DOCSLIB.ORG

Physics Undergraduate Course Handbook

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Physics Undergraduate Course Handbook Physics Undergraduate Course Handbook 2017-2018 2017-2018 Physics 1 B A N B U R Clarendon Laboratory Y N Beecroft Building Denys Wilkinson Building R O Lindemann and Martin A Wood Lecture Theatres Dennis Sciama Lecture Theatre D Teaching Faculty Office (MT2017) Teaching Faculty Office (2018) (both via the Level 4 entrance) D O A E R B L K E B L P A A C R Physics Teaching Laboratories K K H S (entrance down the steps) S A T L L R O GIL R D D A R D E U M S S E ’ U M gt Students in wheelchairs or with mobility needs can access the Lindemann and the Dennis Sciama Lecture Theatres by lifts from the ground floors. The Denys Wilkinson Building and the Clarendon Laboratory have toilet facilities for wheelchair users. The Martin Wood Lecture Theatre has access for wheelchairs and a reserved area within the theatre. There are induction loop systems for students with hearing difficulties in the Lindemann, Dennis Sciama and Martin Wood Lecture Theatres. The Department is able to make provision for disabled students. If you think you may need any special re- quirements, contact the Assistant Head of Teaching (Academic) by e-mail, carrie.leonard-mcintyre@physics. ox.ac.uk for further information. These notes have been produced by the Department of Physics. The information in this handbook is for the academic year Michaelmas Term 2017, Hilary Term 2018 and Trinity Term 2018. 2 Contents How to use this handbook 5 Examinations 13 Assessment of Class 13 Important dates and deadlines 6 Assessment of Practical Work 14 First Year 6 First Year (Prelims) 14 Second Year 6 Second and Third Year 14 Third Year 7 Marking of the Assessed Practical 14 Fourth Year 7 Eligibility for MPhys Course 14 Three or Four year course 14 Introduction 8 Examination Preparation 15 The Department of Physics 8 Examination Entry 15 The Physics Teaching Faculty 8 Examination Conventions 15 Teaching Laboratories 8 Examination Dates 15 Lecture Theatres 8 Sitting your examination 15 Libraries 8 Examination Regulations 15 Computers 8 Examination Results 15 Policies and Regulations 8 Prizes 16 Data Protection 9 External Examiner and Examiners’ Reports 16 University Policy on Intellectual Mathematical, Physical and Life Sciences Property Rights 9 (MPLS) Division 16 Copyright 9 Physics and Philosophy 16 Good academic practice and avoiding Summary of Examination Requirements 17 plagiarism 9 Support for disabled students 9 First Year 2017-2018 18 Student Life, Support and Guidance 9 Induction 18 Complaints and appeals 10 Practical Work 18 Opportunities for skills training and Self-study modules in basic mathematics development 10 and mechanics 18 Employability and careers information and The Preliminary Examination 18 advice 10 Introduction to Computer Programming 19 Departmental representation - The Physics Data Analysis and Statistics 19 Joint Consultative Committee (PJCC) 10 Textbooks 19 Opportunities to provide evaluation and First Year Physics and Maths Lectures 19 feedback 10 Examination Entry 19 Mathematical, Physical and Life Physics and Philosophy 19 Sciences (MPLS) Division and University First Year Patterns of Teaching 20 Representation 10 Enterprising Oxford 10 Second Year 2017-2018 21 The Institute of Physics 10 The BA and MPhys courses 21 Practical Work 21 Aims and objectives, teaching and Individual Presentations examinations 11 (formerly Oral Skills) 21 The Physics Courses – Aims and Objectives 11 Marking of Individual Presentations 21 The Physics Undergraduate Courses 11 Physics Department Speaking Competition 21 Subject Benchmark Statements 12 Alternative subjects, extra practicals and extended Department and College Teaching 12 practicals 22 Expectations of study and student workload Teaching and Learning Physics in Schools 22 (Term time and Vacations) 12 Undergraduate Physics Conference 22 Programme Specifications 12 Examination Entry 22 Accreditation 13 Eligibility for MPhys Course 22 Accessing the Physics Teaching web pages 13 Physics and Philosophy 22 Virtual Private Network (VPN) Service 13 Second Year Patterns of Teaching 24 3 Contents Continued Third Year 2017-2018 [BA Course] 25 Short Options 2017-2018, Language Options & BA Course 25 Alternatives 34 Part B Examination 25 Short Options 35 Practical Work 25 Prelims 35 Mini-project 25 Parts A & B 35 Project Safety 26 Language Option 35 Submitting the report at Examination Alternative subjects 35 Schools 26 Pre-approved subjects 36 Short Options & Language Option 26 Extra practical work 36 Alternative subjects, extra practicals and Assessment of extra practical work 37 extended practicals 26 Alternatives to practical work 37 Changing from the BA to the MPhys 26 Teaching and Learning Physics in Schools 37 Examination Entry 26 Examination Entry 38 Third Year 2017-2018 [MPhys Course] 27 Appendix A: Recommended Textbooks 39 Choice of Course 27 Appendix B: Calculators 47 Part B Examination 27 Appendix C: Syllabuses for Prelims 48 Practical Work 27 Appendix D: Syllabuses for Part A 51 Mini-project 27 Appendix E: Syllabuses for Part B 54 Short Options & Language Option 28 Appendix F: Syllabuses for Short Options 56 Alternative subjects, extra practicals and Appendix G: Syllabuses for Part C 59 extended practicals 28 Appendix H: Special Regulations for the Changing from the MPhys to the BA Preliminary Examination in Physics 62 (MPhys Exit) 28 Appendix I: Regulations for the Honour Undergraduate Physics Conference 28 School of Physics 63 Major Options 28 Appendix J: University Policy on Intellectual Alternative Major Options 28 Property Rights 67 Examination Entry 28 Appendix K: Lecture Feedback 68 Physics and Philosophy 29 Appendix L: Complaints and Appeals 69 MMathPhys 29 Appendix M: Useful Department Contacts 70 Third Year Patterns of Teaching 30 Fourth Year 2017-2018 [MPhys Course] 31 Part C Finals for the 4-year MPhys 31 Lectures and Classes for the Major Options 31 Alternative Major Options 31 Projects 31 Exam Entry 31 Physics and Philosophy 32 Fourth Year Patterns of Teaching 33 4 How to use this handbook Students in their first year should read the two sections ‘Introduction’ (see page 8) and ‘First Year’ (see page 18) in detail and skim the remainder for an overview of the courses. Students in later years should read the sections on the FHS (Final Honours School) examination structure, the details for the relevant year and be aware of the overall requirements and content of their chosen course. At the end of this handbook are appendices giving the syllabuses for the examination papers to be taken in Trinity Term 2018 for Physics Prelims, FHS Parts A and B for the three year BA and four year MPhys courses, and for the Physics papers for the Physics and Philosophy course. Syllabuses are also given for the Part C 4th year Major Option papers. The handbook gives a comprehensive book list for the whole course, important dates for the academic year, informa- tion about the undergraduate consultative committee (PJCC) and a list of people involved in organising the course. Full details about the Practical Course are given in the Practical Course Handbook at http://www2.physics.ox.ac.uk/students/undergraduates Please refer to the Physics and Philosophy Course Handbook at http://www2.physics.ox.ac.uk/students/undergradu- ates for all details of the Physics and Philosophy course that are not covered in the Physics Undergraduate Course Handbook. Everything regarding the course is written down in this handbook, however members of staff will be happy to an- swer what is not documented. For particular information about College teaching, students should contact their tutors. Further information about the courses can be obtained from the Department of Physics website http://www2.physics. ox.ac.uk/students/undergraduates and from the Physics Teaching Faculty. In this document, Michaelmas Term (MT), Hilary Term (HT), Trinity Term (TT), refer to Michaelmas (Winter), Hilary (Spring) and Trinity (Summer) Terms of the academic year, respectively. The weeks in each term are numbered as 1st week, 2nd week and so on, with 0th week being the week immediately before start of full term. Prof Hans Kraus, Head of Teaching For full and up-to date information on lecture timetables, see www.physics.ox.ac.uk/lectures. The examination times given in this handbook are based on information available in September 2017. These may be altered and the definitive times are those published by the examiners; these will be posted on the official examiners’ web page. The Examination Regulations relating to this course are available at https://weblearn.ox.ac.uk/portal/hierarchy/mpls/ physics/teaching/undergrads/exammatters. If there is a conflict between information in this handbook and the Exami- nation Regulations then you should follow the Examination Regulations. If you have any concerns please contact the Assistant Head of Teaching (Academic) by e-mail at [email protected]. The information in this handbook is accurate as at 3 October 2017, however it may be necessary for changes to be made in certain circumstances, as explained at http://www2.physics.ox.ac.uk/students/undergraduates. If such changes are made the department will publish a new version of this handbook together with a list of the changes and students will be informed. 5 Important dates and deadlines First Year Michaelmas Term Event Time Location Week 0 Introduction to the Fri Martin Wood Lecture Theatre & Department (Induction) 14:15 Dennis Sciama Lecture Theatre Week 1 Laboratory Introduction Mon Martin Wood Lecture Theatre 12:00 Week 1 Safety lecture Mon Martin
Load more

Recommended publications
  • Pandit Deendayal Petroleum University School of Liberal Studies
    Pandit Deendayal Petroleum University School of Liberal Studies BSP302T Electricity and magnetism Teaching Scheme Examination Scheme Theory Practical Total L T P C Hrs/Week MS ES IA LW LE/Viva Marks 4 0 0 4 4 25 50 25 -- -- 100 COURSE OBJECTIVES To provide the basic understanding of vector calculus and its application in electricity and magnetism To develop understanding and to provide comprehensive knowledge in the field of electricity and magnetism. To develop the concepts of electromagnetic induction and related phenomena To introduce the Maxwell’s equations and understand its significance UNIT 1 REVIEW OF VECTOR CALCULUS 8 Hrs. Properties of vectors, Introduction to gradient, divergence, curl, Laplacian, Introduction to spherical polar and cylindrical coordinates, Stokes’ theorem and Gauss divergence theorem, Problem solving. UNIT 2 ELECTRICITY 14 Hrs. Coulomb’s law and principle of superposition. Gauss’s law and its applications. Electric potential and electrostatic energy Poisson’s and Laplace’s equations with simple examples, uniqueness theorem, boundary value problems, Properties of conductors, method of images Dielectrics- Polarization and bound charges, Displacement vector Lorentz force law (cycloidal motion in an electric and magnetic field). UNIT 3 MAGNETISM 16 Hrs. Magnetostatics- Biot & Savart’s law, Amperes law. Divergence and curl of magnetic field, Vector potential and concept of gauge, Calculation of vector potential for a finite straight conductor, infinite wire and for a uniform magnetic field, Magnetism in matter,
    [Show full text]
  • Aspin Bubbles Mechanical Project for the Unification of the Forces of Nature
    Aspin Bubbles mechanical project for the unification of the forces of Nature Yoël Lana-Renault Departamento de Física Teórica. Facultad de Ciencias. Universidad de Zaragoza. 50009 - Zaragoza, Spain e-mail: [email protected] web: www.yoel-lana-renault.es This paper describes a mechanical theory for the unification of the basic forces of Nature with a single wave-particle interaction. The theory is based on the hypothesis that the ultimate components of matter are just two kind of pulsating particles. The interaction between these particles immersed in a fluid-like medium (ether) reproduces all the forces in Nature: electric, nuclear, gravitational, magnetic, atomic, van der Waals, Casimir, etc. The theory also designes the internal structure of the atom and of the fundamental particles that are currently known. Thus, a new concept of physics, capable of tackling entirely new problems, is introduced. Keywords: Unification of Forces, Non-linear Interactions. 1. Introduction Our theory presented here is compatible with existing views about the nature of matter, and demonstrates that the essential properties of particles can be described in the mechanical framework of classical physics with certain assumptions about the nature of physical space, which is traditionally called the ether. The theory is a synthesis of ideas used by Newton, Faraday, Maxwell and Einstein. In the past, the hypothesis of the ether as a fluid was decisive in the creation of the theory of the electromagnetic field. Vortex rings were used to construct a model of the atom at a time when the existence of elementary particles was not known. These days, applying vortex models to elementary particles looked reasonable.
    [Show full text]
  • THE FEYNMAN LECTU ES on PHYSICS by Richard P. Feynman
    pursued. Prof. Feynman finds this discouraging, and around Caltech various ways of remedying and understanding the problem are being dis- cussed. But I prefer to discuss the lectures from the point of view of a man who has had at least THE FEYNMAN LECTU ES ON PHYSICS a liberal education in physics - mathematics through calculus, and an introductory physics by Richard P. Feynman, obert B. Leigfzton course - who wants to understand the natural and Matthew Sands world about him, and who is prepared to give as much effort to Feyiiman's lectures as he gives to Joyce's Ulysses. The parallel between the two works is suggestive because both may be read for Reviewed Robert R. Rianflford '59, a greater understanding of the world, yet both graduate ,stz~dentin geophysics abound in wit and humor and demand consider- able concentration. Prof. Feynman was evidently aware that some There is little doubt in my mind that this col- readers might take the wide range of topics and lection of lectures given to Caltech freshmen by the casual tone to imply a shallow treatment char- Prof. Feynman in 1961-1962 fully deserves to be acteristic of a survey course, because in the intro- reviewed in the standard book review journals, duction he feels constrained to say that the lec- such as The New 'York Times Book tures are meant to provide a thorough grounding cause it has great artistic and philos in physics - which they do. esides being a textbook which probably should The philosophy contained in the book is mostly e owned by every scientist and engineer.
    [Show full text]
  • Implementation Guide
    GREAT MINDS® SCIENCE Implementation Guide A Guide for Teachers Great Minds® Science Implementation Guide Contents Contents ........................................................................................................................................................................................... 1 Introduction ...................................................................................................................................................................................... 2 Foundations .................................................................................................................................................................................. 2 Product Components .................................................................................................................................................................... 2 Learning Design............................................................................................................................................................................. 5 Scope and Sequence ..................................................................................................................................................................... 6 Research in Action ........................................................................................................................................................................ 7 Getting Started ..............................................................................................................................................................................
    [Show full text]
  • When Physics Meets Biology: a Less Known Feynman
    When physics meets biology: a less known Feynman Marco Di Mauro, Salvatore Esposito, and Adele Naddeo INFN Sezione di Napoli, Naples - 80126, Italy We discuss a less known aspect of Feynman’s multifaceted scientific work, centered about his interest in molecular biology, which came out around 1959 and lasted for several years. After a quick historical reconstruction about the birth of molecular biology, we focus on Feynman’s work on genetics with Robert S. Edgar in the laboratory of Max Delbruck, which was later quoted by Francis Crick and others in relevant papers, as well as in Feynman’s lectures given at the Hughes Aircraft Company on biology, organic chemistry and microbiology, whose notes taken by the attendee John Neer are available. An intriguing perspective comes out about one of the most interesting scientists of the XX century. 1. INTRODUCTION Richard P. Feynman has been – no doubt – one of the most intriguing characters of XX century physics (Mehra 1994). As well known to any interested people, this applies not only to his work as a theoretical physicist – ranging from the path integral formulation of quantum mechanics to quantum electrodynamics (granting him the Nobel prize in Physics in 1965), and from helium superfluidity to the parton model in particle physics –, but also to his own life, a number of anecdotes being present in the literature (Mehra 1994; Gleick 1992; Brown and Rigden 1993; Sykes 1994; Gribbin and Gribbin 1997; Leighton 2000; Mlodinov 2003; Feynman 2005; Henderson 2011; Krauss 2001), including his own popular
    [Show full text]
  • Edward Lewis and Radioactive Fallout the Impact Of
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Caltech Theses and Dissertations EDWARD LEWIS AND RADIOACTIVE FALLOUT THE IMPACT OF CALTECH BIOLOGISTS ON THE DEBATE OVER NUCLEAR WEAPONS TESTING IN THE 1950s AND 60s Thesis by Jennifer Caron In Partial Fulfillment of the Requirements for the degree of Bachelor of Science Science, Ethics, and Society Option CALIFORNIA INSTITUTE OF TECHNOLOGY Pasadena, California 2003 (Presented January 8, 2003) ii © 2003 Jennifer Caron All Rights Reserved iii ACKNOWLEDGEMENTS Professor Ed Lewis, I am deeply grateful to you for sharing your story and spending hours talking to me. Professor Ray Owen, thank you for your support and historical documents I would not have found on my own. Professor Morgan Kousser, I am grateful for your advice and criticism, especially when this project was most overwhelming. Chris Waters, Steve Youra and Nathan Wozny, thank you for helping me get the writing going. Jim Summers and Winnee Sunshine, thank you for providing me with a quiet place to write. Professors Charles Barnes, Robert Christy, and John D. Roberts, thank you for sharing your memories and understandings of these events. Peter Westwick, thank you for the reading suggestions that proved crucial to my historical understanding. Kaisa Taipale, thank you for your help editing. Professor John Woodard, thank you for helping me to better understand the roots of ethics. Professor Diana Kormos-Buchwald, thank you for being my advisor and for your patience. And Scott Fraser, thank you for telling me about Lewis’s contribution to the fallout debate and encouraging me to talk to him.
    [Show full text]
  • Matthew Sands, Founding Deputy Director of SLAC, Dies | SLAC Today
    Matthew Sands, Founding Deputy Director of SLAC, Dies | SLAC Today Matthew Sands, Founding Deputy Director of SLAC, Dies By Burton Richter, SLAC director emeritus September 18, 2014 Matthew (Matt) Sands, the founding deputy director of SLAC, died peacefully at his home in Santa Cruz, California, on Sept. 13. He was 94 years old. Matt received his master’s degree in physics from Rice University in 1941 and was immediately swept into World War II technical work, first at the Naval Research Laboratory in Washington, D.C., and, from 1943 to 1945, at Los Alamos, where the atomic bomb was being developed. Matt’s work focused on electronics, and his group built the circuits needed for the work of all the other groups at Los Alamos. After the war, the book on electronics he wrote with his colleague William Elmore, Electronics: Experimental Techniques, became a kind of bible of recipes for advanced circuits. He was also one of the founders of what became the Federation of Atomic Scientists, which lobbied hard for control of nuclear weapons. 1 of 3 retrieved 1/10/2020, 2:22 PM Matthew Sands, Founding Deputy Director of SLAC, Dies | SLAC Today After the war ended, Matt went to the Massachusetts Institute of Technology (MIT) for his PhD, working with professor Bruno Rossi on cosmic rays. After his PhD was completed, he was asked to help commission a 300-million-electronvolt synchrotron, which had been completed but did not work. In about one year he had it going. In 1950, Matt moved to the California Institute of Technology (Caltech) in Pasadena, where they were about to start on a 1.5-billion-electronvolt synchrotron.
    [Show full text]
  • Persistent Space Situation Awareness for the Guardians of the High Frontier
    Persistent Space Situation Awareness for the Guardians of the High Frontier Roberta Ewart Disclaimer: The views and opinions expressed or implied in the Journal are those of the authors and should not be con- strued as carrying the official sanction of the Department of Defense, Air Force, Air Education and Training Command, Air University, or other agencies or departments of the US government. This article may be reproduced in whole or in part without permission. If it is reproduced, the Air and Space Power Journal requests a courtesy line. Every moment of every day, year in and year out a watch is being kept. Because of the satellites, the world is a safer place. Through their constant watch, both sides know the number, location, and status of the other’s weapons. And both sides know both sides know. New threats can be identified and countered. A nation can act from knowledge rather than from fear and ignorance. Surprise and bluff are no longer useful tactics. In this way, military satellites represent a stabilizing influence—acting as guardians of whatever peace exists in the world. —Curtis Peebles Guardians: Strategic Reconnaissance Satellites s a nation, the US will have been discussing space power, space warfare, space war fighting, or some combination of those concepts for almost 60 years, since approximately 1958. None of the recent material (2015 to the Apresent) regarding the Space Enterprise Vision (SEV) promulgated by Air Force Space Command (AFSPC) or the at-large space control community is new. In 1994, a report was delivered
    [Show full text]
  • The Trinity Experiments ~
    g . The Trinity Experiments ~ I ~ I' I Thomas Merlan Prepared by Human Systems Research, Inc. Prepared for White Sands Missile Range, New Mexico 1997 THE TRINITY EXPERIMENTS by Thomas Merlan Prepared for White Sands Missile Range, New Mexico Submitted by Human Systems Research, Inc. Tularosa, New Mexico HSR Report 9 701 WSMR Archaeological Report No. 97-15 1997 PREFACE On july 16, 1945, at 5:29:45 a.m. Mountain War Time, the world entered the Nuclear Age with the successful detonation of the first atomic bomb. Over the years, numerous books and articles have been written about the Manhattan Project and the Trinity site. Many of these discuss the national and international social and political conditions and issues relating to the development of the atomic bomb. Other publications take the historical approach, providing a chronology of events that led to the detonation of the bomb and its aftermath. The Trinity Experiments is the first study of the actual experiments associated with evaluating the effects of the explosion. The study is very timely because, during the last year of this study, several scientists associated with the Manhattan Project and nuclear physics have passed away. They include K.T. Bainbridge, Director of the Trinity Project; Alexander Langsdorf, Jr., a pioneer in plutonium physics; C. E. Wiegand, a physicist; and]. Carson Mark, a physicist with the hydrogen bomb. Henry Barshall was interviewed about his participation with the excess velocity gauges; he passed away a couple of months after being interviewed. Using oral interviews of scientists and their post-blast technical reports, plus historic photographs, Mr.
    [Show full text]
  • Feynman's Tips on Physics F E Y N M A
    Feynman Science Feynman’S Tips on Physics is A dElIghtful collection • Gottlieb of Richard P. Feynman’S insightS and an essential companion to hiS lEgendarY Feynman LectureS on Physics. • l ei G ht ith characteristic flair, insight, and humor, Feynman discusses topics physics students on often struggle with and offers valuable tips on addressing them. included here are three f e Y n MA n ’s W lectures on problem-solving and a lecture on inertial guidance omitted from The Feynman Lectures on Physics. an enlightening memoir by matthew Sands and oral history interviews with Feynman and his Caltech colleagues provide firsthand accounts of the origins of Feynman’s FEYNMAN’S TIPS landmark lecture series. also included are incisive and illuminating exercises originally developed to supplement The Feynman Lectures on Physics, by Robert b. leighton and Rochus e. Vogt. Feynman’s Tips on Physics was co-authored by michael a. Gottlieb and Ralph leighton to TIPS ON PHYSICS provide students, teachers, and enthusiasts alike an opportunity to learn physics from some of its A PRobleReflectionsM-solving supp le• MAdviceent to The • Feynmaninsights Lec T•ur Pesra onct Physicsice greatest teachers, the creators of The Feynman Lectures on Physics. Reflections • Advice • insights • Practice ON Richard P. feYnman was a Professor of Physics at the California institute of technology from 5.5 X 8.25 PHYSICS S: 9/16 E 1951 to 1988. he shared the 1965 nobel Prize in Physics for his work on quantum electrodynamics. MichAel A. gottlieb is a Visitor in Physics at the California institute of technology who, BASIC PB with Rudolf Pfeiffer, created and maintains the lateX manuscript used to produce the present RICHARd P.
    [Show full text]
  • A Sonnet from Science
    A Sonnet from Science my little eye can catch one-million-year­ a decision taken in the early 1960s that old light. A vast pattern - of which I Caltech's required introductory course in am a part - perhaps my stuff was physics needed revision. It would include belched from some forgotten star, as a new course outline, a new textbook, and one is belching there. Or see them with the greater eye of Palomar, rushing all some new laboratory experiments. The apart from some common starting point text was produced by taping a set of lec­ when they were perhaps all together. tures given in 1961-62 by Richard Feyn­ What is the pattern, or the meaning, or man, then the Richard Chace Tolman Pro­ the why? It does not do harm to the fessor of Theoretical Physics and soon to mystery to know a little about it. For far be awarded the Nobel Prize. The tapes more marvelous is the truth than any were transcribed, edited by Robert Leigh­ artists of the past imagined! Why do the ton and Matthew Sands, professors of poets of the present not speak of it? physics at Caltech, and published in 1963 What men are poets who can speak of by Addison-Wesley. Jupiter if he were like a man, but if he is an immense spinning sphere of methane Whether the book then really became and ammonia must be silent? the "world's most popular physics book" we don't know, but the publishers have The Feynman Lectures on Physics given us some impressive numbers about Addison Wesley Publishing Co .• Inc., Vol.
    [Show full text]
  • Fişa Disciplinei
    SYLLABUS1 1. Information about the Program 1.1 Higher education institution Politehnica University of Timişoara 1.2 Faculty2 / Department3 Automation and Computers/ Fundamentals of Physics for Engineers 1.3 Chair - 1.4 Domain of study Computers and Information Technology 1.5 Study level Bachelor 1.6 Study programme / Qualification Computers / engineer 2. Information about the Course 2.1 Course Physics 2.2 Lecturer PRETORIAN SIMONA 2.3 Academic staff for seminars/labs PRETORIAN SIMONA, CALINOIU DELIA 2.4 Study year 1 2.5 Semester 1 2.6 Assessment type D 2.7 Course type Mandatory 3. Total time estimated (hours/ semester of didactical activities) 3.1 Hours / week 5 of which: 3.2 lecture hours 3 3.3 seminar/lab hours 1/1 3.4 Total curriculum hours 70 of which: 3.5 lecture hours 42 3.6 seminar/lab hours 14/14 Time distribution hours Study using manuals, support materials, bibliography and notes 24 Supplementary documentation in library, speciality electronic platforms and on site 12 Supplementary preparation for seminars/labs, homeworks, reviews, portofolios and essays 14 Tutoring activities 7 Exams 3 Other 3.7 Total - hours of individual study 50 3.8 Total - hours per semester 130 a. Credits 5 4. Prerequisites (if appropriate) 4.1 curriculum • Mathematical analysis, Algebra and geometry (may be taken concurrently) 4.2 competencies • Algebraic, vectorial, integral and differential calculation, basic high school physics 5. Conditions (if appropriate) 5.1 for lectures • large classroom, laptop, projector, internet access, blackboard/whiteboard 5.2 for seminars/labs • Seminar room, blackboard/whiteboard / lab with specific experimetal stands and devices, computers with specific softwares, blackboard/whiteboard 6.
    [Show full text]