- UCAS course code
- F301
- UCAS institution code
- M20
Course unit details:
Year 1 Lab Work (All Yr)
| Unit code | PHYS10180 |
|---|---|
| Credit rating | 20 |
| Unit level | Level 1 |
| Teaching period(s) | Full year |
| Offered by | Department of Physics & Astronomy |
| Available as a free choice unit? | No |
Overview
Year 1 Lab Work (All Year)
Aims
Computing and Data Analysis: 1. develop the appropriate skills and confidence to use computers for the tasks required in laboratory work 2. introduce the basic concepts and methods required for laboratory data analysis 3. develop sound judgement in interpreting experimental results and uncertainties 4. develop the skills required for good scientific communication. Special Topics: 1. promote awareness of selected topics at the forefront of modern-day research in physics 2. introduce and develop group-working skills 3. enhance writing and written presentation skills 4. develop skills in assessing the quality of one’s own and others’ work. Circuits: ensure that students can competently use an oscilloscope and to foster an understanding of way electrical signals are shaped by passive circuit elements. General Lab Experiments: 1. Investigate number of physical systems/phenomena 2. Develop basic skills used in the physics lab, including use of common lab equipment 3. Gain experience producing clear laboratory records of activities 4. Present experimental findings and analysis in an interview setting 5. Write lab reports.
Learning outcomes
On successful completion, a student will be able to:
- Describe the behaviour of capacitors and inductors (Circuit).
- Observe and explain transients in analog circuits.
- Design and build integrating and differentiating circuits.
- Explain ringing, damping and Q-factors in resonant circuits, including critical damping.
- Use complex notation and complex impedances for circuit analysis including: determination of amplitude and phase, resonant circuits, low-pass and high-pass filters, A.C. bridges.
- Use python commands and scripts to manipulate and present experimental data in the form of graphs and tables.
- Distinguish between random and systematic errors in experiments.
- Organise and carry-out an laboratory experiment in order to achieve goals outlined in an experimental script.
- Work effectively in a small group or with a partner to complete experiments and produce reports and presentations.
- Describe results of laboratory experiments to a lab demonstrator including a clear description of background physics, laboratory procedures, analysis and conclusions.
- Produce a clear record of laboratory work and analysis in a laboratory notebook.
- Write a laboratory report which presents experiment findings at a level readable by a general audience of peers.
- Use the method of least squares-fitting and interpret chi-squared, χ2.
- Assess their own and other’s work against specified assessment criteria.
- Perform a literature review and present on subjects which are substantially beyond that provided in lectures (Special Topics).
- Work in a group to produce a piece of work which promotes physics as an interesting area of study.
- Calculate the uncertainty in quantities derived from experimental results of specified precision and present in a sensible way.
- Estimate the precision of experimental results, from an understanding of the experimental procedure and from a statistical analysis of repeated measurements.
Syllabus
Scientific Computer and Data Analysis: The Scientific Computing module aims to teach students to make use of Python scripts to in solving and physics problems they will face during their studies and to analyse data for lab work. Students will also learn simple tools for using Python to present data in effective and understandable ways. The Data Analysis work aims to teach students to understand and perform calculations with experimental uncertainty, and use this in the context of simple model fitting, including the method of least squares. General Laboratory: Students will carry out a number of laboratory experiments that investigate various physical phenomena. Circuits: Full year students (PHYS 10180) will conduct two experiments that will explore basic analog and digital circuit concepts and practicalities. Topics will include:
- Elementary circuit theory - discrete components, Kirchoffs laws and complex analysis
- Semiconductor amplifiers - real and ideal systems
- Positive feedback, oscillators and control loops
- Analogue - to - digital conversion
Special Topics: Students will attend a series of specialist lectures on selected topics at the forefront of modern day research in physics and a session introducing the project and group working. In the weeks following the lectures they will work together in small groups to produce a short booklet on one of the topics discussed in the lectures. The booklet should be designed for students studying A-level physics and aim to convey the excitement of modern day physics to them. Students will be expected to research beyond the material presented in the lectures in order to produce an informative and attractive piece of work. Each group will assess and grade their own booklet along with a number of booklets from other groups, and these grades will form the basis of the final course assessment.
Teaching and learning methods
Assessment - Practical Exam
Lecture
Independent Study
Practical
Assessment methods
| Method | Weight |
|---|---|
| Practical skills assessment | 100% |
Feedback methods
Oral feedback will be given by demonstrators during the lab sessions and the assessment interviews at the end of each experiment. An annotated copy of each Lab Report will be returned to the student and the marker will discuss their comments with students. Students are also sent an email copy of each experiment assessment and lab report Feedback & Marksheet.
Recommended reading
Practical physics, Squires, G. L., Cambridge University Press 2001, ISBN: 9781139164498
Study hours
| Scheduled activity hours | |
|---|---|
| Assessment practical exam | 4 |
| Lectures | 6 |
| Practical classes & workshops | 138 |
| Independent study hours | |
|---|---|
| Independent study | 52 |
Teaching staff
| Staff member | Role |
|---|---|
| William Bertsche | Unit coordinator |
