Electric Circuit Theory 2Laajuus (5 cr)
Code: 5S00EV47
Credits
5 op
Objectives
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites
Controlling the contents of DC and AC circuits.
Enrolment period
02.07.2023 - 03.09.2023
Timing
28.08.2023 - 15.12.2023
Credits
5 op
Mode of delivery
Contact teaching
Unit
Electrical and Automation Engineering
Campus
TAMK Main Campus
Teaching languages
- Finnish
Seats
0 - 40
Degree programmes
- Degree Programme in Electrical Engineering
Teachers
- Sami Heikkilä
Person in charge
Jarkko Lehtonen
Groups
-
23I231A
Objectives (course unit)
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content (course unit)
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites (course unit)
Controlling the contents of DC and AC circuits.
Assessment scale
0-5
Enrolment period
02.07.2023 - 30.09.2023
Timing
14.08.2023 - 16.12.2023
Credits
5 op
Mode of delivery
Contact teaching
Unit
Electrical and Automation Engineering
Campus
TAMK Main Campus
Teaching languages
- Finnish
Seats
0 - 40
Degree programmes
- Degree Programme in Electrical Engineering
Teachers
- Lauri Hietalahti
Person in charge
Jarkko Lehtonen
Groups
-
22AI231
Objectives (course unit)
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content (course unit)
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites (course unit)
Controlling the contents of DC and AC circuits.
Assessment scale
0-5
Enrolment period
09.11.2022 - 08.01.2023
Timing
09.01.2023 - 07.05.2023
Credits
5 op
Mode of delivery
Contact teaching
Unit
Electrical and Automation Engineering
Campus
TAMK Main Campus
Teaching languages
- Finnish
Seats
0 - 40
Degree programmes
- Degree Programme in Electrical Engineering
Teachers
- Jarkko Lehtonen
Person in charge
Jarkko Lehtonen
Groups
-
22I231B
Objectives (course unit)
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content (course unit)
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites (course unit)
Controlling the contents of DC and AC circuits.
Assessment scale
0-5
Enrolment period
02.07.2022 - 04.09.2022
Timing
29.08.2022 - 17.12.2022
Credits
5 op
Mode of delivery
Contact teaching
Unit
Electrical and Automation Engineering
Campus
TAMK Main Campus
Teaching languages
- Finnish
Seats
0 - 40
Degree programmes
- Degree Programme in Electrical Engineering
Teachers
- Aki Korpela
Person in charge
Jarkko Lehtonen
Groups
-
22I231A
Objectives (course unit)
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content (course unit)
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites (course unit)
Controlling the contents of DC and AC circuits.
Assessment scale
0-5
Enrolment period
29.11.2021 - 09.01.2022
Timing
10.01.2022 - 08.05.2022
Credits
5 op
Mode of delivery
Contact teaching
Unit
Electrical and Automation Engineering
Campus
TAMK Main Campus
Teaching languages
- Finnish
Seats
0 - 40
Degree programmes
- Degree Programme in Electrical Engineering
Teachers
- Jarkko Lehtonen
Person in charge
Jarkko Lehtonen
Groups
-
21I231B
Objectives (course unit)
The student knows
- concepts of AC power
The student can
- model circuits with inductively coupled windings
- model circuit resonance situations and master analysis of passive basic filters
- model circuit switching phenomena and understand their essential differences compared to steady-state circuit modeling
Content (course unit)
AC power: actual power, reactive power, apparent power, complex power.
Circuit Modeling of Mutual Inductance: How Inductively Coupled Coils Are Considered in Circuit Analysis, Circuit Model of Ideal Transformer.
Resonance in Circuits: What does resonance mean and how does it appear in electrical circuits. How to model resonance situations in electrical circuits.
Passive Filter Connections: How low-pass, high-pass, band-pass, and band-pass filters are implemented with resistors, coils and capacitors. How these filter connections are modeled using the voltage gain transfer function.
Switching phenomena: How to model switching phenomena and other transient situations in electrical circuits. Modeling coupling phenomena will inevitably lead to differential equations, which are solved in the course both in time and by Laplace transform.
Prerequisites (course unit)
Controlling the contents of DC and AC circuits.
Assessment scale
0-5