Course detail
Physics 1
FEKT-AFY1Acad. year: 2017/2018
The course Physics 1 deals at first with basis of particle mechanics. Gained knowledge is used to study the influence of physical fields on particle motion. Significant part of the subject is focused on electric and magnetic fields, their formation, laws and mutual nature leading to the concept of electromagnetic field and Maxwell’s equations.
Language of instruction
Czech
Number of ECTS credits
6
Mode of study
Not applicable.
Guarantor
Department
Learning outcomes of the course unit
Graduates in the subject are able to
define concepts of mechanics and dynamics of mass point, and of electric and magnetic fields by means of differential and integral calculus,
describe basic laws and principles of above mentioned area,
discuss conditions for application of laws of mechanics, electricity and magnetism, explain their mutual relations, distinguish the proper form of rules in selected area,
apply knowledge of studied principles in mutual connections, classify forces in electric and magnetic fields and calculate simple trajectories of charged particles,
practice theoretical laws in physical laboratories,
compare and analyze laws of electric and magnetic fields, clarify their mutual nature, explain electromagnetic field described by Maxwell’s equations.
define concepts of mechanics and dynamics of mass point, and of electric and magnetic fields by means of differential and integral calculus,
describe basic laws and principles of above mentioned area,
discuss conditions for application of laws of mechanics, electricity and magnetism, explain their mutual relations, distinguish the proper form of rules in selected area,
apply knowledge of studied principles in mutual connections, classify forces in electric and magnetic fields and calculate simple trajectories of charged particles,
practice theoretical laws in physical laboratories,
compare and analyze laws of electric and magnetic fields, clarify their mutual nature, explain electromagnetic field described by Maxwell’s equations.
Prerequisites
Within the scope of standard secondary school requirements students should
have knowledge of basic principles and laws of mechanics , electricity and magnetism,
be able to explain basic principles and laws of mechanics , electricity and magnetism,
be able to apply basic laws of mechanics to simple motion of particles, to apply laws of electricity and magnetism to simple electric circuits.
Mathematical requirements:
Students should be able to discuss basic concepts of secondary school algebra and geometry, to calculate linear equations and to apply basic goniometric functions.
have knowledge of basic principles and laws of mechanics , electricity and magnetism,
be able to explain basic principles and laws of mechanics , electricity and magnetism,
be able to apply basic laws of mechanics to simple motion of particles, to apply laws of electricity and magnetism to simple electric circuits.
Mathematical requirements:
Students should be able to discuss basic concepts of secondary school algebra and geometry, to calculate linear equations and to apply basic goniometric functions.
Co-requisites
Not applicable.
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations. They include lectures, excercises, computer laboratories and practical laboratories. Course is taking advantage of e-learning (Moodle) system. Students have to write 6 laboratory reports and have to hand in the solution of assigned problems during the course.
Assesment methods and criteria linked to learning outcomes
Study evaluation is based on marks obtained for specified items.
Final classification – max. 100 pts.
Semester:
Laboratories up to 20 pts. (6 laboratory measurements and tests, final test)
Seminars up to 15 pts. (2 written tests)
For obtaining the credit it is necessary to measure out and to evaluate the given number of experimental problems and to gain at least 12 points.
Exam:
Up to 65 pts.
Exam has written form, it consists of the test with selection questions, a theoretical part and examples. To pass the exam it is necessary to gain at least 6 points in theoretical part and in examples.
Final classification – max. 100 pts.
Semester:
Laboratories up to 20 pts. (6 laboratory measurements and tests, final test)
Seminars up to 15 pts. (2 written tests)
For obtaining the credit it is necessary to measure out and to evaluate the given number of experimental problems and to gain at least 12 points.
Exam:
Up to 65 pts.
Exam has written form, it consists of the test with selection questions, a theoretical part and examples. To pass the exam it is necessary to gain at least 6 points in theoretical part and in examples.
Course curriculum
1. Equation of motion and its applications. Oscillations. Work, energy and power. Conservation laws. Collisions.
2. Gravitational and electrostatic field. Actual gravitational field of the Earth.
3. Electric charge, Coulomb's law. Electric field strength and electric field lines. A point charge and a dipole in an electric field.
4. Gauss's law of electrostatics and its applications.
5. Capacitance. Electrostatic field in a dielectric. Energy of an electrostatic field.
6. Electric current, equation of continuity. Ohm's law.
7. Electromotive force. Work and power executed by electric current. Conduction of electric current in matter.
8. Electrical circuits. Calculation of an electric current in a simple electrical circuit. Circuits with more current loops. RC circuits.
9. Magnetic field due to an electric current, Biot's-Savart's law, magnetic field lines.
10. Ampere's law of the total current. Force action of magnetic fields.
11. Gauss's law for magnetic fields. Magnetic field in matter.
12. Faraday's law. Coils and inductances. Alternating electric current. LC and RLC circuits. Transformers.
13. Maxwell's equations in integral and differential form for vacuum and for a dielectric.
Application of electrical and magnetic phenomena in medicine.
2. Gravitational and electrostatic field. Actual gravitational field of the Earth.
3. Electric charge, Coulomb's law. Electric field strength and electric field lines. A point charge and a dipole in an electric field.
4. Gauss's law of electrostatics and its applications.
5. Capacitance. Electrostatic field in a dielectric. Energy of an electrostatic field.
6. Electric current, equation of continuity. Ohm's law.
7. Electromotive force. Work and power executed by electric current. Conduction of electric current in matter.
8. Electrical circuits. Calculation of an electric current in a simple electrical circuit. Circuits with more current loops. RC circuits.
9. Magnetic field due to an electric current, Biot's-Savart's law, magnetic field lines.
10. Ampere's law of the total current. Force action of magnetic fields.
11. Gauss's law for magnetic fields. Magnetic field in matter.
12. Faraday's law. Coils and inductances. Alternating electric current. LC and RLC circuits. Transformers.
13. Maxwell's equations in integral and differential form for vacuum and for a dielectric.
Application of electrical and magnetic phenomena in medicine.
Work placements
Not applicable.
Aims
The main objectives are: to provide the students with clear and logical presentation of the basic concepts and principles of physics, and to strengthen an understanding of these concepts and principles through a broad range of interesting applications.
Specification of controlled education, way of implementation and compensation for absences
Attendance in seminars is compulsory. Excused seminars can be made up.
The content and forms of instruction in the evaluated course are specified by a regulation issued by the lecturer responsible for the course and updated for every academic year.
The content and forms of instruction in the evaluated course are specified by a regulation issued by the lecturer responsible for the course and updated for every academic year.
Recommended optional programme components
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
Fyzika 1. Studijní materiály k přednáškám, cvičením a laboratornímu cvičení. Stránka předmětu na eLearningu VUT. (CS)
Halliday D., Resnick R., Walker J.: Fyzika Vysoké učení technické v Brně, Vutium, Brno, 2014, Překlad 8. orig. vydání (CS)
Halliday, D.; Resnick, R.; Walker J.: Fyzika. Vysoké učení technické v Brně, Vutium, Prometheus Praha, 2000, 2003, 2006, Překlad 5. orig. vydání. (CS)
Halliday D., Resnick R., Walker J.: Fyzika Vysoké učení technické v Brně, Vutium, Brno, 2014, Překlad 8. orig. vydání (CS)
Halliday, D.; Resnick, R.; Walker J.: Fyzika. Vysoké učení technické v Brně, Vutium, Prometheus Praha, 2000, 2003, 2006, Překlad 5. orig. vydání. (CS)
Recommended reading
DOBIS, P., UHDEOVÁ, N., BRÜSTLOVÁ, J., BARTLOVÁ, M.Průvodce studiem předmětu Fyzika 1 (CS)
Hyperphysics: http://hyperphysics.phy-astr.gsu.edu/hbase/hframe.html (EN)
Hyperphysics: http://hyperphysics.phy-astr.gsu.edu/hbase/hframe.html (EN)
Classification of course in study plans
Type of course unit
Lecture
26 hod., optionally
Teacher / Lecturer
Syllabus
Equation of motion and its application. Oscillation. Work, energy, and power. Conservation laws. Collisions.
Gravitational field.
Electric charge, Coulomb's law. Electric field, field lines.
Point charge and electric dipole in an electric field. Gauss' law of electrostatics and its application.
Electric capacitance. Electrostatic field in dielectrics. Energy in electric field.
Electric current and resistance, continuity relation. Ohm's law.
Elelectric circuits, currents in simple circuts, circuits with network loops.
Magnetic field generated by electric current, Biot-Savart's law, magnetic field lines.
Ampere's law, force action of magnetic field.
Gauss' law for magnetic field. Magnetic field in materials.
Faraday's induction law. Coils and inductance.
Integral form of Maxwell's equations in vacuum and in dielectrics.
Electromagnetic oscillation, alternating current and cicuits LC, RLC. Transformers.
Application electric and magnetic phenomenon in medicine.
Gravitational field.
Electric charge, Coulomb's law. Electric field, field lines.
Point charge and electric dipole in an electric field. Gauss' law of electrostatics and its application.
Electric capacitance. Electrostatic field in dielectrics. Energy in electric field.
Electric current and resistance, continuity relation. Ohm's law.
Elelectric circuits, currents in simple circuts, circuits with network loops.
Magnetic field generated by electric current, Biot-Savart's law, magnetic field lines.
Ampere's law, force action of magnetic field.
Gauss' law for magnetic field. Magnetic field in materials.
Faraday's induction law. Coils and inductance.
Integral form of Maxwell's equations in vacuum and in dielectrics.
Electromagnetic oscillation, alternating current and cicuits LC, RLC. Transformers.
Application electric and magnetic phenomenon in medicine.
Laboratory exercise
26 hod., compulsory
Teacher / Lecturer
Syllabus
The rules of work in the laboratory. Evaluation and presentation of measurements.
Gravitational acceleration - Reversion pendulum.
Speed of light.
Elementary charge.
Temperature dependence of resistance of metals and semiconductors. Superconductivity.
Electric circuits and its characteristics.
Magnetic field around a conductor. Force action of the magnetic field.
Magnetic properties of materials.
Hall's effect.
Seminar, seminar work presentation.
Gravitational acceleration - Reversion pendulum.
Speed of light.
Elementary charge.
Temperature dependence of resistance of metals and semiconductors. Superconductivity.
Electric circuits and its characteristics.
Magnetic field around a conductor. Force action of the magnetic field.
Magnetic properties of materials.
Hall's effect.
Seminar, seminar work presentation.