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DEGREE REGULATIONS & PROGRAMMES OF STUDY 2012/2013

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DRPS : Course Catalogue : School of Physics and Astronomy : Undergraduate (School of Physics and Astronomy)

Undergraduate Course: Physics 2A (PHYS08022)

Course Outline
School	School of Physics and Astronomy	College	College of Science and Engineering
Course type	Standard	Availability	Available to all students
Credit level (Normal year taken)	SCQF Level 8 (Year 2 Undergraduate)	Credits	20
Home subject area	Undergraduate (School of Physics and Astronomy)	Other subject area	None
Course website	WebCT	Taught in Gaelic?	No
Course description	This course provides an introduction to classical dynamics, special relativity, geometric optics and the physics of waves. It serves both as a preparation for further study in physics-based degree programmes, and as a stand-alone course for students of other disciplines, including mathematics, chemistry, computer science and engineering. The course is supported by a programme of tutorial workshops and includes an introductory module on Java programming and data analysis.

Entry Requirements (not applicable to Visiting Students)
Pre-requisites	Students MUST have passed: Physics 1A: Foundations (PHYS08016) AND Physics 1B: The Stuff of the Universe (PHYS08017) Students MUST have passed: ( Mathematics for Physics 1 (PHYS08035) AND Mathematics for Physics 2 (PHYS08036)) OR ( Practical Calculus (MATH08001) AND Solving Equations (MATH08002) AND Geometry & Convergence (MATH08003) AND Group Theory: An Introduction to Abstract Mathematics (MATH08004))	Co-requisites
Prohibited Combinations		Other requirements	Alternatively SCE Advanced Higher or A-level Physics and Mathematics at A-grade.
Additional Costs	None

Information for Visiting Students
Pre-requisites	None
Displayed in Visiting Students Prospectus?	Yes

Course Delivery Information

Delivery period: 2012/13 Semester 1, Available to all students (SV1)						WebCT enabled: Yes		Quota: 220
Location	Activity	Description	Weeks	Monday	Tuesday	Wednesday	Thursday	Friday
King's Buildings	Laboratory		2-11	14:00 - 17:00		or 14:00 - 17:00	or 14:00 - 17:00
King's Buildings	Lecture		1-11	09:00 - 09:50
King's Buildings	Lecture		1-11		09:00 - 09:50
King's Buildings	Lecture		1-11				09:00 - 09:50
King's Buildings	Lecture		1-11					09:00 - 09:50
King's Buildings	Tutorial	Workshop	2-11			10:00 - 12:00	or 10:00 - 12:00	or 10:00 - 12:00
First Class	First class information not currently available
Additional information	Tutorial workshops two hours per week, as arranged. Laboratory sessions three hours per week, as arranged.
Exam Information
Exam Diet	Paper Name		Hours:Minutes
Main Exam Diet S1 (December)	Physics 2A: Forces, Fields & Potentials		2:00
Resit Exam Diet (August)			2:00

Summary of Intended Learning Outcomes
Upon successful completion of this course, it is intended that a student will understand - basic Newtonian mechanics; - how to set up a dynamical system for solution using first and second order differential equations; - the role and diversity of simple harmonic motion in physics; - the role of symmetry in simplifying a problem; - the two basic postulates of Special Relativity; - the phenomena of time dilation and Lorentz contraction; - that the notion of simultaneity depends on the reference frame; - relativistic velocities transformation, linear momentum, and total and kinetic energy; - that in the low speed limit relativistic results correspond to classical Newtonian physics; - what is meant a rest mass energy; - geometric optics using Gaussian lens formula and matrix ray methods; - basic optical systems, including the human eye, magnifier, telescope, microscope; concepts of optical aberrations and their control; - types of wave phenomena: standing waves, travelling waves, normal modes, resonance, sound waves; - superposition of waves. Beats. Harmonics. Acoustics; - wavefronts. Huyghen's principle. Doppler effect. Shock waves; - energy storage and transport in mechanical waves. Intensity; - reflection and transmission of mechanical waves at boundaries; - dispersion, group and phase velocities. Water waves; - electromagnetic waves. Spectrum. Speed of light. Red shifts; - reflection and refraction of light. Total internal reflection; - energy storage and transport in electromagnetic waves; - polarisation states. Polarisers. - Interference of light. Two slits. Newton's rings; - interferometers. Michelson. Twyman-Green. Fabry-Perot; - diffraction. Apertures. Gratings; - dispersion of electromagnetic waves. - Wavepackets. Signal transmission. Introduction to Fourier analysis. Other course elements: the Data Analysis course will give the ability to manipulate, plot and fit, in a linear form, with error bars, data using spreadsheet software. The Java component will explain the practical utility of computation for solving physical problems and construct Java programs using variables, control structures and supplied routines to model simple physical systems.

Assessment Information
Weekly assignments, 10% Computing and data analysis, 20% Degree Examination, 70%

Special Arrangements
None

Additional Information
Academic description	Not entered
Syllabus	Dynamics and Relativity - Frames of reference; vector notation; Galilean relativity - Postulates of Special Relativity; time dilation, Lorentz contraction; simultaneity; - Newtonian dynamics; linear momentum; potential, kinetic and total energy; - Simple harmonic motion; damping and resonance; beats; - conservation of energy, linear momentum and angular momentum - motion of rigid bodies; moments of inertia, - Relativistic dynamics; low speed limit; rest mass energy. Optics - geometric optics using Gaussian lens formula and matrix ray methods - basic optical systems; the human eye, magnifier, telescope, microscope; optical aberrations Waves - Introduction to types of waves and their mathematical description. - Waves on a string. The wave equation. - Standing waves. Normal modes. Resonance. - Sound waves. Speed of sound in a gas. - Superposition of waves. Beats. Harmonics. Acoustics. - Wavefronts. Huyghen's principle. Doppler effect. Shock waves. - Energy storage and transport in mechanical waves. Intensity. - Reflection and transmission of mechanical waves at boundaries. - Dispersion. Group and phase velocities. Water waves. - Electromagnetic waves. Spectrum. Speed of light. Red shifts. - Reflection and refraction of light. Total internal reflection. - Energy storage and transport in electromagnetic waves. - Polarisation states. Polarisers. - Interference of light. Two slits. Newton's rings. - Interferometers. Michelson. Twyman-Green. Fabry-Perot. - Diffraction. Apertures. Gratings. - Dispersion of electromagnetic waves. - Wavepackets. Signal transmission. Introduction to Fourier analysis. Scientific Programming - Introduction to programming; Basics of Linux; Data Types, Variables and Operators - Basic Input and Output; Math Class and Constants - File Input and Output; Conditional Statements; Loops; Arrays and Strings - Plotting Graphs Using the ptplot Package - Introduction to Methods; Introduction to Objects - Finding and Fixing Bugs Data Analysis - Uncertainty, Accuracy and precision - Mean value; standard deviation; error on the mean - Microsoft EXCEL for data analysis - Combining uncertainties - Graphs and graph plotting - Least squares methods - Application on a real-world problem
Transferable skills	Not entered
Reading list	Not entered
Study Abroad	Not entered
Study Pattern	Not entered
Keywords	P2A

Contacts
Course organiser	Dr Alex Murphy Tel: (0131 6)50 5285 Email:	Course secretary	Miss Leanne O'Donnell Tel: (0131 6)50 7218 Email:

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