金沙娱城乐怎么可以赢钱-官方网站[welcome]

EN554%20Photonic%20Networks - PowerPoint PPT Presentation

View by Category
About This Presentation
Title:

EN554%20Photonic%20Networks

Description:

The University of Northumbria. U.K. http://soe.unn.ac.uk/ocr. 2. Prof. Z Ghassemlooy ... G Keiser. 14. Prof. Z Ghassemlooy. Couplers - Fabrication ... – PowerPoint PPT presentation

Number of Views:981
Avg rating:5.0/5.0
Slides: 52
Provided by: zghass5
Learn more at: http://soe.unn.ac.uk
Category:

less

Write a Comment
User Comments (0)
Transcript and Presenter's Notes

Title: EN554%20Photonic%20Networks


1
EN554 Photonic Networks
Lecture 2 - Devices Components
Professor Z Ghassemlooy
Northumbria Communications Laboratory School of
Informatics, Engineering and Technology The
University of Northumbria U.K. http//soe.unn.ac.u
k/ocr
2
Contents
  • Connectors Optical Splice
  • Attenuators
  • Coupler
  • Splitter
  • Filters
  • Fibre Brag Grating
  • Optical Isolator
  • Circulators
  • Optical Add/Drop
  • Multiplexer Demultiplexer

3
Connectors
  • A mechanical or optical device that provides a
  • demountable connection between two fibers or a
    fiber and a source or detector.

4
Connectors - contd.
  • Type SC, FC, ST, MU, SMA
  • Favored with single-mode fibre
  • Multimode fibre (50/125um) and (62.5/125um)
  • Loss 0.15 - 0.3 dB
  • Return loss 55 dB (SMF), 25 dB (MMF)

Single fibre connector
5
Connectors - contd.
  • Single-mode fiber
  • Multi-mode fiber (50/125)
  • Multi-mode fiber (62.5/125)
  • Low insertion loss reflection

6
Optical Splices
  • Mechanical
  • Ends of two pieces of fiber are cleaned and
    stripped, then carefully butted together and
    aligned using a mechanical assembly. A gel is
    used at the point of contact to reduce light
    reflection and keep the splice loss at a minimum.
    The ends of the fiber are held together by
    friction or compression, and the splice assembly
    features a locking mechanism so that the fibers
    remained aligned.
  • Fusion
  • Involves actually melting (fusing) together the
    ends of two pieces of fiber. The result is a
    continuous fiber without a break.
  • Both are capable of splice losses in the range
    of 0.15 dB (3) to 0.1 dB (2).

7
Attenuators
  • Singlemode Variable Attenuator
  • Repeatable, variable attenuation from 2 to 40dB
  • lt-70dB reflectance (unconnectorized)
  • Polarization insensitive
  • Low modal noise
  • Long-term reliability

8
Attenuators - contd.
  • Bandpass 1310/1550nm
  • FC, SC, ST, and D4 styles
  • Wavelength independent
  • Polarization insensitive
  • Low modal noise

9
Optical Couplers
  • Optic couplers either split optical signals into
    multiple paths or combine multiple signals on one
    path.
  • The number of input (N)/ output (M) ports, (i.e.s
    N x M size) characterizes a coupler.
  • Fused couplers can be made in any configuration,
    but they commonly use multiples of two (2 x 2, 4
    x 4, 8 x 8, etc.).

10
Coupler
  • Uses
  • Splitter (5050)
  • Taps (9010) or (9505)
  • Combiners
  • An important issue
  • two output differ p/2 in phase
  • Applications
  • Optical Switches,
  • Mach Zehnder Interferometers,
  • Optical amplifiers,
  • passive star couplers, ...

11
Coupler Configuration
12
Coupler - Integrated Waveguide Directional
Coupler
P2 P0 sin2 kz
P1 P0 - P2 P0 cos2 kz
k coupling coefficient (m 1)?/2
13
Coupler - Integrated Waveguide Directional
Coupler
  • A directional coupler
  • Different performance
  • couplers can be made by
  • varying the length,
  • size for specific
  • wavelength.

G Keiser
14
Couplers - Fabrication
  • Multimode Fibres
  • Wavelength independent, depends on how light is
    launched
  • In the coupling region
  • Higher order modes are trapped at the outer
    surface of the cladding thus becoming cladding
    modes
  • Lower order modes remain in the original fibre
    (as the incident angles are still gt the critical
    angle)
  • Cladding modes are converted back
  • into core modes at the output ports.
  • The splitting ratio is determined by the
  • length of the taper
  • thickness of the cladding.

Source Australian Photonics CRC
15
Couplers - Fabrication
  • Single Fibres
  • It is wavelength dependent. Resonance occur when
    the two fibres are close to each other.
  • The coupling length for 1.55 μm gt the coupling
    length for 1.3 μm
  • 100 of light coupling for 1.3 μm to the core of
    fibre B, and to the core of fibre A.
  • 100 of light coupling for 1.55 μm to the core of
    fibre B

Source Australian Photonics CRC
16
Couplers - Fabrication
  • The amount of power transmitted into fibres
    depend on the coupling length
  • The coupling length changes with the wavelength.
  • The splitting ratio can be tuned choosing the
    coupling length.
  • By choosing carefully the coupler length, it is
    possible to combine or separate Two different
    wavelengths

17
Coupler - Performance Parameters
  • Coupling ratio or splitting ratio
  • Excess Loss

18
Coupler - Performance Parameters
  • Insertion Loss
  • Isolation Loss or Crosstalk

In dB
19
Generic 2X2 Guided-Wave Coupler
There are altogether eight possible ways(two
ways) for the light to travel.
20
Generic 2X2 Guided-Wave Coupler
Assume Fraction (1- ?) of power in the input
port 1 appears at output port 1,and the remaining
power ? at the output port 2
Let Eo,2 0, thus in term of optical power
Half the input power appears at each output
21
Tree and Branch Coupler
Fibre
Coupling ratio 11 or 1 n, where n is some
fraction
22
Star Couplers
  • Optical couplers with more than four ports.
  • Types of star couplers
  • transmission star coupler
  • the light at any of the input port is split
    equally through all output ports.
  • reflection star coupler

23
Fibre Star Coupler
Combines power from N inputs and divided them
between M outputs
24
Star Coupler - 8 X 8
Star couplers are optical couplers with more than
four ports
25
Star Coupler - 8 X 8 - contd.
  • If a fraction of power traversing each 3 dB
    coupler Fp,
  • where 0lt Fp lt 1.
  • Then, power lost within the coupler 1- Fp.

Total loss splitting loss excess loss
26
Reflection Star Couplers
The light arriving at port A and is reflected
back to all ports. A directional coupler
separates the transmitted and received signals.
Source Australian Photonics CRC
27
Y- Couplers
Y-junctions are 1 x 2 couplers and are a key
element in networking.
28
Coupler - Characteristics
29
Splitters
  • The simplest couplers are fiber optic splitters.
  • They possess at least three ports but may have
    more than 32 for more complex devices.
  • Popular splitting ratios include 50-50,
    90-10, 95-5 and 99-1 however, almost any
    custom value can be achieved.
  • Excess loss assures that the total output is
    never as high as the input. It hinders the
    performance. All couplers and splitters share
    this parameter.
  • They are symmetrical. For instance, if the same
    coupler injected 50 μW into the 10 output leg,
    only 5 μW would reach the common port.

30
Coupler Splitter - Applications
  • Local monitoring of a light source output
    (usually for control purposes).
  • Distributing a common signal to several locations
    simultaneously.
  • Making a linear, tapped fiber optic bus. Here,
    each splitter would be a 95-5 device that
    allows a small portion of the energy to be tapped
    while the bulk of the energy continues down the
    main trunk.

31
Optical Filters
  • Passband
  • - Insertion loss
  • - Ripple
  • - Wavelengths (peak, center, edges)
  • - Bandwidths (0.5 dB, 3 dB, ..)
  • - Polarization dependence
  • Stopband
  • - Crosstalk rejection
  • - Bandwidths - (20 dB, 40 dB, ..)

Agilent Tech. LW Div.
32
Filters - Thin-film Cavities
  • Alternating dielectric thin-film layers with
    different refractive index
  • Multiple reflections cause constructive
    destructive interference
  • Variety of filter shapes and bandwidths (0.1 to
    10 nm)
  • Insertion loss 0.2 - 2 dB, stopband rejection 30
    - 50 dB

Agilent Tech. LW Div.
33
Fiber Bragg Gratings (FBG)
  • FBG is a periodic refractive index variation
    (Period ?) written along the fibre (single-mode)
    core using high power UV radiation.
  • All the wavelengths statisfying the condition ?0
    2 ? neff are reflected
  • If the optical period is ?0 / 2, the grating
    reflects wavelength ?0 selectively. Useful in
    filtering communication channels in or out.

?
34
Fiber Bragg Gratings (FBG)
Grating pattern etched into body of fibre
wavelength
Optical fibre
For a given grating period a particular
wavelength (frequency) of light is reflected. In
this case yellow light will be reflected
If the grating spacing is changed (e.g. reduced
due to compression of the fibre or a drop in
temperature the wavelength of the reflected
light changes. In this case it becomes higher and
reflects blue light
In practice the colour shifts will be much finer
than those illustated
http//www.co2sink.org/ppt/fbganimation.ppt
35
Fiber Brag Gratings (FBG) - contd.
  • Regular interval pattern reflective at one
    wavelength
  • Notch filter, add / drop multiplexer (see later)
  • Increasing intervals chirped FBG compensation
    for
  • chromatic dispersion

36
Optical Isolators
  • Only allows transmission in one direction through
    it Main application To protect lasers and
    optical amplifiers from returning reflected
    light, which can cause instabilities
  • Insertion loss
  • Low loss (0.2 to 2 dB) in forward direction
  • High loss in reverse direction20 to 40 dB
    single stage, 40 to 80 dB dual stage)
  • Return loss
  • More than 60 dB without connectors

37
Principle of operation
38
Optical Circulators
  • Based on optical crystal technology similar to
    isolators
  • Insertion loss 0.3 to 1.5 dB, isolation 20 to 40
    dB
  • Typical configuration 3 port device
  • Port 1 -gt Port 2
  • Port 2 -gt Port 3
  • Port 3 -gt Port 1

Agilent Tech. LW Div.
39
Dispersion Compensation using Chirped FBG and
Circulator
  • FBG is linearly chirped, I.e. the period of the
    grating varies linearly with position. This makes
    the grating to reflect different wavelengths at
    different points along its length. Therefore,
    introducing different delay.
  • In a standard fibre. Chromatic dispersion
    introduces larger delay for lower frequency (high
    wavelength) components of a pulse.
  • Chirped FBG introduces larger delay for the
    higher frequency components, thus compensating
    for the dispersion effect (I.e. compressing the
    pulse)

40
Add - Drop Multiplexers
  • Circulator with FBG
  • Dielectric thin-film filter design

Agilent Tech. LW Div.
41
Optical ADMux
  • Utilizes the full spectrum of the C and L band
    160 channels / single fibre
  • pair
  • Allows for the direct interface and transport of
    data rates from 100 Mbps
  • to 10 Gbps
  • Transports up to 160 OC-192 signals with a
    capacity of 1.6 Tb/s

Transmit wavelength adapoter
Error detection and correction
Receive wavelength adapoter
Wavelength Add/Dropp
Optical supervisory channel
42
ADMux System Performance
  • Capacity
  • 80 channels on ITU 50 GHz spacing
  • Upgradeable to 160 Channels (C and L band)
  • Bit Rate Compatibility 100 Mbps to 10 Gbps
    (OC-192)
  • Span Performance
  • 13 spans with 25 dB loss per span (OC-48)
  • 10 spans with 25 dB loss per span (OC-192)
  • Bit Error Rate Better than 10-16
  • Dispersion Tolerance
  • 600 to 900 ps/nm at 10 Gbps
  • gt 12,000 ps/nm at 2.5 Gbps

43
Multiplexers (MUX) / Demultiplexers (DEMUX)
  • Key component of wavelength-division multiplexing
    (WDM) technology
  • Types of technologies
  • Cascaded dielectric filters
  • Cascaded FBGs
  • Phased arrays (see later)
  • Low crosstalk is essential for demultiplexing

44
Array Waveguide Grating (AWG)
  • N X N demultiplexer
  • 1 X N demultiplexer!

Agilent Tech. LW Div.
45
AWG - contd.
  • Each l experience a different phase shift
    because of
  • different lengths of waveguide.
  • Phase shifts wavelength are dependent.
  • Thus, different channels focus to different
    output WG, on
  • exit.
  • N-input and N-output fibres
  • Single input wavelength demultiplexer!
  • 1990s - First developed
  • 1999 - Commercially available
  • No. of channels 250 to 1000 _at_ spacing of 10 GHz.

46
Multiplexers
Alcatel 1640 Line Terminal block diagram
47
Multiplexers Supervisory Channel
This extra channel, at 1510 nm, carries all the
management information. It also transports
Electrical Order Wire (EOW) data channels,
service channels, and control commands for house
keeping contacts.
Alcatel 1640 Line Terminal block diagram
48
Multiplexers
  • Transmission lengths of more than 900 km can be
    achieved on a 0.25 dB/km fibre.
  • The 240 channels using 3 optical bands
  • C (15301570 nm)
  • L (15701610 nm)
  • S (14501490 nm)
  • Error detection and correction
  • Different synchronous bit rate
  • Multi bit rae 2.5 Gbps, 10 Gbps and 40 Gbps
  • Judged by the insertion loss/channel

49
MUX - DeMUX - Performance
  • MUX
  • Judged by the insertion loss/channel
  • DeMUX
  • Sensitivity to polarisation
  • Crosstalk (lt -20 dB)

50
References
  • http//oldsite.vislab.usyd.edu.au/photonics/index.
    html

51
Next Lectures
  • Optical amplifier
  • Optical Switches
About PowerShow.com
金沙娱城乐怎么可以赢钱