Trivia Question Which “Big Bang Theory” character is an Optical Physicist? (a) Sheldon Cooper (b) Leonard Hofstadter (c) Howard Wolowitz (d) Raj Koothrappali (e) Amy Farrah Fowler d c a e b
The grand overview of Optics/Photonics Historical Development: Ray Optics → Wave Optics → EM Optics → Quantum Optics. We will cover only CLASSICAL Optics in this course. EM Optics is the most general for optical phenomena which can be explained classically. This uses Maxwell’s Equations from Physics 121. Wave optics is a SCALAR approximation of EM Optics. (No vector properties of E Field) Ray Optics is an approximation in which wavelength short (Diffraction ignored).
Why are we not covering book in order? Material will be covered in the ‘logical’ historical progression of Ray then Wave then EM optics. Text book chapters are not ordered in this ‘logical’ progression. Ray optics requires ALOT less math. EM optics requires the most. So let’s start easy and make things harder (math wise) as we go.
The Electromagnetic Spectrum Chpt. 3.6
The Electromagnetic Spectrum Optics and Photonics is an enabling technology and science It enables advances in many different disciplines of science, engineering, etc.
Radio Waves Power Transmission Radio Broadcasts
Radio Astronomy http://www.ovsa.njit.edu/
Microwaves
Microwaves Microwave source (Magnetron) melted a candy bar in Spencer’s pocket. The next day, he put an egg near the microwave source. It cooked and exploded….. The rest is history
Microwaves
Microwaves – Big Bang Discovery Cosmic background Radiation – Residual ‘Big Bang’ radiation from thermal ‘black body’ spectrum corresponding to radiation at T=2.7K
Terahertz (THz) Non-destructive Evaluation Security Screening Wireless Communications
Concealed Threats in Packaging TRANSMISSION Plastic knife and metal razor blade identified through packaging
Concealed Threats in Clothing REFLECTION Knife in shirt pocket Unmodified Explosive simulant
Terahertz Wireless Communication: Motivation Outline: Demand for wireless data increasing Size of Wireless Cells Shrinking Examples of THz systems NSF Expeditions Application : 100Gb/s Data Centers Graphics courtesy of AT&T Labs Futuristic view of THz Communications: Actively steered THz beams form ultra-high capacity link to moving users. The THz frequency range in USA is unassigned above 300GHz.
Demand for Wireless Services constantly increasing S. Cherry, “Edholm’s law of bandwidth,” IEEE Spectr. 41, 50 Jul. 2004. According to Edholm’s law of bandwidth, the demand for bandwidth in wireless short-range communications has doubled every 18 months over the last 25 years. Examples…. Feb 2011, Cisco Visual Networking Index: Global Mobile Data Traffic Forecast Update 2010-2015 Large increase in data traffic for MOBILE Devices
Commercial THz Wireless Systems (in Demonstration) Japanese Government and Industry (NTT) have committed to THz HD wireless broadcasts for 2016 Tokyo Olympics NTT, 2012 Beijing Olympics But in USA, commercial systems >100GHz can not be sold… So little commercial development relative to Europe and Asia
Infrared – Thermal Imaging
Infrared – Thermal Imaging
Vegetation Mapping http://speclab.cr.usgs.gov
Visible - Oximeter
Visible - Oximeter
UV-Sun/ Crab Nebula – Skin Cancer
X-rays
X-ray
X-ray
Postulates of Ray Optics Light travels as Rays Medium characterized by refractive index n For inhomogeneous medium, the time taken for light to travel from A to B is proportional to optical path length Fermat’s Principle – Light rays travel along the path to minimize the transit time.
Other things appear blue due to scattering…..
Three general classes of Scattering Depending on Particle size
Interference (Brief) Waves which are IN PHASE will add together. Waves which are OUT of phase, when added together will cancel each other
Consider a column of MANY scattering Centers…. Primary wave (Secondary Wave) In forward direction, scattered light forms a wavefront in the same direction
Even if scattering centers NOT in an organized row, forward going scattered light forms a new wavefront which transmits through medium
What about lateral (side) scattering? Destructive interference For a particular spacing between scattering centers, the scattered waves will DESTRUCTIVELY interfere and cancel each other Since there are MANY scattering centers (eg. number of atoms in a solid), we can ALWAYS add the scattering centers in pairs which individually destructively interfere.
Reflection from a boundary
Reflection from a boundary
Reflection from a boundary
Reflection from a boundary
Reflection from a boundary
Rays and Wavefronts Rays are perpendicular to wavefronts: wavefronts denote surfaces of CONSTANT phase
Specular Reflection (from flat surface) Diffusion Reflection (from rough surface) Stealth fighter designed to avoid Diffuse Reflection from radar waves. Reflected waves directed so that reflected light does not retrace path back to be detected.
Huygen’s Principle Break up wavefront into individual points which each acting as a point source. Allow each spherical wavefront to propagate according to the local speed of light in the medium. Combination of spheres defines new wavefront. New wavefront is the line or curve of the crests/ troughs of the point sources of waves Direction of travel (ray) is perpendicular to wavefront
Refraction Pencil appears to be Bent at surface of water Object is DEEPER in water than it appears. Hint: use this figure to visualize Problem 4.25.
Light refracts because speed of light and radius of Huygen’s circle is different in the two mediums
Example of Fermat’s Principle - Mirages Cold Air more dense so air travels SLOWER Hot Air less dense so air travels FASTER
Total Internal Reflection