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EE 230: Optical Fiber Communication Lecture 15

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EE 230: Optical Fiber Communication Lecture 15 WDM Components From the movie Warriors of the Net ITU Grid Wavelengths for CWDM and frequencies for DWDM defined by ... – PowerPoint PPT presentation

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Title: EE 230: Optical Fiber Communication Lecture 15


1
EE 230 Optical Fiber Communication Lecture 15
WDM Components
From the movie Warriors of the Net
2
ITU Grid
  • Wavelengths for CWDM and frequencies for DWDM
    defined by International Telecommunication Union,
    a part of the United Nations located in Geneva
  • Central frequency is 193.1 THz, equivalent to
    1552.52 nm
  • Frequencies for 50 GHz channel spacings are thus
    defined as 193.1 0.05n THz where n is a
    positive or negative integer

3
Active vs. Passive Devices
  • Passive requires no electrical power and
    transfer function cannot be modified by user
  • Active allows user to manipulate what it does
    to light pulses. Requires power.

4
Platforms for WDM components
  • Discrete optics thin-film filters,
    microelectromechanical systems (MEMS), isolators,
    circulators
  • All-fiber components couplers, Mach-Zehnder
    interferometers
  • Planar lightwave circuits (PLC)
    arrayed-waveguide gratings (AWG), couplers, MZs,
    etc.

5
Coupler parameters
  • Splitting ratio P2/(P1P2)
  • Excess loss 10 log (P0/P1P2)
  • Insertion loss 10 log (Pin/Pout)
  • Crosstalk 10 log (P3/P0)

6
Coupling as function of length
7
Mach-Zehnder Interferometer
  • where neff is determined from the Pcore/P graphs

8
Multiplexing/demultiplexing criterion
  • where ?L is the path length difference between
    the two arms

9
Wavelength dependence of MZ output
  • For wavelengths ?1 entering at input port 1, and
    ?2 entering at input port 2,

10
Wavelength adjustment (trim)
  • Coarse adjustment possible with fiber MZs by
    heating and pulling shorter arm to increase
    channel spacing
  • Fine adjustment for both fiber and PLCs done with
    UV irradiation to line transmission peaks up with
    ITU grid

11
Example
  • To multiplex four wavelengths separated by 50 GHz
    (0.4 nm)
  • How many stages needed?
  • (log2 W). How many total MZs?
  • Two in one stage, one in the next.
  • What is ?L for each stage?

12
Example, continued
  • If first frequency is ITU center, what are other
    three, and their wavelengths?
  • 193.10, 193.15, 193.20, and 193.25 THz
  • 1552.52, 1552.12, 1551.72, and 1551.32 nm
  • If neff1.45, determine ?L values

13
Example, continued
  • First stages have 100 GHz channel spacing, one
    for even-numbered wavelengths and one for odd.
    ?L equals c/2n(100x109)1.0 mm
  • Second stages have 50 GHz channel spacing. ?L
    c/2n(50x109)2.1 mm
  • As channel spacing gets smaller, it gets easier
    to make MZs (larger ?L)!

14
General MZ expression
  • For a multiplexer or demultiplexer with N
    wavelengths, you need nlog2N stages where the
    path length difference for stage i is

15
Arrayed-Waveguide Grating
16
AWG channel spacing
  • where nsinput/output waveguide index, nccentral
    waveguide array index, and

17
Tuning an AWG
  • Each input waveguide corresponds to a different
    center wavelength and channel spacing. Several
    waveguides around the center one will correspond
    to the correct channel spacing within the
    tolerance, and the peak wavelengths will vary
    from one waveguide to another.

18
WDM Muxes and Demuxes
19
Grating Based Demultiplexer
20
Optical Filters
21
Interference Filter Based WDM
22
Thermal drift in waveguide devices
  • ?n/?T for silica7.5x10-6 per degree
  • for silicon2.63 ppm per degree
  • d?/dT 12 pm per degree (red shift)
  • 2/3 due to thermooptic effect, 1/3 to CTE

23
Effect of thermal drift
  • Channel spacing100 GHz0.8 nm800 pm
  • DWDM device completely transparent every 800 pm,
    opaque between
  • Silica-on-silicon drifts 12 pm/?
  • Device becomes a beam stop if temperature changes
    by ?
  • 33?! Passive devices routinely T stabilized
    customers unhappy

24
Athermalization Techniques
  • Mechanical compensation flex entire chip,
    adjust point at which signal injected into device
  • Materials compensation design waveguide to be
    inherently athermal
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