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Observational Astrophysics 2 Introduction to the Course Christoph U. Keller Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 1

Outline 1 Course Content 2 Web Page 3 Lecture Notes and Books 4 Schedule and Requirements 5 Lectures 6 Exams and Grades 7 Paper Selection Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 2

Observational Astrophysics 2: NS-AP433M Goal (7.5 ECTS) People Understand how to use astronomical telescopes and instruments to learn more about the universe Christoph Keller (UU, Chair of Experimental Astrophysics) Peter Jonker (SRON Staff Member) Tim van Werkhoven (UU, PhD student in Experimental Astrophysics) Communication everybody: through Blackboard C.U.Keller@uu.nl, P.Jonker@sron.nl, T.I.M.vanWerkhoven@uu.nl Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 3

Course Web Page Course URL www.astro.uu.nl/ keller/teaching/obsastro2_2010 Contents contact information course schedule, subscribe to ical link lecture presentations, exercises, exercise materials presentation topics and assignments including links to papers (only from UU computers) OSIRIS The course web page takes precedence over OSIRIS. Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 4

Lecture Notes and Books Lecture Notes written by Johan Bleeker and Frank Verbunt for previous years updates as needed Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 5

Course Schedule and Requirements Weekly Schedule Day Time Location Topic Monday 13:15 15:00 BBL 412 Lectures Tuesday 13:15 17:00 BBL 112 Computer Exercises Thursday 9:00 10:45 BBL 412 Lectures Thursday 11:00 12:45 BBL 412 Exercises/Presentations Exercises exercises are integral part of course computer exercises and paper exercises (at home) home work has to be submitted by deadline will be checked, returned, and discussed solutions will not be made available in writing Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 6

Presentations select one original paper and present it to peers 20-minute presentation in English public and private discussion of presentation grade is for level of understanding of paper Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 7

Lectures Title Chapter Instructor Introduction to the Course Keller Radiation Fields 1 1 Jonker Radiation Fields 2 1 Jonker Optical Spectroscopy Keller Astronomical Measuring Process 1 2 Jonker Astronomical Measuring Process 2 2 Jonker Polarimetry 1 Keller Polarimetry 2 Keller Fitting Observed Data 1 5 Jonker Fitting Observed Data 2 5 Jonker Indirect Imaging 3 Keller X-Ray Spectroscopy 5 Jonker Imaging 1 4 Keller Imaging 2 4 Keller Observational Astrophysics at SRON Jonker Variability and Periodicity 6 Keller Observational Astrophysics at SIU Keller Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 8

Radiation Fields Astronomical measurements Stochastic processes Distribution functions Correlations and auto-correlations Convolution Fourier transforms Sampling and Nyquist theorem Filtering Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 9

Optical Spectroscopy Astrophysical Spectroscopy Broadband Filters Fabry-Perot Filters Interference Filters Prism Spectrograph Grating Spectrograph Fourier Transform Spectrometer Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 10

Astronomical Measuring Process Power spectra Optimal filtering Discrete Convolution Noise removal Applications of filtering Moments of a stochastic process Stochastic description of radiation fields Fluctuations of radiation fields Thermal and quantum noise Poisson distribution Error propagation Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 11

Polarimetry Polarized Light in the Universe Fundamentals of Polarized Light Descriptions of Polarized Light Polarizers and Retarders Polarimeters Scattering Polarization Zeeman Effect Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 12

Fitting Observed Data Comparing data with a model Least squares fitting Maximum likelihood method Gaussian data Poissonian data Monte Carlo simulations Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 13

Indirect Imaging Interference Coherence Two-Element Interferometer Van Cittert-Zernike Theorem Aperture Synthesis Imaging Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 14

Imaging Overview Photoconductive Detection Charge Coupled Devices CMOS and CMOS Hybrid Devices Array Detector Properties Array Detector Data Reduction Array Detector Problems Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 15

Variability and Periodicity Finding periodicities in data Comparing two distributions Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 16

Exams and Grades Exams content lectures corresponding sections of lecture notes exercises (computer and home work) paper presentations and questions written exam after course ends oral exams after that mock exam before end of lectures Grades 20% presentation 20% exerciseses 60% exam Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 17

Papers for Presentations Topic Paper with Link to ADS Student Name Date Nod and Shuffle Spectroscopy Glazebrook & Bland-Hawthorn 2001 11.3.2010 CCD Spectroscopy Horne 1986 11.3.2010 Sensitive Polarimetry Semel et al. 1993 11.3.2010 Fringe Removal Malumuth et al. 2003 25.3.2010 Doppler Imaging Vogt et al. 1987 25.3.2010 Rotating Modulation Imaging Hurford et al. 2002 25.3.2010 Lucky Imaging Law et al. 2006 1.4.2010 Fourier Filtering Brault and White 1971 1.4.2010 Crowded-field Photometry Stetson 1987 1.4.2010 Radio Image CLEANing Hogbom 1974 8.4.2010 Asteroseismology Bruntt et al. 2007 8.4.2010 Image Deconvolution Lucy 1974 8.4.2010 Christoph U. Keller, Utrecht University, C.U.Keller@uu.nl Observational Astrophysics 2: Introduction to the Course 18

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