Fiber Bragg Gratings Fiber Grating Fiber grating is
Fiber Bragg Gratings
Fiber Grating • Fiber grating is made by periodically changing the refraction index in the glass core of the fiber. The refraction changes are made by exposing the fiber to the UV-light with a fixed pattern. Glass core Glass cladding Plastic jacket Periodic refraction index change (Gratings)
Fiber Grating Basics • When the grating period is half of the input light wavelength, this wavelength signal will be reflected coherently to make a large reflection. – The Bragg Condition trans. in reflect Reflection spectrum Transmission spectrum n r = 2 neff (refraction index difference)
Fiber Bragg Grating: Theory 1978 – Hill et. all • Phenomenon of photosensitivity in optical fibers • Exposed Ge-doped core fibers to intense light at 488 or 514 nm • Induced permanent refractive index changes to the core.
Fiber Bragg Grating: Theory • FBG is a longitudinal periodic variation of the index of refraction in the core of an optical fiber. • The spacing of the variation is determined by the wavelength of the light to be reflected.
Fiber Bragg Grating: Theory The Bragg Condition is the result of two requirements: 1. Energy Conservation: Frequency of incident radiation and reflected radiation is the same. 2. Momentum Conservation: Sum of incident wave vector and grating wave vector equal the wave vector of the scattered radiation. K + ki = kf The resulting Bragg Condition is: • • • B = 2 neff The grating reflects the light at the Bragg wavelength ( B) B is a function of the grating periodicity ( ) and effective index (neff). Typically; B= 1. 5 mm, = 0. 5 mm
Fiber Bragg Grating: Theory • The spectral component reflected (not transmitted) typically has a bandwidth of 0. 05 – 0. 3 nm. § A general expression for the approximate Full Width Half Maximum bandwidth of a standard grating is given by (S = grating parameter (. 5 to 1), N = numbers of grating pains): Δλ =λ B S( (Δn/2 n 0)2 + (1/N)2 )1/2
Fiber Bragg Grating: Theory • The shift in Bragg Wavelength with strain and temperature can be expressed using: B = 2 n ({1 -(n 2/2)[P 12 – n(P 11 + P 12)]}e + [a + (dn/d. T)/n] T Where: e = applied strain Pi, j = Pockel’s coef. of the stress-optic tensor n = Pisson’s ratio a = coef. of thermal expansion T = temperature change [P 12 – n(P 11 + P 12)] ~ 0. 22 • The shift in Bragg Wavelength is approximately linear with respect to strain and temperature.
Fiber Bragg Grating: Theory • The measured strain response at a constant temperature is found to be: (1/ B)d B/ de = 0. 78 x 10 -6 me-1 • Sensitivity Rule of thumb at B = 1300 nm: 0. 001 nm/me
Fiber Bragg Grating: Theory • The measured temperature response at a constant strain is found to be: (1/ B)d B/ d. T = 6. 67 x 10 -6 o. C-1 • Sensitivity Rule of thumb at B = 1300 nm: 0. 009 nm/ o. C
Fiber Bragg Grating: Theory – Blazed Grating • Bragg grating planes are tilted at an angle to the fiber axis. • Light which otherwise would be guided in the fiber core, is coupled into the loosely bound, guided cladding or radiation modes. • The bandwidth of the trapped out light is dependent on the tilt angle of the grating planes and the strength of the index modulation. • As shown above, the vector diagram is a result of the conservation of momentum and conservation of energy requirement. The results of applying the law of cosines yealds: Cos(θb) = ׀ K ׀ /2 v
Fiber Bragg Grating: Theory – Chirped Grating • Bragg grating has a monotonically varying period as illustrated above. • These gratings can be realized by axially varying either the period of the grating or the index of refraction of the core or both. • The Bragg Condition becomes: λB = 2 neff(z)Λ(z) • The simplest type of chirped grating is one which the grating period varies linearly with axial length: Λ(z) = Λ 0 + Λ(z)
Chirped FBG f 1 f 2 f 3 Incident Reflected Dispersion comp. at Chirped FBG 0 Relative Time Delay (ps) 0 Wavelength (nm) Linearly Chirped Dispersion = d. T/d (ps/nm)
Creating Gratings on Fiber • One common way to make gratings on fiber is using Phase Mask for UV-light to expose on the fiber core.
Characteristics of FBG • It is a reflective type filter – Not like to other types of filters, the demanded wavelength is reflected instead of transmitted • It is very stable after annealing – The gratings are permanent on the fiber after proper annealing process – The reflective spectrum is very stable over the time • It is transparent to through wavelength signals – The gratings are in fiber and do not degrade through traffic wavelengths, very low loss • It is an in-fiber component and easily integrates to other optical devices
Temperature Impact on FBG • The fiber gratings is generally sensitive to temperature change (10 pm/°C) mainly due to thermo-optic effect of glass. • Athermal packaging technique has to be used to compensate the temperature drift
Types of Fiber Gratings TYPES CHARACTERS APPLICATIONS Simple reflective gratings Creates gratings on the fiber that meets the Bragg condition Filter for DWDM, stabilizer, locker Long period gratings Significant wider grating periods that couples the light to cladding Gain flattening filter, dispersion compensation Chirped fiber Bragg gratings A sequence of variant period gratings on the fiber that reflects multiple wavelengths Gain flattening filter, dispersion compensation Slanted fiber gratings The gratings are created with an angle to the transmission axis Gain flattening filter
Typical FBG Production Procedures Select Proper fiber H 2 loading Different FBG requires different specialty fiber Increase photo sensitivity for easier laser writing Laser writing Optical alignment & appropriate laser writing condition Annealing Enhance grating stability Athermal packaging For temperature variation compensation Testing Spec test
Current Applications of FBG • • • FBG for DWDM FBG for OADM FBG as EDFA Pump laser stabilizer FBG as Optical amplifier gain flattening filter FBG as Laser diode wavelength lock filter FBG as Tunable filter FBG for Remote monitoring FBG as Sensor ….
Possible Use of FBG in System Wave locker ITU FBG filter E/O Multiplexer Demux ITU FBG filter Pump stabilizer & Gain flattening filter Dispersion compensation filter Dispersion control EDFA OADM EDFA Switch Pump stabilizer & Gain flattening filter ITU FBG filter Tunable filter Monitor sensor Monitor
ITU FBG Filter for DWDM Circulator 1, 2 … n Multiplexer FBG at 1 1 Circulator 1, 2 … n 1 De-multiplexer FBG at 1 Circulator FBG at 2 Circulator 2 3 Circulator 2 FBG at 2 3 FBG at 3 . . .
ITU FBG Filter for OADM Incoming signal Outgoing signal Through signal Circulator FBG Dropped signal Added signal
Dispersion Compensation Filter circulator Dispersed pulse Chirped FBG
FBG and Dispersion Compensation 1 2 3 4 5 Fiber Dispersion t t FBG Disp. Comp. t t
Pump Laser Stabilizer + Fiber Pump Laser Focal lens 980 spectrum 980 Stabilizer
Gain Flattening Filter Gain profile GFF profile Output
- Slides: 26