Course syllabus adopted 2025-02-18 by Head of Programme (or corresponding).
Overview
- Swedish nameRadioastronomiska tekniker och interferometri
- CodeRRY131
- Credits7.5 Credits
- OwnerMPPHS
- Education cycleSecond-cycle
- Main field of studyElectrical Engineering, Engineering Physics
- DepartmentSPACE, EARTH AND ENVIRONMENT
- GradingTH - Pass with distinction (5), Pass with credit (4), Pass (3), Fail
Course round 1
- Teaching language English
- Application code 85149
- Open for exchange studentsYes
Credit distribution
Module | Sp1 | Sp2 | Sp3 | Sp4 | Summer | Not Sp | Examination dates |
|---|---|---|---|---|---|---|---|
| 0113 Project 3 c Grading: UG | 3 c | ||||||
| 0213 Examination 4.5 c Grading: TH | 4.5 c |
In programmes
- MPPHS - Physics, Year 1 (compulsory elective)
- MPPHS - Physics, Year 2 (elective)
- MPWPS - Wireless, Photonics and Space Engineering, Year 2 (elective)
Examiner
Cathy Horellou- Professor, Astronomy and Plasma Physics, Space, Earth and Environment
Eligibility
General entry requirements for Master's level (second cycle)Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.
Specific entry requirements
English 6 (or by other approved means with the equivalent proficiency level)Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.
Course specific prerequisites
Basic knowledge in electromagnetism.Aim
The aim of the course is that students to understand radio astronomy techniques and the astrophysical goals motivating radio astronomy measurements. The course shall enable the students to plan an astronomical experiment using either single dish or interferometry, and to determine the required integration time, choice of instrument etc. The course will explain how to go from raw radio astronomy data to final images/spectra. The level of understanding should be such that the students in their profession as engineers or scientists should be able to apply radioastronomical techniques.Learning outcomes (after completion of the course the student should be able to)
* Become aware of the role played by radio astronomy in the study of the Universe.* Know about the most important radio astronomical instruments (e.g. ALMA, VLA, SKA, LOFAR, VLBI) and their science drivers.
* Understand the mechanisms of continuum and spectral line radiation and the nature of the astrophysical sources (from star-forming regions to supermassive black holes).
* Know the main single-dish observational techniques (e.g. frequency - beam - position switching, polarization measurements, fast scanning).
* Estimate required integration time for a given observation (the radiometer equation).
* Plan, carry out and analyze a single-dish astronomical observation.
* Learn the mathematical tools needed to understand interferometry (signal cross-correlation, 2D Fourier transform, 2D convolution).
* Visualise a simple interferometer and the output response of a point source.
* Understand the process of data calibration and image reconstruction from interferometric observations.
* Critically read, understand, summarize and present a scientific article within the topic of radio astronomy.
Content
The course contains the following parts:* Single-dish radio astronomy.
* Fundamental concepts.
* Basic antenna theory.
* Receiver and signal processing.
* Observational methods.
* Radio astronomical sources.
* Spectral line analysis.
* Planning a single-dish observation.
* Observing with the Onsala 20m telescope.
* Single-dish data analysis.
* The 2-element non-tracking interferometer.
* The tracking interferometer.
* The 2D Fourier transform.
* 'uv' coverage for example interferometers.
* The dirty map and dirty beam.
* Noise in interferometry images.
* Properties of the main radio interferometers where one can apply for observing time.
* Planning an observation with a radio interferometer.
* Deconvolution methods.
* Interferometric data reduction.
* Design of aperture arrays.
Organisation
Lectures, problem classes, practical observations, and computer exercises.Literature
- Lecture notes
- Books (both are available as e-books from the Chalmers library):
- Essential Radio Astronomy, J.J. Condon & S.M. Ransom, Princeton University Press, 2016
- Tools of Radio Astronomy, K. Rohlfs & T.L. Wilson, Springer Verlag, latest edition
Examination including compulsory elements
(1) Written exam. 60% of the final grade.(2) Written report about the observations with a radio telescope (group work), hand-in assignments and oral presentation of a scientific paper. 40% of the final grade.
The course examiner may assess individual students in other ways than what is stated above if there are special reasons for doing so, for example if a student has a decision from Chalmers about disability study support.