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Optical Amplifiers

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The erbium ions decay rapidly to . They experience an atomically long lifetime ... Spontaneous decay of erbium ions from E2 to E1 will generate noise in the ... – PowerPoint PPT presentation

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Title: Optical Amplifiers


1
Optical Amplifiers
  • Why is there a requirement for optical
    amplifiers?
  • gt Light signal over long distances become
    attenuated.
  • gt Regeneration of the light signal is
    necessary especially over distances of perhaps
    several thousand kilometers.
  • gt The overhead of photodetection to
    electrical conversions and back to light via a
    lsaer diode. Contributes to high cost and speed.
  • Optical Amplifiers EDFA, Raman, Laser
    amplifier.

2
Erbium Doped Fibre Amplifier
  • Fibre amplifier
  • Core region is doped with ions.
  • Another rare earth ion dopant that is used is the
    neodynium ion ( )
  • Host fibre is glass based.( ) with
    other glass forming oxides ( )
  • Important factor It is possible to have
    relatively high concentrations of erbium in the
    core (up to 1000 ppm).

3
Erbium Doped Fibre Amplifier
  • Refer to energy diagram.
  • Erbium ions are optically pumped, typically by a
    980 nm laser diode. is raised to .
  • The erbium ions decay rapidly to . They
    experience an atomically long lifetime here (10
    ms).
  • Decays from
  • Therefore there is an accumulation of erbium ions
    at sitting 0.80 eV above ground.
  • This accumulation of erbium ions lead to a
    population inversion between .
  • Photons at 1550 nm have an energy of 0.80eV (
    ).

4
EDFA
  • This triggers stimulated emission of erbium ions
    from
  • Erbium ions left at E1 will absorb the incoming
    1550 nm photons and rise to E2.
  • Stimulated emission must exceed light absorption
    to achieve light amplification.
  • Therefore there must be more erbium ions at E2
    then at E1.

5
EDFA
  • Assume N2 and N1 are the number if erbium ions at
    E2 and E1.
  • The difference between stimulated emission (E2
    toE1) and absorption (E1 to E2) rate controls the
    optical gain.
  • where K is a constant that depends on
    pumping intensity.

6
EDFA
  • Considerations
  • Spontaneous decay of erbium ions from E2 to E1
    will generate noise in the amplified light
    signal.
  • If the EDFA is not pumped then it presents itself
    as an attenuator. 1550 nm photons will be
    absorbed by ions which will rise from E1
    to E2.

7
EDFA
  • The range of stimulated transistions from E2 to
    E1 correspond to a wavelength range of 1525 to
    1565 nm that can be amplified.
  • This delivers an optical bandwidth of 40 nm.
  • This permits usage with a WDM.
  • Problem gt Gain is not uniform across bandwidth.
  • Techniques must be implemented to flatten the
    response.

8
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10
EDFA
  • Factors controlling the degree of gain
    uniformity
  • Concentrations of the active ion (erbium).
  • Optical gain flattening filter.
  • Additional (second ) pump laser at each end of
    the fibre.
  • One pump beam propagates with signal
    beam while the other propagates against it.
    Ensures that population inversion and gain
    remains constant along the fiber.

11
EDFA
  • Physical Components of EDFA
  • Biconical fused fibre couplers.
  • One or two (if high output required) laser pumps.
  • Polarization-insensitive optical isolators front
    and back. Allows only 1550 nm signals to pass.
    Pump radiation should not enter main fibre as
    well as optical feedback from reflections.
  • Optical filter for gain flattening.
  • Phgotodetector system to monitor pump power or
    EDFA output power.
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