Physics 3 - Electromagnetism and WavesLaajuus (4 cr)
Code: TZLF8010
Credits
4 op
Teaching language
- Finnish
- English
Responsible person
- Tuomas Huopana
Objective
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Qualifications
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Assessment criteria, satisfactory (1)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Assessment criteria, good (3)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Assessment criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV23S2Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The assessment is based on exam or exams and points collected from calculation exercises. In the assessment, the emphasis is on participating in contact teaching and completing calculation exercises, but it is also possible to complete the course by exam. In contact teaching, the attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation.
The student must participate in the first contact lesson or inform the course teacher about participating in the course during the first week of the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV23S3Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The assessment is based on exam or exams and points collected from calculation exercises. In the assessment, the emphasis is on participating in contact teaching and completing calculation exercises, but it is also possible to complete the course by exam. In contact teaching, the attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation.
The student must participate in the first contact lesson or inform the course teacher about participating in the course during the first week of the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV23S5Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The assessment is based on exam or exams and points collected from calculation exercises. In the assessment, the emphasis is on participating in contact teaching and completing calculation exercises, but it is also possible to complete the course by exam. In contact teaching, the attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation.
The student must participate in the first contact lesson or inform the course teacher about participating in the course during the first week of the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Virtual portion
4 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV23SMTieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
Virtual lessons, independent work and online work.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The course assessment is based on exam or exams and points collected from calculation exercises.
The student must confirm the registration by logging into the Moodle pages of the course during the first week of the course. If participation in the course is prevented, the course teacher must be notified during the first week of the course at the latest. It is possible to study the course virtually.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- English
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TIC23S1Bachelor's Degree Programme in Information and Communications Technology
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The assessment is based on exam or exams and points collected from calculation exercises. In the assessment, the emphasis is on participating in contact teaching and completing calculation exercises, but it is also possible to complete the course by exam. In contact teaching, the attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation.
The student must participate in the first contact lesson or inform the course teacher about participating in the course during the first week of the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV23S1Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 13th January 2025 - 30th April 2025.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The assessment is based on exam or exams and points collected from calculation exercises. In the assessment, the emphasis is on participating in contact teaching and completing calculation exercises, but it is also possible to complete the course by exam. In contact teaching, the attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation.
The student must participate in the first contact lesson or inform the course teacher about participating in the course during the first week of the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22S1Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit luokassa, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta ensimmäisen kurssiviikon aikana.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22S2Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit luokassa, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta ensimmäisen kurssiviikon aikana.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22S3Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit luokassa, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta ensimmäisen kurssiviikon aikana.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22S4Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit luokassa, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta ensimmäisen kurssiviikon aikana.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22S5Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit luokassa, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta ensimmäisen kurssiviikon aikana.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Virtual portion
4 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22SMTieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Virtuaaliluennot tai kontaktitunnit, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee vahvistaa ilmoittautuminen kirjautumalla kurssin Moodle sivuille ensimmäisen kurssiviikon aikana. Jos kurssille osallistuminen estyy, tulee siitä ilmoittaa kurssin opettajalle viimeistään ensimmäisen kurssiviikon aikana. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Virtual portion
4 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV22SM2Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 8.1.2024 - 30.4.2024.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Virtuaaliluennot tai kontaktitunnit, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee vahvistaa ilmoittautuminen kirjautumalla kurssin Moodle sivuille ensimmäisen kurssiviikon aikana. Jos kurssille osallistuminen estyy, tulee siitä ilmoittaa kurssin opettajalle viimeistään ensimmäisen kurssiviikon aikana. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
20.11.2023 - 04.01.2024
Timing
08.01.2024 - 30.04.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- English
Seats
20 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TIC22S1Bachelor's Degree Programme in Information and Communications Technology
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on 8th January 2024 - 30th April 2024.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do the renewal exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The evaluation takes into account the scores in the exam. At the beginning of the course, the teacher provides assignments to collect additional scores. At least 50 % of the maximum scores is required to pass.
If you are prevented from attending the first contact lesson of the course, the course teacher must be notified of the participation in the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- English
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TIC21S1Bachelor's Degree Programme in Information and Communications Technology
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
The course is implemented on January 9, 2023 - April 28, 2023.
Learning materials and recommended literature
The course material is provided by the teacher.
Literature in Finnish:
-Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
-Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Literature in English:
-Knight, R. D. (2013). Physics for scientists and engineers: A strategic approach with modern physics (3rd ed., [international edition].). Boston: Pearson Education.
-Ali Hamed, S. M. (2018). Electromagnetics for engineering students: Part 2. Bentham Science Publishers. (E-book)
-Franceschetti, G. a. (1997). Electromagnetics: Theory, Techniques, and Engineering Paradigms (1st ed. 1997.). Springer US. (E-book)
Teaching methods
The course covers lectures in the classroom and home exercises.
Practical training and working life connections
The content of the course aims to be working life connected.
Exam dates and retake possibilities
The course exam dates and deadlines for home exercises are announced in the first lecture. You are allowed to do resit exam two times during the semester.
Alternative completion methods
The approval procedures are described in the degree regulations and the study guide. The teacher of the course provides additional information about possible alternative course completion procedures.
Student workload
One credit corresponds to a workload of 27 hours. In total, the course requires 108 hours of work.
Further information for students
The evaluation takes into account the scores in the exam. At the beginning of the course, the teacher provides assignments to collect additional scores. At least 50 % of the maximum scores is required to pass.
If you are prevented from attending the first contact of the course, the course teacher must be notified of the participation in the course.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Virtual portion
2 op
Mode of delivery
50 % Face-to-face, 50 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV21S1Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 9.1.2023 - 28.4.2023.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Virtual portion
2 op
Mode of delivery
50 % Face-to-face, 50 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV21S2Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 9.1.2023 - 28.4.2023.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Virtual portion
2 op
Mode of delivery
50 % Face-to-face, 50 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV21S3Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 9.1.2023 - 28.4.2023.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Virtual portion
2 op
Mode of delivery
50 % Face-to-face, 50 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV21S5Tieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 9.1.2023 - 28.4.2023.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2022 - 05.01.2023
Timing
09.01.2023 - 28.04.2023
Number of ECTS credits allocated
4 op
Virtual portion
4 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV21SMTieto- ja viestintätekniikka (AMK)
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 9.1.2023 - 28.4.2023.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Virtuaaliluennot tai kontaktitunnit, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kurssin ohjauksiin osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee vahvistaa ilmoittautuminen kirjautumalla kurssin Moodle sivuille ensimmäisen kurssiviikon aikana. Jos kurssille osallistuminen estyy, tulee siitä ilmoittaa kurssin opettajalle viimeistään ensimmäisen kurssiviikon aikana. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2021 - 09.01.2022
Timing
10.01.2022 - 29.04.2022
Number of ECTS credits allocated
4 op
Virtual portion
1 op
Mode of delivery
75 % Face-to-face, 25 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV20S1Tieto- ja viestintätekniikka
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 10.1.2022 - 29.4.2022.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2021 - 09.01.2022
Timing
10.01.2022 - 29.04.2022
Number of ECTS credits allocated
4 op
Virtual portion
1 op
Mode of delivery
75 % Face-to-face, 25 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV20S2Tieto- ja viestintätekniikka
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 10.1.2022 - 29.4.2022.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2021 - 09.01.2022
Timing
10.01.2022 - 29.04.2022
Number of ECTS credits allocated
4 op
Virtual portion
1 op
Mode of delivery
75 % Face-to-face, 25 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV20S3Tieto- ja viestintätekniikka
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 10.1.2022 - 29.4.2022.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2021 - 09.01.2022
Timing
10.01.2022 - 29.04.2022
Number of ECTS credits allocated
4 op
Virtual portion
1 op
Mode of delivery
75 % Face-to-face, 25 % Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV20S5Tieto- ja viestintätekniikka
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 10.1.2022 - 29.4.2022.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Kontaktitunnit tai virtuaaliluennot, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Kontaktiopetukseen osallistuminen on vapaaehtoista, mutta suotavaa. Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.
Enrollment
01.11.2021 - 09.01.2022
Timing
10.01.2022 - 29.04.2022
Number of ECTS credits allocated
4 op
Virtual portion
4 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Tuomas Huopana
Groups
-
TTV20SMTieto- ja viestintätekniikka
Objectives
Purpose:
You learn about the basic phenomena of electromagnetism and waves, which is a requirement in information technology to understand the devices used in information technology.
EUR-ACE Competences:
Knowledge and understanding
Engineering practice
Learning outcomes:
After completing the course you know basic principles and concepts of mechanical and electromagnetic waves. You
know about the wave behaviour in various substances and interfaces between substances.
You know the basic concepts and principles of electromagnetism. You also know about the physical fundamentals of electric basic components, direct current motor, electric generator, antennas, and optical fibre.
You are able to recognise the physical phenomena discussed in the course and can make assumptions in modelling the phenomena. You are able to use physical models to solve physical problems.
Content
In this course you study the following contents:
- the modelling of wave motion, the intensity and propagation velocity of wave
- wave motion in interfaces between substances
- interference and standing waves
- sound and Doppler effect
- electric charge in electric field
- voltage (potential) and energy in electric field
- conductor and current loop in magnetic field
- electromagnetic induction
- self-inductance and coil
- electromagnetic waves
- antennas
- optical fibers
Time and location
Opintojakso toteutetaan 10.1.2022 - 29.4.2022.
Learning materials and recommended literature
Luentomoniste ja harjoitustehtävät.
Ensisijainen kirjallisuus:
Hautala & Peltonen: Insinöörin (AMK) fysiikka, osa 1, Lahden Teho-Opetus Oy.
Peltonen, Perkkiö & Vierinen: Insinöörin (AMK) fysiikka, osa 2, Lahden Teho-Opetus Oy.
Vaihtoehtoisesti:
Inkinen, Manninen & Tuohi: Momentti Insinöörifysiikka 2, Otava.
Teaching methods
Virtuaaliset ohjaukset, itsenäinen työskentely ja verkkotyöskentely.
Practical training and working life connections
Kurssin sisältö pyritään kytkemään työelämässä esiintyviin ongelmiin.
Exam dates and retake possibilities
Kurssin tenttikäytänteet ilmoitetaan kurssin ensimmäisellä tapaamiskerralla.
Alternative completion methods
Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.
Student workload
Yhden opintopisteen työmäärä vastaa 27 tunnin opiskelutyötä. Yhteensä opiskelutyömäärä (4 op.) kurssilla on 108 tuntia.
Further information for students
Opintojakso arvioidaan kokeen tai kokeiden ja laskuharjoituksista kerättävien pisteiden perusteella.
Opiskelijan tulee osallistua ensimmäiselle kontaktikerralle tai ilmoittaa kurssin opettajalle kurssille osallistumisesta. Kurssi on mahdollista opiskella virtuaalisesti.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient 1:
You recognize the phenomena in the course content and are able to make assumptions concerning some phenomena. Most of the models you use are related to the phenomenon you recognized, and your assignment solving progresses logically.
Satisfactory 2:
You have described the phenomena in the course content but your description of phenomena needs improvement. You are able to make assumptions based on the phenomena and have selected in most cases the suitable physical models. You have solved correctly unknown parameters, but your solutions need improvement.
Evaluation criteria, good (3-4)
Good 3:
You have described the phenomena in the course content correctly and have made the most important assumptions concerning the models you used. You have in most cases reached correct solutions but you have made some miscalculations.
Very good 4:
You have described the phenomena in the course content quite well and made the assumptions needed to model the phenomena. You are able to find alternative solution models to resolve the problem. You have solved the assignments correctly but have made some minor miscalculations.
Evaluation criteria, excellent (5)
Excellent 5:
You have described the phenomena in the course content accurately and have made the correct assumptions for modelling. You are able to evaluate the suitability of various models when solving problems. You have completed the assignments correctly and you may have some oversight in your calculations.
Prerequisites
Simultaneously or before the course you know the basics of vector calculus, trigonometry and differential and integral calculus
Further information
The course is suitable for degree students both as contact and hybrid implementation.