Predmet: Course title: UČNI NAČRT PREDMETA / COURSE SYLLABUS ELEKTROTEHNIKA IN ELEKTRONIKA ELECTRICAL ENGINEERING AND ELECTRONICS Študijski program Study programme and level Letnik Academic year prvi first Študijska smer Study field Inženiring in vozila Engineering and vehicles Vrsta predmeta / Course type Semester Semester prvi first obvezni/obligatory Univerzitetna koda predmeta / University course code: Predavanja Lectures Seminar Seminar Sem. vaje Tutorial 45 - 20 Nosilec predmeta / Lecturer: Jeziki / Languages: Lab. vaje Laboratory work 10 Teren. vaje Field work Samost. delo Individ. work ECTS - 75 5 Red. prof. dr. /Full Prof. Dr. Rudolf Pušenjak Predavanja / slovenski Lectures: slovenian Vaje / Tutorial: slovenski/slovenian Pogoji za vključitev v delo oz. za opravljanje študijskih obveznosti: vpis v prvi letnik študija študent(ka) mora obvladati osnovna znanja iz matematike Prerequisits: Vsebina: Content (Syllabus outline): Predavanja: Električna napetost in električni potencial. Kondenzator, kapacitivnost. Ohmov zakon, ohmska upornost, Kirchoffova zakona, Joulov zakon. Magnetno polje premega tokovodnika in magnetno polje dolge ravne tuljave. Magnetilna krivulja in histerezna zanka. Preračun magnetnih krogov. Sila na tokovodnik v magnetnem polju. Induktivnost. Faradayev zakon elektromagnetne indukcije. Izmenični tokokrogi. Enofazni in inscription in the first year of study mastering of basic knowledges mathematics in Lectures Voltage and electric potential. Capacitor and capacitance. Ohm's law, ohmic resistance, Kirchoff laws, Joule law. Magnetic field of line conductors and magnetic field of the long straight coil. Magnetization curve and hysteresis loop. Computation of magnetic circuits. Force on the conductor in magnetic field. Inductance. Faraday law of electromagnetic induction. Alternate current circuits. Single phase and polyphase systems. Electric machines and polifazni sistemi. Električni stroji in transformatorji. Električne meritve. Polprevodniške diode, poljski in bipolarni tranzistorji. Močnostna elektronika. Integrirana elektronska vezja. Analogni sistemi in analogno procesiranje signalov. Digitalni sistemi. Sekvenčna vezja. Družine logičnih vezij. Mikroprocesorji in programirana logična vezja. Elektronska vezja za zajemanje in preoblikovanje signalov. Senzorji in aktuatorji. Seminarske in laboratorijske vaje: Poglobitev teoretičnih znanj na seminarskih vajah z reševanjem praktičnih primerov stroke. Pridobitev praktičnih izkušenj na laboratorijskih vajah iz merilne tehnike in spoznavanja delovanja elektronskih vezij. transformers. Electric measurements. Semiconductor diodes, bipolar and field effect transistors. Power electronics. Integrated electronic circuits. Analog systems and analog processing of signals. Digital systems. Sequential circuits. Logic families. Microprocessors and programable logic circuits. Electronic circuits for data acquisition and conversion of signals. Sensors and actuators. Tutorials and Lab works Tutorials are intended to deepen the theoretical knowledge with solving problems, which appear in practice Lab works are intended for acquirement of practical experiences in measurement techniques and understanding the principles of working of electronic circuits Temeljni literatura in viri / Readings: 1. R. Pušenjak: Mehanika in elektrotehnika v logistiki. Elektronsko gradivo. UM, Fakulteta za logistiko, Celje, 2011. 2. R. Pušenjak: Elektrotehnika za strojnike, Univerza v Mariboru, Fakulteta za strojništvo, 2003 3. R. Pušenjak, M. Kastrevc: Zbirka nalog z rešitvami iz elektrotehnike in elektronike za strojnike in tekstilce, Univerza v Mariboru, Fakulteta za strojništvo, 2006 4. M. Kastrevc, R. Pušenjak, Praktikum iz elektrotehnike, Univerza v Mariboru, Fakulteta za strojništvo, 2006 Priporočena literatura/ Recommended readings: 1. G. Flegel, K. Birnstiel, W. Nerreter: Elektrotechnik für Maschinenbau und Mechatronik. 9., aktualisierte Auflage. Carl Hanser Verlag, 2008. 2. J. J. Cathey, S. A. Nasar: Basic Electrical Engineering. Second Edition. Schaum’s Outline Series, 1996. Cilji in kompetence: Objectives and competences: Cilji Objectives Predmet je namenjen pridobitvi osnovnih znanj elektrotehnike in elektronike, praktičnih znanj merilne tehnike, uporabe električnih strojev in naprav, poznavanja elektronskih komponent ter delovanja in uporabe elektronskih vezij v tehniki Kompetence Učna enota prispeva k razvoju naslednjih splošnih in specifičnih kompetenc: sposobnost razčlenitve problemov elektrotehniške stroke, izvedbe njihove analize in sinteze, The subject is intended for acquirement of basic knowledge in electrical engineering and electronics as well as to gain the practical knowledges in measurement techniques, the use of electrical machines and devices, the knowledge of electronic components and circuits, their working principles and their use in engineering. Competences The subject contributes to the development of the following common and specific competences, sposobnost uporabe elektrotehniških zakonov, obvladanja standardnih metod in postopkov v analizi in pri projektiranju električnih in elektronskih naprav in sistemov, sposobnost uporabe pridobljenega teoretičnega znanja v praksi, sposobnost matematičnega opisovanja problemov elektrotehniške stroke in uporabe računalniških orodij v elektrotehniki in elektroniki usposobljenost za eksperimentalno delo in samostojno izvajanje elektriških meritev v stroki, sposobnost uporabe informacijskih in komunikacijskih tehnologij na elektrotehniškem strokovnem področju respectively: ability to analyze problems appearing in the electrical engineering and electronics as well as to perform the synthesis of electronic circuits ability to apply electric laws, mastering of standard methods in the analysis and design of electrical devices and electronic systems ability to use the gained theoretical knowledge in practice ability to mathematically describe electrical engineering problems and to use computational tools in electrical engineering and electronics ability for performing experimental work and electrical measurements in the field ability to use information and communication technologies in the electrical engineering. Predvideni študijski rezultati: Intended learning outcomes: Znanje in razumevanje: Knowledge and understanding: Študent/študentka: pozna in razume osnovne zakonitosti elektrotehnike in elektronike, pozna osnovne elektrotehniške elemente in naprave in njihove lastnosti pozna elektronske elemente in gradnike ter module elektronskih sistemov pozna postopke za analizo električnih in elektronskih vezij pozna postopke projektiranja električnih in elektronskih vezij pozna elektriške merilne instrumente in je sposoben izvajati elektriške meritve pozna sodobna računalniška programska orodja za analizo in sintezo električnih in elektronskih vezij zna načrtovati, uporabljati standarde in strokovno literaturo pozna varnostne predpise in standarde za zaščito ljudi in naprav pri delu z električnim tokom. Metode poučevanja in učenja: predavanja z aktivno udeležbo študentov, ki vsebujejo razprave, diskusije, odgovore na vprašanja in reševanje nalog ob pomoči sodobnih pedagoških pripomočkov, seminarske vaje za poglabljanje teoretičnih osnov in reševanje praktičnih problemov stroke individualno in skupinsko delo s študenti v Student: understands and conquers basic laws of electrical engineering and electronics knows the basic elements and devices of electrical engineering and knows their properties knows the electronic elements and modules of electronic systems knows methods of analysis of electrical and electronic circuits, respectively knows the procedures of synthesis of electrical and electronic circuits, respectively knows the electrical measurement instruments and is qualified to perform electrical measurements is acquainted with the use of computational tools in the analysis and synthesis of electrical and electronic circuits, respectively knows safety regulations and standards for protection of the personal and of the equipment by work with electric current. Learning and teaching methods: lectures with active attendance of students, which incorporate discussions, answers on the questions and solving of exercises with application of the contemporary pedagogical aids tutorials with deepening of theoretical knowledge and solving problems, which appear in practice obliki konzultacij, laboratorijske vaje, ki potekajo v ustrezno opremljenem laboratoriju Načini ocenjevanja: individual and collective work in the form of consultations, lab works, which are performed in a suitable equipped laboratory. Delež (v %) / Weight (in %) Način (pisni izpit, ustno izpraševanje, naloge, projekt) Type (examination, oral, coursework, project): The prerequisite for accession to the written exam is performance of lab works Pogoj za pristop k pisnemu izpitu so opravljene laboratorijske vaje ocena laboratorijskih vaj pisni izpit ustni izpit končna ocena izpita je povprečje vsote ocen posameznih deležev z upoštevanjem uteži Assessment: 20% 40% 40% the grade of lab work written exam oral exam the final grade of the exam is the average of all three grades (of the lab works, the written and the oral exam, respectively) Reference nosilca / Lecturer's references: 1. PUŠENJAK, Rudi, OBLAK, Maks. Rešavanje Helmholtzove (talasne) jednačine metodom konačnih elemenata. Elektrotehnika (Beogr.), 1978, 27, št. 12, str. 1789-1795. [COBISS.SI-ID 43026945] 2. PUŠENJAK, Rudi, OBLAK, Maks. Finite element method using continous elements with constant geometries. V: ROBINSON, John (ur.). Quality assurance in FEM technology : [proceedings of the Fifth world congress sponsored by ISTEL England]. Okehampton: Robinson and Associates, cop. 1987, str. 369-378. [COBISS.SI-ID 443140] 3. PUŠENJAK, Rudi, OBLAK, Maks. The use of continuous finite elements in electron optics. V: TANAKA, Masataka (ur.), CRUSE, Thomas A. (ur.). Boundary element methods in applied mechanics : proceedings of the First Joint Japan/US Symposium on Boundary Element Methods, Tokyo, Japan, 3-6 October 1988. Oxford [etc.]: Pergamon Press, 1988, str. 47-52. [COBISS.SI-ID 7315972] 4. PUŠENJAK, Rudi, OBLAK, Maks. Design of axisymmetric electron optical systems with use of continuous and fully discretized finite elements. V: FEMCAD-88 : proceedings of the Fourth SAS-World Conference, Paris, 17-19 October 1988, (Technology transfer series). Gournay-sur-Marne: IITT-International, 1988, str. 256-263. [COBISS.SI-ID 7316484] 5. PUŠENJAK, Rudi, OBLAK, Maks. Continuous finite element model for solution of paraxial ray equation in electron optics. V: Proceedings. [S.l.]: American Academy of Mechanics, 1989, str. 316-319. [COBISS.SI-ID 7333636] 6. PUŠENJAK, Rudi, OBLAK, Maks. Numerische Lösung einiger Torsionsprobleme unter Anwendung von kontinuierlichen Elementen. Z. angew. Math. Mech., 72 (1992), 6 ; str. T 489-493. [COBISS.SI-ID 3760388] JCR IF (1994): 0.17, SE (54/61), mechanics, x: 0.83, SE (71/85), mathematics, applied, x: 0.484 7. PUŠENJAK, Rudi. Nonlinear almost periodic analysis of FET amplifiers by incremental harmonic balance and multiple time scales. V: BARTOLID, Juraj (ur.). ICECOM '99 : proceedings. Zagreb: KoREMA, 1999, str. 130-134. [COBISS.SI-ID 4870422] 8. PUŠENJAK, Rudi. Computation of electromagnetic waveguide transverse resonances by using continuous finite elements. V: BONEFAČID, Davor (ur.). 16th International Conference on Applied Electromagnetics and Communications, 1-3 October 2001, Dubrovnik, Croatia. ICECOM 2001 : conference proceedings. Zagreb: KoREMA, 2001, str. 257-264. [COBISS.SI-ID 6596630] 9. PUŠENJAK, Rudi. Razvejitve pri Van der Pol-Duffingovem nihalu = Bifurcations of the Van der Pol-Duffing oscillator. Stroj. vestn., 2003, letn. 49, št. 7/8, str. 370-384. [COBISS.SI-ID 8489750] JCR IF: 0.048, SE (99/106), engineering, mechanical, x: 0.61 10. PUŠENJAK, Rudi, OBLAK, Maks. Incremental harmonic balance method with multiple time variables for dynamical systems with cubic non-linearities. Int. j. numer. methods eng., Jan. 2004, vol. 59, iss. 2, str. 255292. [COBISS.SI-ID 8442134] JCR IF: 1.501, SE (3/61), engineering, multidisciplinary, x: 0.57, SE (7/162), mathematics, applied, x: 0.698 11. KASTREVC, Mitja, PUŠENJAK, Rudi. Fuzzy pressure control of hydraulic system with gear pump driven by variable speed induction electro-motor. Exp. tech. (Westport Conn.), May/June 2005, vol. 29, no. 3, str. 5762. [COBISS.SI-ID 9576470] JCR IF: 0.363, SE (64/104), engineering, mechanical, x: 0.644, SE (92/110), mechanics, x: 0.96, SE (19/25), materials science, characterization & testing, x: 0.575 12. PUŠENJAK, Rudi. Extended Lindstedt-Poincare method for non-stationary resonances of dynamical systems with cubic nonlinearit. J. Sound Vib., July 2008, vol. 314, iss. 1/2, str. 194-216. http://dx.doi.org/10.1016/j.jsv.2008.01.002. [COBISS.SI-ID 12081430] JCR IF (2007): 1.024, SE (11/28), acoustics, x: 1.012, SE (23/107), engineering, mechanical, x: 0.706, SE (39/112), mechanics, x: 1.049 13. PUŠENJAK, Rudi, OBLAK, Maks. Discussion on: "Analysis of control relevant coupled nonlinear oscillatory systems". Eur. j. control, 2008, vol. 14, 4, str. 283-285. http://dx.doi.org/10.3166/ejc.14.283-285. [COBISS.SI-ID 12640790] JCR IF (2007): 1.153, SE (20/52), automation & control systems, x: 0.927 14. PUŠENJAK, Rudi, OBLAK, Maks, TIČAR, Igor. Nonstationary Vibration and Transition through Fundamental Resonance of Electromechanical Systems Forced by a Nonideal Energy Source. Int. J. of Nonl. Sci. Num. Sim., May 2009, vol. 10, iss. 5, str. 635-657. JCR IF (2007): 5.099, SE(1/67), engineering, multidisciplinary, SE(1/165),mathematics,applied, SE(2/112) mechanics, (1/43), physics, mathematical 15. PUŠENJAK, Rudi, OBLAK, Maks. Simulacija akcijskega potenciala v Hodgkin-Huxleyevem modelu = Simulation oftheactionpotential in the Hodgkin-Huxley model. Anali PAZU, ISSN 2232-416X, 2011, letn. 1, št. 2, str. 122-127, ilustr. [COBISS.SI-ID 512416061] 16. PUŠENJAK, Rudi, TIČAR, Igor, OBLAK, Maks. Self-excited oscillations and fuel control of a combustion process in a Rijke tube. International journal of nonlinear sciences and numerical simulation, ISSN 15651339. [Print ed.], 2014, vol. 15, no. 2, str. 87-106, ilustr., doi: 10.1515/ijnsns-2011-0039. [COBISS.SI-ID 17621526], [JCR, SNIP, WoS]
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