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electrical_engineering_and_electronics_1:start [2025/09/27 13:50] – [Block plan] mexleadminelectrical_engineering_and_electronics_1:start [2025/10/21 08:49] (aktuell) mexleadmin
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 It spans from basic electrical quantities to DC networks, electrostatics, magnetostatics, and a first introduction to operational amplifiers. \\  It spans from basic electrical quantities to DC networks, electrostatics, magnetostatics, and a first introduction to operational amplifiers. \\ 
 The course combines theory, worked examples, and practical exercises with simulations and real-world devices. The course combines theory, worked examples, and practical exercises with simulations and real-world devices.
- 
-===== Learning outcomes ===== 
-<callout> 
-After completing this course, students will be able to: 
-  - Apply SI units, prefixes, and electrical terminology consistently. 
-  - Explain and calculate fundamental electrical quantities such as charge, current, voltage, resistance, power, and energy. 
-  - Analyze DC circuits using Kirchhoff’s laws, source equivalents, and two-port theory. 
-  - Describe electric and magnetic fields, calculate key field distributions, and apply them to capacitors, inductors, and energy storage. 
-  - Design and analyze simple operational amplifier circuits with feedback and comparator functions. 
-</callout> 
- 
-===== Prerequisites ===== 
-  - Basic physics (mechanics, Newton’s laws, Coulomb’s law). 
-  - Basic calculus (differentiation and integration). 
-  - Familiarity with algebraic manipulation. 
- 
-===== Grading and assessment ===== 
-Assessment is done only by the final written exam. 
- 
-===== Notation & units ===== 
-The course consistently uses the following symbols, units, and typical values: 
- 
-<tabcaption notation | Course-wide notation and units> 
-^ Symbol ^ Quantity                          ^ SI unit   ^ name of the unit  ^ Typical values  ^ 
-| $q$       | Electric charge                | $\rm C$   | Coulomb           | $10^{-19} ~\rm C$ (electron) to $\rm mC$              | 
-| $I$       | Electric current               | $\rm A$   | Ampere            | $\rm \mu A$ (sensors) to $\rm kA$ (lightning)         | 
-| $U$       | Voltage (potential difference)  | $\rm V$  | Volt              | $\rm \mu V$ (noise) to $\rm MV$ (transmission lines)  | 
-| $\varphi$  | Electric potential            | $\rm V$   | Volt              | — | 
-| $P$       | Power                          | $\rm W$   | Watt              | $\rm mW$ (electronics) to $\rm MW$ (machines)         | 
-| $W$       | Energy                         | $\rm J$   | Joule             | $\rm µJ$ (capacitors) to $\rm MJ$ (batteries)         | 
-| $R$       | Resistance                     | $\rm \Omega$  | Ohm           | $\rm mΩ$ to $\rm MΩ$                                  | 
-| $G$       | Conductance                    | $\rm S$   | Siemens           | $\rm µS$ to $\rm S$                                   | 
-| $\rho$    | Resistivity                    | $\rm \Omega \cdot m$      | — | $1.7 \cdot 10^{-8} ~\rm \Omega m$ (Cu)                | 
-| $\sigma$  | Conductivity                   | $\rm S/m$                 | — | $5.8 \cdot 10^{7} ~\rm S/m$ (Cu)                      | 
-| $C$       | Capacitance                    | $\rm F$    | Farad            | $\rm pF$ (ceramic) to $\rm F$ (supercaps)             | 
-| $L$       | Inductance                     | $\rm H$    | Henry            | $\rm \mu H$ to $\rm H$                                | 
-| $E$       | Electric field strength        | $\rm V/m$                 | — | $\rm 1 ~\rm V/m$ to $\rm MV/m$ (breakdown)            | 
-| $D$       | Electric flux density          | $\rm C/m²$                | — | — | 
-| $B$       | Magnetic flux density          | $\rm T$    | Tesla            | $\rm \mu T$ (Earth) to several $\rm T$ (MRI)          | 
-| $H$       | Magnetic field strength        | $\rm A/m$                 | — | — | 
-| $\Phi$    | Magnetic flux                  | $\rm Wb$   | Weber            | $\rm \mu Wb$ to $\rm mWb$                             | 
-| $\theta$  | magnetic voltage (Magnetomotive force)                     | $\rm A \cdot turn$  | — | — | 
-| $R$       | Reluctance                      | $\rm A/Wb$               | — | — | 
-</tabcaption> 
  
 ===== Block plan ===== ===== Block plan =====
-Below is the 24-block plan (90 minutes each): 
  
-[[:electrical_engineering_1:introduction_in_ee1|Introduction in Electrical Engineering 1]]  +<callout> 
- +[[introduction_in_eee1|Introduction in Electrical Engineering 1]]  
-<WRAP>+</callout> 
 +<WRAP group >
 <WRAP column third> <WRAP column third>
 +<callout>
 **Chapter 1 — Electrical Fundamentals** or: Watt is Power and Current? **Chapter 1 — Electrical Fundamentals** or: Watt is Power and Current?
-  * [[block01|Block 01 — Physical quantities and units]] (SI system, prefixes) +  * [[block01|Block 01 — Physical quantities and units]]  
-  * [[block02|Block 02 — Electric charge and current]] (charge, current sources, flow conventions) +  * [[block02|Block 02 — Electric chargecurrent and voltage]]  
-  * [[block03|Block 03 — Voltage, power, resistance]] (potential, sources, resistance, practical resistors)+  * [[block03|Block 03 — resistance and power]] 
 +</callout>
  
 +<callout>
 **Chapter 2 — DC Networks** or: something lumpy with two Pins and why shortcircuits may be important **Chapter 2 — DC Networks** or: something lumpy with two Pins and why shortcircuits may be important
   * [[block04|Block 04 — Kirchhoff’s laws]]   * [[block04|Block 04 — Kirchhoff’s laws]]
Zeile 68: Zeile 27:
   * [[block06|Block 06 — Real sources and source equivalents]]   * [[block06|Block 06 — Real sources and source equivalents]]
   * [[block07|Block 07 — Power-relevant figures]]   * [[block07|Block 07 — Power-relevant figures]]
-  * [[block08|Block 08 — Two-port theory and transforms]] +  * [[block08|Block 08 — Two-terminal theory and transforms]] 
 +</callout>
 </WRAP> </WRAP>
 <WRAP column third> <WRAP column third>
  
 +<callout>
 **Chapter 3 — Electric Fields** or: positivity might be repulsive **Chapter 3 — Electric Fields** or: positivity might be repulsive
   * [[block09|Block 09 — Force on charges and electric field strength]]   * [[block09|Block 09 — Force on charges and electric field strength]]
Zeile 80: Zeile 40:
   * [[block13|Block 13 — Capacitor circuits and energy]]   * [[block13|Block 13 — Capacitor circuits and energy]]
   * [[block14|Block 14 — Steady conduction field]]   * [[block14|Block 14 — Steady conduction field]]
 +</callout> 
 +<callout>
 **Chapter 4 — Magnetic Fields** or: Why ist the north pole on the south pole? **Chapter 4 — Magnetic Fields** or: Why ist the north pole on the south pole?
   * [[block15|Block 15 — Magnets and their effects]]   * [[block15|Block 15 — Magnets and their effects]]
Zeile 88: Zeile 49:
   * [[block19|Block 19 — Magnetic circuits and inductance]]   * [[block19|Block 19 — Magnetic circuits and inductance]]
   * [[block20|Block 20 — Electromagnetic induction and energy]]   * [[block20|Block 20 — Electromagnetic induction and energy]]
 +</callout>
 </WRAP> </WRAP>
 <WRAP column third> <WRAP column third>
 +<callout>
 **Chapter 5 — Operational Amplifiers** - golden rules and infinite gain **Chapter 5 — Operational Amplifiers** - golden rules and infinite gain
   * [[block21|Block 21 — Op-amp basics]]   * [[block21|Block 21 — Op-amp basics]]
Zeile 97: Zeile 58:
   * [[block23|Block 23 — Comparator circuits]]   * [[block23|Block 23 — Comparator circuits]]
   * [[block24|Block 24 — Wrap-up and applications]]   * [[block24|Block 24 — Wrap-up and applications]]
 +</callout>
 </WRAP> </WRAP>
 </WRAP> </WRAP>
  
 +<callout>
 [[old English exams]] [[old English exams]]
 +</callout>
 +~~PAGEBREAK~~ ~~CLEARFIX~~
  
 +===== Learning outcomes =====
 +<callout>
 +After completing this course, students will be able to:
 +  - Apply SI units, prefixes, and electrical terminology consistently.
 +  - Explain and calculate fundamental electrical quantities such as charge, current, voltage, resistance, power, and energy.
 +  - Analyze DC circuits using Kirchhoff’s laws, source equivalents, and two-port theory.
 +  - Describe electric and magnetic fields, calculate key field distributions, and apply them to capacitors, inductors, and energy storage.
 +  - Design and analyze simple operational amplifier circuits with feedback and comparator functions.
 +</callout>
 +
 +===== Prerequisites =====
 +  - Basic physics (mechanics, Newton’s laws, Coulomb’s law).
 +  - Basic calculus (differentiation and integration).
 +  - Familiarity with algebraic manipulation.
 +
 +===== Grading and assessment =====
 +Assessment is done only by the final written exam.
  
 ====== Additional Links ====== ====== Additional Links ======
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   * A great introductary script into electrical engineering can be found at [[https://phys.libretexts.org/Bookshelves/University_Physics/Book%3A_University_Physics_(OpenStax)/Map%3A_University_Physics_II_-_Thermodynamics%2C_Electricity%2C_and_Magnetism_(OpenStax)|LibreText - Physics II Thermodynamics, Electricity and Magnetism]]. The content ist originally from [[https://cnx.org/contents/[email protected]:Ai7EWAra@5/Introduction|OpenStax]] and covers most of the parts of my course   * A great introductary script into electrical engineering can be found at [[https://phys.libretexts.org/Bookshelves/University_Physics/Book%3A_University_Physics_(OpenStax)/Map%3A_University_Physics_II_-_Thermodynamics%2C_Electricity%2C_and_Magnetism_(OpenStax)|LibreText - Physics II Thermodynamics, Electricity and Magnetism]]. The content ist originally from [[https://cnx.org/contents/[email protected]:Ai7EWAra@5/Introduction|OpenStax]] and covers most of the parts of my course
   * Another good introduction ist given by [[http://hyperphysics.phy-astr.gsu.edu/hbase/hframe.html|HyperPhysics]]   * Another good introduction ist given by [[http://hyperphysics.phy-astr.gsu.edu/hbase/hframe.html|HyperPhysics]]
 +  * Alternatively, Tony R. Kuphaldt developed a very detailed and easy booklet on EEE1 and EEE2: [[https://www.ibiblio.org/kuphaldt/electricCircuits/|online version]] \\ {{electrical_engineering_and_electronics_1:dc.pdf|PDF for EEE1}},{{electrical_engineering_and_electronics_1:ac.pdf|PDF for EEE2}}, {{electrical_engineering_and_electronics_1:semi.pdf|PDF for semiconductor part}}
 </WRAP> </WRAP>