nastavno-naucnom ve• cu fizi¶ ckog fakulteta• … · nastavno-naucnom ve• cu fizi¶ ckog...

NASTAVNO-NAUCNOM VECU FIZICKOG FAKULTETA

UNIVERZITETA U BEOGRADU

Posto smo na VI sednici Izbornog i Nastavno-naucnog Veca Fizickog fakulteta Uni-

verziteta u Beogradu odredjeni za clanove Komisije za pripremu izvestaja po raspisanom

konkursu za izbor jednog docenta za naucnu oblast Nastava fizike na Fizickom fakultetu

u Beogradu podnosimo sledeci

R E F E R A T

Na konkurs za izbor jednog docenta za naucnu oblast Nastava fizike na Fizickom

fakultetu u Beogradu, koji je objavljen u oglasniku “POSLOVI” (dvobroj 669-670), od 13.

aprila 2016. godine, prijavio se kao jedini kandidat

Dragan V. Redzic,

docent,

Fizicki fakultet

Studentski trg 12,

tel. 7158 169,

[email protected]

BIOGRAFIJA, NASTAVNA I NAUCNA

AKTIVNOST Dragana Redzica

I. OSNOVNI BIOGRAFSKI PODACI

Dragan Redzic je rodjen od oca Vucete i majke Milijanke 7. januara 1958. godine

u Doboju. Osnovnu skolu i gimnaziju zavrsio je u Beogradu sa prosecnom ocenom

5,00. Fizicki fakultet Univerziteta u Beogradu, istrazivacki smer - teorijska fizika, je

zavrsio 1981. godine (prosecna ocena 9,22). Diplomirao je 16. januara 1981. na temi

1

“Veza izmedu entropije i drugih termodinamickih velicina u Penrouzovom aksiomatskom

zasnivanju statisticke termodinamike”kod prof. dr Save Milosevica. Rad je iste go-

dine nagradjen Oktobarskom nagradom grada Beograda za najbolje naucne i strucne

radove studenata. Postdiplomske studije je zavrsio na Fizickom fakultetu Univerziteta

u Beogradu na smeru Nastava fizike 2004. godine sa prosecnom ocenom 10,00. Magis-

tarsku tezu (tema: “Neki metodoloski problemi elektrodinamike tela u kretanju”, mentor:

prof. dr Natasa Nedeljkovic) je odbranio 1. oktobra 2004. godine. Doktorsku disertaciju

“Egzaktna resenja nekih problema elektrodinamike tela u kretanju u okviru magneto-

fluidodinamickog modela”, mentor: prof. dr Natasa Nedeljkovic, odbranio je 20. marta

2009. godine. Dragan Redzic je zaposlen na Fizickom fakultetu od 1. jula 1982. godine

kao asistent-pripravnik, a 1988. godine je reizabran. U zvanje asistenta izabran je 2005.

godine, a 2009. godine je reizabran. U naucno zvanje visi naucni saradnik za naucnu oblast

Fizika cestica i polja izabran je 7. jula 2010. godine. U zvanje docenta za naucnu oblast

Nastava fizike izabran je 16. juna 2011. godine, sa 18 publikovanih radova u vodecim

casopisima za navedenu oblast.

II. NASTAVNA AKTIVNOST

Dragan Redzic je zaposlen na Fizickom fakultetu od 1. jula 1982. godine kao asistent-

pripravnik, asistent, odnosno docent. Drzao je racunske vezbe na sledecim predmetima:

Opsta fizika III i Opsta fizika IV (Elektromagnetizam i optika) (II godina: Opsta fizika,

Astrofizika), Elektromagnetizam i atomistika (II godina: Meteorologija) Kvantna teorija

polja (IV godina: Teorijska fizika), Fizika II (II godina: Fizicka hemija), Fizika III (II

godina: Meteorologija), Elektromagnetizam (II godina: Astrofizika), Matematicka fizika

III (IV godina: Teorijska fizika), Fizicka optika (II godina: Astrofizika), Elektromagne-

tizam i optika (II godina: Astrofizika), Fizika I (I godina: Fizicka hemija), Fizika II (II

godina: D i E smer). Osim toga, jedno vreme drzao je i eksperimentalne vezbe iz Fizicke

mehanike za studente fizike. Vecinu kurseva pokrivao je zbirkama zadataka u rukopisnoj

formi. Poslednjih pet skolskih godine drzao je nastavu iz predmeta Elektromagnetizam i

osnovi atomske fizike za studente Meteorologije.

2

Ocene studenata za nastavu u prethodnim godinama kandidata dr Dragana Redzica

su 4,5 (letnji semestar 2006/2007) i 4,1 (zimski semestar 2007/2008).

Bio je mentor jednog master rada, studenta iz Libije, koji je baziran na publikaciji

[A43].

III. NAUCNA AKTIVNOST

A. Publikacije

Osnovna naucno-istrazivacka oblast kojom se Dragan Redzic bavi je Klasicna teorija

polja. Uslovno, ova oblast potpada pod naucnu oblast Fizika cestica i polja kao i naucnu

oblast Nastava fizike. Tekuca istrazivanja kandidata su najvecim delom posvecena teori-

jskom proucavanju elektrodinamike tela u kretanju, i srodnim temama. Do sada je objavio

43 rada (ukljucujuci naucnu kritiku i polemiku), po 2 u J. Phys. D i J. of Electromagn.

Waves and Appl., 6 u Am. J. Phys., po jedan u Prog. Electromagn. Res., Czech. J.

Phys., Prog. Electromagn. Res. M i Fizika A (Zagreb), i preostalih 29 u Eur. J. Phys.

Iz tematike kojom se bavi publikovao je jednu knjigu, u sopstvenom izdanju, uz podrsku

Ministarstva nauke.

Kandidat je jedini autor na 36 radova, glavni autor (od dva) na 2 rada, glavni autor

(od tri) na 3 rada i prvi autor (od dva) na dva rada. U svom naucnom radu ispoljio je

izrazitu samostalnost. Publikovao je najvise u casopisima Am. J. Phys. i Eur. J. Phys.,

koji su specificnog profila (vodeci medjunarodni casopisi u oblasti edukacije u fizici, koji

publikuju originalne istrazivacke radove pod uslovom da mogu biti iskorisceni i u nastavi

fizike na postdiplomskom ili dodiplomskom nivou); priblizno cetvrtina radova kandidata

spada u naucnu kritiku ili polemiku. 6 radova kandidata imaju impakt faktor veci od 1,

dok 23 rada imaju impakt faktor veci od 0.5 i publikovani su u vodecim medjunarodnim

casopisima za oblast Nastava fizike. Radovi su mu citirani 132 puta, od toga 88 puta na

Web of Science + Scopus.

Kandidat je sluzio kao recenzent u casopisima: American Journal of Physics, Journal

of Physics A, Journal of Physics D, Journal of Electromagnetic Waves and Applications,

3

Progress in Electromagnetics Research, Physica Scripta, New Journal of Physics, Euro-

physics Letters, Journal of Electrostatics, European Journal of Physics, Afrika Matematika

i Results in Physics, ukupno 25 puta dosad.

B. Ucesce na naucnim projektima i medjunarodna saradnja

Ucesnik je na projektima Ministarstva nauke 171028 i 171029.

Saradjivao je sa Prof. Janezom Strnadom (Univerzitet u Ljubljani), iz cega je prois-

tekao rad [A42], sa Prof. Paulom Lorrainom (McGill University, Montreal) (na rezultatima

te saradnje bazirana su 3 poglavlja u monografiji Paul Lorrain et al 2006 Magneto-Fluid

Dynamics: Fundamentals and Case Studies of Natural Phenomena (New York: Springer)

na sta je ukazano u predgovoru i na pocetku svake od ovih glava), i sa Prof. Vladimirom

Hnizdom [A26].

IV. PREGLED NAUCNIH REZULTATA

Oblasti naucnog rada Dragana Redzica su Klasicna teorija polja, N1, i Specijalna

Relativnost, N2, pri cemu veliki broj publikacija kandidata pripada i jednoj i drugoj

oblasti. Kako je vec napomenuto, radovi svakako spadaju i u oblast Nastave fizike.

A. N1 [A1,..,A3,A9,..,A11,A14,A17,...,A19,A21,A23,..,A26,A31,..,A34,A36,..,A38,B1,E1,E2]

U oblasti klasicne elektrodinamike, kandidat je generalizovao resenja nekih elektro-

statickih i magnetostatickih problema dobijena primenom metoda likova [A1,A2,A17,A25],

odnosno korigovao pogresna resenja [A31,A34]. Resavanjem Poissonove i Laplaceove

jednacine u odgovarajucim koordinatama, dobio je resenje jednog bazicnog elektrostatickog

[A10], i jednog bazicnog magnetostatickog problema [A18]. Razliciti aspekti Faradayevog

zakona elektromagnetne indukcije u opstem slucaju filamentarne provodne konture koja

se krece relativistickim brzinama i pri tome menja svoj oblik proucavani su u radovima

[A19,A21,A37,A38]; neki jos nepublikovani rezultati iz ove teme prezentirani su u dis-

ertaciji [E2]. Radovi [A11,A36], i esencijalni delovi radova [A18,A19,A21,A26,A34], spadaju

4

u oblast matematicke fizike. Reference [A7,A32,A42] su u izvesnom smislu sinteza Speci-

jalne Relativnosti, klasicne i kvantne teorije.

Preostale reference oblasti N1 se odnose na elektrodinamiku tela u kretanju u uzem

smislu, i Specijalnu Relativnost, i bice diskutovane u narednom odeljku.

B. N2[A4,..,A6,A8,A9,A12,A13,A15,A16,A20,A22,A23,A27,..,A29,A32,A33,A35,A39,A40,

A42,

A43,B1,E1,E2]

Nekoliko publikacija posveceno je analizi osnovnih rezultata i koncepata Specijalne Rel-

ativnosti [A4,..,A6,A20,A22,A28,A29,A40,B1,E1,E2], sto je dovelo do sagledavanja Dewan-

Beran-Bellovog problema iz nove perspektive [A5,A22,A39]. Osim toga, kandidat je dobio

egzaktna resenja nekih problema elektrodinamike tela u kretanju [A3,A8,A9,A12,A14].

Recimo, zahvaljujuci slucajnom otkricu neobicnog svojstva raspodele naelektrisanja na

izduzenom provodnom sferoidu, nadjeni su elektromagnetni likovi provodnih sferoida u

ravnomernom kretanju duz ose rotacije, koristeci metod specijalne relativnosti i teoriju

likova [A9]. Ovaj rezultat doveo je do uvidjanja jedne asimetrije inherentne Maxwellovoj

elektrodinamici koja, pod uslovom da je adekvatno interpretirana, daje ‘precicu’ ka Lorent-

zovim transformacijama [A13]. Takodje, data su egzaktna resenja niza problema elektro-

dinamike tela u kretanju, u okviru teorije prvog reda fenomenoloske elektrodinamike tela

u kretanju Minkowskog. Nadjeno je jedno resenje veoma teskog problema priblizavanja

ravnotezi kod omskih nemagnetnih krutih provodnika u proizvoljnom kretanju u konstant-

nom spolja primenjenom magnetnom polju [A14], i korigovane ranije analize stacionarnih

situacija kod omskih nemagnetnih provodnika u v×B poljima [A33,A35]. Efekt inertnosti

kondukcionih elektrona na elektromagnetno polje u slucaju osnosimetricnog provodnika

koji ravnomerno rotira oko svoje ose simetrije analiziran je u referenci [A12]. Znacaj Speci-

jalne Relativnosti pri “sobnim” brzinama detaljno je diskutovan u referencama [A23,A28];

novi uvidi u relativisticko usporavanje satova dati su u referenci [A29].

5

V. SPISAK PUBLIKACIJA

A Radovi u medjunarodnim casopisima, IF > 1

[A1] D V Redzic and S S Redzic

Image charge inclusions in the prolate dielectric spheroid

J. Phys. D: Appl. Phys. 38 3991-4 (2005)

[A2] D V Redzic

An extension of the magnetostatic image theory for a permeable sphere

J. Phys. D: Appl. Phys. 39 4136-41 (2006)

[A3] D V Redzic

Electromagnetostatic charges and fields in a rotating conducting sphere

Prog. Electromagn. Res. 110 383-401 (2010)

[A4] D V Redzic et al

Derivations of relativistic force transformation equations

J. of Electromagn. Waves and Appl. 25 1146-55 (2011)

[A5] D V Redzic

Relativistic length agony continued

Serb. Astron. J. 188 55-65 (2014)

[A6] D V Redzic

Direct calculation of length contraction and clock retardation

Serb. Astron. J. 190 49-58 (2015)

Radovi u medjunarodnim casopisima za Nastavu fizike, IF > 0.5

[A7] D V Redzic

The Doppler effect and conservation laws revisited

Am. J. Phys. 58 1205-8 (1990)

6

[A8] D V Redzic

On the electromagnetic field close to the surface of a moving conductor

Am. J. Phys. 60 275-7 (1992)

[A9] D V Redzic

Image of a moving spheroidal conductor

Am. J. Phys. 60 506-8 (1992)

[A10] D V Redzic

An electrostatic problem: a point charge outside a prolate dielectric spheroid

Am. J. Phys. 62 1118-21 (1994)

[A11] D V Redzic

The operator ∇ in orthogonal curvilinear coordinates

Eur. J. Phys. 22 595-9 (2001)

[A12] D V Redzic

Electromagnetism of rotating conductors revisited

Eur. J. Phys. 23 127-34 (2002)

[A13] D V Redzic

Image of a moving sphere and the FitzGerald-Lorentz contraction

Eur. J. Phys. 25 123-6 (2004)

[A14] D V Redzic

Conductors moving in magnetic fields: approach to equilibrium

Eur. J. Phys. 25 623-32 (2004)

[A15] D V Redzic

Momentum conservation and Einstein’s 1905 Gedankenexperiment

Eur. J. Phys. 26 991-7 (2005)

7

[A16] D V Redzic

Does ∆m = ∆Erest/c2?

Eur. J. Phys. 27 147-57 (2006)

[A17] D V Redzic and S S Redzic

Image current inclusions in the permeable sphere

Eur. J. Phys. 27 787-92 (2006)

[A18] D V Redzic

The magnetic field of a static circular current loop: a new derivation

Eur. J. Phys. 27 N9-N14 (2006)

[A19] D V Redzic

Faraday’s law via the magnetic vector potential

Eur. J. Phys. 28 N7-N10 (2007)

[A20] D V Redzic

Towards disentangling the meaning of relativistic length contraction

Eur. J. Phys. 29 191-201 (2008)

[A21] D V Redzic

Various paths to Faraday’s law

Eur. J. Phys. 29 257-62 (2008)

[A22] D V Redzic

Note on Dewan-Beran-Bell’s spaceship problem

Eur. J. Phys. 29 N11-N19 (2008)

[A23] D V Redzic

Charges and fields in a current-carrying wire

Eur. J. Phys. 33 513-523 (2012)

[A24] D V Redzic

The calculation of the electrostatic potential of infinite charge distributions

8

Eur. J. Phys. 33 941-946 (2012)


Image charge inclusion in the dielectric sphere revisited

Eur. J. Phys. 33 1751-1759 (2012)

[A26] D V Redzic and V Hnizdo

Time-dependent fields of a current-carrying wire

Eur. J. Phys. 34 495-501 (2013)

[A27] D V Redzic

The case of the Doppler effect for photons revisited

Eur. J. Phys. 34 1355-1366 (2013)

[A28] D V Redzic

Force exerted by a moving electric current on a stationary or co-moving charge:

Maxwell’s theory versus relativistic electrodynamics

Eur. J. Phys. 35 045011 (2014)

[A29] D V Redzic

Subtleties of the clock retardation

Eur. J. Phys. 36 065035 (2015)

Naucna kritika i polemika

[A30] D V Redzic

Comment on ‘Some remarks on classical electromagnetism and the principle of rela-

tivity,’ by U. Bartocci and M. M. Capria [Am. J. Phys. 59 1030-2 (1991)]

Am. J. Phys. 61 1149 (1993)

[A31] D V Redzic

Comment on ’Electrostatic images by multipole expansion,’ by J L Marin and R

Rosas [Am. J. Phys. 52 358-61(1984)] Am. J. Phys. 62 182 (1994)

9

[A32] D V Redzic

Comment on the Compton effect

Eur. J. Phys. 21 L9 (2000)

[A33] D V Redzic

Comment on electrostatic charges in v ×B fields

Eur. J. Phys. 22 L1 - L2 (2001)

[A34] D V Redzic

Comment on ’Electrostatic image theory for the dielectric prolate spheroid’ by I V

Lindell and K I Nikoskinen

J. of Electromagn. Waves and Appl. 17 1625-7 (2003)

[A35] D V Redzic

Electrostatic charges in v ×B fields: with or without special relativity?

Eur. J. Phys. 25 L9-L11 (2004)

[A36] D V Redzic

Comment on ‘Matrix representations for vector differential operators in general or-

thogonal coordinates’ by S. Visnovsky

Czech. J. Phys. 55 217-219 (2005)

[A37] D V Redzic

Reply to comment on ‘Faraday’s law via the magnetic vector potential’

Eur. J. Phys. 29 L5 (2008)

[A38] D V Redzic

Comment on ‘Note on Faraday’s law and Maxwell’s equations’

Eur. J. Phys. 29 L33-L35 (2008)

[A39] D V Redzic

Reply to comment on ‘Note on Dewan-Beran-Bell’s spaceship problem’

Eur. J. Phys. 30 L7-L9 (2009)

10

[A40] D V Redzic

Comment on ‘Lorentz contraction and current-carrying wires’

Eur. J. Phys. 31 L25-L27 (2010)

[A41] D V Redzic

Comment on ‘Forces on a current loop and magnetic moment’

Eur. J. Phys. 34 L9-L10 (2013)

Rad u medjunarodnom casopisu indeksiranom u Scopusu

[A42] D Redzic and J Strnad

Einstein’s light complex

Fizika A 13 113-20 (2004)


An extension of the Kelvin image theory to the conducting Heaviside ellipsoid

Progress In Electromagnetics Research M 18 233-46 (2011)

Monografije, udzbenici, pomocni udzbenici

[B-1] Dragan Redzic

Recurrent topics in special relativity: seven essays on the electrodynamics of moving

bodies

Beograd 2006 (authorial edition)

E. Magistarski i doktorski rad

[E-1] M. Sc. teza: Neki metodoloski problemi elektrodinamike tela u kretanju, 2004,

Fizicki fakultet Univerziteta u Beogradu (engleski prevod ove teze, Some method-

11

ological problem of the electrodynamics of moving bodies, bio je niz godina dostupan

na sajtu fakulteta)

[E-2] Ph. D. disertacija: Egzaktna resenja nekih problema elektrodinamike tela u kre-

tanju u okviru magneto-fluidodinamickog modela, 2009, Fizicki fakultet Univerziteta

u Beogradu

VI. CITATI

[A1] D V Redzic and S S Redzic, J. Phys. D: Appl. Phys. 38 3991-4 (2005)

1. C Xue and S Deng, Phys. Rev. E 81 016701 (2010)

2. E Bichoutskaia, A L Boatwright, A Khachatourian, A J Stace, J. Chem. Phys.

133 024105 (2010)


4. B Techaumnat and M Washizu, J. of Electrostatics 69 388-393 (2011)

5. S Deng, C Xue, A Baumketner, D Jacobs and W Cai, J. Comput. Phys. 245

84-106 (2013)

[A2] D V Redzic, J. Phys. D: Appl. Phys. 39 4136-41 (2006)

1. A Bonanno, G Bozzo, M Camarca, P Sapia, Il Nuovo Cimento C 33 131-136

(2010)

2. A Bonanno, M Camarca and P Sapia, Eur. J. Phys. 32 849-866 (2011)

3. S Wolf, Einfluss der Geometrie und Struktur von Korpermodellen auf die

lokale Energiedeposition in der Hochfeld MRT, PhD thesis, Otto-von-Guericke-

Universitat Magdeburg (2013)

[A3] D V Redzic, Prog. Electromagn. Res. 110 383-401 (2010)

1. L Zilberti, O Bottauscio and M Chiampi, IEEE Magnetics Letters 6 1500104

(2015)

12

2. M A Masterova, The dynamics of a charged particle in the field of the rotating

magnetized celestial body (in Russian), PhD thesis, Tomsk State University

(2015)

[A5] D V Redzic, Serb. Astron. J. 188 55-65 (2014)

1. https://en.wikibooks.org/wiki/Special Relativity

2. B Coleman, Results in Physics 6 31-38 (2016)

[A7] D V Redzic, Am. J. Phys. 58 1205-8 (1990)

1. D C Lemons, Am. J. Phys. 59 391 (1991)

2. D C Lemons, Am. J. Phys. 59 1046-7 (1991)

3. Y S Huang and K H Lu, Can. J. Phys. 82 957-64 (2004)

4. G Giuliani, Eur. J. Phys. 35 025015 (2014)

5. G Giuliani, Eur. J. Phys. 36 065008 (2015)


1. V Poulbot, Contribution a l’etude des champs electriques tres basses frequences

en milieu oceanique, PhD thesis, l’Ecole Central de Lyon, 1993

online at http://tel.archives-ouvertes.fr/docs/00/13/95/37/PDF/These ECL1993-

36 Poulbot.pdf

2. J I Gersten, Am. J. Phys. 78 258-263 (2010)

3. P Moylan, Moving charge distributions in classical electromagnetism and the

FitzGerald-Lorentz contraction (2010)

online at http://arxiv.org/pdf/1006.2029v1


1. C Yao, Am. J. Phys. 63 520-3 (1995)

2. A Cvitkovic, N Ocelic and R Hillenbrand, Optics Express 15 8550-65 (2007)

13

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spective (Oxford, Clarendon, 2005)





1. I V Lindell and K I Nikoskinen, J. of Electromagn. Waves and Appl. 17

1629-30 (2003)

2. A Cvitkovic, N Ocelic and R Hillenbrand, Optics Express 15 8550-65 (2007)

3. S Deng, J. of Electrostatics 66 549-60 (2008)

4. G Zhen-duo, D Yuan-gang, Z Xian-zhou, J Hui, Journal of Henan Normal

University (Natural Science) 37 56-58 (2009)

5. C Xue and S Deng, Commun. Comput. Phys. 8 374-402 (2010)


7. Z Xu and W Cai, SIAM Review 53 683-720 (2011)

8. C Xue and S Deng, Physica E 43 1118-1126 (2011)

9. L Duggen et al, Eur. J. Phys. 33 689-696 (2012)

10. B K Jawad, Modelisation de l’electrolocation pour la bio-robotique, PhD thesis,

l’Universite Nantes, 2012


84-106 (2013)

12. G Nemeth, Nanostrukturak vizsgalata kozeli teru infravoros spektroszkopiaval,

M. Sc. thesis, BME Faculty of natural Sciences, Budapest University of Tech-

nology and Economics (2015)

[A11] D V Redzic, Eur. J. Phys. 22 595-9 (2001)

14

1. S Visnovsky, Czech. J. Phys. 55 217-219 (2005)

2. D M Shyroki, IEEE Trans. on Microwave Theory and Techniques 55 1132-8

(2007)

3. E Stalberg, A high order method for simulation of fluid flow in complex geome-

tries, Licentiate thesis, Department of Mechanics, KTH, 2005

online at www.mech.kth.se/thesis/2005/lic/lic 2005 erik stalberg.pdf

4. S Guarino, A stress-based approach to the solution of Saint Venant problem,

PhD thesis, University of Naples, 2011

5. C Jung, E Park and R Temam, Boundary layer analysis of nonlinear reaction-

diffusion equations in a smooth domain, Adv. Nonlinear Anal. (2016) ahead of

print


1. E Bringuier, Eur. J. Phys. 24 21-9 (2003)

2. J C Phillips, Phil. Mag. 83 1949-62 (2003)

3. E Bringuier, Eur. J. Phys. 25 L13-L15 (2004)

4. M de Montigny and G Rousseaux, Eur. J. Phys. 27 755-68 (2006)

5. B A Knyazev, I A Kotel’nikov, A A Tyutin et al, Physics-Uspekhi 49 937-46

(2006)


1. H R Brown, Physical relativity: space-time structure from a dynamical per-

spective (Oxford, Clarendon, 2005)

2. V M Red’kov, B Rothenstein and G J Spix, Proceedings of 5th International

Conference Bolyai-Gauss-Lobachevsky: Non-Euclidean Geometry in Modern

Physics (BGL-5) (Minsk, Belarus, 2006), pp 328-339

online at ifanbel.bas-net.by/bgl5/red-bern-spix.pdf

15

3. V Hnizdo, Regularization of the second-order partial derivatives of the Coulomb

potential of a point charge (2006)

online at http://arxiv.org/abs/physics/0409072v4






2. C C Sanchez, Forward and inverse analysis of electromagnetic fields for MRI

using computational techniques, PhD thesis, University of Nottingham, 2008

online at etheses.nottingham.ac.uk/629/1/thesis.pdf

3. C C Sanchez, R W Bowtell, H Power et al, Eng. Anal. Bound. Elem. 33

1074-88 (2009)

4. K Jokela and R D Saunders, Health Phys. 100 641-653 (2011)

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22

Z A K LJ U C A K

Na osnovu prethodno izlozenih podataka o nastavnom i naucnom radu kandidata,

Komisija smatra da dr Dragan Redzic zadovoljava sve propisane kriterijume za izbor u

zvanje docenta. Njegov dosadasnji rad pokazuje visoku sposobnost, zainteresovanost i

strucnost za oblast Nastava fizike, te je Komisija uverena u sposobnost kandidata da

pruzi visok kvalitet nastave iz navedene oblasti. Stoga sa zadovoljstvom preporucujemo

Nastavno-naucnom vecu Fizickog fakulteta da izabere dr Dragana Redzica za docenta za

naucnu oblast Nastava fizike.

Beograd, 6. maj 2016. godine.

Komisija,

dr Mico Mitrovic, redovni profesor

Fizickog fakulteta, Beograd

dr Bratislav Obradovic, vanredni profesor

Fizickog fakulteta, Beograd

dr Maja Stojanovic, vanredni profesor PMF,

Novi Sad

23

nastavno-naucnom ve• cu fizi¶ ckog fakulteta• … · nastavno-naucnom ve• cu fizi¶ ckog...

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