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Ch 6: Optical Sources

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... EDFA EDFA: Gain EDFA Raman Amplifiers Ch 6: Optical Sources Variety of sources LED Recent advances: LED: Light Emission LED: Coupling LED: ... – PowerPoint PPT presentation

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Title: Ch 6: Optical Sources


1
Ch 6 Optical Sources
  • Variety of sources
  • LS considerations
  • Wavelength
  • Dl
  • Output power
  • Modulation
  • Coupling
  • Cost/performance
  • LED
  • Operation
  • Spontaneous emission

2
LED
  • lhc/ePH
  • Recent advances
  • Porous silicon
  • Semiconductor polymers

3
LED Light Emission
4
LED Coupling
5
LED Characteristics
  • Low cost
  • Low power 100 uW (recently 75 mW)
  • Wide spectrum 50-100 nm
  • Incoherent light neither directional nor coherent
  • Digital modulation up to 300 Mbps
  • Analog modulation simply

6
LD
  • LASER Light Amplification by the Stimulated
    Emission of Radiation
  • For stimulated emission to happen
  • Material capable of st. emission (have a
    metastable high energy state
  • Laser active media
  • Laser action Absorption, spont. Emission,
    stimulated emission
  • Population inversion pumping

7
LD
  • Lasing requires
  • Active medium
  • Supplying energy
  • Confinement

8
Fabry-Perot Laser
  • LED with couple of mirrors
  • Fabry-Perot resonator
  • Operation
  • Llx/2n

9
FPL
Modes
Spectral Characteristics
10
FPL
Gain threshold
11
DFB Laser
  • Disadvantages of FPL
  • Spectral width of 5-8 nm
  • Mode hopping
  • WDM
  • DFB Operation

12
DFB Laser
  • DFB Phase shifted grating
  • DFB Spectral characteristics

13
DFB Characteristics
  • Very narrow linewidths
  • Low chirp
  • Low relative intensity noise (RIN)
  • Sensitive to reflections
  • Temperature sensitive
  • Output power fluctuations
  • High cost
  • Speed?

14
DFB
  • Integrated Electro-Absorption Modulator
  • Q-Switching
  • Stability?

15
Distributed Bragg Reflector (DBR)
  • More stable
  • Less efficient
  • Quantum Well Lasers (QW)
  • When light is confined to an area l, it behaves
    like a particle
  • Fundamental differences of SQW over non QW
  • Reduction in lasing threshold
  • Low output power
  • No lateral modes
  • Narrower linewidth

16
MQW/Tunable DBR
  • MQW vs SQW
  • Strained layer QW
  • High power
  • Construction
  • Low threshold
  • Advantages
  • Breadth of materials
  • Broader linewidth
  • Tunability
  • Tunable DBR Lasers
  • 3 section tunable DBR
  • Complex electronics
  • 10 nm range

17
Tunable DBR
  • Sampled grating TDBR
  • 100 nm range
  • External Cavity TDBR
  • Wide range
  • Slow
  • Expensive

18
Frequency stabilized DBR
  • External fiber cavity DBR
  • Low cost
  • Accurate wavelength control
  • Narrow linewidth
  • Temepreture control is shifted out
  • Difficult positioning
  • Coherence collapse operation

19
Vertical Cavity Surface Emitting Laser
  • Low power
  • Scarce of wavelengths
  • MM and SM lasers
  • Easy coupling
  • Low threshold current
  • Simple electronics
  • High modulation BWs
  • Very stable

20
In Fiber Lasers
  • Characteristics
  • High output power
  • Low noise
  • Tunability
  • Very narrow linewidths
  • Good soliton generation
  • External modulation is required
  • Preselected wavelength
  • Mode hopping
  • Upconversion (double pumping)

21
Comparison
22
Optical Amplifiers EDFA
Materials Praseodymium Neodymium
L Band CoDopants Longer fiber
2nd generation Gain control Gain equalization
Wavelengths 1480 980
23
EDFA Gain
24
EDFA
25
Raman Amplifiers
  • Multistage
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