Durham University
Programme and Module Handbook

Undergraduate Programme and Module Handbook 2013-2014 (archived)

Module PHYS3681 : LABORATORY SKILLS AND ELECTRONICS 3

Department: Physics

PHYS3681 : LABORATORY SKILLS AND ELECTRONICS 3

Type Open Level 3 Credits 20 Availability Available in 2013/14 Module Cap None. Location Durham

Prerequisites

  • Discovery Skills in Physics (PHYS1101) AND Foundations of Physics 1 (PHYS1122) AND ((Single Mathematics A (MATH1561) and Single Mathematics B (MATH1571)) OR (Calculus and Probability 1 (MATH1061) and Linear Algebra 1 (MATH1071))).

Corequisites

  • None

Excluded Combination of Modules

  • Laboratory Skills and Electronics (PHYS2641).

Aims

  • This module is designed primarily for students studying Natural Sciences degree programmes.
  • It builds on laboratory skills, such as experiment planning, data analysis and specific practical skills, encountered in the module PHYS1101 Discovery Skills in Physics.
  • It aims to teach electronics as a theoretical and a practical subject, to teach the techniques of computational physics and numerical methods and to provide experience of a long laboratory experiment in Physics.

Content

  • A team-based project, undertaken in June of the previous academic year, providing a transition from Level 1 laboratory work.
  • Activities to develop skills in data interpretation, experiment design, specific practical techniques, report writing, error analysis, team working and critical thinking.
  • Electronics lectures: Analogue Electronics: Components: Introduction to electrical circuit theory, networks, AC theory, passive filters, diodes, transistors; systems: noise, measurements, amplifiers. Digital Electronics: components, JK elements, counters.
  • Electronics practical sessions.
  • Performance of an extended laboratory practical.
  • Computational physics: functions, random numbers, integration, linear algebra, ordinary differential equations.

Learning Outcomes

Subject-specific Knowledge:
  • Having studied this module students will know how to plan experiments and will be familiar with advanced techniques for the interpretation of data quantitatively and systematically.
  • They will understand the theoretical principles of basic and more advanced electronics.
  • They will have formed a detailed appreciation of the physics underlying a particular project and be prepared to undertake and report on similar projects.
  • They will know how to structure physics problems and their computational solutions.
Subject-specific Skills:
  • Students will have specific laboratory practical skills generally useful in practical physics.
  • They will have developed practical skills in electronics.
  • They will be able to apply their programming skills to solve problems using numerical methods.
Key Skills:
  • Students will have developed their written and oral presentation skills sufficiently to be able to write fluent and well-structured reports and to give clear and convincing oral presentations.
  • They will be able to work successfully as part of a team to solve an open-ended problem.

Modes of Teaching, Learning and Assessment and how these contribute to the learning outcomes of the module

  • Teaching will be by lectures, practical sessions, workshops and project work.
  • The open-ended ‘bridge project’ is undertaken in June of the previous academic year, providing a transition from Level 1 to Level 2 laboratory work. Students will work in teams on an extended project lasting one week, which will develop their problem-solving, teamwork and presentation skills. (Students who are unable, for good reason, to undertake the bridge project in June will undertake an equivalent project in the following Epiphany Term.)
  • The practical sessions are small group activities designed to develop skills in data interpretation, experiment design, team working, specific practical techniques and reporting. The skills covered form the foundation needed for the long experiment in the second term and for later practical work. Students will be able to obtain help and guidance from laboratory scripts and through discussions with laboratory demonstrators.
  • The electronics lectures aim to give a theoretical grounding in the elements of electronics – analogue and digital circuits, circuit logic and design – while the practical sessions provide a working knowledge of the subject.
  • The computational physics lectures aim to give a theoretical grounding in the elements of computational physics and numerical methods, while the workshops provide opportunities for practice and discussion of the algorithms.
  • Regular exercises in coding algorithms, to be submitted and checked electronically, will give students practice in applying these principles and will form the basis for discussion in the workshops.
  • Student performance is summatively assessed through a short presentation on the ‘bridge project’, through a formal report for the skills sessions, through an electronics practical examination, through a formal report for the long experiment and through exercises.
  • The practical classes, workshops and exercises provide opportunity for feedback, for students to gauge their progress and for staff to monitor progress throughout the duration of the module.

Teaching Methods and Learning Hours

Activity Number Frequency Duration Total/Hours
Lectures 15 1 per week 1 hour 15
Project 1 One full week in previous Easter Term 35 hours 35
Workshops 8 1 per week in term 1 1 hour 8
Practicals 17 1 per week 3 hours 51
Preparation and Reading 91
TOTAL 200

Summative Assessment

Component: Bridge Project Component Weighting: 20%
Element Length / duration Element Weighting Resit Opportunity
Bridge Project 100% Equivalent project during summer vacation
Component: Skills Session Component Weighting: 20%
Element Length / duration Element Weighting Resit Opportunity
Skills Session 100% Resubmitted writeup
Component: Long Experiment Component Weighting: 20%
Element Length / duration Element Weighting Resit Opportunity
Long Experiment 100% Resubmitted report
Component: Electronics Practicals Component Weighting: 20%
Element Length / duration Element Weighting Resit Opportunity
Assessed Electronics Practical 100% Resit assessed electronics practical
Component: Computational Physics Exercises Component Weighting: 20%
Element Length / duration Element Weighting Resit Opportunity
Exercises 100% Completing a set of exercises during the vacation

Formative Assessment:

Formative assessment of laboratory record by laboratory staff.


Attendance at all activities marked with this symbol will be monitored. Students who fail to attend these activities, or to complete the summative or formative assessment specified above, will be subject to the procedures defined in the University's General Regulation V, and may be required to leave the University