N_FLP Physics in logistics processes

Institute of Technology and Business in České Budějovice
winter 2016
Extent and Intensity
2/2. 5 credit(s). Type of Completion: zk (examination).
Teacher(s)
doc. Ing. Irena Hlaváčová, Ph.D. (seminar tutor)
Guaranteed by
doc. Ing. Irena Hlaváčová, Ph.D.
Department of Informatics and Natural Sciences – Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice
Supplier department: Department of Informatics and Natural Sciences – Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice
Timetable of Seminar Groups
N_FLP/L3: Sat 22. 10. 14:50–16:20 B5, 16:30–18:00 B5, 18:10–19:40 B5, Sun 27. 11. 8:00–9:30 B5, 9:40–11:10 B5, 11:25–12:55 B5, I. Hlaváčová
N_FLP/P01: Mon 11:25–12:55 B3, I. Hlaváčová
N_FLP/S01: Mon 16:30–18:00 D617, I. Hlaváčová
N_FLP/S02: Tue 14:50–16:20 A6, I. Hlaváčová
Prerequisites (in Czech)
MAX_KOMBINOVANYCH ( 96 ) && MAX_PREZENCNICH ( 60 )
Course Enrolment Limitations
The course is offered to students of any study field.
The capacity limit for the course is 156 student(s).
Current registration and enrolment status: enrolled: 0/156, only registered: 1/156
Course objectives supported by learning outcomes
The aim of the course is to get the students acquainted with physical and technical aspects of material and information flows in logistics systems. Graduates demonstrate sufficient knowledge of applied mechanics, physical fields, electromagnetic waves and observation methods of motion of bodies.
Syllabus
  • 1 Circular motion in mechanical systems. Forces in curvilinear motion. Centrifugal regulators. The principle of dynamic sensor. Torque and angular momentum. Work as a trace effect of the force. Impulse of force as a time effect of the force. Momentum and impulse during rotational movement. Force transfer in couplings and gearboxes. 2 Moment of inertia. Flywheels and their practical use. Free flywheel, Maxwell flywheel, gimbal. Heavy flywheel, its precession and nutation. 3 Gyroscopic effects in transport equipment in curves (aircraft, ship, rocket). Gyroscopic effects in multiple- and single-rail vehicles. Stabilization of flying discs and missiles. 4 Four laws of thermodynamics. Carnot efficiency. The conversion of thermal energy into mechanical one. 5 Gravitational field. Intensity and potential of gravitational field. Movements in the Earth gravity field. 6 Electrostatic Field. Intensity and potential of electrostatic field. Electrostatic field of charged conductors. 7 Electric current. Conductors, insulators and semiconductors. 8 Magnetic field of permanent currents. Magnetic circuits. Generation of the AC voltage in a rotating loop. 9 Closed and open electromagnetic oscillator. Electromagnetic waves generation and propagation. Classification of electromagnetic waves. 10 Light as electromagnetic waves and corpuscular radiation. Coherent sources. Light interference. Difraction by the opaque edge, slit and grating. Light polarization, birefringence and its use in practice. 11 Photon energy, mass and momentum. Einstein's equation of photoelectric effect. Wave-particle dual nature of light. 12 Coherent and incoherent sources for optical communication systems. Detectors of radiation. Optical fiber and planar waveguide structures. 13 Signal transmission by optical fiber. Optical signals processing. Information transfer in atmosphere and other dielectric environment. The principle of satellite Earth observation.
Literature
    required literature
  • Feynman, Richard Phillips. Feynmanovy přednášky z fyziky s řešenými příklady. Feynman, Leighton, Sands. 1. vyd. Havlíčkův Brod : Fragment, 2000-2002. 3 sv. Přeloženo z angličtiny. ISBN 80-7200-405-0.
  • Halliday, David. Fyzika: vysokoškolská učebnice obecné fyziky. Část 1, 2, 3, 4 a 5. Brno Praha: VUTIUM Prometheus, 2000. ISBN 80-214-1868-0, ISBN 80-7196-213-9.
    recommended literature
  • Horák, Z., Krupka, F. Fyzika. Příručka pro fakulty strojního inženýrství. SNTL Praha, SVTL Bratislava. Praha 1966.
  • Ondráček, E., Janáček, P. Výpočtové modely v technické praxi. SNTL Praha 1990.
  • Sequens, Jiří. Technika zobrazení fyzikálních polí. Praha : Academia, 1980.
  • Sodomka,L., Fiala. J. Fyzika, chemie kondenzovaných látek s aplikacemi. ADHESI. Liberec 2003.
Forms of Teaching
Lecture
Seminar
Consultation
Teaching Methods
Frontal Teaching
Group Teaching - Cooperation
Critical Thinking
Individual Work– Individual or Individualized Activity
Student Workload
ActivitiesNumber of Hours of Study Workload
Daily StudyCombined Study
Project presentation1 
Preparation for the Mid-term Test13 
Preparation for Lectures13 
Preparation for Seminars, Exercises, Tutorial13 
Preparation for the Final Test26 
Unaided calculation of physical problems at the whiteboard13 
Project preparation12 
Attendance on Lectures26 
Attendance on Seminars/Exercises/Tutorial/Excursion13 
Total:1300
Assessment Methods and Assesment Rate
Exam – written 70 %
Test – final 10 %
Project – group 10 %
Seminar activity- unaided calculation of problems 10 %
Exam conditions
Students of combined form will gain continuous assessment by elaboration of a seminar work (must be delivered no later than one week before the exam) and demonstrating basic knowledge of the subject matter in the test (work 10, authorship verification by demonstrating understanding 10, basic knowledge of subject 10). Final written exam is evaluated by 70 points.
Language of instruction
Czech
Teacher's information
https://is.vstecb.cz/auth/el/5610/zima2014/N_FLP/index.qwarp
The course is also listed under the following terms winter 2014, summer 2015, winter 2015, Summer 2016, winter 2017, winter 2018, summer 2019, winter 2019, summer 2020, winter 2020, summer 2021.
  • Enrolment Statistics (winter 2016, recent)
  • Permalink: https://is.vstecb.cz/course/vste/winter2016/N_FLP