Last modified: 25 May 2018 11:16
This 100% continuously assessed course explores two fundamental areas of physics. In electronics you will go from building simple circuits to designing complex logical architectures, using both real components and simulation software.
The optics half of the course explores various fascinating optical phenomena, some of which are practically applicable for geologists and many other scientific disciplines. The practicals elegantly demonstrate the fundamental properties of light.
|Session||Second Sub Session||Credit Points||15 credits (7.5 ECTS credits)|
The course is evenly divided between an introduction to the fundamentals of digital electronics and optical experiments illustrating theory discussed in the PX 2013 course. The first six weeks of twelve are spent doing electronics, the remaining weeks are for optics.
The electronics begins at the level of specifying the behaviour of the basic logic gates and the construction on a breadboard of simple circuits from circuit diagrams, covers Boolean algebra and ends with using Karnaugh maps to develop fairly complex circuits from a set of desired behaviours.
The optics covers: interference effects, such as using Newton's rings to determine the radius of curvature of a lens and then the refractive index of water; polarisation, including optical activity and Brewster's angle; the function of lens systems, from finding focal to length to determining the six cardinal points of a telephoto lens; and laser diffraction from various different gratings and objects.
The optics experiments include a number of places where digital photographs are taken of an optical effect (the ring system for a lens on an optical flat, the Peacock's eyes from the aser beam) and used, particularly in the former case, to make measurements.
This is the total time spent in lectures, tutorials and other class teaching.