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This course presents the physical point of view and the physical interpretation of chemical knowledges toughed in our university. In introduction, the brief overview of modern physics, the creation and evolution of Earth and life are given. Next, this course presents the application of mathematical knowledge for basic modeling of behavior of life organisms and other systems. It presents the physical interpretation of basic rules of thermodynamic and physical chemistry, biological membranes, diffusion, osmoses, surface tension etc. At the end, it presents interesting topics as biomechanics, biophysics of seeing and hearing, action potential, neurons and neural network, intelligence and artificial intelligence, radiation interaction with organisms, or physical methods of microbial decontamination.
Last update: Scholtz Vladimír (06.02.2018)
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Student will be able to: apply the laws of physics and mathematics to objects of wildlife and interpret the principles of physical processes in biological objects and the behavior of both biological and general systems. Last update: Scholtz Vladimír (06.02.2018)
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Podmínkou získání zápočtu je absolvování seminářů, laboratorních cvičení a závěrečný test. Zkouška je písemnou i ústní formou. Last update: Scholtz Vladimír (04.01.2018)
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R: Hrazdira I. a kol.: Biofyzika, Avicenum, Praha, 1983 R: Krempaský, J.: Synergetika, Slovenská technická univerzita Bratislava, 2001 A: Kulhánek P.: Moderní kosmologie, Hvězdárna Valašské Meziříčí, 2011, http://www.aldebaran.cz/download/Kosmologie.pdf A: Hrazdira I., Mornstein V., Lékařská biofyzika a přístrojová technika, Neptun, 2001, ISBN 80-902896-1-4 A: Biophysics, Glaser R., Springer Verlag 2009, ISBN 3-540-67088-2 Last update: Scholtz Vladimír (06.02.2018)
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Přednášky, cvičení, laboratoře. Last update: Scholtz Vladimír (06.02.2018)
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1. Creation and formation of Universe, life and organic structures - possibilities and prepositions. 2. Evolution theory, evolution strategies. Behavior of biological, chemical and social systems. 3. One dimensional dynamic systems, mathematical models, examination, methods of approximative solution and estimation of behavior, application on biophysical systems. 4. Multidimensional dynamic systems, mathematical models, examination, methods of approximative solution and estimation of behavior, phase portrait, application on biophysical systems. 5. Thermodynamics of life: Principles of biochemical reactions, problem of entropy and information. 6. Boundaries and gradients: thermodynamic of transport, passive and active transport. 7. Morphology and function of several biological membranes for transport of material and energy. 8. Electrical characteristics of membranes, action potential. 9. Action potential of neural fibers. Neurons and neural networks. Intelligence and artificial intelligence. 10. Biomechanics: fractal biological structures, musculoskeletal system, hydromechanics, blood flow, flying. 11. Self-organization and creation of biological structures: formation of fractal structures, multicellular organisms, reaction-diffusion model of animal morphology (bacterial colonies, texture of shells). 12. Optics (geometrical optics, the human eye, defects and their correction). 13. Acoustics (organ of hearing, hearing theory, ultrasound). 14. Ionizing radiation. Consequence of the interaction of ionizing radiation with matter. Last update: Scholtz Vladimír (06.02.2018)
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https://ufmt.vscht.cz/index.php/cs/elektronicke-pomucky/predmety-bakalarskeho-studia/6-n444010-biofyzika Last update: Scholtz Vladimír (06.02.2018)
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Physics I and Mathematics I or equivalent Last update: Scholtz Vladimír (07.01.2014)
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Teaching methods | ||||
Activity | Credits | Hours | ||
Konzultace s vyučujícími | 0.5 | 14 | ||
Účast na přednáškách | 1 | 28 | ||
Příprava na zkoušku a její absolvování | 2 | 56 | ||
Účast na seminářích | 0.5 | 14 | ||
4 / 4 | 112 / 112 |
Coursework assessment | |
Form | Significance |
Regular attendance | 20 |
Oral examination | 80 |