical domain (after optical front end). Such a
transformation is possible with coherent optical receivers.

No, if we use direct detection as optical front end, because photo diode detects
only magnitude squared and no phase of the optical signal. Thus we have
nonlinearity |...|2 in our system and a simple linear equalizer filters fail or results in
only limited compensation performance.
49
03 – Optical Channel
Optical Polarization
50
Click To EditinMaster
Polarisation
FibersTitle Style
Solution of wave equations result (approximately) in a fundamental (single) mode,
which is a linearly polarized transversal wave. I.e. regarding a plane z=const the Evector has (approximately) no longitudinal (in z-direction) component and moves in
this plane on a straight line with a certain angle against x-axis.
 vector can be decomposed in x- and y-components (orthogonal components)
51
03 – Optical Channel
Click To
Edit Master Title Style
Jones
Vector
E(r , z, t )  Re{Ex (r , z, t )e x + E y (r , z, t )e y }


 ˆ

- jx z 
 E0 x (r )e
  e jwT t 
 Re 
- j z
 Eˆ 0 y (r )e y 

 



J=Jones-Vector
State of Polarization (SOP) is considered in plane z=const
Linear Polarisation: E0xE0y, x=xz=±y=yz components
Circular Polarisation: E0x=E0y, y=x/2
are in-phase
(+ right, - left circular)
 Eˆ 0 x e jx 
 fig. 2.-3
J 
 Eˆ e j (x  /2) 
 0x

 Eˆ 0 x e jx 
 fig. 2.-2
J 
 Eˆ 0 y e jx 


Elliptical Polarisation: E0xE0y, xy
 Eˆ 0 x e jx
J 
 Eˆ 0 y e j y

52
03 – Optical Channel

 fig. 2.-5


Click To&Edit
Master Polarized
Title StyleLight
Linearly
Circularly
53
03 – Optical Channel
Click To Edit
Master Light
Title Style
Elliptically
Polarized
See a nice animated tutorial on polarization at:
https://www.keysight.com/main/editorial.jspx?cc=DE&lc=ger&ckey=2475067&i
d=2475067&cmpid=zzfindpolarization-form
54
03 – Optical Channel
Click To
Master Title
Style
States
of Edit
Polarisation
(SOP)
in SMF
Polarized light:
SOP in plane z=const remains constant
Un-polarized light:
SOP changes
Ideal case:
for perfect cylindrical symmetry the SOP (e.g. linear) of incoming light is preserved
along the fiber
Real world:
Distortions from cylindrical symmetry through manufacturing process (core ellipticity)
or fiber installation (stress, bending)
 slightly different propagation constants of orthogonal modes = Birefringence
 along the fiber the SOP changes within some cm. (SMF is “polarization
maintaining” only over some cm).
"Beat length" approx. 10m
55
03 – Optical Channel
ClickLength
To Edit Master Title Style
Beat
Consequences:

Polarization-dependent optical components and systems (e.g. semiconductor opt.
amplifiers, Mach-Zehnder modulators) need polarizers and polarization
maintaining fibers (special geometry of core) for interconnection of these
components

Optical receivers for intensity modulation detect optical power (direct detection)
 independent of polarization
56
03 – Optical Channel
Click
To Edit Mode
MasterDispersion
Title Style
Polarisation
PMD is a serious impairment of the fiber channel for high speed transmission!
PMD stems from slightly different propagation velocities (=birefringence) of the
orthogonal modes (x- and y-component) of the light due to
(i) non-ideal core geometry and
(ii) environmental influences on installed cable (pressure, bending).
PMD is changing along fiber and with time  stochastic process.
57
03 – Optical Channel
Click
To Edit Master Title Style
Birefringence
In the case of birefringence we have a fast and a slow polarization axis.
With
D |  gx -  gy |
Differential Group Delay (DGD)
A perfectly birefringent fiber is called PM-fibre (polarization maintaining), where the
slow and fast axes remain constant over the entire length and
D g is relatively high (Fig.12.10a)
In typical transmission fiber, birefringence is maintained only over a short distance.
The orientation of the axes changes with distance  "mode coupling". Hence the
PMD of a fiber can be modeled as pieces of birefringent fiber with random axes
rotation. This model is called "waveplate model" (Fig. 12.10b).
Due to this mode coupling, D increases not linearly (as in PM-fiber) but with the
square root of the fiber length L.
58
03 – Optical Channel
Click
To Edit Model
Master Title Style
Waveplate
59
03 – Optical Channel
Pulse
Outage
Click
ToBroadening
Edit Masterand
Title
Style Probability
due to PMD
60
03 – Optical Channel
Click
Edit Master Title Style
PMD To
Characterization
It is common to characterize PMD by the DGD D, which is a random parameter.
DGD D has a Maxwellian-probability density function (pdf)
D 2
2 D 2 - 2 q2
pD (D ) 
e
 q3
pD(D )
where q 

8
E{D }
Maxwell pdf
ok _24_maxwell.dsf
D=DGD
E(D )
Definitions:
DGD-value: D
[ps]
PMD-value: E{D} [ps]
PMD-coefficient:
E{D
}
km
[ps/√km]
Typical values for SSMF:
PMD-coeff.  E{D km }  0,05 ... 2
61
ps
km
03 – Optical Channel
Click To Edit
Master
Title Style
Influence
of PMD
on Digital
Transmission
New fibers have very low PMD-coefficients.
Old installed fibers (‘legacy fiber’) had sometimes no PMD-specification (today < 0.1
ps/sqrt(km) specified!)
 high PMD in transmission link is possible
 worst case must be considered for network design!
62
03 – Optical Channel
Click Impairments
To Edit Master Title Style
PMD
PMD in IM/DD Systems
Rule of thumb: (Estimation from statistical and experimental investigations)
E{D} ≈ 0.1 T
b
10% of bit duration
is the limit of a tolerable PMD-value.
 PMD is critical for high bit rates of 10 Gb/s and above!
PMD compensation is required!
PMD in Coherent Transmission systems
PMD can be compensated by linear equalizers in the electrical domain after opt/elect
conversion by means of digital signal processing
x- and y-polarizations are detected in parallel paths. 2x2 MIMO equalizer separates
polarizations.
63
03 – Optical Channel
Click
To EditPMD
Master Title Style
First-order
64
03 – Optical Channel
Click
To EditPMD
Master
Title Style
First-order
– System
Model
ok_232_signalubertrag.dsf
|...| 2

x(t)=
Px(t)
+
D
|...| 2
y(t)=
P(t)
1-
Delay
Optical power detected by photo diode
P(t )   | E x (t ) |2 + (1 -  ) | E x (t - D ) | 2   Px (t ) + (1-  )Px (t - D )
where  = power ratio in fast/slow axis (varies statistically!), uniformly distrib. in [0,1]
 For detected power: PMD behaves as a linear multipath system!
 Compensation (equalisation) by an inverse system e.g. in electrical part of receiver
(after o/e conversion) is possible
65
03 – Optical Channel
Waveplate
Model
of PMD
forStyle
“all- order” PMD
Click To Edit
Master
Title
Cascade of birefringent wave plates with arbitrarily rotated fast and slow axis. In
equivalent LP-domain:
1
propagation constant in fast axis:  fast ( f )  C fast + 1 fast f +  2 fast f 2 + ...
2
1
propagation constant in slow axis:  slow ( f )  Cslow + 1slow f +  2 slow f 2 + ...
2
neglecting dispersion, results in transfer function for a single wave plate
H f (w )  e
- j (  Cf L +  1 f Lw )
H s (w )  e- j ( Cs L +  1s Lw )
66
03 – Optical Channel
System
Model
Click To
Edit Master Title Style
H f (w )  e
- j ( Cf L +  1 f Lw )
H s (w )  e - j ( Cs L +  1s Lw )
oc_24_PMD.dsf
fast
+j
e
slow
67
-j
e
D
2
D
2
+j
e
-j
e
D g
2
D g
2
2 f
2 f
03 – Optical Channel
Waveplate
Model
of PMD
Click
To Edit
Master
Title Style
Vectorial Description
Light incident to the fiber has linear polarization in x,y-coordinates. We rotate the components
by angle a to the fast and slow axis (x',y') of the wave plate. Rotation in matrix form = Jones
y
matrix calculus:
y'
 E x' 0   cos a


 E 'y 0   - sin a


oc_24_PMD.dsf
x'
sin a   E x 0 


cos a   E y 0 
a
x
Concatenated wave plates are rotated (with resp. to fast and slow axis) by arbitrary angles ai .
68
03 – Optical Channel
Click To Edit Master Title Style
y
y'
 E x' 0   cos a


 E 'y 0   - sin a


oc_24_PMD.dsf
x'
sin a   E x 0 


cos a   E y 0 
a
x
Concatenated wave plates are rotated (with resp. to fast and slow axis) by arbitrary angles ai .
Therefore we can derive the model:
e(+jD1/2) e(+jD1w/2)
+
n
si
+
e(-jD1/2) e(-jD1w/2)
Transfer matrix of one
rotated birefringent
element:
cos a2
 cos ai
 - sin a
i

...
-s
in
a
2
a
-s
in
1
oc_24_PMD-model.dsf
a3
a2
a1
si
na
e(+jD3/2) e(+jD3w/2)
cos a3 +
e(+jD2/2) e(+jD2w/2)
+
n
si
in
-s
cos a1
69
cos a2
3
cos a1
+
e(-jD2/2) e(-jD2w/2)
 + j Di + D gi 2 f
2
2
sin a i   e

cos a i  

0

03 – Optical Channel
cos a3
+
e(-jD3/2) e(-jD3w/2)

 cos a
0
sin a i +1 
i +1
 
 - sin ai +1 cos a i +1 
D  D g i
-j i2 f  
2
2
e

Conclusions
Click To Edit Master Title Style
10 to 15 wave plates result in sufficient statistical accuracy for modelling PMD of
fibers.  Implementation as a simulation model
a i and i are chosen randomly from uniform distribution in [0, 2 ]
D gi group delay difference is chosen from (near) Gaussian distribution
according to desired PMD value.
70
03 – Optical Channel
Click To EditNonlinearity
Master Title Style
Fiber
71
03 – Optical Channel
Click To Edit
Master
Title Style
Non-Linear
Fiber
Characteristics
For large and medium optical power (from approx. P>= 1mW i.e. 0dBm)
optical fibers behave non-linearly
Non-linear influence depends on:

mean power at fiber input

Peak-to-average power ratio (PAPR) of instantaneous optical power

Spatial power distribution over the fiber-core cross section  effective area

fiber length and exponential decrease of signal power along the fiber
72
03 – Optical Channel
Click
To Edit Length
Master L
Title
Style
The
Effective
eff
Influence of fiber nonlinearity decreases along z-axis due to exponential decrease of
power with length.
Simplified model: assume constant power over a certain fiber length L ≤ actual
eff
length L  effective length
Leff
:
Typical value:
1
P0
L

L
P ( z )dz

z 0

e -a z dz
z 0

1 - e -a L
a
Exercise:
For a multi-span link (span length Lspan with in-line amplifiers of total link length Ltot )
we find:
Leff

1 - e-a L Ltot
a
Lspan
The effective length can be interpreted as the length of an equivalent fiber with no
loss, but having the same nonlinear impact
73
03 – Optical Channel
Clickeffective
To Edit Area
Master
The
AeffTitle Style
Influence of fiber nonlinearity depends on the distribution of light power inside the
fiber-core cross section

For SMF: Field distribution has approx. Gaussian-function

Define an effective cross-sectional area: circle of area A
eff
where the power is
assumed to be uniformly distributed(see fig. 4.25)

A
is approximately equal to the core area

A
= 50…80 m for SMF , A
eff
2
eff
74
eff
2
= 20 m for DCF
03 – Optical Channel
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Linear
Fiber
Linear Fiber Effects
Attenuation
75
Dispersion
Polarization
Mode Dispersion
03 – Optical Channel
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Title Style
Nonlinear
Fiber
Properties
Nonlinear Fiber Effects
Inelastic
Elastic (Kerr-Effect)
SPM
XPM
FWM
SPM: Self-phase modulation
XPM: Cross-phase modulation
FWM: Four-wave mixing
76
SRS
SBS
SRS: Stimulated Raman Scattering
SBS: Stimulated Brillouin Scattering
03 – Optical Channel
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Master Scattering
Title Style
Stimulated
Brillouin
SBS = interaction between light and acoustic waves
 signal is backscattered, if a certain threshold with resp. to spectral power density
(in W/Hz) is exceeded!
SBS critical, if power is concentrated in small bandwidth, B (e.g. 100 MHz) = Laser
Q
with small spectral linewidth.
 SBS-threshold:
Pth, SBS
BQ
77

21  Aeff
g B  Leff  BB
03 – Optical Channel
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 SBS-threshold:
Pth, SBS
BQ

21  Aeff
g B  Leff  BB
A ≈50…80(m)2, effective mode field area, depends on field distribution
eff
L ≈ 20km, effective length of nonlinear interaction
eff
B ≈ 20MHz, SBS gain bandwidth
B
g ≈ 4 10-11m/W, SBS gain coefficient
B
Typical result:
Pth, SBS  6.5mW for BQ  100MHz
SBS cancellation:
Slight spectral broadening of power e.g. by a slowly varying (e.g. 100 kHz) frequency
modulation of light carrier (=laser)  linewidth enhancement
78
03 – Optical Channel
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Stimulated
Raman
Scattering
Raman Scattering = interaction between light (photons) and molecular vibrations of
the fiber’s silica molecules.
The molecules absorb some energy (E=hf ) from the photons  reduces frequency
of scattered light by Df
R
Stimulated Raman Scattering (SRS)
An optical wave with frequency f < f is amplified through stimulation by a second
1
wave of frequency f = f +Df
2
1
2
R
SRS crosstalk in WDM
WDM with channel spacing ≈ Df : lower frequencies are amplified  gain tilt
R
79
03 – Optical Channel
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Title Style
Spontaneous
vs. Stimulated
Raman Scattering
Spontaneous Raman Scattering
E
Scattered Photon
Pump-Photon
Phonon
Stimulated Raman Scattering
E
Signal-Photon
Signal-Photon
Signal-Photon
Pump-Photon
80
Phonon
03 – Optical Channel
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Raman
dPS
g
 -a S PS + R Pp PS
dz
Aeff
dPp
dz
 -a pPp -
S g R
PS Pp
p Aeff
PS: Signal power
PP: Pump power
a: Attenuation constant
Aeff: effective fiber area
gR: Raman gain coefficient
81
03 – Optical Channel
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SRS
Copropagating channels
log(P)
Local
Dispersion

Accumulated
Dispersion
CH1
Power transfer from lower
to higher wavelengths
through SRS
Accumulation of the
individual segments
Input
CH2
CH1
log-lin tilt(~ Ptot BWtot)
and noise-like interference
(multichannel, multisegment)
on the “1” of the IM signal
Output
CH2
82
03 – Optical Channel
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Raman
Amplifier
An optical wave at frequency f can be amplified through stimulation by a co
1
propagating second wave of frequency f = f +Df
2
1
R
from a (high power) “Raman pump
laser”
Raman Gain
Raman effect is most efficient for Df ≈ 10..16THz
R
(i.e. “bad” for SRS cross talk, “good” for Raman amplifier)
83
03 – Optical Channel
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Optical
Kerr
Refractive index depends on light intensity = Kerr nonlinearity
| E |2
n  n(w, E )  nlin (w ) + n2
Aeff
Propagation constant is related to refractive index
   (w , E ) 
wc
w
w n
 n(w , E )  c nlin (w ) + c 2 | E |2  lin +  | E |2
c
c
c  Aeff


wc n2
c Aeff
 nonlinearity parameter
Phase shift of light signal is related to propagation constant (b=·L)
2
e- j (w ,E )L  e- j[ lin (w )+ |E|
84
]L
03 – Optical Channel
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Self-Phase
Modulation
Intensity modulation (IM)
of the signal
t
Phase modulation (PM)
due nonlinear refractive index
Accumulated
Dispersion
PM-IM conversion
Signal distortion
(Intersymbol interference)
D>0
85
D<0
03 – Optical Channel
t
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Influence
SPM
on Signal
Transmission
Dispersion and loss management
Optical long distance transmission = wide area networks WAN (>100km … several
1000km):
Loss compensation  optical amplifiers
Dispersion compensation  DCF (Dispersion compensating fibre)
For linear transmission (small optical power) full compensation of dispersion is
possible with DCF. Usually we use higher power (e.g. 0…10dBm)
 non-linear transmission
 signal distortions due to NL and chromatic dispersion (CD)
 link design for minimum distortions (=“Dispersion management“).
Criteria:

required receiver input power for fixed BER, e.g. BER=10-9 (minimum)

eye diagram with open eye (eye opening = maximum)
86
03 – Optical Channel
Non-linear
Intermodulation
Effects
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in WDM Transmission
In communications theory well known:

Nonlinear channel properties may result in new spectral components

These new spectral components may interfere with neighbour channels, if
frequency division multiplexing transmission scheme is used

Example: CATV, highly linear amplifiers required!
Therefore we expect intermodulation effects in optical WDM transmission systems,
where we transmit multiple channels with different carrier wavelengths separated by
a given channel spacing.
87
03 – Optical Channel
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To EditExplanation
Master Title Style
Qualitative
Kerr-effect is a nonlinear impairment

single-channel transmission
 nonlinear distortions of complex envelope
(Self Phase Modulation=SPM)

multi-channel transmission (=WDM)  generation of intermodulation products
(Cross Phase Modulation=XPM, Four Wave Mixing=FWM)
Question: All impairments (SPM, XPM, FWM) are due to Kerr effect. Why are they
separated into SPM, XPM and FWM?
Answer: The way SPM, XPM and FWM disturb signal transmission is fairly different
although all of them stem from the Kerr effect.
It makes sense to treat them separately.
88
03 – Optical Channel
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Title Style
Quantitative
Derivation
First issue:
How to express the complex envelope of a multi-channel (i.e. WDM) signal?
Well known: bandpass-lowpass transform of a single-channel (i.e. single-carrier)
signal

bandpass signal:
sBP (t )  a(t ) cos[2 f ct +  (t )]

analytical signal:
s BP (t )  a(t ) e j (t )e j 2 fct

complex envelope:
A(t )  a (t ) e j (t )
Now apply formalism on multi-channel signal (N channels)
N
bandpass signal:
sBP (t )   ai (t ) cos[2 f cit + i (t )]
i 1
with
ai(t): amplitude modulation of channel number i
fci:
carrier frequency of channel number i
i(t): phase modulation of channel number i
89
03 – Optical Channel
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
N
N
i 1
i 1
sBP (t )   ai (t )e ji (t ) e j 2 fcit   Ai (t ) e j 2 fcit
analytical signal:
with i(t): complex envelope of channel number i

complex envelope: WDM signal has more than one carrier. Which frequency
f c should be used for quadrature mixing into baseband? For practical reasons
choose f c such that it falls right into the center of the WDM spectrum.
Result for complex envelope:
N
AWDM (t )   Ai (t )e
i 1
j 2 fcit - j 2 fct
e
N
  Ai (t )e j 2Dfit
i 1
With Dfi  f ci - f c difference between carrier frequency of channel i and fc
90
03 – Optical Channel
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To Edit Master Title Style
Example
Properties of AWDM (t ) :

baseband signal

multi-carrier signal
Example for N=5:
91
03 – Optical Channel
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To Edit Master
Title Style
Cross-Phase
Modulation
(XPM)
Intensity Modulation (IM)
of copropagating channels
Local
Dispersion
Phase Modulation (PM)
due to nolinear refractive index
Accumulated
Dispersion
PM-IM Conversion
Noiselike crosstalk
(multi-channel, multi-segment)
on the “1” of an NRZ signal
from 010101... pattern
In contrast to SPM, for XPM the origin of the induced phase modulation is not the optical
power of the signal itself but the sum of the powers of all co-propagating WDM channels.
92
03 – Optical Channel
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Properties
XPM Title Style

XPM from each disturbing channel is twice as strong as SPM

XPM only results in phase modulation
 not a problem for direct detection systems

however fiber dispersion converts phase modulation into intensity modulation
 results in signal degradation also for direct detection

XPM may add up to strong phase modulation for high number of channels

But:
o disturbing channel and disturbed channel have different group velocity
(for dispersive fiber, represented by 1~D)
o group delay difference (walk-off) is higher the larger the spacing
between the channels
 impact of XPM is averaged out
 fiber dispersion is required to mitigate impact of XPM !
 only direct neighbours have significant impact
 more impact for tight WDM channel packing
93
03 – Optical Channel
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Master(FWM)
Title Style
Four-Wave
Copropagating channels
atfi,fj, fk
-20
cw, full resolution
-30
Power @ Pre (dBm)
Power @ Pre (dBm)
-25
-35
-40
-45
-50
-55
-60
-65
1553
1554
1555
1556
1557
Local
Dispersion
Accumulated
Dispersion
Coherent mixing:
Sideband generation through
nonlinear refractive index
at fijk = fi+fj-fk with k  i,j
Accumulation of
the individual mixing products
1558
Noiselike distortion
(multi-channel, multi-segment)
on the “1” of the signal
94
03 – Optical Channel
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Description
Origin of name: three waves generate a fourth wave  four wave mixing
precondition: equidistant channel spacing (in almost all cases fulfilled)
Normal FWM
P
w4 = w2 + w3 - w1
w1
w2
w3
w4
w
Degenerate FWM
P
w1 = 2 w2 - w3
w4 = 2 w3 - w2
Dw Dw Dw
w1
95
w2
w3
w4
03 – Optical Channel
w
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ToMismatch
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Phase
Mechanism of phase mismatch:

FWM is generated continuously along the fiber

if all contributions along the fiber add up in-phase:
 phase mismatch D=0
 strong FWM

if contributions along the fiber do not add up in-phase:
 phase mismatch D >0
 weak FWM
Phase mismatch depends heavily on fiber dispersion parameter

D=0  2=0 (i.e. dispersion shifted fibre, DSF):
 no phase mismatch
 strong FWM
 WDM on DSF is near to impossible!

D>0  | 2|>0
 phase mismatch higher the larger spacing of contributing channels
 only neighbouring channels have impact
 on SSMF: FWM generally weaker than XPM
96
03 – Optical Channel
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Example
97
03 – Optical Channel
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To EditManagement
Master Title Style
Dispersion
dispersion
Full compensation of the accumulated
dispersion after each span
0
distance
0
. . . SSMFN-1
SSMF1
acc. dispersion
Distributed undercompensation of
the dispersion after each span
0
DC 1
DC
SSMFN
N-1
DCN
distance
98
03 – Optical Channel
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To EditUnmanaged
Master TitleTransmission
Style
Dispersion
Links
In modern (“high-end”) transmission links with coherent receivers, it is preferred to
avoid DCF in the link. DC is rather compensated for by linear equalizers in the
receiver by a digital signal processing unit.
This is possible, since coherent receivers are “linear transducers”. They transform the
optical signal into the lowpass domain, including all distortions.
99
03 – Optical Channel
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Propagation
Modes
100
03 – Optical Channel
Propagation
ModesTitle
in Fibres,
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To Edit Master
Style
Characteristics of MMF and POF
Concept of modes
Electro-magnetic waves in fibers propagate according to the wave equation (WE),
which can be derived from Maxwell’s equations.
In general there are many solutions to the WE  fiber modes
Each (fiber) mode has a different

propagation speed (group velocity)  explained by ray optics

field distribution (intensity pattern) over the fiber’s cross section
The number and types of modes depend on the refractive index profile (n1, n2) and on
core diameter d.
Modes in fibers are (approximation of "weakly guided" waves ) ≈ linear polarized (LP
modes).
The different modes are sorted by designating order numbers:
LP
101
jm
where j (azimuth wave number) and m (radial wave number).
03 – Optical Channel
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Multimode
andMaster
Single Title
ModeStyle
Condition
The following plot shows the normalized propagation constant:
B :
(  / k ) 2 - n22
n12 - n22

 / k - n2
n1 - n2

 / k - n2
n1D
n -n
with D  1 2
n1
over normalized frequency
V  wC
d 2 2
n1 - n2
c

the larger V, the more modes (high order modes)

only one mode if V < 2.405
102
Single mode condition
03 – Optical Channel
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To Edit Master Title Style
bV
Characteristics
B
1,0
0,8
LP01
0,6
11
02
0,4
21
31
•
22
12
51
0,2
41
32
03
61
13
0
0
2
4
6
8
10
V
103
•
03 – Optical Channel
the larger V, the more
modes (higher order
modes)
only one mode, if V <
2.405 (Single mode
condition)
FieldToDistribution
Modes
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Style
(Intensity Patterns)
104
03 – Optical Channel
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Intensity
Distribution
MMF

Many modes co-propagate in a fiber (multi-mode fiber)

lower order modes travel in core center

higher order modes travel off center
SMF:
105

LP

field distribution is approximately Gaussian
01
is the only mode that propagates (single mode fiber)
03 – Optical Channel
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LP01 – Approximation
weakly guiding fiber
Exact solution for
step-index fiber
106
03 – Optical Channel
Transmission
Characteristics
of SMF
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Title Style
SMF:

for high speed, long distance applications  WAN

core diameter: ≈ 9µm

sophisticated handling due to small core diameter, e.g.

connectors

launching laser light
n
nk
nm
r
Single Mode
Step-Index Fiber
107
03 – Optical Channel
Transmission
Characteristics
of
Click To Edit Master
Title Style
MMF & FMF
MMF:
n

for high speed, short distance applications  LAN

core diameter: ≈ 50µm or ≈ 62.5µm

simple handling and light power launching due to large core diameter

main limitation: mode dispersion

Graded index MMF much better than step index MMF

Challenge: 10Gb/s (Ethernet protocol) over 300m ?

Channel model of MMF very different from SMF!

Channel model not fixed as MMF properties differ in brought range!
nk
nm
r
e.g. dips or holes in refractive index profile!
Multimode
Graded Index Fiber
FMF (few mode fiber)

Core diameter 10…20m

Only a few modes (2 …6) propagate

Used for mode division multiplexing (MDM): Use each mode for transmitting a separate
data stream!  capacity
108
03 – Optical Channel
Transmission
Characteristics
of
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Title Style
POF (Plastic Optical Fiber)
POF:

polymer (plastic) fiber, material e.g. PMMA (polymethylmethacrylate), no glass!

core diameter up to ≈1000 m (1mm)

large core diameter, thousands of modes

short reach, low cost applications

loss: typ. ~100dB/km in 500nm…650nm window (advanced POF: ~10dB/km at
1050nm)

very simple handling (connectors, bending radius,…)
Applications:

automobiles

sensor networks

In-house LAN
109
03 – Optical Channel
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ToUp
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Wrap
What you should recall from this chapter:
•
•
•
•
•
•
•
•
•
•
•
110
What are the bit durations for 10 Gb/s and 40 Gb/s transmission?
Give the loss (in dB) and the dispersion (in ps/nm) of 80 km SSMF
in O-, C- and L-bands
Explain PMD of 1st order, give the model
What is linear polarization and circular polarization?
What is the value of cut-off (normalized) frequency V for single
mode condition?
Look at the equation for Aeff and identify the impact on fiber
nonlinearity
What is the definition of the extinction ratio?
What are the nonlinear fiber effects in single channel (i.e. no WDM)
transmission?
Explain the wave-plate model for PMD
What is the origin of PMD in transmisson fibers and what is the
impact on transmission?
Give the dispersion length for 40 Gb/s data transmission
03 – Optical Channel
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Appendix
111
03 – Optical Channel
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Edit Master Title Style
Soliton
Transmission
Soliton: special pulse form, which results as a stable solution (i.e. pulse shape is
maintained for all z) in attenuation-free (a=0) fiber transmission
dA  z , t 
dz
2
 - j A  z , t  A  z , t  + j
2
2 d A  z, t 
2
dt 2
st
Soliton of 1 Order:
1
A  z, t  
T0
112
2
 e

j
2
2T02
z
 t 
 sech  
 T0 
03 – Optical Channel
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1
A  z, t  
T0
"FWHM"
1.76 T0

solution holds for  <0 only, i.e. D > 0 (anomalous dispersion)

sech  x   1/ cosh  x  

1
soliton-amplitude:
T0
2
2
e x + e- x
2
T2
is fixed for fixed dispersion  2  D

2 c
w n
non-linearity parameter (   T 2 ), and pulse duration T0
c Aeff
113
03 – Optical Channel
2
 e

j
2
2T02
z
 t 
 sech  
 T0 
Click To
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Style
Soliton
Transmission
Applications

|A(z,t)| is independent from z (no pulse distortion due to dispersion)
 Due to interaction non-linearity  dispersion, soliton maintains its pulse shape,
(theoretically) over arbitrary long distances.

For compensation of loss (we assumed a=0!) we use optical amplifiers (regular
amplifier spacing 30 ... 50km)

In general T0<<Tb (no pulse overlap)
Soliton = RZ-(Return to Zero) pulse. It is sufficient to generate roughly soliton-like
pulses at transmitter, along transmission fibre, the soliton pulse shape is created
automatically

Therefore RZ-pulse shape has better performance (e.g. longer transmission
distance) than NRZ-pulse shape in nonlinear fibre regime (more robust!)

Proposed applications: ultra long haul submarine systems (however not used in
commercial systems)
114
03 – Optical Channel
Lecture
Optical Communications
Lasers
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Click To Edit Master Title Style
Optical Sources
LED (Light emitting diode) Broadband emission spectrum ( Dl  4060nm
)  not a single
frequency carrier  dispersion limit at approx. 10 Mbit/s. Low-cost applications.
Semiconductor Laser (Laser=Light Amplification by Stimulated Emission of Radiation)
• small size
• high reliability
• narrow emission spectrum (quasi single frequency carrier possible)
• emission wavelength in optical window 1 (~850 nm), 2 (~1310 nm), and 3 (~1550 nm) possible
• direct modulation possible up to several Gbit/s
• small emission radius of light beam (coupling to optical fiber)
2
04 – Lasers
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Semiconductor Lasers
pn-diode operating with forward bias. Light emission due to special semiconductor material.
Materials
Materials: III-V compounds:
• GaAs
 in 1st optical
window (850nm)
• InGaAsP  in 2nd and 3rd
optical windows
3
04 – Lasers
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Basic Principle
Oscillator (energy source, amplifier, resonator)
• Energy source (pump) = electrical current through pn-junction.
• Active gain medium (active layer) = volume charge zone of pn-junction stimulated emission of
photons by recombination of electrons with holes.
• Resonator (cavity) = wave guide with facettes as reflecting mirrors (coating).
4
04 – Lasers
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Energy Band Model
Physical structure:
Special, heavily doped (degenerated) pn-junction with a double-hetero structure ("Hetero"=layers
with different band gaps). I.e. cavity (recombination zone = active layer) with defined width where
photons are generated by recombination and which serves also as dielectric wave guide
(confinement zone which is guiding the laser beam).
heavily p-doped
slightly p-doped
heavily n-doped (degener. WF>WV)
Conduction band
Wg2
Wg3
WF
Valence band
Wg2 <Wg1 ,Wg3
Active layer
(recombinations
zone)
ok_313_bändermodell 2010.dsf
-x
5
U=0, (thermodynamic equilibrium)Wg1
04 – Lasers
Click To Edit Master Title Style
Energy Band Model (Forward Bias)
heavily p-doped
slightly p-doped
heavily n-doped (degener. WF>WV)
Conduction band
Wg2
Wg3
WF
Valence band
Wg2 <Wg1 ,Wg3
Active layer
(recombinations
zone)
ok_313_bändermodell 2010.dsf
-x
6
04 – Lasers
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Guiding of Laser Beam
Recombination zone
Energy
p-doped
Conduction band
Electrons
Band gap
Valence band
Field distrib. Refract.
index n
n-doped
Holes
n1
n2
n2
ok_314_laserführung.dsf
~2m
7
04 – Lasers
-x
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Recombination Mechanism
Non-radiating (electron-hole) recombination in indirect band-gap semiconductors (e.g. Si) results in thermal
radiation (heat). Here unwanted!
Radiating recombination in direct band-gap semiconductors (e.g. GaAs) results in light radiation (photon)
active layer
- -
-
Conduction band = excited state
WC
Wc
hf>Wg
hf>Wg
Wg=WC-WV
Wg
hf>Wg
Wg
WV
Wv
Valence band = ground state
a)Absorption
Light attenuation in
laser
8
z
b)Spontaneous emission
random direction and
phase (LED)
04 – Lasers
ok_124_laser_rekombination.dsf
c)Stimulated emission
direction, phase, frequency,
polarisation same as in
incoming light (Laser)
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Physical Structure
Horizontal confinement of active laser cavity (x-direction) by double heterostructure
Lateral confinement (y-direction) Gain-guided or index-guided (preferred today)
9
04 – Lasers
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Fabry-Perot Resonator, Lasing Condition
Volume with rectangular cross section = resonance cavity (active layer).
Reflections at planar boundaries: Laser-material (e.g. GaAs n=3,6) / air (n=1)
 standing longitudinal waves
complex envelope of forward travelling wave

E ( z )  A0 e
s  g
2
Air
n=1
n~3,6 (GaAs)
ok_317_FP_resonator_laser.dsf
Air
n=1
z  j z
e
after one round trip: forward length L,
reflection r1,
backwards length L,
reflection r2:
Facette
L~100...500m
z
Amplification=gain g
by stimul. emission
Attenuation=loss S
!
E ( z  0 |2 L )  r1r2 A0 e ( s  g ) L e  j  2 L  E ( z  0 |0 )  A0
constructive interference
compensation of loss
10
04 – Lasers
Click To Edit Master Title Style
Phase Condition
l
  2 L  2 m
  kn 
2
l
2nL
m
m integer, n~3,6 (refr. index)
n
Resonance wavelength.
Amplitude condition:
with R1=|r1|2, R2=|r2|2 power reflection coefficients
gth   s 
1
1
ln
2 L R1R2
"Lasing modes"
minimum gain necessary for lasing:
Gain g
Line-width
(<0,1nm)
g  gth
gth
Resonance modes
ok_317_FP_resonator_laser.dsf
m-1
m
m+1
Laser emission
11
04 – Lasers
l
~0,3nm
Click To Edit Master Title Style
Single-Mode Lasers
FP-Laser has some disadvantages:
(i) not single-moded (= e.g. high dispersion sensitivity),
(ii) “Mode hopping“ = center mode changes from lm to lm+1 with changes in modulation current,
(iii) "Mode partition noise" = change of mode distribution of emitted power with changes in modulation current.
For (high end) communication systems:
• DFB-laser (distributed feedback),
• DBR-laser (distributed Bragg reflector),
• MQW-laser (Multi quantum well)
Mirrors of FP-laser replaced by Bragg-grating (BG). BG acts as a mirror, reflects however only one
wavelength (only center mode)  filter
Bragg-grating = cascade of partly reflecting mirrors in distance
m
l
2
,
m  integer
Implemented in semiconductor laser by periodic variation of refractive index
12
04 – Lasers
Click To Edit Master Title Style
DFB and DBR Lasers
Laser structures using built-in frequency-selective resonator gratings.
DBR
DFB
Tunable Lasers:
Tuning of emission wavelength by
(i) changing cavity-length (mechanical stretching)
(ii) changing refractive index (temperature control)
13
04 – Lasers
Click To Edit Master Title Style
VCSELs (Vertical Cavity Surface-Emitting Laser )
Light emission is perpendicular to semiconductor surface
Advantages:
• integration of multiple lasers in an array  WDM application
• On-waver testing possible
14
04 – Lasers
Click To Edit Master Title Style
Laser Rate Equations
Coupled differential equations describing interaction of photons and electrons within active region
dN (t ) I (t ) N (t )


 G (t ) S (t )
dt
qV
te
dS (t )
N (t ) S (t )
 G (t ) S (t )  d

dt
te
tp
Terms used:
= carrier (electrons) density [1/m3]
= photon density [1/m3]
=1,6 10-19As = electron charge
= volume of active layer (≈ 0.510-16m3)
te
= lifetime of carriers (≈ 10-9s at 300K)
tp
= lifetime of photons (≈ 10-12s)
d
= fraction of spontaneous emission, that contributes to lasing (<10-4).
G(t) = g0 [N(t)-N0 ] gain coefficient of stimulated emission
N0
= carrier density at transparency (1.210-24m-3)
N(t)
S(t)
q
V
15
04 – Lasers
Click To Edit Master Title Style
Laser Modeling
We are interested in:
1.) P(t) = optical power (P(t) ~ S(t) )
2.) Df(t) = frequency modulation (Df(t) ~ N(t) )("Chirp")
3.) Noise
I(t)
Numerical solution
of rate-equations
(e.g. Runge-Kutta)
S(t)
P(t)
N(t)
Df(t)
Modulation
current
16
04 – Lasers
z
jDf(t)
Fibre
P(t) e
Df(t)
ok_319_Lasermodell.dsf
Compl. envelope
at fibre-output
Click To Edit Master Title Style
Power - Current Characteristics
From stationary solution (dN(t)/dt=0, dS(t)/dt=0, I(t)=const.) of rate eq.
 minimum required carrier density N>NTh for lasing (lasing threshold)
 minimum required current I>ITh for lasing (lasing threshold)
ITH 
qV
te
NTH 

qV  1
 N0 

t e  g0t p

te in (3.1-4) strongly temperature dependent  empirical formula
T
T0
ITH  I 0e ,
for
T0  50...100 K
Relationship: light-power and injection current:
P
hf T
h d ( I  I TH ) ,
2q

I  I TH
h
h = 6.626 10-34 Ws2 (Planck's constant)
hd = Quantum-efficiency (e.g. 22%)
h= slope of light-current characteristic
17
04 – Lasers
Click To Edit Master Title Style
Direct Modulation of a Laser
From stationary solution (dN(t)/dt=0, dS(t)/dt=0,
I(t)=const.) of rate eq.
 minimum required carrier density N>NTh for
lasing (lasing threshold)
 minimum required current I>ITh for lasing
(lasing threshold)
Step response: 
Bias required in order to avoid
turn-on delay
18
04 – Lasers
Click To Edit Master Title Style
On-Off-Keying with Bias
Bias, so that extinction ratio>0
P
ok_3111_direktmod_laser.dsf
Laser driver
driver circuitry for delivering
sufficient current amplitudes
to laser modulation input.
P(t)
Pmax
Slope= h
Pmin
t
0
ITH
IBias
I
Extinktion ratio:
Imod(t)
t
19
04 – Lasers
ex=
Pmin
___
, exdB=10 lg ex
Pmax
Click To Edit Master Title Style
Large Signal Modulation
20
04 – Lasers
Click To Edit Master Title Style
Laser Chirp
Change in injection current  change in carrier density.
refractive index depends on carrier density  change in refractive index  variation of phase (and thus
frequency) with time = chirp
df (t ) 1 
1 
   g0 ( N (t )  N 0 )  
dt
2 
t p 
= Line-width enhancement factor (= Henry-factor = chirp parameter)
From rate eq. (with d<< 1)
dS (t ) 
1 
  g 0 ( N (t )  N 0 )   S (t )
dt
t p 

I(t)
t
f(t)
we find relationship df/dt (Chirp) with S(t) (Photon density)

df (t )  1 dS (t )  d ln S (t )


 2Df (t )
dt
2 S (t ) dt
2
dt
t
Df(t)
ok_3113_chirp.dsf
rough approximation:
t
df (t ) dS (t ) dP (t ) dI (t )
~
~
~
~ Df (t )
dt
dt
dt
dt
Chirp produces frequency modulation (FM) with amplitude (frequency shift) of several GHZ
 transmitted spectrum is widened (= line-width enhancement)
 after dispersive fiber we expect (in most cases) additional distortion!
21
04 – Lasers
Click To Edit Master Title Style
Small Signal Performance, Laser Frequency-Response
Frequency response for sinusoidal modulation I(t)=I0 cos(mt) above threshold. Gives information on
modulation bandwidth  maximum bitrate
From rate-equations with exponential ansatz and some simplifying assumptions:  linear Diff.eq.
2nd order 
1
H (m ) 
2
 
2D 
1   m   j 02 m
0
 0 
with:
0 
I BIAS / ITH  1
t et p
D0 
I BIAS
2 0t e ITH
1
D0 < 1:  overshoot in step-response
 Relaxation oscillations
22
04 – Lasers
Click To Edit Master Title Style
Laser Noise
Spontaneous emission in laser:
1. Intensity noise
 Relative Intensity Noise (RIN)
 Line-width enhancement ()
2. Phase noise
RIN:
Power Spectral Density (=power in 1 Hz
bandwidth) relative to the mean output power P,
with B = (narrow) measurement bandwidth
P
2
2
/B

ok_3_Laserrauschen.dsf
Pn2 (t ) / B
P
RIN-LDS[dB/Hz]
 P(t )  P 
RIN 
2
ok_3_Laserrauschen.dsf
P
P(t)
-120
P(mW)
1
-160
0,1
t
23
Typical shape:
04 – Lasers
2
1
3
f/GHz
10
Click To Edit Master Title Style
Phase Noise (Laser Linewidth)
 PSD of electrical field with phase noise:




P 
1
1

S Laser ( f ) 



2
2
Df
 2( f  fT )  
1   2( f  fT ) 
1 

 
 
Df
Df


 

Df results from 3dB-bandwidth, typically 10kHz-100MHz
P/Df
P/2Df
Df
ok_3_laserrauschen.dsf
fT
24
04 – Lasers
Lorentzian line
Click
To EditTunable
Master Title
Broadband
LaserStyle
(DBR)
Y-branch laser
Setup:
►
►
►
►
2 Reflector sections (Branches)
1 Multi-Mode-Interferometer (MMI)
1 Phase section
1 Gain section
Principal of operation:
► Wideband tunability (Dl = 40 nm) by Vernier effect in reflector sections
► Fine adjustment by phase section with 0,35 nm wavlength span
25
04 – Lasers
Vernier
Click
ToEffekt
Edit Master Title Style
2 scales with 10% difference
A shift of one scale by dx, leads to a shift of the point where both scales fall together by
Dx = 9 dx.
26
04 – Lasers
LaserTo
Resonator
Click
Edit Master Title Style
Example:
Resonator 1
Reflection
Resonator 2
Wavlength [nm]
Tuning of resonator 2 by 0.34 nm leads to a shift of the overall reflection by 1.7 nm.
Problem: Temperature stability
► Usually requires use of a thermo-electric cooler (TEC)
27
04 – Lasers
Click To Edit Master Title Style
Wrap Up
What you should recall from this chapter:
•
•
•
•
•
•
•
•
•
28
Explain, why a directly modulated laser should be driven above threshold
Plot the PSD of a laser output for a laser linewidth of 10MHz
Plot the PSD of a laser output for a laser linewidth of 0MHz
Explain direct modulation of a laser with the power-current characteristics
What kind of resonator is used in a DFB and a DBR laser?
What is the advantage of VCSELs?
Explain the difference between single-mode lasers and Fabry-Perot lasers
What is the twofold purpose of the active zone in a laser?
Explain the tunability of a broadband DBR laser
04 – Lasers
Lecture
Optical Communications
Modulators and Modulation Formats
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
External Modulators
Directly modulated laser  Chirp!
Alternative: cw-laser followed by an additional external modulator.
Two Types:
1. Electro-absorption modulator (EAM)
2. Mach-Zehnder modulator (MZM)
2
05 – Modulation
Electro-Absorption Modulator
Intensity modulation by changing the absorption properties of modulator material
(III-V semiconductor pn-junction) as a function of applied external voltage
 physical effect: "Franz-Keldish-Effect"
P1(t)=const.
I=const.
Laser
EAM
cw
P2(t)
f(t)
ok_32_modulator.dsf
u(t), Modulation
Modules with DFB-laser und EAM commercially available up to 20 Gb/s
P2 (t )  T {u (t )}  P1 (t )
 Transmission characteristic s(exponential shape)
d (t )
a 1 dP2 (t )
 2pf (t ) 
dt
2 P2 (t ) dt
 a = chirp parameter
(approx. 10 times smaller compared to direct modulation)
3
05 – Modulation
Transmission and Chirp Characteristics
of an EAM
Measured transmission of an EAM
versus applied drive voltage [Lucent
Technologies]
4
Measured Chirp parameter of an EAM versus
drive voltage [Lucent Technologies]
05 – Modulation
Phase Modulator
Phasor Diagramm
Q
Phase modulator
V1
I
Ein
Applied voltage U1, U2 changes refractive index through "Linear electro-optical effect"
("Pockels-Effect")
 propagation constant changes  resulting in a phase change.
5
05 – Modulation
Mach-Zehnder Modulator (MZM)
MZM works as an interferometer:
Splits light into 2 wave-guide arms (coupler).
Applied voltage U1, U2 changes refractive index through "Linear electro-optical effect" ("Pockels-Effect")
 propagation constant changes  resulting in a phase change.
Recombining signal (coupler):
 constructive (in-phase) or destructive (out-of phase) interference
Waveguide
ocn_32_modulator.dsf
U1
1
Ein ,Pin
Eout ,Pout
U2
2
MZM available as integrated optical component (e.g. PLC=planar lightwave circuit)
 LiNbO3 (Lithium-Niobath)
6
05 – Modulation
Coupler
For splitting and combining (optical) signals we need a coupler (optical component).
Here: 3dB coupler with 2 inputs and 2 outputs (2x2 coupler)
Ei1
Eo1
ok_63_bilder.dsf
Input
Output
Ei2
L
Eo2
coupling length
Implementation: melting fibers together (= fiber optic solution), or wave-guides in integrated optics
L= coupling length (a few mm)
Coupler model
2x2 coupler is a MIMO system described by a 2x2 transmission matrix (scattering matrix):
S3dB 
7
1  j L  1 j 
e


2
 j 1
05 – Modulation
MZM Model (Block View)
Ei1
Ei2
1
+ 1/ 2
e j1
j
j
j
j
1
+ 1/ 2
e  j2
oc_32_modulator.dsf
8
1
05 – Modulation
1
+ 1/ 2
Eo1
+ 1/ 2
Eo2
MZM Model (Mathematical Model)
Eo 2

jEi1
1   j1  j2 
e
e

2

 
cos 1 2  e
2
j
1 2
2
 H MZM
With MZM arbitrary amplitude and/or phase modulation of optical carriers possible!
9
05 – Modulation
Push-Pull Operation of an MZM
Push-pull operation of an MZM: 1  2
For
U D  Vp


U1  U 2
 UD
1  p / 2  2
zero output (destructive interference)
1 
p
2Vp
U D
  2
Vp is a characteristic parameter of an MZM
In Push-pull mode, an MZM is an amplitude modulator (no phase modulation, no "chirp")
 p

 
2
H  cos 1 2  cos 1  cos 1  cos 
UD 
2
2
 2Vp

| H |2 
10
 p

cos 2 
UD 
 2Vp

05 – Modulation
MZM in Push-Pull Operation
ocn_32_modulator.dsf
Im{H}
Hpush-pull
Hpush-pull
12
21
1
2
Re{H}
Phasor representation
(upper and lower branches)
0
2 Vp
UD
Field (blue) and power (red) transfer function
Phasor representation
(output power)
11
Vp
05 – Modulation
MZM in Push-Pull Operation (Modulation)
Pout
UBias
Pmax
UD1
p
2Vp
UD

Ein
+
-
Eout
p
UD2
2Vp

ubias
oc_32_modulator.dsf
Vp
MZM-Model
ocn_32_modulator.dsf
Amplitude (intensity)
modulation:
Amplitude (intensity)
modulation with MZM:
Small drive voltage swing
at quadrature bias point:
≈ linear P-U-characteristic
≈ √- field-ampl.-U-charact.
12
05 – Modulation
2Vp
UD
MZM (Lab Photo)
13
05 – Modulation
IQ-Modulator
IQ-Modulator
V1
I
Ein
Q
I
90°
Q
V3
V2
Nested configuration of two MZMs with 90° phase shift in lower
branch.
14
05 – Modulation
Usable for arbitrary
IQ-constellations
Modulation Formats
15
05 – Modulation
Basic Formats (OOK / BPSK)
Q
Q
I
0
I
-A
A
BPSK: Binary Phase Shift
Keying
OOK: On-Off Keying
Coding of one bit per symbol
(MZM sufficient as modulator)
16
A
05 – Modulation
Higher-Order Modulation
Higher-order modulation:
Several bits are coded in one symbol
Reduced symbol rate / tighter spectrum
Higher data rates
(> 100 Gb/s)
Increase in spectral
efficiency
Satisfies future capacity
requirements
Disadvantages:
17
•
Reduced transmission reach
•
Higher complexity of transmitter
and receiver
05 – Modulation
Amplitude Shift Keying (ASK)
Q
01 11 10
00
Q
I
000
0
110 101
I
001 010 111 100
4-ASK
8-ASK
Coding of 2 bits per symbol
Coding of 3 bits per symbol
Gray coding of all symbols
18
011
05 – Modulation
Phase Shift Keying (PSK)
101 -jA
Q
0110
0111
0010
0011
jA
0101
0001
0100
0000 I
1100
-A
A
1000
1101
1001
1111
1010
1110
-jA 1011
QPSK:
Quadrature
Phase Shift
Keying
8PSK:
8 Phase Shift
Keying
16PSK:
16 Phase Shift
Keying
2 bits/symbol
3 bits/symbol
4 bits/symbol
Q
11
Q
011
010
jA
01 I
10
-A
A
00
-jA
001
jA
000 I
110
-A
A
111
100
Requires use of phase modulator
19
05 – Modulation
Quadrature Amplitude Modulation (QAM)
0000
Q
011
Q
11
0100
01
001
010
0001
0101
Q
1100
1000
1101
1001
000 I
I
I
110
10
00
100
111
0011
0111
1111
1011
0010
0110
1110
1010
101
4QAM:
4 Quadrature
Amplitude
Modulation
8QAM:
8 Quadrature
Amplitude
Modulation
16QAM:
16 Quadrature
Amplitude
Modulation
2 bits/symbol
3 bits/symbol
4 bits/symbol
Requires use of IQ-modulator
20
05 – Modulation
System Configuration
21
05 – Modulation
Transmitter Setup with IQ-Modulator
Digital-AnalogConverter
Driver
Amplifier
(linear)
Data
(I)
Data
(Q)
Q
I
I
90°
Q
Laser
f  193.1 THz
(C-Band)
22
IQ-Modulator
05 – Modulation
Transmitter Setup for Polarization Multiplexed
Transmission
Data
(Ix)
Data
(Qx)
Q
Polarization
Beam Splitter
I
I
X-Polarization
90°
Q
I
90°
Y-Polarization
Q
Q
I
Data
(Iy)
Data
(Qy)
23
05 – Modulation
Wrap Up
What you should recall from this chapter:
• Explain the structures of an EAM and of an MZM
• Assume a MZM in push-pull configuration with Vp=5V. Plot the phasors of both arms for 0V,
2.5V, 5V, 10V DC voltage
• Plot the MZM phasors for quadrature biasing.
• Give the biasing and drive voltage conditions for an MZM with (nearly) linear intensity
modulation
• Give both, the power and the electrical field for a MZM at quadrature bias
• Explain how to connect the 4 contacts of an MZM for (i) push-pull configuration and for
(ii) pure phase modulation
• Is it possible to use an EAM as a phase modulator?
• How does an optical IQ-modulator work?
• What higher modulation formats are used in optical communications?
• How does a transmitter look like for optical IQ-modulation and polarization multiplexed
transmission?
24
05 – Modulation
Lecture
Optical Communications
Receivers
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Optical Receivers
Block diagram
Optical
Optical
preBPamplifier filter
Photo diode
=O/E-conv.
Transimpedance
amplifier
EDFA
p1(t)
Pulsformerfilter
Limiteramplifier
Sampling+
decision device
=slicer
TIA
p(t)
i(t)
Data
u(t)
Clock
Optical
front-end
oc_5_empf.dsf
2
06 – Receivers
CDR
(Clock&Data
Recovery)
Clock
recovery
Optical Receivers: Components
• Optical preamplifier:
Optional e. g. for long distance transmission. Increases overall receiver
sensitivity, however, adds ASE (amplified spontaneous emission) broadband
noise  optical BP filter
• Photo diode:
optical/electrical converter
• Trans-impedance amplifier (TIA):
low noise preamplifier
• Pulse-former filter (Matched filter, Nyquist filter):
optional or implemented in TIA.
• Limiting amplifier
for eliminating signal level variations (overshoots) prior to CDR
• Clock and data recovery (CDR)
e. g. with PLL for clock recovery. Clock for sampler and decision device (slicer)
and successive electronic stages (e.g. SDH-demultiplexer)
3
06 – Receivers
Optical-Electrical Converter
Photo-diodes are realized either as PIN-diode or APD-diode
Requirements:
• high sensitivity
Responsivity and quantum efficiency for pin-diodes
• low intrinsic noise
• high bandwidth
Semiconductor materials:
Material with band gap suitable for received
wavelength.
Si (~0.8 nm)  suitable for joint integration of
photo diode and electronic circuitry on one
single chip, opto-electronic ICs
InGaAs, InGaAsP, Ge (~1.2-1.6 nm)  large
range of wavelengths
4
06 – Receivers
Absorption Coefficient 
•
•
•
5
06 – Receivers
Wavelength c at which  becomes 0 is
called cutoff wavelength
Material can only be used as
photodetector for  < c
Indirect bandgap materials (Si, Ge) show
can be used as photodetector (however,
with reduced absorption edge steepness)
PIN Photo Diode
PIN-Diode: pn-junction with intrinsic (i.e. weakly doped) layer of some m thickness where
absorption of photons takes place, pn-junction backward biased
Absorption of photons pairs of electrons/holes electrical current
i(t )  R  P(t ) ~ R | E (t ) |2
q
R    R=Responsivity
hc
 =Quantum efficiency<1 (e.g.90%), q=electron charge, h=Planck's constant (6.63  10-34 J/Hz)
Voltage/current characteristic of a photodiode
6
06 – Receivers
Reverse Biased Operation
Depletion
region
Diffusion
region
w~1/2
•
Elctron-hole pairs are generated through
absorption
Large electric field inside of depletion region
accelerates electrons and holes to opposite
directions
Drift component dominates over diffusion
component
Resulting flow current is proportional to the
incident optical power
•
•
•
7
06 – Receivers
Drift
region
Rise Time
•
Rise time Tr is defined as the time during which the response increases from 10 to 90% of its final output
value
When the input voltage across an RC circuit changes instantaneously from 0 to V0 the output voltage
changes as
•
=
•
1 − exp −
The rise time is then calculated by
=
9
•
In a photodetector a transit time tr needs to be added to consider the time before the carriers are
collected after their generation through absorption of photons
•
tr can be thus reduced by decreasing the width W of the intrinsic region. However, for W<3 the
quantum efficiency  decreases significantly.
•
There is a tradeoff between bandwidth and responsitivity (speed versus sensitivity) of a photodetector
8
06 – Receivers
APD (Avalanche Photo Diode)
Very high backwards-bias voltage (>100V)  Photons produce electron/hole
pairs  additional pairs of electrons/holes by impact ionisation = avalanche
effect
q
RAPD  1  ,
RAPD  M  R, M =avalanche gain (e.g. 100)
hc
high gain, but usually lower bandwidth, more intrinsic noise
•
•
•
9
An accelerated electron can generate a new electronhole pair
The energetic electron gives part of ist kinetic energy to
another electron in the conduction band (leaving behind
a hole)
Many secondary electrons and holes can be generated
06 – Receivers
Front-End Amplifiers
Photo diode with parasitic C (small signal equivalent circuits)
Load
ok_5_empf.dsf
Ip
Cp
Photo
diode
RL
+A
-
Load
Rp=RL
High-impedance amplif.
Ip
RL
-A
+
Cp
Photo
diode
Load
Rp=RL/(A+1)
Trans-impedance amplif.
1.) low noise power (resistor noise):  value of RL as large as possible!
2.) high bandwidth:  load resistor RP seen from photo diode as small as possible!
 usually transimpedance amplifier (TIA) used (additional advantage: high dynamic range for optical input
signal), which is a current-to-voltage converter
10
06 – Receivers
Noise Performance
Quantum Limit
The process of current generation from incident photons is of statistical nature
modelled as a shot-noise process with Poisson probability distribution (approximately
Gaussian)
Photon rate (= number of photons arriving at photo diode (PD) per second), [rp]=1/s
rp 
P(t ) P(t )

T , where hfT Energy of one photon [Ws]
hf
hc
T
We consider binary on/off keying (0,1 signalling) with P1=optical received power at photo diode for “1”-level.
Then:
PT
N 1b
hfT
=mean number of photons arriving at PD during the "1"=bit intervall of duration Tb
and from Poisson probability distribution, the probability that a number of n photons arrive
during the “1”-bit interval is:
n
 PT
1 b
PT
1 b



 hfT   e hfT
n!
11
06 – Receivers
Minimum Number of Photons
An ideal on/off receiver (photo detector) expects zero photons to arrive during the “0” bit interval
and at least one photon to arrive during the “1” bit interval
 Bit error, if in “1” bit interval (dk=1) n=0 photons arrive
W {n  0 | d k  1} 
1
2


e
PT
1 b
hfT

1 N
e
 BER
2
W {d k 1}
Quantum-limit:
1
BER   e  N  10(lg 2  lg e N )  10(0.3 0.4343 N )
2
BER = 10-9  N =20 photons per Tb  minimum received power P1
BER = 10-12  N =27 photons per Tb  minimum received power P1
12
06 – Receivers
Noise Performance of Real Receivers
Noise Contributions:
1. Shot noise (see above), Poisson probability density function
2. Thermal noise of receiver electronics, Gaussian
3. Optical noise, if optical preamplifier is used
first we consider only 1. and 2. (3. will follow in next lecture: optical amplifiers)
13
06 – Receivers
Approximation for Shot Noise (PIN-Diodes)
Photo current = Superposition of (filtered) current pulses occurring at photon rate rp.
If the photo current is well above quantum limit,
"0"
i (t )  isignal (t )  ishot (t )
"1"
"0"
ok_5_rauschen.dsf
isignal (t )  R P(t )
mean value (≈const. during Tb)
ishot (t) (shot noise) ≈ Gaussian random process
with zero mean and variance 2shot within
electrical bandwidth Be:
2
 shot
 2q  Be  isignal (t )  2q  R  P(t )  Be
Shot noise power is proportional to signal power (P1(t))
 “1” is more severely disturbed than “0”!
For APD-Diodes
Useful signal
isignal (t )  M R P(t )
Shot noise: (increases with increasing avalanche gain)
2
 shot
 2q Be M 2 FA ( M ) R  P(t )
with
FA ( M )  k A M  (1  k A )( 2  1 / M ) = excess noise factor
kA = ratio (0<kA<1) of ionisation coefficients
14
06 – Receivers
Tb
Photons
t
Excess Noise Factor
Excess noise factor as
a function of the
average APD gain M for
several values of the
ionization-coefficient
ration kA
15
06 – Receivers
Thermal Noise
Thermal noise based on resistor noise power spectrum density (PSD)
Noise power measured in receiver bandwidth Be
 kT 
2
 therm
 2
  2 Be
R 

It2
with: k = Boltzmann's const. 1,38·10-23 Ws/K
T = absolute temperature
R = load resistor
PSD of current (current density), typically It≈10…20 pA/√Hz
Electrical receiver bandwidth: according to Nyquist bandwidth for cancelling ISI (Inter-Symbol-Interference)
e.g. 10 Gb/s  Tb=100ps
ok_5_rauschen.dsf
5 GHz
in practice:
Be 
1
2Tb

1
Tb
-Tb 0 +Tb
100ps
(5 ... 10 GHz at 10Gb/s)
16
06 – Receivers
t
-fb/2
0
+fb/2
f
Thermal Noise Impact of Trans-Impedance Amplifier
with Noise Figure Fn
Definition of the noise figure:
(SNR)in
Fn 
( SNR )in
( SNR )out
(SNR)out
ok_5_rauschen.dsf
Thermal noise power after amplifier:
2
 therm

4kT
 Fn  Be
R
Total noise power
Shot noise and thermal noise are statistically independent  total noise power:
2
2
 2   shot
  therm
 2qR  Be  P (t ) 
17
4kT
 Be
RL
06 – Receivers
Common Values
18
06 – Receivers
Receiver Front-End Model
Simulation model with noise sources:
Poisson
noise
source
2
_
E(t)
R=
P(t)
q

__
hf T
+
+
+
H(f)
i(t)
isignal(t)
id(t)
Gaussian
dark current
noise
source
Magnitude squared operation of photo diode
Dark current = residual current with no light input (reverse biased diode)
19
06 – Receivers
ok_5_empf.dsf
Clock Recovery
20
06 – Receivers
Decision Circuit
21
06 – Receivers
Wrap Up
What you should recall from this chapter:
•
•
•
•
•
•
•
•
•
•
22
Give the quantum limit for BER=10-3 in terms of average photons per bit and in received power
Which semiconductor materials are suitable in 3rd optical window (1550 nm region)?
Discuss the use of Si as semiconductor material in optical communications
Compare the shot noise variance and thermal noise variance using typical parameter values.
The mean optical power at receiver is 3dBm and the extinction ratio is 10 dB. Calculate the
power levels for “0” and for “1”
Explain why optical detection is always random in nature
Calculate the signal to noise power (S/N) for the electrical current at optical front-end output,
assuming shot noise and thermal noise
Shot noise power is proportional to signal power. Explain how this fact can be noticed in the eye
diagram.
Explain how the threshold in the slicer must be adjusted for the above effect
Compare pin-diode and APD noise performance
06 – Receivers
Lecture
Optical Communications
Optical Amplifiers
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Optical Amplifiers
General Concepts
Applications:
a) compensation of loss (fiber, insertion loss of components)
b) (rarely) for making use of non-linear optical properties of optical elements
(optical network elements like switches, wavelength converters,…)
Application areas:
a) In digital long-haul transmission systems as power amplifier (booster-ampl. in
transmitter), pre-amplifier (in front of photo diode), in-line amplifier (ampl. within
transmission link)
b) In access networks (PONs - Passive Optical Networks) at the central office (optical
line terminal): compensates for the loss of 1:N-star couplers at the remote node
2
07 – Amplifiers
3-R Regeneration
Prior to the optical amplifier era (≈1995): Digital transmission with o/e/o repeaters
(regenerators) inserted in transmission link with
3-R-Regeneration:
1. Reamplification (signal amplification)
2. Reshaping (signal shaping e.g. through limiting amplifier)
3. Retiming (clock recovery and clock jitter cleaning)
o/e
electrical
receiver
transmitter
amplification
clock recovery
data decision
laser driver
e/o
ok4_repeater.dsf
• complex and expensive device
• works at fixed bit rate and modulation format, i.e. not transparent
• for WDM not useful due to high cost (one repeater per WDM channel!)
• very good signal cleaning
3
07 – Amplifiers
Example of 3R Regeneration vs. Optical Amplification
3R Regeneration
80km
Significant costs
due to optical-electrical conversion
80km
80km
80km
80km
80km
80km
80km
80km
1550
1550
1550
1550
1550
1550
1550
1550
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
1550
1550
1550
1550
1550
1550
1550
1550
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
10G
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
RPTR
Optical Amplification
10G
10G
10G
10G
10G
10G
10G
WDM
10G
10G
TERM
10G
10G
10G
10G
10G
10G
10G
4
~80 km
EDFA
~80 km
07 – Amplifiers
EDFA
~80 km
10G
10G
10G
10G
10G
10G
10G
10G
WDM
10G
TERM
10G
10G
10G
10G
10G
10G
10G
Optical Amplifiers
• only 1R-Regeneration, no improvement (signal cleaning) of transmission impairments
as e.g. dispersion, PMD, jitter
• reshaping (optical limiting amplifiers) in optical domain very difficult
• transparent
• amplifies many WDM-channels with only 1 amplifier (wide amplifier bandwidth of several
THz)
• 2 Types:
a) fiber amplifiers (Erbium-Doping: EDFA for 3rd opt. window, Praseodymium-Doping:
PDFA for 2nd opt. window) and
b) semiconductor opt. amplifiers (SOA, 2nd und 3rd opt. window)
5
07 – Amplifiers
Semiconductor Optical Amplifiers
Description and properties:
• optically active medium = semiconductor
resonator (anti-reflection coating)
=> similar to semiconductor laser without
• due to semiconductor geometry (rectangular geometry of active zone)
dependent
=> polarization
• Problem of fiber-chip interconnect => coupling loss (insertion loss)
• non-linear saturation effects => intermodulation in a WDM system with many wavelength
channels => for WDM-amplifier not a good solution
• Gain at both  = 1.3 m and 1.55 m with very large gain bandwidth (>100nm) => useful
for both optical windows
• as integrated optical component well suitable for miniaturization
• Applications as optical switch and wavelength converter in WDM-networks (makes use of
non-linear properties)
Block diagram:
6
07 – Amplifiers
Fiber Optical Amplifiers
Silica (glass) fiber doped with rare earth elements is used as active amplifying medium.
Typically used dopents:
a) Erbium (amplification in 3rd opt. window), commercially available, widely used
b) Praseodymium (amplification in 2nd opt. window), low commercial interest
here: EDFA = Erbium Doped Fiber Amplifier
Er fiber
Signal
ASE
980 nm
7
l
1480 nm
07 – Amplifiers
Output spectrum
Noise

λ
Isolator
Filter
Filter
Tap
VOA
Coupler
Isolator
EDFA Block Diagram
• Coupler adds pump laser signal and (modulated) input signal
• Erbium-doped fiber: silica fiber where the core is doped with Er-Ions (length: several meters
e.g. l = 10m)
• Optical isolator to reduce oscillations due to reflection at connectors, components, etc.
• Pump laser: provision of (optical) energy. Wavelength is given through energy levels of Er.:
pump = 980nm or pump = 1480nm, Ppump ~ 50mW
• Optical filter for noise reduction (optional)
• other arrangements are possible: reverse pumping, bi-directional pumping, remote pumping
(undersea systems)
8
07 – Amplifiers
Setup of a 2-Stage Optical Amplifier
Stage 1
Preamp
In
C/L
Stage 2
VOA
Booster
95:5
95:5
Mon IN
OSC/RX
Inter Stage
12 dB
Pump
upgrade
Mon OUT
OSC/TX
OSC: Optical Supervisory Channel
VOA: Variable Optical Attenuator
only for C-Band
L-Band
L-Band
22
dB
21
dB
12 dB
30 dB
log(P)
VOA:1-13 dB
max. 8 dB
l
9
07 – Amplifiers
Out
C/L
Interaction between Er-Ions and Photons
Absorption
Spontaneous emission
Stimulated emission
An arriving photon hits an
Er-ion in ground state and
raises an electron up into
laser level. The photon is
absorbed
An electron in excited state
(laser level) falls
spontaneously from laser
level to ground level and a
photon is generated.
A photon hits an Er-ion in laser level
and stimulates its transition to ground
level. Another photon is emitted. This
photon has the same frequency, phase,
polarization and direction as the
incoming photon which stimulated this
radiation process. This is a light
amplification process.
Laser level
Ground level
10
07 – Amplifiers
Energy Levels in Erbium
Energy
Level Nr.
Pump
Three energy levels of
Er-ions in silica material
(3-level scheme):
Energy difference  Wavelength
Stimulated
Emission
11
E  E pump  E ground  h  f 
07 – Amplifiers
hc
 pump
Optical Gain
pump level
laser lavel
980nm
energy
E3
E2
s
p
1530nm
absorption
spontan.
emission
ok_432_energieniveau
ground level
E1
stimulated
emission
• Due to energy of pump laser (980nm), carriers move from E1  E3 by absorption
• Carriers at level E3 have short lifetime of several s. Transition to E2 by emission of heat.
• Carriers at level E2 have long lifetime of several ms!  meta-stable state
• Inversion state with high carrier density at level E2: N2 > N1
• Therefore signal light at ~1530 nm is amplified by stimulated emission (E2  E1).
• Pump energy levels are not discrete but are split in many sub levels ("Stark-splitting").
Therefore we have a broad gain bandwidth in the range of 1525-1570nm with wavelength
dependent gain
• Spontaneous emission noise within signal wavelength is also amplified
 Amplified Spontaneous Emission (ASE): un-polarised wideband noise distortion
12
07 – Amplifiers
Energy
Broadening of the Energy Levels
•
•
13
Homogeneous broadening of the energy levels arises from the interactions with phonons of the glass.
Inhomogeneous broadening is caused by differences in the glass sites where different ions are hosted.
07 – Amplifiers
EDFA Characteristics
Typical gain spectrum of an EDFA
Sopt()
ok_432_energieniveau
1530
Pump power and Saturation
14
07 – Amplifiers
1560
/nm
Gain Flattening Filter
Issues:
15
•
Synthesis of the filter function (reproducability)
•
Temperature dependence of the active fiber
•
Polarization dependence of the gain
•
Inhomogeneous saturation of the EDFA
•
Dependence of the gain spectrum on the pump wavelength
07 – Amplifiers
Gain in dB
Dynamic Tilt of the Gain Spectrum
Wavelength in µm
16
07 – Amplifiers
•
Gain must be adjusted to
the attenuation on the link
•
A change in gain tilts the
spectrum
Gain in dB
Amplifier Saturation
Output Power in dBm
17
07 – Amplifiers
Optical Power in dBm
Signal Power Evolution
Pump power
Signal power
ASE+
ASE-
z in m
18
07 – Amplifiers
Comparison of Major SOA and EDFA Characteristics
19
Type of
amplifier
Pumping
source
Carrier
lifetime
Insertion
losses
Center
wavelength
(gain bandwidth)
Physical
length
Inputoutput gain
Typical
noise
figure
SOA
Electrical
(~100mA)
~1 ns
~3dB
1.3 or 1.55 m
(50-75nm)
~500m
10-15dB
8-12dB
EDFA
Optical
(~20100mW)
~1 ms
~0.2dB
1.55 m
(30-45nm)
~10m
10-40dB
4-5dB
07 – Amplifiers
Noise in Optical Amplifers
20
07 – Amplifiers
EDFA Noise
EDFA noise = amplified spontaneous emission (ASE) noise
= additive white Gaussian-noise in the optical domain
with mean optical noise power per each of the two polarizations (x and y):
x
PASE
 nsp  h  fc (G  1) Bopt

x
N ASE
Bopt
-fT
x
S ASE
(f)
1 x
1
N ASE  nsp  h  f c (G  1)
2
2
ok_434_EDFA_rauschen.dsf
NASE/2
0
+fT
f
nsp = spontaneous emission factor nsp >1, typically nsp ≈1.5…3
G
= optical power gain of EDFA, e.g. G ≈400 (26dB)
Bopt = optical bandwidth
h
= Planck’s constant
ASE noise is unpolarized and occurs in both polarizations (x-pol. and y-pol.)
with total noise power in both polarizations:
x
PASE  2  nsp  h  f c (G  1) Bopt  2 N ASE
Bopt

x
N ASE
21
07 – Amplifiers
Noise Calculation with EDFA Pre-Amplifier
Optical field at photo receiver input
E (t )  2GPrec (t )  cos(2 f ct   )  nASE (t )
Decompose BP-noise into in-phase and quadrature component
E (t )  2GPrec (t )  cos(2 fct   )  niASE (t )  cos(2 f ct   )  nqASE (t )  sin(2 f ct   )
Optical instantaneous power (squaring of BP optical field and taking low pass components only)
1 2
2
E 2 (t )  GPrec (t )  2GPrec (t )  niASE (t ) 
niASE (t )  nqASE
(t )
2

22
07 – Amplifiers

Signal-Spontaneous Beat Noise Power
Photo current:
iP (t )  R  E 2 (t )
Calculate ACF Ripip(t) and by F.T. power spectrum density PSD Sipip(f) of ip(t)
Si pi p ( f ) / R 2  G 2 Prec 2  2GPrec N ASE Bopt  ( N ASE Bopt ) 2    0 ( f )  2GPrec  SiASE ( f )  2 SiASE ( f )  SiASE ( f )


Signal-spontaneous beat noise power after electrical filter of single sided Bandwidth Be:
2
2
 sig
 spont  4 R GPrec N ASE Be
23
07 – Amplifiers
Spontaneous-Spontaneous Beat Noise Power
Si pi p ( f ) / R 2  G 2 Prec 2  2GPrec N ASE Bopt  ( N ASE Bopt ) 2    0 ( f )  2GPrec  SiASE ( f )  2 SiASE ( f )  SiASE ( f )


Spontaneous-spontaneous beat noise power after electrical filter of single sided Bandwidth Be:
2
2 2
2 2
 spont
 spont  2 R N ASE  2 Bopt  Be  Be  4 R N ASE Bopt Be
may be reduced by
reducing optical Bandwidth Bopt:
typical values: G>10dB, Bopt>2Be, , therefore
2
 sig
 spont
2
  spont
 spont
2
  shot
Signal-spontaneous beat-noise is dominating!
24
07 – Amplifiers
Noise Figure of an EDFA
Typically the noise contribution of an EDFA is given by the noise figure Fn
Fn 
SNRinp
SNRout
 2nsp
nsp  1
where SNR is measured with a photo detector in the electrical domain
Therefore we find: "Best case" noise-figure: 3dB, typically: 4...7dB
25
07 – Amplifiers
Optical Signal-to-Noise Ratio (OSNR)
OSNR can be measured with OSA (Optical Spectrum Analyzer).
Typical result of OSA measurement of WDM signal:
OSA measurement principle:
optical
BP
BW=Bm
variable fcenter
A/D
conv.
Signal
proc.
Display
PD
Measurement of optical power within
the resolution bandwidth (RBW) Bm of
opt. BP for various BP center
frequencies (frequency sweep).
26
07 – Amplifiers
Amplifier Chain
Booster
Inline
RX
TX
Power
Distance


Noise Figure (G >> 1) F  PASE h  f ref  G  Bref
> 3dB, typ. 6.5 dB
F  h  f ref  Bref
1
P
P
 ASE  ASEopt 
OSNRlin , Bref
PAv G  Pin
Pinopt
1 EDFA:
OSNRdB , Bref 0,1nm  58dBm  10 log
F
Pinopt
Amplifer chain with N similar fiber spans (F and Pin in dB) :
Fi
OSNRdB , Bref 0,1nm  58dBm  10 log  opt
 58dBm  F  Pinopt  10 log N
i Pin
27
07 – Amplifiers
OSNR Measurement
Measurement of optical power within the resolution bandwidth (RBW) Bm
of opt. BP for various BP center frequencies (frequency sweep).
x
Noise pwr. measurement: Pnoise  PASE  2 N ASE  Bm
Signal pwr. measurement Psig ,m  PBP (t )  S signal ( f  fc )  Bm if Bm <≈ signal BW
Psig ,m  PBP (t )  Psignal
if Bm >≈ signal BW
with Ssignal = PSD of modulated opt. signal
Full signal power is directly measured, if RBW Bm is larger than signal BW!
28
07 – Amplifiers
OSNR Calculation
According to standardization OSNR is given with resp. to
0.1 nm noise BW, i.e. 12.5 GHz BW in Hz @1550nm
OSNRref 
OSNRref 
29
Psignal
Psignal  Bm
Psignal Bm
Mean opt. signal power




x
x
Noise power in 0.1nm ref. BW 2 N ASE
P
 Bref 2 N ASE  Bm  Bref
noise Bref
GPrec
x
2  N ASE
 Bref

GPrec
 Prec 
2  nsp h fc (G  1)  Bref
07 – Amplifiers
1
Fn

1
h fc Bref
Wrap Up
What you should recall from this chapter:
• Give the bandwidth of an EDFA in THz. How many WDM channels fit in this bandwidth
(approximately)?
• Give applications for SOAs
• Explain 3-R-regeneration
• Why does an EDFA amplify only in the 3rd optical window?
• Compare basic OSA and EDFA properties
• What is the physical source for EDFA noise
• Consider an inline EDFA: Describe the noise model in the optical domain.
• Consider an EDFA pre-amplifier: Describe the noise model after the photo detector
• Identify the noise power contributions of a pre-amplified optical receiver
• The noise figure of an EDFA is given (data sheet) as Fn=5dB. Calculate nsp
30
07 – Amplifiers
Lecture
Optical Communications
Optical Filters
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Optical Filters
Applications:
• Noise reduction (ASE noise of optical amplifiers)
• De-multiplexer in WDM-systems  Bandpass filter bank for selection of (wavelength-)
channels, bandwidth ≈ channel spacing
1
2
3
4
1 2 3 4
1 2 3 4
MUX
DMUX
1
2
3
4
• Mux and Demux in network elements (add-drop multiplexer, wavelength routers)
2
08 – Filters
Applications
• Dispersion compensation (delay filter with linear group delay)
g(Df)|Filter
fT
f
g(Df)|SSMF
ok_6_filteranwend.dsf
• Equalization of frequency response of EDFA (power gain spectrum is not flat!) .
3
08 – Filters
Technology & Properties
Technologies:
• Integrated optical wave-guides based on Si, InGaAs, polymer  planar light-wave
circuits (PLC) = photonic integrated circuits (PIC)
• Free space optical filters
• Filters based on optical fibre
Properties:
• Optical filters can be described by transfer functions H(f) (magnitude |H(f)| and phase
b(f) = -arg{H(f)} response) for the optical field  power transfer function |H(f)|2
• Filter function in bandpass domain at optical fc. May be transformed to equivalent LP
domain by BP-LP transformation
• We may want to tune the center frequency (tuneable filters) or the filter bandwidth
4
08 – Filters
Filter Parameters

Attenuation

Bandwidth (1dB, 3dB)

Crosstalk (Isolation)
CW
1dB
 To adjacent channels
 To non-adjacent channels
I ADJ
 Phase response
I NADJ
 Dispersion
 Ripples

Polarization dependence
 Polarization mode dispersion (PMD)
 Polarization dependent loss (PDL)


Passive / active
 Is temperature control required?
5
08 – Filters
Ci

Ci+1
 Ci+2
Fabry-Perot Filter (Dielectric Filter)
Also called “etalon” (e.g. used as laser resonator)
Cavity (Resonanzraum)
- z
E0 t1e
t1
n
E0t1t2e- L
r1
r 2 t2
E0t1t2r1r2e- L
L
Facet
(Spiegel)
oc_6_filter.dsf
z
t1,t2: transmission- r1,r2 reflection coefficients of facets
2 n
2 n f
= /2 j
Propagation constant:  =  / 2  j  =  / 2  j

c
E-field at right output of mirror (facet):
Et = E0t1t2e
6
 L
 L
1  r1r2e 2 L  (r1r2e 2 L ) 2   = t1t2e
E

 1  r r e 2 L 0
12
08 – Filters
Calculation of Transfer Function
GFP
| Et |2
| t1t2 e  L |2
=
=
| E0 |2 |1  r1r2 e2 L |2
With power reflection coefficient:
R1 = r12 , R2 = r22
and no loss at facets:
GFP
finally for
t1 = 1  r12 , t2 = 1  r22
(1  R1 )(1  R2 )e  L
=
(1  R1 R2 e L ) 2  4 R1 R2 e L sin 2 (  L)
R1 = R2 = R,   0
GFP ( f ) =
7
t12  r12 = 1
1
2
L
2 R
2 n L O
1 M
sin(
f )P
1

R
c
N
Q
08 – Filters
Power Transfer Function
In f periodic transfer function
GFP(f) = max if:
f =k
c
, k = 0,1,2,...
2nL
i.e. choose n and L such that waves add constructively at filter output
8
08 – Filters
Calculation of Free Spectral Range
Free Spectral Range (FSR) = distance between peaks
Df =
c
2nL
Full Width at Half Maximum (FWHM) bandwidth:
BFWHM =
FG
H
c
1 R
arcsin
nL
2 R
IJ
K
Finesse:
F=
Df
BFWHM

 R
1 R
for large
R 1
Typical values: insertion loss 1…2dB, Finesse > 150
9
08 – Filters
Filter Tuning
Change Cavity-length L or refractive index n by
• Mechanical displacement of mirrors (facets)
• Piezo-electrical material  Cavity length is reduced by ext. appl. voltage
Multistage Filters
Cascade of F-P filters with various values of FSR
10
08 – Filters
Bragg Gratings
A Bragg Reflector is a periodic array of reflective “mirrors” (made from any boundary surface
like refractive index step changes). Maximum reflectivity occurs, if distance between mirrors
is such that reflected waves from all mirrors superimpose constructively. I.e. if the distance of
mirrors is related to half wavelength, resulting in full wavelength optical path difference of all
reflected waves.
11
08 – Filters
Fiber Bragg Gratings
Piece of single mode fiber, where “mirrors” are implemented by
refractive index variations of fiber core along z.
Interaction between forward and backward travelling waves
described by a pair of coupled mode equations
Solution for reflected optical field (for uniform grating)
12
08 – Filters
Fiber Bragg Grating Properties
Frequency response for the reflected optical field:
r ( L,  ) =
| A2 ( z = 0) |
 j B sinh (L)
=
| A1 ( z = 0) | j  cosh (L)   Dk sinh (L)
with:
B =
 (n3  n2 )
h

Dk =
1
1

 /(2neff ) 
 =  B2  (Dk ) 2
where h = fraction of
wave intensity in core (e.g. 0,6)
Dn = n3  n2
typically 10-5 …10-3
Maximum power reflectivity R=|r|2 at
Bandwidth:
Bragg wavelenght:
D =
2
Rmax = R ( Dk = 0) = tanh ( B L)
13
08 – Filters
B2
 neff L
 2  ( B L) 2
Spectra
14
08 – Filters
Applications
Band pass filters: a circulator drops the reflected (backwards) wave (4) at port 3
Band stop filter: transmitted wave
Add-Drop-Multiplexer in WDM-Networks BP und Band stop filter for channel selection
15
08 – Filters
Fiber Gratings for Dispersion Compensation
Dispersion in anomalous regime (e.g. D=+17ps/(nm  km)):
Increasing wavelength  increasing group delay, linearly increasing group delay over 
therefore we need: a filter, with linearly decreasing group delay
and constant magnitude in a wide frequency range  flat top BP filter
 Chirped Fibre-Bragg-Grating
16
08 – Filters
Working Principle
ok_6_FBG_dispersionskomp.dsf
L
large 
small 
max
min
large (red) are reflected at beginning of
FBG  short delay
small (blue) are reflected at end of FBG
 large delay
 delay compensation = Dispersion
compensation
17
08 – Filters
Optical Delay-Line Filters
Basics
IIR-filter (Infinite Impulse Response), recursive filter, filter degree n
(=ARMA-filter (Auto-Regressive Moving Average))
x(t)
bn
+
-cn
ok_64_dig_filter.dsf
bn-1
T
+
T
-c n-1
b1
+
b0
T
y(t)
-c1
y (t ) = bn x(t  nT )  bn 1x(t  (n  1)T )  ...  b1x(t  T )  b0 x(t )
 cn y (t  nT )  cn 1 y (t  (n  1)T )  ...  c1 y (t  T )
n
 b z 
H ( z) =
Y ( z)
=  =0
n
X ( z)
1   c z  
 =1
Filter with poles and zeroes in complex z-plane
18
08 – Filters
FIR Filter
FIR-filter (Finite Impulse Response), non-recursive filter, filter degree n (MA-filter)
x(t)
T
b0
T
b1
T
ok_64_dig_filter.dsf
bn
+
+
n
y (t ) =
y(t)
n
 b x(t  T )
H ( z) =
 =0
 b z v
 =0
Filter with zeroes in z-plane, all poles at z=0
n
H( f ) =
 b e
 =0
19
 j 2 Tf
n
h0 (t ) =
 b  0 (t  T )
 =0
08 – Filters
coeff. = impulse response
Phase and Frequency Response
FIR-filter has linear phase, if all coefficients are symmetrical:
m1 = multiplicity of zero at e jT = z = 1
b = ( 1) m1 bn 
FIR and IIR: frequency response periodic with  = 2 / T
H ( ) = H (  m
2
)
T
m integer m = 0,  1,  2,...
Normalisation:
e j 2 fT = e jT = e j = z 1 = e sT
20
08 – Filters
Digital vs. Optical Filters
Digital filters: T=sampling interval (delay by 1 sampling interval), frequency response
is periodic with f s = 1/ T . We are interested (in most cases) in the spectral range
0  f  f s = 1/ T
Optical filters: T=time delay of a delay line (e.g) (we assume time delays are integer
multiples of an elementary delay T in order to be able to apply z-transform).
Periodicity = free spectral range (FSR). We are interested in the frequency range (i.e.
the period) close to optical carrier frequency (e.g. 193 THz)
dig. LP-filter
ok_64_dig_filter.dsf
0
0
1/T
1
2/T
2
f

opt. BP-filter(=LP in equiv. baseband
for compl. envelope)
fT
ok_64_dig_filter.dsf
0
0
21
1/T
1
(m-1)/T
m-1
m/T
(m+1)/T
m
m+1
optical
carrier frequency
08 – Filters
f

Optical Delay-Line Filters
Basic building blocks: Signal splitting, delay, coefficients, adders
by choosing appropriate
Requirements:
Adaptive, reconfigurable
parameters (coefficients,
flexible frequency resp. designs
degree, etc.)
Delay lines: wave-guides of appropriate length DL :
speed of wave: v =
c
m DL
 2 108 =
n
s
T
DL
T
FSR
2cm
100ps
10GHz
0,2cm
10ps
100GHz
for n  1.46 (fibre)
Signal splitting and combining: directional couplers
Coefficients:

coupling ratio of splitting couplers

attenuator / opt. amplifier (EDFA)

phase shifter (negative and complex coefficients are possible!)

modulators (EAM,MZM) fast reconfigurable  adaptive optical filter
22
08 – Filters
Mach-Zehnder-Filters
Single stage optical FIR filter
Schematic
coupler 1
coupler 2
Input 1
Output 1
Length
difference DL
ok_63_bilder.dsf
Input 2
Output 2
Two couplers connected via two paths of different lengths.
coupler 1:
c
S1 =  1
 js1
c1,2 = cos(1,2 L1,2 )
s1,2 = sin(1,2 L1,2 )
23
js1 

c1 
coupler 2:
c
S2 =  2
 js2
where L= coupling length,
= coupling coefficient
08 – Filters
js2 

c2 
Mathematical Model
length difference DL
 Phase shift:
DL  = DL
 delay:
DT =
2 n

= DL
2 n
f = D
c
D
n
= DL
2 f
c
delay in frequency domain:
e j DT  = e j 2DT  f = z 1 = e j
( = DT  )
Model MZ-filter:
Ei1
Ei2
c1
+
js1
js2
js1
js2
c1
+
1
 Eo1    s1s2  c1c2 z


=
 Eo 2   j ( s1c2  c1s2 z 1 )
24
c2
z-1
+
Eo1
ok_63_bilder.dsf
c2
+
Eo2
j ( s1c2  c1s2 z 1 )   Ei1   H11 ( z ) H12 ( z )   Ei1 

=

1   Ei 2   H 21 ( z ) H 22 ( z )   Ei 2 
c1c2  s1s2 z

08 – Filters
= non-recursive filter functions of 1st order
Filter coefficients: coupling ratio in coupler 1 and 2.
Complex filter coefficients are possible!
Example
Example: coupler 1 = coupler 2 = 3dB-coupler:

c1 = c2 = 1/ 2 ,
s1 = s2 = 1/ 2
Ei 2 = 0
Transfer functions at out 1 and out 2

1 1
1



1
1
Eo1 ( z ) = H11 ( z ) Ei1 ( z ) = (1  z 1 ) Ei1 ( z ) =  z 2  z 2  z 2  Ei1 ( z )
2
2




1
1
1
  
 
j
j
Eo 2 ( z ) = H 21 ( z ) Ei1 ( z ) = (1  z 1 ) Ei1 ( z ) = z 2  z 2  z 2  Ei1 ( z )


2
2


25
08 – Filters
Example: coupler 1 = coupler 2 = 3dB-coupler:

c1 = c2 = 1/ 2 ,
s1 = s2 = 1/ 2
Ei 2 = 0
Transfer functions at out 1 and out 2

1 1
1
 
j
j 2  2
1
Eo 2 ( z ) = H 21 ( z ) Ei1 ( z ) = (1  z ) Ei1 ( z ) = z
z  z 2  Ei1 ( z )


2
2


Magnitude of frequency response:

| H11 |=

| H 21 |=
| Eo1 |
| Ei1 |
| Eo 2 |
| Ei1 |
~ sin
1 1
1
 
1
1 2  2
1
Eo1 ( z ) = H11 ( z ) Ei1 ( z ) = ( 1  z ) Ei1 ( z ) =  z
z  z 2  Ei1 ( z )


2
2



1
= sin DT 
2
2
~ cos

1
= cos DT 
2
2
Periodic frequency response with free spectral range:

=D

=D
f FSR =
Interleaving transfer functions at out 1 and out 2.
26
08 – Filters
1
DT
Mutli Stage Filters
27
08 – Filters
Optical FIR-Filter for Equalization of Signal Distortion
cascaded Mach-Zehnder Filter

coupler 1
coupler 3
coupler 2
coupler N
coupler N+1
Input 1
Output 1
DL
***
DL
Input 2
DL
Output 2

single-input single-output device

the output 1 can be reached from input 1 by following N+1 different paths
characterized by delay times from 0 to N DT

therefore the time domain output response y(t) for an input signal x(t) is:
N
y (t ) =  cn x(t  nT )
n =0
which is the response of a FIR-Filter!

equalization of all single channel distortions: chromatic dispersion, SelfPhase Modulation, Polarization mode Dispersion, Group Delay Ripple
28
08 – Filters
Arrayed Waveguide Grating
29
•
The incoming WDM signal (1) is coupled into an array of planar
waveguides after passing through a free-propagation region (2) in the form
of a lens.
•
In each waveguide (3), the WDM signal experiences a different phase shift
because of different lengths of waveguides. Moreover, the phase shifts are
wavelength dependent because of the frequency dependence of the
mode-propagation constant.
•
As a result, different channels focus (4) to different output waveguides (5)
when the light exiting from the array diffracts in another free-propagation
region. The net result is that the WDM signal is demultiplexed into
individual channels.
08 – Filters
Application Example in WDM-System
Channel 1
C-Band
C-Band
192 193 194 195 196THz
186 187 188 189 190 191 192 193 194 195 196THz
even
odd
160 Channels
50 GHz
Basic technologies :
Dielectric filters
Fiber gratings
30
C-/L-Band Filter
192 193 194 195 196THz
even
odd
80 Channels
50 GHz
Interleaver
L-Band
Basic technologies :
MZI (fiber, integrated optical)
08 – Filters
40 Channels
even,100 GHz
...
even
C-Band
100 GHz
DEMUX
195 196THz
40 Channels
odd,100 GHz
Basic technologies:
Dielectric filters
Arrayed Waveguide Grating
Gratings
Fiber gratings
Wrap Up
What you should recall from this chapter:
• Give the requirements for an optical filter to be used as EDFA gain equalizer
• Give the Bragg condition for reflection by (i) a formula and (ii) by your own words
• An optical filter has center wavelength 1555 nm and spectral width (FWHM) of 0.1 nm.
Calculate the center frequency and the 3-dB-bandwidth in Hz.
• Explain how FBG filters can be fabricated
• Explain how an Add-drop Multiplexer with circulator and FBG works
• Explain the working principle of an FBG, which is used for dispersion compensation
• Explain the pros and cons, if an FBG instead of a DCF is used as dispersion compensator
• Which types of optical filters do you know?
• Which components are required for designing an optical FIR filter?
• Explain how an interleaver based on a single stage Mach-Zehnder filter works.
• Calculate the FSR and DL of an interleaver based WDM demultiplexer for 100 GHz channel
spacing
• Explain the working principle of an AWG
31
08 – Filters
Lecture
Optical Communications
Optical Transmission Systems
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Setup of an Optical Transmission System
Optical
Multiplexer
Electrical
Switch
Optical
Demultiplexer
Reconfigurabel Optical
RamanAdd-Drop Multiplexer
Amplifier
ROADM
Dispersion-
Transmission
Fiber
Compensation
Module
(optional)
Optical
Cross-Connects
OXC
Transponder
RX / TX
S
...
...
... X ...
S
Transponder
RX / TX
Optical
Amplifier (EDFA)
2
Optical
Line Amplifier (EDFA)
09 – Optical Transmission Systems
Optical
Pre-Amplifier
...
...
Transponder
RX / TX
Transmission Impairments
ASE
SBS
Raman Tilt/
Raman XTK
Loss
PDGL
ROADM
ISI
GVD (CD)
Tilt
Ripple
ISI – Intersymbol Interference
GVD – Group Velocity Dispersion
CD – Chromatic Dispersion
ASE – Amplifier Spontaneous Emission (Noise)
PDGL – Polarisation Dependent Gain/Loss
XTK - Crosstalk
3
PDGL SPM, FWM,
XPM
XTK
ISI
PMD
XTK
ISI
PMD – Polarisation Mode Dispersion
THN – Thermal Noise
SPM – Self-Phase Modulation
XPM – Cross-Phase Modulation
FWM – Four-Wave Mixing
SRS/SBS – Stimulated Raman/Brillouin Scattering
09 – Optical Transmission Systems
ISI
THN
Setup of an Optical Transponder Modul
10-100 Gb/s
in
(shortreach)
Photodiode
CDR/DMUX
Electrical Amplifier
Digital Signal
Processing (DSP)
FEC
OTH/SDH
CLOCK
RZ Generator
RZ
10-100 Gb/s
out
(longhaul)
VOA
MUX
DATA
NRZ
External
Modulator
Laser
Bias Control
Laser Control
CDR: clock & data recovery
VOA: variable optical attenuator
MSA Modul
Internal IF (e.g.. 10x10 Gb/s)
4
09 – Optical Transmission Systems
Optical Modules (Client Side)
 Left: CFP Modul (C form-factor
pluggable module)
 100 Gb/s (C = centum)
 Reach up to 40 km
 Bottom: hot-pluggable SFP+ Module
(small form-factor pluggable)
 10 Gb/s, different bit rates
supported (e.g. 1 GbE, 10 GbE,
CPRI mobile fronthaul, OTH, ..)
 Various reach classes up to 80 km
5
09 – Optical Transmission Systems
Important Optical Modulation Formats
1.
3.
2.
6
09 – Optical Transmission Systems
4.
Recap:
Transmitter Setup with IQ-Modulator
Driver
Digital-Analog- Amplifier
Converter
(linear)
Data
(I)
Data
(Q)
Q
I
I
90°
Q
Laser
f  193.1 THz
(C-Band)
7
IQ-Modulator
09 – Optical Transmission Systems
Coherent Reception
Balanced
Detection
Input
Signal
ES
90-DegreeHybrid
E1
I
E2
=
ELO
E3
Local
Oscillator
Laser
+j
Q
E4
1
2
1
=
2
1
=
2
1
=
2
=
Homodyne Reception
+
=
−
=
( )
( )−
( )
=
−
=
( )
( )−
( )
−
+
−
Control of local oscillator phase and frequency required
(or estimation in DSP)
8
09 – Optical Transmission Systems
Recap: Transmitter Setup for
Polarization Multiplexed Transmission
Data
(Ix)
Data
(Qx)
Q
Polarization
Beam Splitter
I
I
X-Polarization
90°
Q
I
90°
Y-Polarization
Q
Q
I
Data
(Iy)
Data
(Qy)
9
09 – Optical Transmission Systems
DPSK Transmission
Balanced DPSK
Receiver using
Delay-Line-Interferometer
Balanced
Receiver
A
T
Input
Signal
B
DI
DI: Delay-Line Interferometer
T = Bit duration
A: „Destructive“ port
B: „Constructive“ port
Suitable for differentially encoded PSK
(DI converts differentially encoded PSK to IM)
10
09 – Optical Transmission Systems
DQPSK Transmission
CSRZ Differential Quaternary Phase-Shift Keying
10 GHz
Vp
CSRZ-DQPSK
-Vp
50ps +p/4
DPSK
CSRZ
LD
aI
aQ
dI
DQPSK
Precoder dQ
-Vp/2Vp/2
Square
90°
PM
LPF
-Vp/2Vp/2
Square
RI
40 Gb/s
50ps -p/4
LPF

Very high spectral efficiency – supports 40G at 50GHz grid

Very robust against PMD due to reduced Baud rate

Two DI Demodulators / Balanced Receivers for I + Q

May be susceptible to crosstalk and phase noise
11
09 – Optical Transmission Systems
^
dI
^
aI
^
dQ
DQPSK ^
Decoder aQ
RQ
Im
DQPSK
Re
Duobinary Modulation
1
Binary Input Data
0
1
0
0
1
1
1
Q
NRZ (electrical field)
0
-1
I
0
200
400
600
800
1000
1200
1400
1
Duobinary signal
(electrical field)
Q
0
-1
I
0
200
400
600
800
1000
1200
1400
1
Electrical signal
(Direct detection)
0.5
0
Optical Carrier
(symbolic)
0
200
400
600
800
1000
1200
1400
 3-level signal offers potential for bandwidth reduction
 Coding rule: an uneven number of zeros inverts the following ones
 Can be received with standard direct detection RX
12
09 – Optical Transmission Systems
Transmitter Setup
E
Realisierung
-Vp
Delay&Add bk
Coding
z-1
+
Vp
-E
ck
LPF
MZ
driver
MZ
modulator
MZ
driver
MZ
modulator
fc=3fb/4
Delay&Add Coding
Filtered
Duobinary Signal
bk
LPF
fc=fb/4
 Delay & Add coding is similar to fb-periodic low-pass filter
 Electrical fb/4 low-pass filter (similar properties) is simpler to realize
 Both implementations need manual optimization of the filter bandwidths for
optimum performance
13
09 – Optical Transmission Systems
Example of Signal Coding
ck=bk-1+ bk
bk=bk-1 d’k
dk
clock
ck
divide-by-2
counter
AND
LPF
diff. pre-coding
MZ
driver
c’k
Ek
MZ
modulator
Fiber
=fb/2
ffcg=f
b/4
k
dk
-1
0
0
1
0
0
0
-Vp
E
1
1
0
1
1
1
0
0
0
2
1
0
1
2
Vp
-E
1
3
0
1
0
1
0
0
0
4
0
1
1
1
0
0
0
5
1
0
1
2
Vp
-E
1
6
1
0
1
2
Vp
-E
1
d’k
bk
ck
c’k
Ek
E
ek=dk
0
-Vp
Differential pre-coding: standard Rx, no error propagation
14
Direct
dection
09 – Optical Transmission Systems
Vp
-E
ck  c’k
0  -Vp
1 0
2  +Vp
ek
Eye Diagrams
Delay&Add Coding
Filtered Duobinary Signal
Electrical Input
Signal to MZM
Received Eye
(back-to-back)
V-shaped eye for filtered duobinary signal leads
to Back-to-Back Penalty
15
09 – Optical Transmission Systems
Eye Diagram after Transmission
Filtered Duobinary Signal
NRZ
200km SSMF
100km SSMF
back-to-back
Delay&Add Coding
Filtered duobinary signals allows much higher system reach
16
09 – Optical Transmission Systems
Optical Spectra
50
Duobinary Filter
Gaussian Filter 1st order,
Bandwidth 10GHz
DB filtering
DB encoder, 7.5GHz LPF
NRZ, ideal EXT
40
30
Duobinary Coding
Delay&Add Coding and
Gaussian Filter 2nd order,
Bandwidth 7.5GHz
PDS [dB]
20
10
0
NRZ
With ideal extinction
-10
Receiver
Bessel Filter 5th order,
Bandwidth 7.5GHz
-20
-30
-40
-20
-15
-10
-5
0
f-f [GHz]
5
10
15
20
c
Data rate
10 Gbit/s
Reduced spectral width:
Improved dispersion tolerance and spectral efficiency
17
09 – Optical Transmission Systems
Futher Optical Modulation Formats
50
NRZ
DPSK
RZ-DPSK
DQPSK
RZ-DQPSK
DB (filtered)
40
30
PSD [dB]
20
DB
Q
I
DPSK
Q
10
I
0
DQPSK
01
-10
Q
00
-20
I
-30
11
-40,
-20
-15
-10
-5
0
5
f-fc [GHz]
10
15
10
20
PSK and QPSK are relevant for 40-100 Gb/s
(spectral efficiency, sensitivity, robustness)
18
09 – Optical Transmission Systems
90°
QPSK
Coder
Filter +
Driver
PBS
LO
PC
90°
90°
Hybr.
0°
 50 GHz DWDM with 2 (bit/s)/Hz spectral efficiency
 2500 km reach on uncompensated fiber (~2000 km with inline DCF)
 DSP as standard component
19
09 – Optical Transmission Systems
Client I/F (CFP)
PBC
90°
FEC, Framing, Monitoring
PC
PBS
PC
ADC
CW
LD
0°
Digital Filter (FFE)
90°
90°
Hybr.
ADC
Filter +
Driver
ADC
FEC, Framing, Monitoring
Client I/F (CFP)
QPSK
Coder
ADC
Coherent Dual-Polarization Transmission System
Digital Signal Processing
20
09 – Optical Transmission Systems
Block Diagram (Single Polarization)
ADC
IQCorr.
CDComp.
Timing
Recov.
ADC
Freq.
&
Phase
Est.
Data
Recov.
First signal flow for reception of only one polarization axis is shown
(i.e. 1 complex signal)
21
09 – Optical Transmission Systems
Block Diagram (Polmux)
ADC
X-Pol
IQCorr.
CDComp.
ADC
Timing
Freq.
&
Phase
Est.
Data
Recov.
Freq.
&
Phase
Est.
Data
Recov.
Pol.
Equal.
Recov.
ADC
Y-Pol
IQCorr.
CDComp.
ADC
22
09 – Optical Transmission Systems
IQ-Imbalance Correction
 The (maximum) voltage swings of both channels (I/Q) can be different.
 The angle between I- and Q-axis in the 90°-hybrid can be different from 90°.
Q- channel with 1.2x amplitude and
angle between I- and Q of 100°.
23
After (automatic) correction the
constellation diagram is circular.
09 – Optical Transmission Systems
Timing Recovery
 The sampling rates of Tx and Rx can be (slightly) different.
 The optimum sampling point (i.e. center of a bit) may not be hit exactly.
Input:
IQ-imbalance corrected signal
24
Output:
Circular constellation diagram
09 – Optical Transmission Systems
Algorithm
 Gardner Algorithm F. M. Gardner, IEEE Trans. Comm., vol. 34, no. 5, pp. 423-429, May 1986.
 Square Timing Recovery M. Oerder, H. Meyr, IEEE Trans. Commun., vol. 36, no. 5, pp. 605-612, May 1988.
In the following short explanation of the Gardner algorithm working principle:
 Uses 2 samples per symbol (bipolar signal required)
 Error is determined by en   yn  yn  2  yn 1 with a T / 2 distance between two samples
 Typically PI-control loop to find optimum sampling time
Correct Timing
en=(-1-1)0 = 0
25
Too late sampling
en=(-0,8-0,8)(-0,2) = 0,32
09 – Optical Transmission Systems
Too early sampling
en=(-0,8-0,8)0,2 = -0,32
Extensions for
Polarization Multiplexed Transmission
Gardner Algorithmus verliert Regelinformation für DGD = 0.5 Tbit
Lösung:
 Addiere Gardner Phase Detector (GPD) Terme für Signale mit und ohne Entzerrung
 Verwende Schmetterlingsfilter als Entzerrer mit gleichgewichteten Koppeltermen
C. Hebebrand, et al, „Clock Recovery with DGD-tolerant Phase Detector for CP-QPSK Receivers“, SPPCom 2010.
26
09 – Optical Transmission Systems
Equalization (only Polmux)
 (Linear) Polarization effects (PMD & PDL) lead to crosstalk.
 Equalizer (butterfly structure) approximates Jones matrix to compensate for crosstalk.
Input:
Retimed Signal (T/2 DGD + PDL)
27
Output:
Equalized signal (10 dB OSNR)
09 – Optical Transmission Systems
Algorithm
 Constant Modulus Algorithmus (CMA) S. J. Savory, Optics Express, vol. 16, no. 2, 2008.
C.R. Johnson, et al, Proc. IEEE, vol. 86, 1998.
Working principle:
 For each polarization axis the amplitude should be constant (circular constellation diagram).
 Adapt complex filter coefficients (hxx, hxy, hyx, hyy) iteratively by minimizing the root mean
square error (RMSE).
28
09 – Optical Transmission Systems
Frequency & Phase Estimation
 The carrier frequencies of Tx and Rx lasers are not identical.
 Phase noise can additionally degrade the signal.
Input:
Retimed Signal
29
Output:
Frequency & Phase corrected signal
09 – Optical Transmission Systems
Algorithm
 Viterbi & Viterbi Algorithm A. J. Viterbi, A. N. Viterbi, IEEE Trans. Inf. Theory, vol. 29, no. 4, pp. 543-551, 1983
 Recommended: S. Hoffmann, et al, IEEE PTL, vol. 20, no. 18, September 2008.
Working principle carrier frequency estimation:
 Normalize input data (if multi-level modulation formats are used)
 Determine phase difference between neighobring symbols (Modulo p / 2)
 Average over a high number of samples (e.g. 500) & correct for frequency offset
Working principle phase estimation:
 Remove modulation by exponentiating (e.g. raise to the power of 4 for QPSK)
 Determine average value with symmetrically decaying coefficients
 Determine (average) phase & corrected sampling values using estimated phase
30
09 – Optical Transmission Systems
Data Recovery & BER Calculation

Divide constellation diagram into sectors

Allocate bit sequence to sectors

Count bit errors by comparison with original sequence at Tx

Calculate BER
I = 0,
Q=1
I = 0,
Q=0
31
I = 1,
Q=0
I = 1,
Q=1
09 – Optical Transmission Systems
Outlook to Higher System Capacity
32
09 – Optical Transmission Systems
Development of Transmission System Capacity
33
09 – Optical Transmission Systems
Developments towards Higher System Capacity
Im
OOK
Im
DPSK
Im
DP-QPSK
Im
DC-DPQPSK
Im
Re
Re
or
Im DP-16QAM
DC-DPRe
QPSK
Re
Re
Re
1T
Intensity
Modulation
Phase
Modulation
Direct
Detection
Self-coherent
Detection
Phase
Modulation
Phase Modulation, QAM
Single / Dual Carrier
Digital coherent Intradyne Detection
Single Polarization
34
Dual Polarization
09 – Optical Transmission Systems
QAM
O-OFDM
Maximum Fiber Capacity
Spectral Efficiency [bits/s/Hz]
9
Shannon Limit
8
256QAM
7
2000 km
Fiber Capacity
Limit [1]
6
64QAM
5
8000 km
4
16QAM
3
2
QPSK
1
BPSK
[1] Essiambre, et al., “Capacity Limits of
Optical Fiber Networks,” JLT, vol. 28, no.
4, Feb. 2010
Shannon Limit
Gaussian Ch.
0
0
5
10
15
20
25
SNR/bit [dB]
Boundary conditions:
Transmission on a single polarization, SSMF, 100-km fiber spans, ideal amplification with
Raman amplifiers, no inline DCF, 5-channel WDM
Total fiber capacity is limited due to nonlinear fiber effects
35
09 – Optical Transmission Systems
Modulation Formats for 400 Gb/s Transmission
Format
DP-16QAM
DP-QPSK
DP-QPSK
PS-QPSK
DP-8QAM
DP-64QAM
Symbol
Rate
60 GBd
60 GBd
30 GBd
40 GBd
40 GBd
40 GBd
Bits /
Symbol
8
4
4
3
6
12
# Subcarriers
1
2
4
4
2
1
Req. BW
DP-64QAM
Reach Penalty
vs. 100G
7 dB
1.2 dB
1.2 dB
-1.8 dB
5.2 dB
14.4 dB
100 GHz
150 GHz
150 GHz
200 GHz
100 GHz
50 GHz
Capacity x Reach = const.
DP-8QAM
DP-16QAM
DP-QPSK
PS-QPSK
100G DP-QPSK
36
09 – Optical Transmission Systems
Options for 1 Tb/s Transmission
Format
DP-16QAM
DP-8QAM
PS-16QAM
DP-QPSK
Symbol
Rate
38 GBd
40 GBd
40 GBd
60 GBd
Bits /
Symbol
8
6
5
4
# Subcarriers
4
5
6
5
Req. BW
150 GHz
200 GHz
250 GHz
300 GHz
Reach Penalty
vs. 100G
9.2 dB
5.7 dB
10 dB
2.2 dB
Capacity x Reach = const.
DP-16QAM
DP-8QAM
PS-16QAM
DP-QPSK
100G DP-QPSK
37
09 – Optical Transmission Systems
Outlook: Software-Defined Optics
Multi-level modulation
Client
signal
Symbol
Mapping
Client
signal
Symbol
Mapping
Multi-carrier modulation
f
Maintain symbol rate
38
Client
signal
SubCarrier
Mapping
Optical
OFDM
f
Client
signal
SubCarrier
Mapping
Optical
OFDM
f
Increase number of subcarriers
Constant clock rate
Change optical bandwidth
Constant bandwidth
Requires flexible wavelength grid
Change modulation format
Change subcarrier modulation format
Information content per symbol
Information content per symbol
Noise and impairment tolerance
Noise and impairment tolerance
09 – Optical Transmission Systems
Wrap Up
What you should recall from this chapter:
•
•
•
•
•
•
•
•
39
What system components are typically deployed in an optical transmission system?
How does a optical transponder module look like internally?
What optical modulation formats are typically used?
Describe the setup of an optical transmitter/receiver for coherent and polarization
multiplexed transmission
What is a delay-line interferometer? How can it be used at the RX side?
How does signal coding for duobinary transmission work?
Which steps need to be taken for digital signal processing of a coherently received
signal?
Which impairments need to be corrected by the DSP on the receiver side?
09 – Optical Transmission Systems
Lecture
Optical Communications
Simulation
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Outline
 General Concept
 Nonlinear Schrödinger Equation
 Split-Step Fourier Method
 Step Size Distribution
 Noise Representation
 Simulation of Polarization Mode Dispersion
2
10 – Simulation
Complex Baseband Representation
3
10 – Simulation
Signal Representation
Instead of sampling the entire waveform (including the ultra high
frequency optical carrier) only the envelope of the signal (blue line) is
sampled.
The number of samples must be
a power of two (to enable use of
FFT).
The complex baseband
representation requires the
definition of a center frequency
(zero frequency in the baseband).
Frequency shifts (e.g. of other
WDM channels) lead to phase
shifts (in time domain) in the
complex baseband.
4
10 – Simulation
Nonlinear Schrödinger Equation (NLSE)
Can be used to model propagation of light through optical fiber.
There exist several different forms of the NLSE, which shall be outlined
in the following.
 NLSE for total field representation (TF)
 NLSE for separated channels representation (SC)
 TF equation including terms for coupling of polarization axes
 Various other versions exist making more or less simplifications
(e.g. low or high birefringence in the fiber, inclusion of Raman effects,
…)
more in information in Lecture on „Numerische Simulation analoger
und digitaler Nachrichtensysteme“ by J. Leibrich
5
10 – Simulation
Total Field Representation
+ Suitable model for all linear and nonlinear effects
occurring within a fiber
- Frequencies between WDM channels are simulated
 Waste of simulation bandwidth for CWDM systems
 Slow for these systems
6
10 – Simulation
Separated Channels Representation
+ Simulation bandwidth is used more efficiently
+ Nonlinear effects between different WDM channels can
be evaluated independently
- Linear crosstalk between different WDM channels cannot
be simulated
7
10 – Simulation
Nonlinear Schrödinger Equation
(Linear part)


 j
2 1
3 
A  z, t     j  0  1   2 2  3 3  A  z, t   0
z
t 2 t 6 t 
2
Taylor series expansion of the propagation constant  (truncated after
third order term)
Derivaties with respect to time can be replaced by multiplications with
j   in the frequency domain.
Important: fiber attenuation constant  is given here in linear units:
 Neper km   dB km 
8
ln10
  dB km  0.23.
10
10 – Simulation
Propagation Constant 
d
1 d 2
     0  
  0  
d 0
2 d 2
  0 
0
2
1 d 3

6 d 3
  0 
3
 ...
0
Usually derivaties to the angular frequency are abbreviated by:
d n
d n
 n .
0
The first element 0 of the Taylor series expansion induces a
frequency-independent phase response.
The second term 1 is usually eleminated in simulations by a moving
coordinate system (with the group velocity of the center frequency).
Nota bene: There may exist a difference in 0 values between both
polarization axes (and of course also of 1).
9
10 – Simulation
Dispersion Parameters
For completeness: The dispersion parameter D and dispersion slope
parameter S are related to the propagation constant derivatives in the
following way:
2
dD  2 c   1
1

S




d
 3   3  c 2 
d 1
2 c
D
  2 2
d  vg

d 1
d 1
2
2 


D
d  d  vg
2 c
10
10 – Simulation
d 2
3
3 

 S  2D 
2 
d   2 c 
Fiber Birefringence
In single mode fibers generally two fundamental modes, orthogonal to
each other, are guided.
The difference of the propagation constants for both modes can be
written as:
1  1, x  1, y and  0  1    1  c
This leads to the propagation equation for a linear, birefringent fiber:
  Ax  z, t     j   0

  
z  Ay  z, t    2 2  0
0  1  1
0  j
2 1
 3   Ax  z, t  
 
  0.

 
  
 0  2  0 1  t 2 2 t 2 6 3 t 3   Ay  z, t  
More on the simulation of random varying birefringence (PMD) will
follow later.
11
10 – Simulation
Nonlinear Schrödinger Equation
(Nonlinear Part)
Dependence of the refractive index on the optical power described by
the Kerr effect:
n(t )  nlinear  n2 A(t )

2
n2  0
c0  Aeff
An optical fiber with large birefringence (beat length lB >> l)
2
lB 
.
x   y
can be modelled by
0  j
  Ax   1  1
 2 1  3   Ax 
 3
 
   
  2
z  Ay   2 2  0 1  t 2 t 2 6 t 3   Ay 
2
 2 2

A

A
0
y
 x
  Ax 
3
Total Field
 j 
 
2
2
Representation
2   Ay 

0
A

A

y
x 
3


12
10 – Simulation
Nonlinear Schrödinger Equation
(Separated Channels)
In separated channels representation the electric fields Ai of the
individual WDM channels are separated. The different nonlinear
contributions are included by coupling terms:
 An 
 An
 2 An 1
 3 An
j

An   1,n  1,ref 
  2,n
 3,n

2
3
z
2
 t 
2
t
6 
 t



Attenuation
Time delay
Dispersion
Dispersion slope


N
 2
2
 j An  An  2  Ai   j
Ai Aj Ak exp   j kz 

 i 1,i  n
n  i  j  k ;i , j  k
 SPM 
  


XPM


FWM
N
 n 1 n
gR
gR
2
2
Ai  
Ai  An
 


2
K

A
2
K

A
i 1
i  n 1
i
eff
eff



SRS
13
10 – Simulation
Split-Step Fourier Method
14
10 – Simulation
Solution of the NLSE by the
Split-Step Fourier Method


Split nonlinear Schrödinger equation in linear and nonlinear parts
Separate solution of linear and nonlinear parts

Solution of the linear part in the frequency domain and of the nonlinear part in
time domain (acceptable for small step-sizes)

Transformation between time and frequency domains by FFT
(significant speedup can be expected from parallization)
15
10 – Simulation
15
Fast Fourier Transform (FFT)
M 1
2 j  k 

 M


k
with wM  exp 
V     DFT v  k    v  k   wM k ,   0,..., M  1
k 0
The idea of the FFT is to split up the input sequence into two
sequences with even and odd arguments
 M /2  1
V   
 M / 2  1
 v  2l   w
 2 l
M

l 0
 v  2l  1  w 
 2 l 1
M
,   0,..., M  1
l 0
 2l
l
With the help of the relation wM  wM this can be rewritten
 M /2  1
V   
 M / 2  1
 v  2l   w
 2 l
M

wM 
l 0
 v  2l  1  w ,
l
M
l 0
 V1     wM  V2    .
16
10 – Simulation
  0,..., M  1
FFT (cont.)
Finally, M / 2 DFTs of length 2 remain, which can be calculated by:
1
k
G      g  k   w2 ,
k 0
G  0   g  0   g 1
  0,1 
G 1  g  0   g 1
The Cooley-Tukey algorithms has a complexity of approximately
5n log2 n operations for an FFT length of 2n.
17
10 – Simulation
Four-Step-FFT Algorithm
Multiply with M twiddle factors
and transpose the matrix
FFT implementation of length M = 16.
8 FFTs of length 2 along the lines and 2 FFTs of length 8 along the lines.
1. Calculate M2 DFTs of length M1 along the lines
2. Multiply the data with the complex twiddle factors wMk2  µ1  exp  2 j 

k 

M

3. Transpose the complex matrix M1 M2 yielding M2  M1
4. Calculate M1 DFTs of length M2 along the lines
18
10 – Simulation
18
1 2
Criteria to Limit Step-Size
 Maximum nonlinear phase shift between two split-steps
 Maximum amount of artifical four-wave mixing
 Maximum walk-off between two WDM channels
As the signal is attenuated along the fiber longer split-steps can be
tolerated towards the end of the fiber as the nonlinear fiber effects are
reduced.
19
10 – Simulation
Nonlinear Phase Shift
The maximum nonlinear phase shift is defined as:
2
φNL,max   Amax z.
As nonlinearity (nonlinear part of NLSE) and dispersion (linear part of
NLSE) interact by transfering phase into amplitude fluctuations, the
nonlinear phase shift must be limited.
A good choice is a maximum nonlinear phase shift of ~0.1 mrad.
20
10 – Simulation
Artifical Four-Wave Mixing (FWM)
Maximum admissible step size:
1  1 n 
z  
ln 
2  1   n  1 



n  1...K
  1  exp  2 l   / K
3
K   P  leff   10
4 
21
PartificialFWM
10



2
10 – Simulation
G. Bosco et al, „Suppression of spurious
tones in fiber system simulations based
on the Split-Step method“, LEOS
conference, 1999.
Maximum Walk-Off between Channels
Bound for step-size due to walk-off
z 
Tmin  max walkoff
D  
(Linear) walk-off results from different propagation velocities of the
WDM channels due to dispersion.
If the maximum walk-off is chosen too large, it is possible that bits in
the outermost WDM channels completely move across each other and
crosstalk (e.g. XPM) cannot be determined correctly anymore.
Thus the maximum admissible walk-off should only be a fraction of a bit
period.
22
10 – Simulation
Modelling of Noise
23
10 – Simulation
Noise Representation by Noise Bins
(Analytic Noise Representation)
In analytic noise representation separate bins are used to represent the
stochastic properties of noise.
These bins have a certain coarse bandwidth (~4 GHz).
A high spectral entire noise bandwidth should be simulated to ensure
accurate results (~8 THz).
24
10 – Simulation
Noise Representation by Noise Process
(Numeric Representation)
In numeric noise representation noise is included into the sampled
signal. The simulation bandwidth has to be chosen accordingly.
Numeric noise representation is the only way to accurately model
the nonlinear interaction between noise and fiber effects (GordonMollenauer effect).
Also receiver properties are modelled more accurately by numeric
noise representation.
25
10 – Simulation
Analytic BER Estimation
The following noise terms can be included (and can be deactivated separately):
 ASE-shot noise
 ASE-ASE noise
 ASE-channel beat noise
 Channel shot noise
 Thermal noise
26
10 – Simulation
BER Calculation
(Analytic Noise Representation)
P1
P0
 12
i1
 02
ith
i0
Probability density
 ith  i0 
 i1  ith 
1
1



BER  P1  P0 1  P0  P 1 0    P0 1  P 1 0   erfc
 erfc


2
2 
 1 2 
  0 2 
The variance of the zero and one levels of the signal is derived from the
analytical noise representation.
27
10 – Simulation
BER Estimation
(Numeric Noise Representation)
Determination of the BER:
• Monte-Carlo simulations
- Very time consuming for a low BER
+ Very accurate
• Tail extrapolation
- Only valid for Gaussian distributed mark
and space values
+ Very fast
28
10 – Simulation
Tail Extrapolation for Estimation of Low
BER Levels
Deliberately vary the decision threshold to determine
between zeros and ones of a binary signal. Count errors
for these cases and plot them into a graph.
Extrapolation of these BER curves yields the BER.
29
10 – Simulation
Simulation of PMD
30
Simulation of Polarization Mode Dispersion
(Wave Plate Model)
Discretize fiber into small waveplates (e.g. of 1 km length), randomly
turn polarization in front of waveplate.
Waveplates are assumed to have a birefringence of 1  1,x - 1,y
The mode coupling between the different elements is determined by the two
angles  and . The matrices for the transformation of the polarization state are
referred to as Jones matrices.
31
10 – Simulation
Transmission Function of a Waveplate
H ( )  D 1  B( )  C  D
  1


exp





z
0


1
i


2



B( )  
1



0
exp 1zi 

2

  

exp

j
0




2



C
 

0
exp j 

 2 
 cos  sin  
D

 sin  cos 
32
10 – Simulation
Click To Edit Master Title Style
Wrap Up
What you should recall from this chapter:
•
•
•
•
•
•
•
•
•
•
33
Describe the linear and nonlinear parts of the NLSE.
What is the difference between total field and separated channels representation?
How can the Split-Step Fourier Method be used to solve the NLSE?
How can the step-size be determined?
How does the artifical FWM process limit the maximum admissible step-size?
What different approaches can be taken to model noise effects?
What are the advantages and disadvantages of these approaches?
How can PMD be modelled?
What is a Jones matrix?
How can the transmission function of a wave-plate be calculated?
10 - Simulation
Lecture
Optical Communications
Outlook
Prof. Dr.-Ing. Dipl.-Wirt.-Ing. Stephan Pachnicke
Overview
• Next generation access networks
• Functional and structural convergence of fixed and mobile
networks
• Conclusion
2
11 - Trends
Traffic Growth in the Internet
DE-CIX GlobalPeer
• Exponential growth of the bandwidth with approx. 30% p.a.
• Drivers are new services such as IP-TV, Cloud, …
3
11 - Trends
Access Network Technologies
Fiber-to-the-Home
10G-EPON, XG-PON
Fiber-to-the-Curb
ADSL
Copper
ISDN
Year
• DSL-based technology cannot be scaled to higher data rates
•
•
VDSL2 ~100 Mbit/s with reach of ~550-850 m
G.fast (Vectoring) ~150 Mbit/s, ~250 m reach
Fiber-to-the-Curb
• Solution: fiber based systems, passive optical networks (PON)
4
11 - Trends
System Architecture (FTTx)
Point-to-point
CO
GPON
TDMA-PON
Passive
splitter
CO
NG-PON2
WDM-PON
CO
Acronyms:
WDM
Mux/Demux
+
Physical layer p2p connection
+
High reach (approx. 80 km)
+
Aggregate bit rate/fiber = end user bit rate
–
N fibers in the CO
–
N transceivers in the CO
+
1 fiber in the CO
+
1 transceiver in the CO
–
Shared multipoint connection
–
Lower reach (approx. 10 km)
–
Aggregate bit rate/fiber = N x end user bit rate
+
Physical layer p2p connection
+
Medium reach (approx. 40 km)
+
1 fiber in the CO
+
1 transceiver in the CO
+
Aggregate bit rate/wavelength = end user bit rate
CO=Central office; TDMA=Time Division Multiple Access; WDM=Wavelength Division Multiplex
GPON=Gigabit capable passive optical networks; NG-PON2=Next Generation–PON2
5
11 - Trends
WDM-PON Challenges
Customer Premises
Central Office
Challenges
Solutions
• Integration of multi-channel
transmitters and receivers
• Photonic integrated circuit
(PIC) (& driver array)
• Low-cost tunable laser
• Development of a novel
(wavelength) tunable
tranceiver module with
centralized control
SFP+
6
11 - Trends
Transmission System Setup
OLT
ONU
AWG
(G.698.3)
SFP
(L-Band)
1GBE
.
.
.
L-Band
(RX)
C-Band
(TX)
RN
L-Band
C-Band
VOA
CPE
(with T-SFP+)
.
.
.
Fiber
AWG
(G.698.3)
90%
SFP
(L-Band)
1GBE
C-Band
AWG
10%
Wavelength
Controller
L/C Splitter
CPE
(with T-SFP+)
OLT: optical line terminal; RN: remote node;
ONU: optical network unit; VOA: Variable Optical
Attenuator; AWG: arrayed waveguide grating
CPE: Customer Premises Equipment
7
11 - Trends
Field Trial WDM-PON (2014)
•
Two different fiber routes (looped back to central office)
•
15 km – red (approx. 7 dB attenuation) – Gmunden to Olsdorf
•
25 km – orange (approx. 11 dB attenuation) – Gmunden to Laakirchen
8
11 - Trends
Results
S. Pachnicke, et al, OFC,
Los Angeles, 2015.
9
11 - Trends
Automatic Wavelength Control
194,9
Frequency [THz]
194,8
194,7
194,6
194,5
194,4
0
10
20
30
Phase 1
(Power Feedback)
40
50
Time [s]
60
70
80
90
100
Phase 2
(Wavelength & Power Feedback)
On turn-on the ONU automatically tunes to the wavelength, which is
equivalent to the AWG port it is attached to (considering the wavelength and
power feedback it receives from the centralized controller)
10
11 - Trends
Long Term Stability
Long-term wavelength stability is achieved by the closed-loop wavelength
control provided by the central office
11
11 - Trends
Convergence of Fixed and Mobile
Networks
12
11 - Trends
Increase of Mobile Traffic
Quelle: Cisco VNI Mobile, 2015
• Global mobile traffic will reach 24.3 EB/month in 2019
• Bandwidth growth of approx. 57% p.a.
13
11 - Trends
Fixed-Mobile Convergence (FMC)
NID / RGW
Universal Access Gateway
UAG
Carrier Ethernet
Switch / Aggregator
U
E
eNB
Access- and
aggregation network
NFV
Server
WiFi AP
Low-Latency Cross-Connect
eNB ONU
Small
Cell
RRU ONU
RRU ONU
RRU ONU
WDM-PON OLT
Mobile
Fronthaul
Shared use of the infrastructure by fixed and mobile networks
14
11 - Trends
Advantages
Use of a shared infrastructure for fixed and mobile networks:
•
Improved QoE for the end user (e.g. seamless handover between WiFi/LTE)
•
Reduced costs and lower energy consumption
Differentiation into
•
•
15
Functional convergence wrt. required functions in fixed and mobile networks
•
Enhanced control
(improved offloading, seamless handover between fixed and mobile networks)
•
Use of virtualized functions on a shared NFV server
(e.g. for universal authentication functionality, universal data path management, …)
Structural convergence wrt. the infrastructure
•
Shared use of network infrastructure
(e.g. PON network for FTTH & dedicated wavelengths for mobile fronthaul)
•
Consolidation of network nodes
11 - Trends
Functional Convergence
Management / Control
SDN UAG
/ OpenFlow
GbE / 10GbE Carrier Ethernet
Switch / Aggregator
eNB
SDN / OpenFlow VNF 1
NFV
VNF 2
VNF 3
Server
Access and
Aggregation
WiFi AP
IP / MPLS
Network
SDN / OpenFlow
Backbone
LER
BBUH
Low-Latency Cross-Connect
Sync
Timing
WDM-PON OLT
RRU ONU Mobile
RRU ONU
RRU ONU Fronthaul
Content
Cache
Mobile
EPC
uAAA
Perform. Interface
Monitor
Select
Enhanced control & virtualization functions
(SDN/OpenFlow Controller, NFV-Server)
16
11 - Trends
NFV & SDN
Software Defined Networking
(SDN)
Network Function Virtualization
(NFV)
Cache Firewall Router
App
App
App
API’s
Rework of network applications
to run on arbitrary hardware,
independent of custom networking hardware
17
Forwarding plane is
programmable in real time
by independently developed
software
11 - Trends
Network Function Virtualization
(NFV)
Traditional Network Appliances
Message
Router
DPI
CDN
Firewall
Virtualized Network Functions
Session Border
WAN
Controller Acceleration
Carrier
Grade NAT
Standard, high-volume
servers
Standard, high-volume
storage
Tester/QoE
Monitor
Standard, high-volume
switches
SGSN/GGSN
PE Router
BRAS
RAN Controller
Use of commodity hardware (e.g. blade server),
software-based network functions,
faster innovation cycle
18
11 - Trends
Examples of NFV
Implementations
Mobile Networks
• Virtual EPC (vEPC), Centralized RAN (C-RAN)
Residential Customers
• Virtual Home Gateway (vHG)
Business Customers
• Virtual Customer Premises Equipment (vCPE)
First use in mobile networks
then for residential and business customers
19
11 - Trends
Advantages of NFV
Physical
Network
Hybrid
Network
Virtual
Network
Scope
Functions tied to
hardware
Selective functions virtualized with gradual
introduction of orchestration
Orchestration across
virtualized functions
Operations
Slow, manual service
creation
Gradual transition, benefits expand as
scope of virtualization grows
Automated real-time
service creation
Cost
CAPEX-heavy,
over-provisioning
Initial impact may be limited, because
functions are virtualized in isolation
OPEX-heavy, licensebased model
Innovation
Cycle
Innovation tied to both
hardware and software
Impact depends on which functions are
virtualized
Software and hardware
become independent
Source:
It is crucial to find the right way to a fully
virtualized network
20
11 - Trends
Example: Double Attachment
SDN Controller
Network Assistance for
Access Selection and Utilization
UE
WiFi AP
Interface
Selection
WiFi AP
Double
Attachment
Interface Changing
(Inter-system Handover)
SDN-API
Northbound
uAAA
U
E
WiFi AP Changing
(Inter-AP Handover)
Control Plane
U
E
Access- and
aggregation network
UAG
LTE-EPC
Performance
Monitoring
U
E
Content
Cache
SDN: Software-defined networking, uAAA: universal
Authentication, Authorization and Accounting, UAG: universal
access gateway, EPC: evolved packet core; UE: user equipment
•
User Equipment (UE) authenticates via uAAA in mobile and WiFi networks
•
UE can be attached via different paths at the same time (double attachment)
•
Centralized network control steers traffic (offloading)
21
11 - Trends
Example: Centralized-RAN
Management / Control
SDN UAG
/ OpenFlow
GbE / 10GbE Carrier Ethernet
RRU ONU
RRU ONU
RRU ONU
Switch / Aggregator
SDN / OpenFlow VNF 1
NFV
VNF 2
VNF 3
Server
Access and
Aggregation
WiFi AP
IP / MPLS
Network
SDN / OpenFlow
Backbone
LER
BBUH
Low-Latency Cross-Connect
Sync
Timing
WDM-PON OLT
RRU ONU Mobile
RRU ONU
RRU ONU Fronthaul
Content
Cache
Mobile
EPC
uAAA
Use of BBU hoteling.
Advantages by
• Sharing of the same BBU for serving a business area in day time
• and a residential area during night
22
11 - Trends
Perform. Interface
Monitor
Select
Conclusions
•
Bit rates in access networks will increase exponentially in the next years
•
Fiber-to-the-Home systems will be the only long-term solution
•
Especially WDM-PON systems are promising due to their high bandwidth
and low latency
•
Fixed- and mobile networks will converge in the future
•
NFV & SDN will allow flexible reconfiguration of the network and
realization of network functions in software
23
11 - Trends