700.110 (23S) Microelectronics

Sommersemester 2023

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Erster Termin der LV
06.03.2023 08:00 - 10:00 B04.1.06 On Campus
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Überblick

Lehrende/r
LV-Titel englisch Microelectronics
LV-Art Vorlesung
LV-Modell Präsenzlehrveranstaltung
Semesterstunde/n 2.0
ECTS-Anrechnungspunkte 3.0
Anmeldungen 25
Organisationseinheit
Unterrichtssprache Englisch
LV-Beginn 06.03.2023
eLearning zum Moodle-Kurs

Zeit und Ort

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LV-Beschreibung

Intendierte Lernergebnisse

  • Good understanding of the physics of semiconductors and study of some concrete/specific applications of semiconductor physics in industry.
  • Understand the industrial production (i.e., manufacturing) of the PN junction (diode) based on semiconductor technology and study of some practical applications of the PN junction (diode) in electronics.
  • Understand the industrial production (i.e., manufacturing) of the MOSFET transistors based on semiconductor technology and study of some practical applications of the MOSFET transistors in electronics.
  • Understand the technology of CMOS transistors and study of some concrete / specific applications of CMOS transistors in digital electronics.
  • Application of CMOS transistors in digital circuit design: CMOS logic gates; CMOS flip-flops.
  •  Good knowledge of the theory of operational amplifiers and mastery of some concrete applications of classical electronic circuits based on operational amplifiers.

Lehrmethodik

• The lecture is held on-campus.

• The slides are available for the entire lecture. These slides are uploaded to the MOODLE system. The entire content of each slide is systematically explained by the lecturer. Additional examples not included in the slides are suggested by the lecturer to allow a good understanding of the information provided.

Very important note: 

•  The lecturer will explain all the concepts of the lecture clearly and verify for each concept that at least 75% of the students have understood the explained concept. Otherwise, the lecturer will keep explaining the same concept until at least 75% of the students understand it.

• The slides contain exercises with solutions to help students understand the content of each chapter. These solutions are systematically explained by the lecturer (during the lecture).

• The slides contain exercises with solutions to be solved by students during the lecture (this is part of the oral exam). The students are fully assisted/supported by the lecturer to obtain/get correct/exact solutions to the suggested exercises. This will be helpful in checking whether the students have understood the chapters or not.

Inhalt/e

Chapter 1. Basic concepts of semiconductor physics and semiconductor technology

Chapter 2. PN junction (semiconductor diode) based on semiconductor technology and concrete practical applications in electronics

Chapter 3.  MOSFETs (transistors) technology and some concrete applications of MOSFETs in electronics

Chapter 4.  CMOS technology and concrete applications in digital circuit design: CMOS logic gates; CMOS flip-flops

Chapter 5. Theory of operational amplifiers and concrete applications of practical interest in electronics

Literatur

Important note. The digital versions of books below are available online for free (see Google)

  • Jacob Millman & Christos, C. Halkias Jacob Millman, & Christos C. Halkias, « Electronic Devices & Circuits », McGraw-Hill 1967. (Update version of Jan 3, 2012)
  • G.Fontaine Diodes & Transistors Philips, « Diodes & Transistors » Technical Library 1963. (Update version of Aug 10, 2011)
  • Ian R. Sinclair, « Practical Electronics Handbook », Newnes Technical Books ( Butterworth & Co.(Publishers) Ltd.) 1980
  • W.W. Smith, «Electronics for Technician Engineers », Hutchinson Educational 1970.

Prüfungsinformationen

Im Fall von online durchgeführten Prüfungen sind die Standards zu beachten, die die technischen Geräte der Studierenden erfüllen müssen, um an diesen Prüfungen teilnehmen zu können.

Prüfungsmethode/n

• The final exam takes place on-campus in the form of a written exam.

• The total duration of the final exam is 3 to 4 hours. 

Prüfungsinhalt/e

• The questions for the final exam cover all five chapters of the lecture.

Beurteilungskriterien/-maßstäbe

• The final exam (i.e., a written exam) corresponds to 50% of the overall grade of the lecture.

• Taking part in the lecture and answering questions correspond to the oral examination. This is evaluated with 25% of the overall grade of the lecture.

• All assignments (i.e., homework) correspond to 25% of the overall grade of the lecture.

Beurteilungsschema

Note Benotungsschema

Position im Curriculum

  • Bachelorstudium Informationstechnik (SKZ: 289, Version: 22W.1)
    • Fach: Elektronik und Schaltungen (Pflichtfach)
      • 6.1 Mikroelektronik ( 0.0h VO / 3.0 ECTS)
        • 700.110 Microelectronics (2.0h VO / 3.0 ECTS)
          Absolvierung im 2. Semester empfohlen
  • Bachelorstudium Informationstechnik (SKZ: 289, Version: 17W.1)
    • Fach: Elektronik und Schaltungen (Pflichtfach)
      • 5.1 Mikroelektronik ( 0.0h VO / 3.0 ECTS)
        • 700.110 Microelectronics (2.0h VO / 3.0 ECTS)
          Absolvierung im 2. Semester empfohlen
  • Bachelorstudium Informationstechnik (SKZ: 289, Version: 12W.2)
    • Fach: Elektronik und Schaltungen (Pflichtfach)
      • Mikroelektronik ( 2.0h VO / 3.0 ECTS)
        • 700.110 Microelectronics (2.0h VO / 3.0 ECTS)
          Absolvierung im 2. Semester empfohlen
  • Bachelorstudium Robotics and Artificial Intelligence (SKZ: 295, Version: 22W.1)
    • Fach: Design and Modeling Tools for Robotics (Wahlfach)
      • 8.2 Design and Modeling Tools for Robotics ( 0.0h VO, VC, UE, KS / 12.0 ECTS)
        • 700.110 Microelectronics (2.0h VO / 3.0 ECTS)

Gleichwertige Lehrveranstaltungen im Sinne der Prüfungsantrittszählung

Sommersemester 2024
  • 700.110 VO Microelectronics (2.0h / 3.0ECTS)
Sommersemester 2022
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2021
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2020
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2019
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2018
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2017
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2016
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2015
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2014
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)
Sommersemester 2013
  • 700.110 VO Mikroelektronik (2.0h / 3.0ECTS)