PHYS 241 Final Exam Review Kevin Ralphs

Overview General Exam Strategies Concepts Practice Problems

General Exam Strategies Don’t panic!!! If you are stuck, move on to a different problem to build confidence and momentum “Play” around with the problem Take fifteen to twenty minutes before the exam to relax… no studying. Dimensional analysis is a good tool, but can give false results

Concepts Inductance AC Circuits – RMS – Reactance – Impedance – Phasors Displacement Current Electromagnetic Waves (Light) – Wave/Particle Duality – Poynting Vector

Concepts Optics – Refraction Index of Refraction Snell’s Law – Total Internal Reflection – Malus’s Law – Mirrors – Lenses – Diffraction

Inductance

Why should I care? – This is the sister component to the capacitor making it one of the most fundamental electronic components CapacitorInductor Depends on geometry and material between the plates Depends on geometry and material in intervening space Proportionality between charge and voltage Proportionality between flux and current Stores energy in an electric fieldStores energy in a magnetic field Causes current to lag voltageCauses current to lead voltage Current starts at maximum and drops to zero Current starts at zero and increases to maximum

Alternating Current (AC) - RMS

AC - Reactance

AC - Impedance What does it tell me? – It represents the relationship (magnitude and phase difference) between the applied voltage and the current Why should I care? – Impedance provides a compact way to carry a lot of information about your circuit

AC - Impedance

AC - Phasors A phasor is a graphical representation of the relationship between voltage and current in a system This exploits the power of complex numbers as both vectors and rotations The phasor rotates through the complex plane and the real projections of the phasor give the measured value See Demonstration

Displacement Current

Why do I care? – The correction completes Ampere’s law bringing it in agreement with the Biot-Savart Law – Like Faraday’s law, this allows for the propagation of electromagnetic waves

Poynting Vector Work done insideEnergy flowing outChange in internal energy

Poynting Vector

Index of Refraction

Snell’s Law

Malus’s Law

Assumptions/Conventions

Mirrors Rules for Ray Diagrams Parallel RaysReflected through focal point Focal RaysReflected parallel to optical axis Radial RaysReflected back on itself Sign Convention s is positive if object is on the incident-light side s’ is positive if the image is on the reflected-light side R is positive if the mirror is concave

Lenses Rules for Ray Diagrams Parallel RaysRefracted through focal point Focal RaysRefracted parallel to optical axis Central RaysNo deflection when refracted Sign Convention s is positive if object is on the incident-light side s’ is positive if the image is on the refracted-light side r is positive if center of curvature is on the refracted-light side

Diffraction What does it tell me? – How a wave behaves near objects – Only an appreciable affect when the length scale of the wave and the geometry are similar Visible light: 400nm – 700nm Sound waves: 17mm – 17m

Interference

Main Strategy For any kind of diffraction, the game is always about counting up phase shifts; these can be expressed in terms of angles or wavelengths – Angles Constructive Interference: Even multiples of π Destructive Interference: Odd multiples of π – Wavelengths Constructive Interference: Integer multiples of λ Destructive Interference: Odd half-integer multiples of λ

Practice Problem