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Module Specifications

Archived Version 2010 - 2011

Module Title Wave Optics
Module Code PS307
School School of Physical Sciences

Online Module Resources

Module Co-ordinatorProf. Enda McGlynnOffice NumberN106
Module Co-ordinatorProf. Enda McGlynnOffice NumberN106
NFQ level 8 Credit Rating 5
Pre-requisite None
Co-requisite None
Compatibles None
Incompatibles None
Description

This course is designed to: (i) To provide an appreciation of the fundamental concepts of wave optics. (ii) To illustrate the relevance of these concepts in modern applications of optics (iii) To develop numerical problem solving skills in wave optics The course is predominantly knowledge-based. The main learning activities are attending lectures and tutorials and the related learning activity of solving numerical and other problems related to the topics covered. Students are expected to attend lectures and tutorials and to prepare for both by appropriate study (including the use of on-line moodle resources provided and textbooks) and thus be able to engage fully in discussions and other interactions in lectures and tutorials. Students are further expected to prepare for in-class tests and end of module examinations via study and, as needed, discussion with the lecturer.

Learning Outcomes

1. Explain the essential physical aspects of the phenomena of wave polarization, interference and diffraction, both qualitatively and mathematically, including the generation and manipulation of particular polarizations, interference by division of wavefront and amplitude, and diffraction from various simple aperture configurations
2. Discuss, both qualitatively and mathematically, optical information storage, image formation, and holography, and their linkages to other basic concepts in optics
3. Describe, both qualitatively and mathematically, examples of applications of interference, spatial filtering, and practical holographic systems



Workload Full-time hours per semester
Type Hours Description
Lecture24Lecture
Tutorial6Tutorial
Independent Study95Study for lectures, tutorials, in-class tests and final exam
Total Workload: 125

All module information is indicative and subject to change. For further information,students are advised to refer to the University's Marks and Standards and Programme Specific Regulations at: http://www.dcu.ie/registry/examinations/index.shtml

Indicative Content and Learning Activities

Indicative syllabus
(i) Short Review of Waves: Light as a wave motion; plane waves, spherical waves; complex amplitude.

Indicative syllabus
(ii) Polarisation: Definition of states of Polarisation; Birefringence; Dichroism; Polarisers and Retarders; Polarisation by Reflection and Scattering; Induced Birefringence (Kerr Cell).

Indicative syllabus
(iii) Interference: Superposition and Two-beam Interference; Concept of Coherence; Interferometers (amplitude and wavefront-splitting); Michelson Interferometer and Applications; Multiple-beam Interference and Fabry-Perot Interferometer; AR-coatings, Interference Filters.

Indicative syllabus
(iv) Diffraction: Fraunhofer Diffraction (single, double, multiple slit); Circular Aperture and Spatial Resolving Power; Diffraction Gratings; Basic Fresnel Diffraction (Straight Edge, Slit & Zone Plate).

Indicative syllabus
(v) Fourier Optics: Spatial Frequency, Periodic and Non-Periodic Spatial Waves (Fourier series and Fourier transforms in optics), Point Spread and Modulation Transfer Functions (Principles & Applications), Convolution and De-Convolution, Spatial Filtering and Phase Contrast Techniques.

Indicative syllabus
(vi) Holography: Basic Idea, Gabor's Original Method, On & Off Axis Holograms, Reconstructing a Hologram, Information Storage in Holograms, Applications.

Learning activities
Students are expected to attend lectures and tutorials and to prepare for both by appropriate study (including the use of on-line moodle resources provided and textbooks) and thus be able to engage fully in discussions and other interactions in lectures and tutorials. Students are further expected to prepare for in-class tests and end of module examinations via study and, as needed, discussion with the lecturer.

Assessment Breakdown
Continuous Assessment20% Examination Weight80%
Course Work Breakdown
TypeDescription% of totalAssessment Date
Reassessment Requirement
Resit arrangements are explained by the following categories;
1 = A resit is available for all components of the module
2 = No resit is available for 100% continuous assessment module
3 = No resit is available for the continuous assessment component
Unavailable
Indicative Reading List

  • Hecht: 1998, Optics, 2 or more recent, All covered in syllabus, Addison Wesley,
  • Fowles: 1989, Introduction to Modern Optics, Reprint, All covered in syllabus, Dover Publications,
Other Resources

1014, Moodle, Enda McGlynn, 0, PS307 lecture notes on moodle,
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