NFYK23003U Introduction to Signal Processing in Experimental Physics
Progress in natural science and technology is based on carefully conducted experiments: ranging from particle accelerators, gravitational waves observatories, genome sequencing, to autonomous vehicles.
To enable you to contribute to this progress this course introduces the basics of signal acquisition and processing using modern analog and digital electronic circuitry.
The course is organised in lecture tutorials, laboratory exercises and an experimental project.
Skills:
Understand and set-up simple passive electronic circuits
Design simple active circuits for signal conditioning
Describe (linear) systems with transfer functions
Discuss the limitations and noise of sensors and circuits
Select and use suitable ADCs for data acquisition tasks
Construct truth tables for Boolean functions
Implement simple logic operations in FPGA hardware
Understand and discuss different data representation
Competences:
This course gives the student a solid background in signal processing, practical experience with modern data acquisition and experiment control methods. It provides students with a good basis for laboratory work in MSc or PhD projects and experimental work in all natural sciences dealing with data acquisition.
Knowledge:
Passive and active electronic components
Transfer functions of linear systems, filters
Operational amplifier circuits
Signal conditioning and feedback
Noise in electronic circuits
Sampling and analog to digital conversion
Data types and representations/encoding
Boolean algebra
Introduction to Field Programmable Gate Arrays (FPGAs)
See Absalon for a list of course literature
Lecture notes, book chapters, research articles.
Short hands-on exercises will be part of the lecture tutorials for a deeper understanding of the presented concepts.
In the first weeks of the course, lab exercises will be offered to the students. They will work in groups and get acquainted with the lab instrumentation. The goal is to apply the topics learned during the lecture tutorials.
In the last weeks of the course the group of students will work on an experimental project
- Category
- Hours
- Lectures
- 22
- Preparation
- 135,5
- Practical exercises
- 12
- Laboratory
- 36
- Exam
- 0,5
- Total
- 206,0
- Credit
- 7,5 ECTS
- Type of assessment
- Oral examination, 30 minutesWritten assignment, during course
- Type of assessment details
- 30 minutes, no preparation time
Oral exam: 80% of the final grade
Written project report (max 5 pages): 20% of the final grade.
The parts of the exam do not need to be passed separately, only the total exam. - Aid
- All aids allowed
- Marking scale
- 7-point grading scale
- Censorship form
- No external censorship
Several internal examiners
- Re-exam
The same as for the ordinary exam.
The student can choose to re-use the written report from the ordinary exam or hand in a new report no later than 3 weeks before the oral re-exam.
Criteria for exam assesment
See Intended learning outcome.
Course information
- Language
- English
- Course code
- NFYK23003U
- Credit
- 7,5 ECTS
- Level
- Full Degree Master
- Duration
- 1 block
- Placement
- Block 3
- Schedule
- B
- Course capacity
- 24
The number of places might be reduced if you register in the late-registration period (BSc and MSc) or as a credit or single subject student.
Study board
- Study Board of Physics, Chemistry and Nanoscience
Contracting department
- The Niels Bohr Institute
Contracting faculty
- Faculty of Science
Course Coordinators
- Jörg Helge Müller (muller@nbi.ku.dk)
- Alessandra Camplani (a.camplani@nbi.ku.dk)
- Jean-Baptiste Sylvain Béguin (jbeguin@nbi.ku.dk)
Lecturers
Alessandra Camplani
Jean-Baptiste Sylvain Béguin