Dispersion Syed Abdul Rehman Rizvi Optical Communication Intermodel
Dispersion Syed Abdul Rehman Rizvi Optical Communication
Intermodel dispersion (Multimode dispersion) Φc X X X L L X= L/SinΦc= n 2/n 1 Optical Communication
Intermodel dispersion (Multimode dispersion) T he extent of pulse broadening can be estim ated by considering the longest and shortest ray paths. T he shortest path occurs for θ i = 0, and is just equal to the fiber lenght 'L'. T he longest path occurs for θ i show n previously and has a lenght 'L/sin Φ c. v = c / n 1 , the tim e delay is given by ; ∆ T = TM ax − TM in L n 1 − L x−L s n 2 Ln 1 − n 2 = = n 1 c v v cn 2 n 1 = Ln 12 ∆ cn 2 W hen ∆ << 1 under this condition ∆ = n 1 − n 2 m ay also be true n 2 Ln 1 �n 1 − n 2 � ∆ T = Ln 12 − Ln 1 = � − 1� = � � cn 2 c c �n 2 � c � n 2 � = Ln 1 ∆ Ln 12 2 ∆ L ( N A ) 2 = = c 2 n 1 c �Q (N A ) 2 = 22 n 1 � ∆ � Optical Communication
The time delay between the two rays taking the shortest and longest paths is a measure of broadening experienced by an impulse launched at the fiber input. We can relate ∆T to the information-carrying capacity of the fiber measured through the bit rate B. Although a precise relation between B and ∆T depends on many details, Requirement for minimal inter symbol interference: B ∆t < 1 where B = bit rate Optical Communication
Dispersion in single mode fiber Intermodal dispersion in multimode fibers leads to considerable broadening of short optical pulses (~ 10 ns/km). In geometrical optics description this is attributed to different paths followed by different rays. In the modal description it is related to the different mode indices or group velocities associated with different modes. The main advantage of single mode fiber is that intermodal dispersion is absent but that doesn’t mean that dispersion has vanished altogether. The group velocity associated with the fundamental mode is frequency dependent because of chromatic dispersion. The result is that different spectral components of the pulse travel at slightly different group velocities and the phenomena is referred as group-velocity dispersion (GVD), intramodal dispersion or simply fiber dispersion.
Intramodal dispersion has two contributions, material dispersion and waveguide dispersion, such that D = DM + DW Where DM is material dispersion and waveguide dispersion. Optical Communication DW is
Group-Velocity Dispersion Consider a single-mode fiber of length L. A specific spectral component at the frequency ω would arrive at the output end of the fiber after a time delay L T= vg Where vg is the group velocity defined as dω 1 − 1 = (dβ dω ) = vg = dβ dβ dω
Remember at the same time, phase velocity is defined as ω vp= β In nondispersive medium the phase velocity is independent of the wave frequency and the group velocity and phase velocity are the same. So in such case v p = vg Optical Communication
By using β = n k 0 = n ω c where n is mode index or effective index, β is propagatio n constant, k 0 is free space propagtion constant or free space wave number k 0 = ω c = 2π λ and ω is angular frequency. At the same time vg = c ng Where ng is the group index given by ng = n + ω (dn dω )
The frerquency dependence of group velocity leads to pulse broadening because different spectral components of the pulse disperse during propagation and don't arrive simultaneously at the fiber output. If ∆ω is the spectral width of the pulse, the extent of pulse broadening for a fiber of length L is governeddb by d �L � d. T ∆ω = ∆T = � � ∆ω � dω dω � �vg � d 2β =L 2 ∆ω dω = Lβ 2 ∆ ω ( Q T = L vg ) ( Q vg = ( dβ dω) ) -1 The parameter β 2 = d 2 β dω 2 is known as the GVD parameter. It determines how much an optical pulse would broaden on propagation inside the fiber.
In some optical communicat ion systems, the frequency spread ∆ω is determined by the range of waveleng ths ∆λ in place of ∆ω. By using ω = 2π c λ and ∆ω = (− 2π c λ 2 )∆λ d �L � � �∆ω Q ∆T = dω � �v g� � Where d �L � � �∆ω = DL ∆λ ∴∆T = � dλ � v g � � d � 1 � 2πc � � =− 2 β 2 D= λ dλ � �vg � D is called the dispersion parameter and is expressed in units of ps/(km - nm).
T h e e ffe c t o f d is p e rs io n th e b it ra te B c a n b e e s tim a te d b y u s in g th e c rite rio n B ∆ T < 1. B y p u ttin g th e v a lu e o f ∆ T = D L ∆ λ th is c o n d itio n becom es BL D ∆ λ < 1 F o r s ta n d a rd fib e r s D is re la tiv e ly s m a ll in th e w a v e le n g h t re g io n n e a r 1 3 0 0 n m [ D ~ 1 p s /(k m -n m )]. F o r a s e m ic o n d u c to r la s e r th e s p e c tra l w id th ∆ λ is 2 -4 n m. T h e B L p ro d u c t o f s u c h lig h t w a v e s y s te m s c a n e x c e e d 1 0 0 (G b /s ) -k m. T e le c o m m s y s te m s w o rk in g a t 1 3 0 0 n m ty p ic a lly o p e ra te a t a b it ra te o f 2 G b /s w ith a re p e a te r s p a c in g o f 4 0 -5 0 k m. B L p ro d u c t o f s in g le m o d e fib e r c a n e x c e e d 1 (T b /s )-k m w h e n s in g le m o d e s e m ic o n d u c t o r la s e rs w ith ∆ λ b e lo w 1 n m. Optical Communication
D d ep en d s u p o n o p eratin g w avelen g th b ecau se o f freq u en cy d ep en d en ce o f m o d e in d ex n. W e alread y k n o w th at ∴D = − 2 λ D= d dλ � 1 � �v g � � 2π c d � 1 � � dn 2π d 2 n � +ω � −� 2= � 2 � v � dω � λ � d ω 2 � � g� u sin g th e relati o n n g = n + ω ( dn d ω ) D can b e w ritten as su m o f tw o term s D = D M + DW W h ere th e m aterial d isp ersio n D M an d th e w aveg u id e d isp ersio n DW are g iven b y Optical Communication
2π dn 2 g 1 dn 2 g = DM = − 2 λ dω c dλ 2π∆ �n 2 g Vd 2 ( Vb ) dn 2 g d ( Vb ) � + � DW = − 2 � 2 λ � dω d. V � �n 2ω d. V where n 2 g is group index of material and V is 2 normalized frequency and b is normalized propagation constant as already defined. ∂ A/∂ z Optical Communication
ZMD
Optical Communication
• The single-mode values of interest are from V = 2. 0 to 2. 4, as shown in Fig. • The value of Vd 2(Vb)/d. V 2 decreases monotonically from 0. 64 down to 0. 25.
Optical Communication
Material dispersion occurs because the refractive index of silica, the material used for fiber fabrication, changes with the optical frequency ω. On a fundamental level, the origin of material dispersion is related to the characteristic resonance frequencies at which the material absorbs the electromagnetic radiation. Far from the medium resonances, the refractive index n(ω) is well approximated by the Sellmeier equation. Optical Communication
where ωj is the resonance frequency and B j is the oscillator strength. Here n stands for n 1 or n 2, depending on whether the dispersive properties of the core or the cladding are considered. In the case of optical fibers, the parameters Bj and ωj are obtained empirically by fitting the measured dispersion curves. They depend on the amount of dopants (Boron, arsenic and Antimony etc). Optical Communication
Figure shows the wavelength dependence of n and n g in the range 0. 5– 1. 6 µm for fused silica. Material dispersion DM is related to the slope of ng by the relation DM = c− 1(dng/d λ). It turns out that dng/d λ= 0 at λ= 1. 276 µ m. This wavelength is referreddtto as the zero-dispersion wavelength λZD, since DM = 0 at λ= λZD. The dispersion parameter DM is negative below λZD and becomes positive above that. In the wavelength range 1. 25– 1. 66 µ m it can be approximated by an empirical relation.
Lemda zero may be extended to 1550µm Lowering the normalised freq Increasing the relative refractive index difference ∆ Suitable doping of the silica with germenium. Optical Communication
Waveguide Dispersion The contribution of waveguide dispersion DW to the dispersion parameter D is given by following Eq. DW is negative in the entire wavelength range 0– 1. 6 µm. On the other hand, DM is negative for wavelengths below λZD and becomes positive above that. D = DM +DW, for a typical single-mode fiber. The main effect of waveguide dispersion is to shift λZD by an amount 30– 40 nm so that the total dispersion is zero near 1. 31 µ m. It also reduces D from its material value DM in the wavelength range 1. 3– 1. 6 µ m that is of interest for optical communication systems. Typical values of D are in the range 15– 18 ps/(km-nm) near 1. 55 µ m. This wavelength region is of considerable interest for lightwave systems, since the fiber loss is minimum near 1. 55 µ m. High values of D limit the performance of 1. 55 - µ m lightwave systems.
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Since the waveguide contribution DW depends on fiber parameters such as the core radius a and the index difference ∆, it is possible to design the fiber such that λZD is shifted into the vicinity of 1. 55 µm. Such fibers are called dispersion shifted fibers. It is also possible to tailor the waveguide contribution such that the total dispersion D is relatively small over a wide wavelength range extending from 1. 3 to 1. 6 µm. Such fibers are called dispersion-flattened fibers. The design of dispersion modified fibers involves the use of multiple cladding layers and a tailoring of the refractiveindex profile. Waveguide dispersion can be used to produce dispersiondecreasing fibers in which GVD decreases along the fiber length because of axial variations in the core radius. In another kind of fibers, known as the dispersion compensating fibers, GVD is made normal and has a relatively large magnitude.
Higher order dispersion BL product of a single-mode fiber can be increased indefinitely by operating at the zero-dispersion wavelength λZD where D = 0. The dispersive effects, however, do not disappear completely at λ = λZD. Optical pulses still experience broadening because of higherorder dispersive effects. This feature can be understood by noting that D cannot be made zero at all wavelengths contained within the pulse spectrum centered at λZD. Clearly, the wavelength dependence of D will play a role in pulse broadening. Higher-order dispersive effects are governed by the dispersion slope S = d. D/dλ. The parameter S is also called a differentialdispersion parameter. Optical Communication
where β 3 = dβ 2/dω≡ d 3 β/dω3 is the third-order dispersion parameter. At λ= λZD, β 2 = 0, and S is proportional to β 3. The numerical value of the dispersion slope S plays an important role in the design of modern WDM systems. It may appear from following Eq. that the limiting bit rate of a channel operating at λ = λZD will be infinitely large. However, this is not the case since S or β 3 becomes the limiting factor in that case. Optical Communication
We can estimate the limiting bit rate by noting that for a source of spectral width ∆ λ, the effective value of dispersion parameter becomes D = S∆ λ . The limiting bit rate–distance product can now be obtained by using this value of D. The resulting condition becomes Optical Communication
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