Curricula

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

The course is scheduled to take place from August 26th, 2024, to October 11st, 2024.

Learning materials and recommended literature

The course material is provided by the teacher.

Course literature:
-Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition. 10th edition.
-Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

In the course, you will get to know the theory with the help of the lecture material, after which you will do exercises on each topic independently. It is possible to study the course remotely.

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 week. You are allowed to take 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 81 hours of work.

Further information for students

The assessment 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. More detailed information about the assessment will be given in the first week of the course.

If you are prevented from participating in the course during the first week of the course, you must inform the course teacher about your participation in the course.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

The course is scheduled to take place from August 26th, 2024, to October 11st, 2024.

Learning materials and recommended literature

The course material is provided by the teacher.

Course literature:
-Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition. 10th edition.
-Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

The course covers lessons in the classroom and home exercises. Lessons are held only in the classroom.

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 take 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 81 hours of work.

Further information for students

The assessment takes into account the scores in the exam. At the beginning of the course, the teacher provides assignments to collect additional scores. The attendance requirement is 80 %. The exam will be held in the classroom only. There is no remote exam option with this implementation. The first lesson provides more detailed assessment information.

If you are prevented from attending the first 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 are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- self-study
- distance learning
- exercises

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.

Teaching methods

- self-study
- distance learning
- exercises

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exam

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Summer studies/IT-institute students

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2x2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

2 välikoetta, ajankohdat julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Kokeet 4 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h

Further information for students

Opintojakso arvioidaan kahdella välikokeella. Lisäpisteitä kokeisiin saa viikoittaisista kotitehtävistä ja kontaktitunneilla työskentelystä.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- self-study
- distance learning
- exercises

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- lessons
- self-study
- exercises

Exam dates and retake possibilities

Exam and two possible resits. Dates and places will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- lessons
- self-study
- exercises

Exam dates and retake possibilities

Exam and two possible resits. Dates and places will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.

Teaching methods

- lessons
- self-study
- exercises

Exam dates and retake possibilities

Exam and two possible resits. Dates and places will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exercises and the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- lessons
- self-study
- exercises

Exam dates and retake possibilities

Exam and two possible resits. Dates and places will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

The course is scheduled to take place from January 8th, 2024, to February 23rd, 2024.

Learning materials and recommended literature

The course material is provided by the teacher.

Course literature:
-Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition. 10th edition.
-Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

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 take 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 81 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 are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Kurssilla käytetään opettajan tekemiä videoita sekä pdf-muotoista materiaaleja.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kurssi koostuu perinteisestä luento-opetuksesta, opetusvideoiden katselusta, laskuharjoitusten laskemisesta sekä laboratoriotyöstä. Luennoista tulee tallenteet.

Exam dates and retake possibilities

Kurssin koeaikataulut ilmoitetaan ensimmäisellä luennolla.

Student workload

Suomeksi
36 h kontaktiopetusta
5 h loppukoe
40 h itsenäistä opiskelua

Further information for students

Kurssi arvioidaan harjoitustehtävien, kokeiden sekä laboratoriotyöstä kirjoitettavan raportin perusteella.

Lisäksi kurssilla on päiväopiskelijoita koskeva läsnäolovelvoite (80% oppitunneista on oltava paikalla).

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Kurssilla käytetään opettajan tekemiä videoita sekä pdf-muotoista materiaaleja.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kurssi koostuu perinteisestä luento-opetuksesta, opetusvideoiden katselusta, laskuharjoitusten laskemisesta sekä laboratoriotyöstä. Luennoista tulee tallenteet.

Exam dates and retake possibilities

Kurssin koeaikataulut ilmoitetaan ensimmäisellä luennolla.

Student workload

Suomeksi
36 h kontaktiopetusta
5 h loppukoe
40 h itsenäistä opiskelua

Further information for students

Kurssi arvioidaan harjoitustehtävien, kokeiden sekä laboratoriotyöstä kirjoitettavan raportin perusteella.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

The course is implemented on 2nd October 2023 - 19th December 2023.

Learning materials and recommended literature

The course material is provided by the teacher.

Course literature:
-Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition. 10th edition.
-Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

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 take 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 81 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 are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- self-study
- distance learning
- exercises

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (28.8.-15.12.2023) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (28.8.-15.12.2023) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (28.8.-15.12.2023) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (28.8.-15.12.2022) pääosin etänä Zoomissa.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Viikottain etätunti, mahdollisuus osallistua päiväryhmien kontaktitunneille.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä. Tentin voi tehdä Dynamolla tai etänä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 15 h
Itsenäinen opiskelu ja kotitehtävät 60 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (28.8.-15.12.2022) pääosin etänä Zoomissa.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Viikottain etätunti, mahdollisuus osallistua päiväryhmien kontaktitunneille.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä. Tentin voi tehdä Dynamolla tai etänä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 15 h
Itsenäinen opiskelu ja kotitehtävät 60 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, Laajalehto Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- lessons
- self-study
- exercises

Exam dates and retake possibilities

Exam and two possible resits. Dates and places will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from the exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Material made by the teacher.
Textbook: Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

-lectures
-distance learning
-small group learning
-exercises
-learning tasks

Exam dates and retake possibilities

The possible date and method of the exam will be announced in the course opening information.

Alternative completion methods

The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.

Student workload

One credit corresponds to an average of 27 hours of work, which means that the load of three credits is approximately 81 hours. The load is distributed in different ways depending on the course implementation.

Further information for students

The course is assessed on the basis of a two-part (different levels) final exam.

Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Kurssilla käytetään opettajan tekemiä videoita sekä pdf-muotoista materiaaleja.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kurssi toteutetaan käänteisen luokkahuoneen menetelmällä opetusvideoiden, laskuharjoitusten ja ohjaustilaisuuksien avulla. Lopuksi tehdään kaksiosainen loppukoe sekä kotona suoritettava laboratoriotyö.

Exam dates and retake possibilities

Kurssin tenttien aikataulu kerrotaan ensimmäisellä luennolla.

Student workload

3 h ohjausta Jamkilla.
5 h ohjausta etänä.
5 h kokeita
68 h itsenäistä työskentelyä.

Further information for students

Kurssi arvioidaan kokeiden perusteella.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Material offered by the teacher.
Textbook: Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

- distance learning
- exercises

Exam dates and retake possibilities

The dates and methods of the exams will be announced on Moodle.

Student workload

One credit corresponds to an average of 27 hours of work, which means this course needs approximately 81 hours of work.

Further information for students

Assessment criteria: points from exercises and the exam

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- lessons
- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Exam and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Material offered by the teacher.
Textbook: Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

-lectures
-distance learning
-exercises
-learning tasks

Exam dates and retake possibilities

The dates and methods of the exam and two resits will be announced in the course opening information.

Student workload

One credit corresponds to an average of 27 hours of work, which means that the load of three credits is approximately 81 hours. The load is distributed in different ways depending on the course implementation.

Further information for students

Assessment criteria: exercises, exam
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- lessons
- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Exam and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Kurssilla käytetään opettajan tekemiä videoita sekä pdf-muotoista materiaaleja.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kurssi koostuu perinteisestä luento-opetuksesta, opetusvideoiden katselusta, laskuharjoitusten laskemisesta sekä laboratoriotyöstä. Luennoista tulee tallenteet.

Exam dates and retake possibilities

Kurssin koeaikataulut ilmoitetaan ensimmäisellä luennolla.

Student workload

32 h kontaktiopetusta
5 h loppukoe
44 h itsenäistä opiskelua

Further information for students

Kurssi arvioidaan kaksiosaisen loppukokeen ja laboratoriotyön perusteella.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Material offered by the teacher.
Textbook: Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

-lectures
-distance learning
-exercises
-learning tasks

Exam dates and retake possibilities

The dates and methods of the exam and two resits will be announced in the course opening information.

Student workload

One credit corresponds to an average of 27 hours of work, which means that the load of three credits is approximately 81 hours. The load is distributed in different ways depending on the course implementation.

Further information for students

Assessment criteria: exercises, exam
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suomeksi
Kurssilla käytetään opettajan tekemiä videoita sekä pdf-muotoista materiaaleja.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kurssi koostuu perinteisestä luento-opetuksesta, opetusvideoiden katselusta, laskuharjoitusten laskemisesta sekä laboratoriotyöstä. Luennoista tulee tallenteet.

Exam dates and retake possibilities

Kurssin koeaikataulut ilmoitetaan ensimmäisellä luennolla.

Student workload

Suomeksi
36 h kontaktiopetusta
5 h loppukoe
40 h itsenäistä opiskelua

Further information for students

Kurssi arvioidaan harjoitustehtävien, kokeiden sekä laboratoriotyöstä kirjoitettavan raportin perusteella.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

The course is implemented on August 29, 2022 - December 16, 2022.

Learning materials and recommended literature

The course material is provided by the teacher.

Course literature:
-Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition. 10th edition.
-Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

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 81 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 are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (29.8.-16.12.2022) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (29.8.-16.12.2022) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (29.8.-16.12.2022) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (29.8.-16.12.2022) Dynamolla, Lutakon kampuksella.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Kontaktiopetus 2 h/viikko, joissa luentoa ja laskuharjoituksia.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 25 h
Itsenäinen opiskelu ja kotitehtävät 50 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Time and location

Opintojakso toteutetaan viikoilla 35 - 50 (29.8.-16.12.2022) pääosin etänä Zoomissa.

Learning materials and recommended literature

Opettajan oppimisympäristössä jakama kirjallinen materiaali ja videomateriaali.

Seuraavat kirjat sisältävät kurssilla käsiteltäviä aiheita:

1.) Young, Hugh D.; Freedman, Roger A. University Physics with Modern Physics. International edition.
2.) Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition.
3.) Suvanto, K. Tekniikan Fysiikka 1. Edita.
4.) Suvanto, K. Tekniikan Fysiikka 2. Edita.

Mitkä tahansa painokset kelpaavat.

Teaching methods

Viikottain etätunti, mahdollisuus osallistua päiväryhmien kontaktitunneille.
Viikoittaiset kotitehtävät.
Itsenäistä opiskelua varten on olemassa luentovideot.

Exam dates and retake possibilities

Julkaistaan opintojakson alussa oppimisympäristössä. Tentin voi tehdä Dynamolla tai etänä.

Alternative completion methods

Hyväksilukemisen menettelytavat kuvataan tutkintosäännössä ja opinto-oppaassa. Opintojakson opettaja antaa lisätietoa mahdollisista opintojakson erityiskäytänteistä.

Student workload

Luennot + laskuharjoitukset n. 15 h
Itsenäinen opiskelu ja kotitehtävät 60 h
Tentti 3 h
Kuormitus on tasainen koko opintojakson ajan, yhteensä 80 h.

Further information for students

Opintojakso arvioidaan kurssin lopulla pidettävällä kokeella. Viikoittaisista kotitehtävistä saa lisäpisteitä kokeeseen.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Online exam (Zoom) and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.

Teaching methods

- lessons
- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Exam and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Suvanto, K. Tekniikan FYSIIKKA 1. Edita. All editions.
Suvanto, K. Tekniikan FYSIIKKA 2. Edita. All editions.

Teaching methods

- lessons
- distance learning
- exercises
- learning tasks

Exam dates and retake possibilities

Exam and two possible resits. Dates will be announced in the beginning of the course.

Student workload

One credit equals 27 hours of work, which means that this course needs about 81 working hours.

Further information for students

Assessment criteria: points from exercises and the exam.
Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Material made by the teacher.
Textbook: Knight, Randal D. Physics for Scientists and Engineers. Pearson International edition. 2nd edition.

Teaching methods

-lectures
-distance learning
-small group learning
-exercises
-learning tasks

Exam dates and retake possibilities

The possible date and method of the exam will be announced in the course opening information.

Alternative completion methods

The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.

Student workload

One credit corresponds to an average of 27 hours of work, which means that the load of three credits is approximately 81 hours. The load is distributed in different ways depending on the course implementation.

Further information for students

The course is assessed on the basis of a two-part (different levels) final exam.

Open AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.

Objectives

Purpose:
During the course, you will learn the physic laws of conservation and the basics of oscillation. In addition, you will learn about physical measurements and the basics of error analysis. After the course, you will be able to apply this information to mathematics as a help in the study modules that you will later study in the degree program.

EUR-ACE Competences:
Knowledge and understanding 

Learning outcomes:
After completing this course, you will know the basic principles of work and energy in both linear motion and rotational motion.You will understand the laws of oscillation and, with your knowledge, understand the basic legalities and problems dealing with oscillation in your own profession.

Content

In this course, you will learn the fundamental conservation laws of physics and the basics of oscillatory motion, as well as the basics of physical measurements and error analysis. After the course, you will be able to apply this knowledge through mathematics in your future studies. You will understand the basic principles of work and energy in rectilinear and rotational motion and the laws of oscillation. This course will give you the skills to solve problems related to vibration in your field of work and to apply what you learn in practice.

Linear momentum and impulse, elastic and inelastic collisions, angular momentum, conservation of mechanical energy, mechanical work, power and efficiency, kinetic energy, gravitational potential energy, elastic potential energy, simple harmonic motion, damped oscillation

Learning materials and recommended literature

Opettajan kokoama materiaali.
Oppikirja: Suvanto, K. Tekniikan Fysiikka 1. Edita. 6. painos eteenpäin

Teaching methods

- itseopiskelua
- harjoitustöitä
- oppimistehtäviä

Exam dates and retake possibilities

Tentin ajankohta ja toteutustapa sovitaan jokaisen opiskelijan kanssa erikseen aktiivitoteutuksen aikana.

Student workload

Yksi opintopiste tarkoittaa laskennallisesti keskimäärin 27 tunnin työtä eli kolmen opintopisteen opintojakson kuormitus on noin 81 h.

Further information for students

Opintojakso arvioidaan oppimis- ja harjoitustehtävien sekä tentin perusteella.
Avoin AMK: 5

Evaluation scale

0-5

Evaluation criteria, satisfactory (1-2)

Sufficient 1
You are able to recognize phenomena and the models attached to the field of the course.
You can solve simple course related problems. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Satisfactory 2
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems with the help of examples. You can read different kinds of tables and graphs to get the right information. Your calculations may have some mistakes.

Evaluation criteria, good (3-4)

Good 3
You are able to understand phenomena and the models attached to the field of the course.
You can solve basic problems. You can read different kinds of tables and graphs and you are also able to produce them yourself. Your calculations may have some mistakes.

Very good 4
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to produce them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. Your calculations are mainly right.

Evaluation criteria, excellent (5)

Excellent 5
You are able to understand phenomena and the models attached to the field of the course.
You can solve challenging problems. You can read different kinds of tables and graphs and you are able to make make them yourself. You are also able to evaluate the assumptions and applicabilities of the models you are using. You can apply your knowledge to new situations. Your calculations are right but may have some careless errors.

Prerequisites

The course completion requires abilities to use basic functions and solve groups of equations. The ability to use coordinate systems is needed for solving motion and force related problems.