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Headings denoted with an asterisk ( * ) is retrieved from the course syllabus version Spring 2023
Content and learning outcomes
Course contents
This course introduces the most important semiconductor components that are used in the modern electronics. We focus on the MOS-transistor, pn and schottkydiodes and different types of memory cells. Furthermore, solar cells, photodiodes and light-emitting diodes are included. In the course, power consumption and gate delay in CMOS-based circuits are discussed. An overview is given of the development of so-called technology nodes for advanced CMOS according to Moore's law. You should be familiar with the process flow that is used to produce modern microelectronics. Strong emphasis is placed on sustainability aspects such as energy consumption and finite resources.
Intended learning outcomes
After passing the course, the student shall be able to
describe the electronic band structure for insulators, semiconductors and metals qualitatively
use the concepts electron- and hole-concentration, bandgap and mobility for calculations of current-voltage relations in semiconductor components
analyse and calculate the internal electrostatics (charges, electric field and potential) in semiconductor components based on pn and MOS-structures
describe the function and the application areas for the pn-diode, the MOS-transistor and common types of memory cells and some kind of semiconductor sensor
describe the basic properties for CMOS-inverters and how these are used to implement integrated circuits.
give an account of the most important sustainability aspects in production of modern microelectronics.
Learning activities
To achieve the course goals it is necessary to actively study during all weeks of the course. It is assumed that the students have followed the reading instructions before each lecture, since the lectures contains sections that require active participation from the students.
Note that the weekly student recitations which also require preparation ahead of each class!
The course gives 7.5 credits (HEC) (200 hours of which 46 hours are in class).
Course overview
12 scheduled lectures (recommend attendance)
6 student recitations (mandatory attendance)
1 laboratory session with 2 seminars (mandatory attendance)
Lectures
There are reading instructions at the end of this course-PM. During the lectures there will be sections that require active participation by the students, so called concept questions orother types of peer group discussions.
Student recitations
The material for each student recitation is posted in Canvas. Each week six (6) new problems are assigned.
Before each student recitation the students should try their best to solve all problems.
The student should also prepare to present the solution on the board (or scanned notes in Zoom) for the class.
The level of difficulty of the problems on the student recitation corresponds to the written exam.
In detail, a student recitation is organized as follows:
At the beginning of the student recitation each student will sign-up (online in Canvas or Google Docs) to indicate which of the six problems he/she is prepared to present to the class
One student is randomly picked to present a solution
After the solution has been presented there is a discussion, in which all students are expected to participate. Students are expected to give feedback on the presented solution and possibly provide alternative solutions
When the discussion is finished a new student presents a solution to the next problem
When all problems have been presented and discussed the student recitation ends
The requirement for an acceptable presentation is that it should be clear to the teacher and the class that the student has made an honest attempt to solve the problem, but not necessarily getting the correct answer.
It is of course allowed (and encouraged) that students collaborate in order to prepare for the student recitations.
Laboratory work, seminars and report
Location:
Electrum building, KISTA CAMPUS, elevator C, level 3.
Signup:
Lab groups (four students) for signup will be scheduled by in Canvas.
Overview of tasks for completed lab course:
See also Lab Module in Canvas
Before the lab, a dedicated lab seminar will introduce extraction procedure and report writing.
During two hours measurement data is collected under the guidance of a lab assistant.
After the lab, each student submits an individual lab report that presents the measurements, the extraction procedure and the results. The report should be submitted under the ASSIGNMENTS menu in Canvas. Submission deadline found in the schedule at the end of this course-PM.
Feedback seminar and peer review: Reports for peer review will be assigned through Canvas. About half a page constructive feedback for each report must be posted in Canvas before the feedback seminar. At the feedback seminar each student will give (to their peers) and receive (from their peers) feedback on their reports.
After the seminar students can improve their reports and the final report should be submitted before the second deadline stated in the schedule at the end of this course-PM.
Detailed plan
Will be updated latest Jan 16, 2023 see schedule for now
Preparations before course start
Literature
No information inserted
Support for students with disabilities
Students at KTH with a permanent disability can get support during studies from Funka:
There are recorded Videos from previous course rounds in 2021 and 2022. It is highly recommended to browse them ahead of lectures.
Examination and completion
Grading scale
A, B, C, D, E, FX, F
Examination
LABA - Laboration, 1.5 credits, Grading scale: P, F
SEMA - Seminar, 1.5 credits, Grading scale: P, F
TENA - Written exam, 4.5 credits, Grading scale: A, B, C, D, E, FX, F
Based on recommendation from KTH’s coordinator for disabilities, the examiner will decide how to adapt an examination for students with documented disability.
The examiner may apply another examination format when re-examining individual students.
Grading criteria/assessment criteria
Intended learning outcome
Having passed the course, the student shall be able to
1 Bandstructure
describe the electronic band structure for insulators, semiconductors and metals qualitatively
2 Concentrations
use the concepts electron- and hole-concentration, bandgap and mobility for calculations of current-voltage relations in semiconductor components
3 Electrostatics
analyse and calculate the internal electrostatics (charges, electric field and potential) in semiconductor components based on pn- and MOS-structures
4 Operation principles
describe the function and the application areas for the pn-diode, the MOS-transistor and common types of memory cells and some kind of semiconductor sensor
5 Circuits
describe the basic properties for CMOS-inverters and how these are used to implement integrated circuits
6 Sustainability
give an account of the most important sustainability aspects in production of modern
microelectronics
The intended learning outcomes are examined according to this matrix
Nummer & beskrivning
TENA (summative)
LABA (summative & formative)
SEMA (formative)
Other
1 Bandstructure
Yes
Yes
2 Concentrations
Yes
Partly
Yes
3 Electrostatics
Yes
Partly
Yes
4 Operation principles
Yes
Partly
Yes
5 Circuits
Yes
Yes
6 Sustainability
In class
Ethical approach
All members of a group are responsible for the group's work.
In any assessment, every student shall honestly disclose any help received and sources used.
In an oral assessment, every student shall be able to present and answer questions about the entire assignment and solution.
Further information
Changes of the course before this course offering
This is the first instance of IL2240 it is partly based on the previous offerings IH1611. More focus is placed on integrated circuits and reduced emphasis is given to device physics.