Insinöörifysiikka (FYSLV0001), 6 op

Basic information

Prerequisites

Course contents (core content level)

Kinematics
- vectors and scalars, kinematics in one and two dimensions
Dynamics
- Newton?s laws of motion, applications of Newton laws, work and energy, conservation of energy, power, linear momentum and collisions, uniform circular motion, rotations of rigid bodies, static equilibrium, gravity
Fluids
- fluid statics (pressure, hydrostatic pressure, Pascal? principle, buoyancy and Arkhimedes? principle) and fluid dynamics (the continuity equation, Bernoulli?s equation, applications of Bernoulli?s principle, viscosity, laminar flow, turbulent flow)
Thermal physics
- temperature, thermal expansion, specific heats, phases and phase changes, latent heats, conduction, convection and radiation
Electricity
Static electricity
- electric charge, Coulomb?s law, electric field, insulators and conductors, charging by friction, charging by induction, electric potential and voltage, parallel plate capacitors, capacitors in series and parallel
Direct current circuits
- electric current, resistance, resistivity, Ohm?s law, energy and power in electric circuits, resistors in series and parallel, Kirchhoff?s rules, am meters and voltmeters

Course contents (additional)

- accelerometers (MEMS) in dynamics, liquid column manometer, hydrometer, venturi tube, Pitot tube, flow in tubes: , MEMS- pressure sensors,
- elasticity (normal stress, shear stress, Young?s modulus, shear modulus, Poisson constant)
- bimetallic element, heat transfer in multilayer structure, energy balance
- dielectric material properties
- Gauss?s law, cathode-ray tube, microwave heating, ink-jet printer, RC-circuits, piezoelectricity, capacitive sensors (for displacement, acceleration, pressure, level,humidity), resistive sensors, superconductivity, thermistor, thermocouple, Wheatstone bridge and strain gauge, Capacitive sensing method in Micro Electro Mechanical Systems (MEMS) accelerometer and pressure sensor.

Core content level learning outcomes (knowledge and understanding)

During completion of this course the student acquires basic knowledge of physical concepts, laws, principles and theories in the fields of kinematics, dynamics, properties of solids and fluids, thermal physics and electricity. Student becomes aware that physical theories are based on and verified by observations and measurements.

Core content level learning outcomes (skills)

During completion of this course the student will learn how to formulate and solve equations related to basic physical problems that appear in the fields of physics covered by this course. The knowledge gained helps the student in independent information acquisition in further studies and professional activities.

Recommended reading

Hautala, M. ja Peltonen, H. 2005. Insinöörin (AMK) fysiikka, osa I. Lahden Teho-opetus, 7. painos.

Study material, exercises, project study definitions at course website.

Teaching and learning strategies

Lectures: 56 h
Tutorials: 28 h
Individual learning assignment: 10 h
Exams: 3?3 h = 9 h
Student?s workload: student workload analysis not carried out
Total: -
Tuition in Finnish.

Teaching methods and student workload

Assessment weighting and grading

Assessment is based on student activity during classes, individual tests, one individual learning assignment and three exams.

In order to pass the course (grade 1) all the individual tests, individual learning assignment and exams have to be completed successfully.

Related competences of the degree programme

Theoretical basis and mathematical and science skills