Www.bzupages.com. Band width Refractive Index Wavelength Information carrying capacity of optical fiber. The ratio of velocity of light in vacuum to velocity.

Slides:



Advertisements
Similar presentations
Properties of Light.
Advertisements

Unit-2 Polarization and Dispersion
Reflection and Refraction of Light
Instructor: Sam Nanavaty Fiber Optics-1. Instructor: Sam Nanavaty Advantages of Fiber Optics Bandwidth Low attenuation (few tenths of dB/Km) Immune to.
Waveguides Part 2 Rectangular Waveguides Dielectric Waveguide
Chapter 2 Optical Fibers: Structures, Waveguiding & Fabrication
Chapter Fifteen: Radio-Wave Propagation
Lecture 3 Light Propagation In Optical Fiber
© John Parkinson 1 © John Parkinson 2 I think we are being watched! Refraction is the Bending of Waves due to a Change in Velocity Refraction is the.
1 UCT PHY1025F: Geometric Optics Physics 1025F Geometric Optics Dr. Steve Peterson OPTICS.
LIGHT A FORM OF ELECTROMAGNETIC RADIATION THAT STIMULATES THE EYE.
Optical Fiber Basics Part-3
UNIT III Lecture 61 Fiber optics Basic principles Physical structure of optical fibre Propagation characteristics of optical fibre PH 0101 UNIT-3 LECT.
Fiber-Optic Communications James N. Downing. Chapter 2 Principles of Optics.
INTRO TO SPECTROSCOPIC METHODS (Chapter 6) NATURE OF LIGHT AND INTERACTION WITH MATTER Electromagnetic Radiation (i.e., “light”) –Wave-particle duality.
Bending and Bouncing Light Standing Waves, Reflection, and Refraction.
Lecture 4b Fiber Optics Communication Link 1. Introduction 2
Fiber-Optic Communications
Optical Fiber Communications
FIBER OPTICS Light propagation through thin glass fibers.
Chapter 33. Electromagnetic Waves What is Physics? Maxwell's Rainbow The Traveling Electromagnetic Wave, Qualitatively The Traveling.
Reflection and Refraction of Light
PHY2054 Fall 2011 The second exam is on Tuesday Nov. 8, 8:20-10:10PM. Please check the room assignments on the exam page. HW set 7 was due Monday 10/24.
NET 535 : NEW TECHNOLOGIES DR.HANAA ABDALAZIZ ABDALLAH 1.
Fiber-Optics Chad Richmond Aaron Parker Billy Spies Fiber.
Review: Laws of Reflection and Refraction
OPTICAL MINERALOGY Dr. AZZA RAGAB.
Optical Fiber Basics-Part 2
By: Dr. N. Ioannides (Feb 2010)CT0004NI - L.06 – Fibre Optic Communications - pp 1/28 Fibre Optic Communications Saroj Regmi Lecture 06 CT0004NI Principles.
The Hong Kong Polytechnic University Optics II----by Dr.H.Huang, Department of Applied Physics1 Light Waves Nature of Light: Light can be viewed as both.
Reflection and Refraction of Light
 Name : Amandeep Rai  Enrollment No. :  Department : Mechanical  Subject : Physics  Subject Teacher : Mitesh D.Parmar.
Fiber Optics Nov 21, Announcements One lecture left in the semester –Next class, Dec 5 - Wireless System –Suggested problems to prepare for Final.
Fiber Optic Transmission
Objectives Understand the importance of fiber-optic technologies in the information society Identify the fundamental components of a fiber-optic cable.
Lecture Six: The Nature of Light and the Laws of Geometric Optics
The Nature of Light and the Laws of Geometric Optics
Light Refraction of Light. Learning Objectives You will learn to recall and use the terms used in refraction, including normal, angle of incidence and.
Fiber Optic Transmission SL/HL – Option C.3. Reflection/Refraction Reflection – A wave encounters a boundary between two mediums and cannot pass through.
The Nature of Light The earliest (~1000 A.D.) description of light was that of a stream of tiny particles –Newton described light with a particle model.
Reflection and Refraction
Light Waves.
Chapter 2 Light Propagation In Optical Fiber
Chapter 22 Reflection and Refraction of Light. The Particle Nature of Light “Particles” of light are called photons Each photon has a particular energy.
.. What Happened?? Look at the data you collected during the simulation Are the angles the same for every scenario? Why is there a difference?
Physics 213 General Physics Lecture Last Meeting: Electromagnetic Waves, Maxwell Equations Today: Reflection and Refraction of Light.
1 The Nature of Light and the Laws of Geometric Optics.
Fiber Optic Transmission SL/HL – Option F Mr. Jean.
FIBER OPTIC TRANSMISSION
How Light Behaves at a Boundary
Fiber Optics.
IB Physics Option F – Fibre Optics Mr. Jean. The plan: Video clip of the day Fibre Optics – C+-+Imaginghttps://ibphysics2016.wikispaces.com/Option+
ENE 429 Antenna and Transmission lines Theory
Refraction. Have you ever seen this? Refraction of Light When light travels through a surface between two different media, the light will be refracted.
OPTICAL FIBER COMMUNICATION
6/8/20161 Chapter 2 Light Propagation In Optical Fiber.
Unit-3 FUNDAMENTALS OF FIBER OPTIC COMMUNICATION.
UPM, DIAC. Open Course. March FIBER 2.1 Nature of Light 2.2 Refractive Index 2.3 Fiber Structure 2.4 Waves 2.5 Rays.
RAY THEORY AND OPTICAL WAVEGUIDE BY DR. NEENA GUPTA Assistant Professor E&EC Deptt. Punjab Engineering College,Deemed University,CHANDIGARH.
Digital Hierarchies There are two hierarchical structures that exist for digital networks: 1. Plesiochronous Digital Hierarchies 2. Synchronous Digital.
Optical Fiber Basics Part-3
EC2402 -OPTICAL COMMUNICATION AND NETWORKING
OPTICAL FIBRE BASED ON MODES (OR) MODE TYPES
Optical Fiber.
The Optical Fiber and Light Wave Propagation
Reflection and Refraction of Light
The law of reflection: The law of refraction: Image formation
ENGINEERING PHYSICS B.TECH :I YEAR SEM-I MECHANICAL & CIVIL
OPTICAL FIBER AND ITS APPLICATIONS
OPTICAL FIBRES.
Presentation transcript:

Band width Refractive Index Wavelength Information carrying capacity of optical fiber. The ratio of velocity of light in vacuum to velocity of Light in other transmission medium. The distance between crests of electromagnetic waveform measured in nm. Wavelength

1.Reflection The amount of light reflected away from the surface. Two types of Reflections. Diffuse Reflection: The reflection from rough surface. Specular Reflection: The reflection from smooth surface. A good mirror is specular reflection source. According to law of reflection The angle of incidence = Angle of reflection

2. Absorption It describes the amount of light that is absorbed by the surface when it strikes. Absorption varies with different chemical substances. 3. Transmission The amount of electromagnetic radiations transmitted through a substance or media is called Transmission. The total of light transmitted towards a substance consists of some reflection, some absorption and some transmission.

4. Refraction As electromagnetic wave changes direction at the interface of two mediums, if the angle of incidence is not 90 then the index of refraction of light is the sine of angle of incidence to the sine of angle of refraction. The refractive index is the function or wavelength. The Snells law is n1/n2 = sinβ/ sinα When light moves from rare medium to denser medium it refracts towards normal and vice versa. n1 n2 α β Away movement Normal Rare Medium Denser Medium › › ›

5.Total Internal Reflection If the light rays enter from optically denser medium to optically rare medium, it will move away from the normal. If the angle of incidence is increased so that the angle of refraction becomes The phenomena known as total internal reflection will occur,if angle of incidence is further increased. The light instead of refracting will reflect internally. The phenomenon used in optical fibre communication/ propagation.

Jacket Cladding (lower refractive index) Light Core (higher refractive index) α0α0 3 2 β0β0 Medium 1 Medium Rare Medium Denser Medium

6.Polarization Light consists of two fields perpendicular to each other electric field and magnetic field. In normal light there are infinite number of perpendicular osculating planes propagated in the direction of travel of light. The light can be polarized by reflection and refraction. Example many people buy sunglasses that reduce reflection from wet roads effect due to sun.

TE (Transmittance of electrically polarized vector) If the field intensity of electrical vector remains unchanged and the field intensity of magnetic vector decreases, it is called TE polarized. TM (Transmittance of magnetically polarized vector) In which magnetic field intensity is unchanged and electric field intensity is minimized.

Magnetic field M Electric field E The fields propagate synchronously E M

Laser Light enters the fibre strikes the core cladding boundary, the angle of incidence is such that the light is totally reflected in to the fibre core due to difference of refractive indices of core & cladding on the principle of total internal reflection. The light travels in a core of single/ multi mode step index fibres in this manner until it reaches at the other end of the fibre. Core cladding boundary Cladding Core Normal

Classification Of Optical Fibre - According to light propagation a. Single/ mono-mode b. Multimode According to refractive index (a) Step index fibre The refractive index of core is uniform and it undergoes abrupt change at the boundary of Core and Cladding. The light is propagated along fibre on the principle of total internal reflection.

(b) Graded index fibre The refractive index of the core is non uniform. It varies gradually along the radius of core. The light waves travel as sine waves along the core. Types Of Propagation In Fibre (a) Reflective type - Single mode step index - Multi mode step index (b) Refractive type - Multi mode graded index

125 μm 50 μm Multimode graded index fibre 125 μm 10 μm Singlemode step index fibre

S.NoMM.SIMMGISMSI (1)Core dia 50µm50µm10µm (2)Used for short haul distance used for short haul distance used for long haul distance (3)Core R.I constant gradually varies core R.I constant (4)Signal is delayed no delay (5)Power launching is easy easydifficult (6)LED can be used LEDLaser (7)Splicing is easy easy difficult Comparison Of Various Fibres

The Characteristics Of Single mode Step Index Fiber The single mode step index fibre has the characteristics of low attenuation, less dispersion, large bandwidth, low cost and Recommended by ITU.T for long distance optical transmission.

Types Of Single Mode Step Index Fibres. There are four types of single mode step index Optical Fibres recommended by ITU-T. G-652 It is single mode Non dispersion shifted fibre (NDSF) also called 1310nm property single mode fibre. The zero dispersion point is at 1310nm. It is used by PTCL. G-653 It is dispersion shifted fibre or 1550 nm property fibre. The zero dispersion point is shifted near to 1550 nm Optical window to minimize attenuation in this window and to achieve ultra high speed and ultra long distance for Optical transmission. It is also called dispersion shifted fibre (DSF).

G-654 It is cutoff wavelength shifted single mode fibre. This type of fibre is designed to reduce attenuation at 1550 nm window. Its zero dispersion point is still near 1310 nm window. It is mostly used for submarine Optical Fibre communication to achieve long regenerator distance. G-655 It is non zero dispersion shifted fibre (NZDSF). It preserves some dispersion near 1550nm window to avoid four wave mixing phenomenon. It is most suitable for DWDM applications for bit rates >2.5 Gb /sec.

Applications - Long Distance Network. - Local/ Junction Network. - Fibre Access Network. - Submarine Network. - Free Space Optics (FSO). - All Photonic Network. - Cable TV Network. - Medical Services. - Angiography/ Andoscopy. - Military Services. - Dense wavelength Division Multiplexing.

Normalized Frequency (V) The number of modes that can pass through fibre core are dependant on normalized frequency. V= 2πa x √N N 2 2 λ Modes Modes are possible route that light wave follow down in an optical fiber. One to hundred & even thousand of modes are transmitted N=V 2 2

Numerical Aperture This parameter describes the light gathering ability of fibre. The amount of optical power accepted by fibre. The sine value of acceptance angle is called Numerical Aperture sinβ = √N N 2 2.

n2 n1 n0n0 α β

Mode Field Diameter It describes the radial propagation of fundamental mode. A core diameter and a portion of cladding is called MFD. The mode field diameter of G652 fibre at 1310 nm is 8.6 to 9.6µm. The MFD for G655 fibre at 1550 nm is 8 to 11µm with deviation less than 10%. It is a performance measure of fibre when coupled to light source.

Mode Field Concentricity Error The distance between the core centre and cladding centre divided by core diameter of the interconnected fibre. The connector loss is proportional to the square of the mode field concentricity error. The MFCE is used to reduce connector loss. The MFCE value should not exceed.5 in both G652 and G655 fibres.

Cut Of Wavelength The cutoff wavelength can guarantee single mode generation. In shortest cable to suppress the occurrence of higher order modes and to reduce power penalty. e.g. for G652 fibre the cut off wavelength <1260 nm for 2m cable, for G655 the cut off wavelength < 1480 nm for 2 m cable length.