[et_pb_section fb_built=”1″ disabled_on=”on|off|off” admin_label=”Bandeau Titre Page” _builder_version=”4.6.6″ _module_preset=”f72d8d51-b4b2-4591-b8ad-bec6e6410659″ background_color=”#c4c4c4″ height=”133px” global_module=”274″ saved_tabs=”all”][et_pb_row admin_label=”Bandeau Titre” _builder_version=”4.6.6″ _module_preset=”default” custom_margin=”-50px|auto||auto||”][et_pb_column type=”4_4″ _builder_version=”4.6.6″ _module_preset=”default”][et_pb_text _builder_version=”4.9.4″ _module_preset=”9f82c9dc-48b4-4484-b775-9e8a3cc8ddaa” text_font=”Trebuchet||||||||” text_text_color=”#ffffff” text_font_size=”60px” text_orientation=”center”]<\/p>\n
Solar Astronomy<\/p>\n
[\/et_pb_text][et_pb_text _builder_version=”4.9.4″ _module_preset=”9f82c9dc-48b4-4484-b775-9e8a3cc8ddaa” text_font=”Trebuchet||||||||” text_text_color=”#ffffff” text_font_size=”28px” text_orientation=”center”]<\/p>\n
Observing, imaging and studying the Sun<\/p>\n
[\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ admin_label=”Section Contents” _builder_version=”4.6.6″ _module_preset=”a03dd6b3-905d-4d9b-9fcb-2eb96694acf7″ background_color=”#f7f7f7″ custom_padding=”15px||27px|||” collapsed=”off”][et_pb_row _builder_version=”4.6.6″ _module_preset=”default”][et_pb_column type=”4_4″ _builder_version=”4.6.6″ _module_preset=”default”][et_pb_text admin_label=”Titre Contents” _builder_version=”4.9.4″ _module_preset=”c6d8d8ee-7ceb-4272-942a-c1a39e3e21f5″]<\/p>\n
Contents<\/strong> [\/et_pb_text][et_pb_text _builder_version=”4.9.4″ _module_preset=”55ea697a-4a74-41dd-8f98-93065051adbf”]<\/p>\n Observing the Sun: there are many ways to enjoy solar observation, from visual observation to high resolution imaging, using commercial telescopes or home-made dedicated solar telescopes, from observation of the photosphere in “white light” to observation of the chromosphere with specialized narrow-band filters, including radio observation with a TV satellite dish.<\/p>\n The goal of this book<\/strong> is to provide a comprehensive guide to solar observation techniques, including examples and advice, for the beginner as well as the seasoned amateur. Contents:<\/strong> This part offers, as an appetizer, a general introduction to the Sun: Needless to say, this part is the main course. It gives a presentation of the phenomena observable by the amateur and an in-depth discussion of the long chain of elements involved in solar observation: Armed with this background, we can get into solar observing, whether visual or by imaging with a DSLR camera or a video camera: Two additional chapters complement this 2nd part, by developing the two following themes: Obtaining a beautiful image brings an undeniable satisfaction, which can prompt the amateur to go one step further and embark in an observing program. This is the purpose of this 3rd part. Finally, the reader will find at the end of the book additional documentation including a list of references, the main data about our Sun, a list of filter suppliers, a list of the largest solar professional telescopes around the world, a glossary and the indispensable index helping to find one\u2019s way through the book.<\/p>\n Even if there is a progression in the sequence of chapters, they are largely independent from each other. Indications are given when needed to navigate thru the book.<\/p>\n Beginners will find a guide to their first observations in Part I, and in the introductory paragraphs of chapters 6 and 7 related to the observation of the photosphere and the chromosphere. As they get more experienced, they will benefit from the more advanced parts. As for the advanced amateurs, no doubt they will pick up here and there on information or an idea that will help them to make further progress.<\/p>\n Part II is largely dedicated to the techniques of observation. The main objective of this part is to bring an understanding of how the equipment works and how to make the best use of it. Even if there are many references to commercial products, this part is not intended to be a buying guide on solar scopes or solar filters. For this, the reader will refer to reviews published in his\/her favorite astronomical magazine, to forum discussions, or to actual in-field testing and comparison at astronomical meetings.<\/p>\n Finally, the authors are not professional astronomers. They have tried their best to present up-to-date and reliable information, checked as much as possible from original sources. This is one of the reasons why references to the original professional papers are given in some chapters. The authors hope this information will prompt readers to pursue their exploration and understanding of the Sun. The authors beg professional astronomers to forgive them whenever they oversimplified the description of the solar physics and the observed phenomena. If mistakes remain in the text, they are the sole responsibility of the authors.<\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ admin_label=”Service Area” _builder_version=”3.25″ _module_preset=”default”][et_pb_column type=”1_2″ _builder_version=”3.25″ _module_preset=”default” custom_padding=”|||” custom_padding__hover=”|||”][et_pb_blurb title=”1. History of solar observation ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig1.3a.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″]<\/p>\n 1.1<\/strong> Pre-telescopic observations [\/et_pb_blurb][et_pb_blurb title=”2. Understanding our star” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig2-9b-Structure-cropi.png” _builder_version=”4.9.4″ _module_preset=”7470ffd1-e04a-4ea0-8f79-1c2c0b28f709″ header_font=”Montserrat|600|||||||” header_font_size=”20px” body_font=”||||||||” body_line_height=”1.8em” custom_padding=”10px|10px|10px|10px|false|false” animation_style=”fold” animation_direction=”bottom” animation_intensity_fold=”20%” animation_starting_opacity=”100%” border_width_all=”1px” border_color_all=”#CCCCCC” border_width_top=”1px” border_width_right=”1px” border_width_bottom=”1px” border_width_left=”1px”]<\/p>\n 2.1 The quiet Sun <\/strong> 2.2 The active Sun <\/strong> 2.3 The Sun, its life, its work <\/strong> [\/et_pb_blurb][et_pb_blurb title=”3. Observing the Sun safely ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig3.2-Occular-absorbtionj.png” _builder_version=”4.9.4″ _module_preset=”7470ffd1-e04a-4ea0-8f79-1c2c0b28f709″ header_font=”Montserrat|600|||||||” header_font_size=”20px” body_font=”||||||||” body_line_height=”1.8em” custom_padding=”10px|10px|10px|10px|false|false” animation_style=”fold” animation_direction=”bottom” animation_intensity_fold=”20%” animation_starting_opacity=”100%” border_width_all=”1px” border_color_all=”#CCCCCC”][\/et_pb_blurb][et_pb_blurb title=”4. Observation conditions” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig4.37a-site1-obs16pm.jpegk_.png” _builder_version=”4.9.4″ _module_preset=”7470ffd1-e04a-4ea0-8f79-1c2c0b28f709″ header_font=”|600|||||||” header_text_color=”#000000″ custom_padding=”10px|10px|10px|10px|false|false” border_width_all=”1px” border_color_all=”#CCCCCC” border_width_top=”1px” border_width_right=”1px” border_width_bottom=”1px” border_color_bottom=”#CCCCCC” border_width_left=”1px”]<\/p>\n 4.1 What is turbulence?<\/strong> 4.2 Which aperture for observation of the Sun? <\/strong> 4.3 Local turbulence and instrument turbulence <\/strong> 4.4 The variation of turbulence during the day: what is the best time for observation? <\/strong><\/p>\n 4.5 Measuring the seeing in real-time with a SSM <\/strong> [\/et_pb_blurb][et_pb_blurb title=”5. Telescopes for solar observation ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig5.21-Schema-Dall-Kirckham_Al.png” _builder_version=”4.9.4″ _module_preset=”7470ffd1-e04a-4ea0-8f79-1c2c0b28f709″ header_font=”|600|||||||” header_text_color=”#000000″ header_font_size=”20px” custom_padding=”10px|10px|10px|10px|false|false” border_width_all=”1px” border_color_all=”#cccccc”]<\/p>\n 5.1 Introduction<\/strong><\/span><\/p>\n 5.2 The main telescope designs<\/strong> 5.3 Resolution and aperture<\/strong><\/p>\n 5.4 Quality criteria for high resolution optics<\/strong> 5.5 The effects of obstruction<\/strong> 5.6 Collimation and star testing<\/strong> 5.7 Appendix: more on wavefront error<\/strong><\/p>\n [\/et_pb_blurb][et_pb_blurb title=”6. Observation of the photosphere ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig6.10-sans-annotation-AR2546_16May2016-8h54mnUT-N300-540nm_USm.png” _builder_version=”4.9.4″ _module_preset=”7470ffd1-e04a-4ea0-8f79-1c2c0b28f709″ header_font=”|600|||||||” header_font_size=”20px” custom_padding=”10px|10px|10px|10px|false|false” border_width_all=”1px” border_color_all=”#999999″]<\/p>\n 6.1 Introduction<\/span><\/strong><\/p>\n 6.2 Which instrument for observing the photosphere?<\/strong> 6.3 The features visible on the photosphere<\/strong> 6.4 Observation by eyepiece projection<\/strong> 6.5 Full aperture filters<\/strong> 6.6 Solar wedge and uncoated mirrors<\/strong> 6.7 Color filters<\/strong> 6.8 Appendices<\/strong> [\/et_pb_blurb][et_pb_blurb title=”7. Observation of the chromosphere ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig7.27b-Flare-8August2016-10h35mnUT-C8-Ion03An.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 7.1 Introduction<\/strong><\/span><\/p>\n 7.2 Chromospheric layers visible in Ha and Ca II<\/strong><\/p>\n 7.3 The observation of the chromosphere in Ca II<\/strong> 7.4 Observation of the chromosphere in Ha<\/strong> 7.5 Appendix 1: Fabry-Perot formulas<\/strong> 7.6 Appendix 2: measurement of the transmission profile of the elements of a Coronado Ha filter<\/strong><\/p>\n 7.7 Appendix 3: the He line<\/strong><\/p>\n 7.8 Appendix 4: height of the layers sampled in Ca K in areas of quiet Sun and in plages<\/strong><\/p>\n 7.9 Appendix 5: influence of the filter CWL on Ca H images<\/strong><\/p>\n 7.10 Appendix 6: influence of the filter CWL on Ha images<\/strong><\/p>\n 7.11 Appendix 7: testing etalon quality<\/strong> [\/et_pb_blurb][et_pb_blurb title=”8. The coronagraph ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig8.9-schema-coro-v2p.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 8.1 History of the coronagraph <\/strong><\/span><\/p>\n 8.2 Principle of operation <\/strong> 8.3. The coronagraph in detail <\/strong> 8.4 Construction of a coronagraph <\/strong><\/p>\n 8.5 Appendix 1: diffraction, Lyot diaphragm and apodization <\/strong> 8.6 Appendix 2: position of the optical elements of the coronagraph <\/strong><\/p>\n 8.7 Appendix 3: observation of prominences in bands other than Ha <\/strong><\/p>\n [\/et_pb_blurb][et_pb_blurb title=”9. Amateur solar instruments ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig9.36_RR175b.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 9.1 Introduction<\/strong><\/span><\/p>\n 9.2 Norma Desprez\u2019s solar Maksutov<\/strong><\/p>\n 9.3 Fran\u00e7ois Rouvi\u00e8re\u2019s 210 mm solar telescope<\/strong><\/p>\n 9.4 Christian Viladrich\u2019s 300 mm solar telescope<\/strong> 9.5 Fran\u00e7ois Rouvi\u00e8re\u2019s folded 175 mm aspherical lens refractor 9.7 Philippe Tosi\u2019s 225 mm coronagraph<\/strong> 9.8 Jean-Jacques Poupeau\u2019s spectroheliograph<\/strong> 9.9 Harald Paleske\u2019s 225 mm Unigraph refractor<\/strong> 9.10 Bob Yoesle\u2019s 140 mm double-stack Ha refractor<\/strong> [\/et_pb_blurb][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.6.6″ _module_preset=”default”][et_pb_blurb title=”10. Drawing, a school of observation ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/Fig10.9-4-1-1-fred-groupe-tachesb.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 10.1 Sketching as a school of observation<\/strong> 10.2 The art of drawing<\/strong> [\/et_pb_blurb][et_pb_blurb title=”11. Image acquisition ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig11.52a-montage-808c.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 11.1 Introduction<\/strong><\/span><\/p>\n 11.2 Daytime polar alignment<\/strong> 11.3 Focal length, image field and sampling<\/strong> 11.4 Focusing<\/strong> 11.5 Solar autoguiding<\/strong> 11.6 Digital sensors<\/strong> 11.7 Video cameras and their settings<\/strong> 11.8 Acquisition with video cameras<\/strong> 11.9 DSLRs and their settings<\/strong> 11.10 Appendix<\/strong> [\/et_pb_blurb][et_pb_blurb title=”12. Image processing ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig12.37-r6-wavelet-bandeg-ad.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 12.1 The basic treatment: registering\/sorting\/stacking<\/strong> 12.2 AutoStakkert! v3<\/strong> 12.3 The enhancement of micro-contrast<\/strong> 12.4 Differentiated local treatments<\/strong> 12.5 Finalization of images (gamma, visualization thresholds, colorization)<\/strong> 12.6 Mosaics<\/strong><\/p>\n 12.7 Animations<\/strong> 12.8 Some additional interesting software and utilities<\/strong> 12.9 Appendix: introduction to color management 367<\/strong><\/p>\n [\/et_pb_blurb][et_pb_blurb title=”13. Amateur solar radio astronomy ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig13-18-Lucie-block-diagram-v2e.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 13.1. Introduction<\/strong><\/span><\/p>\n 13.2. What is radio astronomy?<\/strong> 13.3. Solar activity at radio wavelengths<\/strong> 13.4. Lucie: a solar radio telescope for the beginning radio astronomer<\/strong> 13.5. Solar radio observation at other wavelengths<\/strong><\/p>\n 13.6. Concluding thoughts<\/strong><\/p>\n [\/et_pb_blurb][et_pb_blurb title=”14. Solar eclipses ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig14.53-ecl2017-nico-hr-7dec2017f.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 14.1. What is a solar eclipse?<\/strong> 14.2. Partial eclipse<\/strong> 14.3. Annular eclipse<\/strong> 14.4. Hybrid eclipse<\/strong><\/p>\n 14.5. Total eclipse<\/strong> 14.6. Observing the eclipse from an airplane or a ship<\/strong><\/p>\n 14.7. Next solar eclipses<\/strong><\/p>\n 14.8. The solar corona: shape, structure and brightness<\/strong><\/p>\n 14.9. A closer look at totality<\/strong> 14.10. Processing the images of totality<\/strong> 14.11 Appendix: acquisition control software<\/strong><\/p>\n [\/et_pb_blurb][et_pb_blurb title=”15. Amateur observing programs ” image=”https:\/\/solar-astronomy-book.com\/wp-content\/uploads\/2021\/07\/fig15.15-moreton-bg.png” _builder_version=”4.9.4″ _module_preset=”cb69ddf6-6c33-438d-8c1f-aebebbe43170″ header_font=”|600|||||||”]<\/p>\n 15.1 Introduction<\/strong><\/span><\/p>\n 15.2 Orientation of the Sun on images or drawings<\/strong> 15.3 Counting sunspots: Wolf number<\/strong> 15.4 Recording sunspot positions<\/strong> 15.5 Observation of prominences and other Ha features<\/strong> 15.6 Detection of Moreton-Ramsey waves<\/strong> 15.7 SOHO\/LASCO and STEREO\/SECCHI comet detection<\/strong> 15.8 Solar stormwatch<\/strong> 15.9 Measuring the variation of ovalization of the chromosphere<\/strong> 15.10 F-Chroma program<\/strong>
<\/strong><\/p>\n
This book could not be the work of only one. The diversity of contributors is a testimony of the various possible fields in solar observation. Each contributor, with his own style and favorite topics, shares here with us his experience and passion.<\/p>\n
The various themes are presented in three main parts.<\/p>\n1st part “Discovering the “Sun”<\/strong><\/span><\/h4>\n
Chapter 1<\/strong>: overview of the long history of solar observation.
Chapter 2<\/strong>: brief description of the main phenomena observable on our star.
The goal of this part is not to cover extensively these two themes but to raise the curiosity of the reader, and encourage him\/her to refer to the works given in the references for further information.<\/p>\n2nd part “Observation, equipment and techniques”<\/strong><\/span><\/h4>\n
Chapter 3<\/strong>: essential warnings on eye safety.
Chapter 4<\/strong>: observing conditions and atmospheric turbulence.
Chapter 5<\/strong>: different types of telescope designs with their pros and cons for solar observation.
Chapter 6<\/strong>: observation of the visible “surface” of the Sun, i.e. the photosphere, with the required instrumentation and associated filters.
Chapter 7<\/strong>: observation of the chromosphere, with the required instrumentation and associated filters.
Chapter 8<\/strong>: the coronagraph.
Chapter 9<\/strong>: examples of home-made instruments specialized in solar observation, actually used by the contributors, from the simplest to the most sophisticated.<\/p>\n
Chapter 10<\/strong>: drawing.
Chapter 11<\/strong>: image acquisition with a camera or a DSLR (sensor characteristics, setting of the cameras and DSLR).
Chapter 12<\/strong>: image processing. This last step is one of the most fascinating: how to enhance, without falling into excess, every detail contained in the image.<\/p>\n
Chapter 13<\/strong>: radio astronomy, with a presentation of radio telescopes, the solar physics at work at radio wavelengths and the description of a radio telescope an amateur can build, with examples of observations.
Chapter 14<\/strong>: observing and imaging solar eclipses.<\/p>\n3rd part “Observing projects”<\/strong><\/span><\/h4>\n
Chapter 15<\/strong>: presentation of various observing programs that can be undertaken by the amateur for monitoring solar activity, from its simplest form to more advanced studies directly derived from professional work.
Chapter 16<\/strong>: the dynamic solar activity can also be followed even without an instrument, thanks to the large resources available on the Internet.<\/p>\n
1.2<\/strong> First telescopic observations
1.3<\/strong> Observation in the 19th century
1.4<\/strong> The 20th century
1.5<\/strong> The quest for high resolution: 130 years of solar imaging<\/p>\n
2.1.1 The solar surface (photosphere)
2.1.2 Granulation
2.1.3 Revelations of spectral analysis
2.1.4 Chromosphere
2.1.5 Corona
2.1.6 Towards the interior of the Sun
2.1.7 The energy of the Sun<\/span><\/p>\n
2.2.1 Activity cycles
2.2.2 Solar activity: description
2.2.3 Solar activity: some explanations<\/p>\n
2.3.1 Life and death of the Sun
2.3.2 The Sun and us
2.3.3 In conclusion<\/p>\n
4.1.1 Atmospheric turbulence
4.1.2 The different layers of turbulence
4.1.3 Image quality, seeing and the Fried parameter
4.1.3.1 The effects of air turbulence on star images
4.1.3.2 The effects of air turbulence on solar images<\/span><\/p>\n
4.2.1 Which aperture for imaging?
4.2.2 Which aperture for visual observation?<\/p>\n
4.3.1 Local turbulence and the choice of observation site
4.3.2 Turbulence related to telescope shelters<\/p>\n
4.5.1 Scintillation of stars, planets and the Sun
4.5.2 The Solar Scintillation Monitor and its use by amateurs
4.5.2.1 Search and comparison of solar observation sites
4.5.2.2 Optimization of a solar observation site
4.5.2.3 Automatic triggering of acquisitions
4.5.2.4 Implementation and limitations of SSM<\/p>\n
5.2.1 The refracting telescope
5.2.2 The Newtonian reflector
5.2.3 The Schmidt-Cassegrain telescope
5.2.4 The Dall-Kirkham Telescope
5.2.5 The classical Cassegrain telescope
5.2.6 Maksutov-Cassegrain telescope<\/p>\n
5.4.1 Tolerances for the complete instrument
5.4.2 Surface tolerance for internally mounted filters
5.4.3 Surface tolerance for the 45\u00b0 secondary mirror of a Newtonian Telescope
5.4.4 Wavelength and geometric precision of a mirror surface
5.4.5 Cumulative error of different optical elements in a telescope<\/p>\n
5.5.1 Diffraction by a central obstruction
5.5.2 Diffraction by spacers of a Fabry-Perot etalon
5.5.3 Sub-pupil diffraction
5.5.4 Diffraction by the secondary mirror spider<\/p>\n
5.6.1 Collimation
5.6.2 Principle of star testing<\/p>\n
6.2.1 Observation of the photosphere \u2026 it\u2019s simple!
6.2.2 Refractor or reflector?
6.2.3 Small or large aperture? 1
6.2.4 Heating of lenses: does it pose a risk?
6.2.5 All things considered, which is the best instrument?<\/p>\n
6.3.1 Visible details according to the aperture of the instrument
6.3.2 The solar zoo of the photosphere: spots, pores, umbral dots, faculae, etc.<\/p>\n
6.4.1 Projection screen and its orientation
6.4.2 Calculating the solar disk diameter on the screen
6.4.3 The Solarscope \u2122
6.4.4 The SunGun
6.4.5 Solar Projection Eyepiece<\/p>\n
6.5.1 Glass filters
6.5.2 Film filters<\/p>\n
6.6.1 Introduction
6.6.2 Some optical principles
6.6.3 The Herschel prism
6.6.4 Solar telescopes with uncoated mirror<\/p>\n
6.7.1 Effect of filter color on the theoretical resolution of the images
6.7.2 Effect of filter color on the optical performance of the instrument
6.7.3 Effect of filter color on seeing
6.7.4 Effect of filter color on atmospheric dispersion
6.7.5 Effect of filter color on the contrast of images
6.7.6 Types of color filters
6.7.7 Some specialized filters for the observation of the photosphere
6.7.8 In short: which filters for visual observation?
6.7.9 In short: which filters for imaging?<\/p>\n
6.8.1 Density and transmission
6.8.2 Polarization of light
6.8.3 Transmission of neutral and polarizing filters in the infrared
6.8.4 Another variant of the solar wedge
6.8.5 Influence of filter wavelength on high resolution images of granulation
6.8.6 Influence of filter wavelength on the detection of intergranular bright points<\/p>\n
7.3.1 The Ca II K and H lines
7.3.2 What do we see with a Ca II filter?
7.3.3 Instruments and filters for Ca II observation<\/p>\n
7.4.1 What do we see with a Ha filter?
7.4.2 Instruments and filters for Ha observation
7.4.3 The Fabry-Perot etalon and its use
7.4.4 And the Lyot filter?
7.4.5 The energy rejection filter (ERF)
7.4.6 Blocking filter (BF)
7.4.7 The Induced Transmission Filter (ITF)
7.4.8 Some practical tips<\/p>\n
7.5.1 Basic formulas
7.5.2 Etalon mounting in a converging beam<\/p>\n
7.11.1 Test in diffuse light and a Ha lamp
7.11.2 Test in collimated beam and a Ha lamp
7.11.3 Test in telecentric beam using Sun as a light source<\/p>\n
8.2.1 Two types of coronagraph
8.2.2 Principle of coronagraph operation
8.2.3 Observation of the solar corona<\/p>\n
8.3.1 The occulting cone
8.3.2 The Ha filter
8.3.3 Manufacturers
8.3.4 Using a coronagraph<\/p>\n
8.5.1 Diffraction of light by the objective
8.5.2 Lyot diaphragm and apodization<\/p>\n
9.4.1 Objectives and specifications
9.4.2 Choosing the optical design
9.4.3 Primary mirror coated or not?
9.4.4 Choice of material for the primary mirror
9.4.5 Rear face of the primary mirror polished or frosted?
9.4.6 Thermal aspects and minimization of internal turbulence
9.4.7 Stray light
9.4.8 Secondary mirror and spider
9.4.9 Focus assembly
9.4.10 Collimation
9.4.11 What\u2019s the balance sheet after four years of use?<\/p>\n
<\/strong>
9.6 Jean-Pierre Brahic\u2019s 230 mm solar refractor<\/strong>
9.6.1 The project
9.6.2 What do we see through a 230 mm solar telescope?
9.6.3 Assessment after six years of use
9.6.4 The cost of a dream? 29
9.6.5 The future?<\/p>\n
9.7.1 Optics
9.7.2 Coronagraph tube
9.7.3 Occulting cone
9.7.4 Equatorial mount
9.7.5 Results obtained<\/p>\n
9.8.1 Introduction
9.8.2 Principle of the instrument
9.8.3 Optical layout
9.8.4 Construction
9.8.5 Synthesis of the image using a video camera
9.8.6 Processing spectral images to spectroheliograms
9.8.7 Results achieved
9.8.8 Conclusions<\/p>\n
9.9.1 The first development
9.9.2 A 225\/2600 mm FH Unigraph for Ha solar observation
9.9.3 Conclusion<\/p>\n
9.10.1 The beginning of a passion
9.10.2 First step in Ha\u2026
9.10.3 Solar nirvana?
9.10.4 The quest goes on
9.10.5 The SM140\/SM90 refractor
9.10.6 Rebuilding the SM140\/SM90 refractor
9.10.7 First light with the rebuilt SM140\/90 refractor
9.10.7 Back to work again
9.10.8 Success at last<\/p>\n
10.1.1 The purpose of sketching
10.1.2 Drawing material
10.1.3 Which instrument to use?
10.1.4 Eyepiece and filter choice
10.1.5 One method among many
10.1.6 And now in Ha?
10.1.7 To go further
<\/span><\/p>\n
10.2.1 Drawing the solar photosphere in white light
10.2.2 Drawing the Sun in Ha wavelength<\/p>\n
11.2.1 For visual observation
11.2.2 For imaging<\/p>\n
11.3.1 Focal length, sensor size and angular field of view
11.3.2 Sampling
11.3.3 Optimal sampling for high resolution
11.3.4 How to adjust the sampling value: Barlow or eyepiece?
11.3.5 How to measure the sampling and the effective focal length of the instrument?<\/p>\n
11.4.1 What focus tolerance?
11.4.2 Focusing techniques<\/p>\n
11.5.1 Autoguiding with acquisition software
11.5.2 Autoguiding with guide telescope<\/p>\n
11.6.1 Main features
11.6.2 Some useful technical concepts
11.6.3 All things considered: which camera is best for solar imaging?<\/p>\n
11.7.1 Windowing
11.7.2 Number of acquisition bits
11.7.3 Setting the gain
11.7.4 Setting the offset (or black level)
11.7.5 Setting the exposure time
11.7.6 Capture rate
11.7.7 Adjusting the gamma<\/p>\n
11.8.1 Format of the acquisition file
11.8.2 Duration of the acquisition
11.8.3 Animations
11.8.4 CMOS Fixed Pattern Noise Correction
11.8.5 Making flat field images (\u201cflats\u201d)
11.8.6 Cleaning the sensor
11.8.7 What to do in case of glare?
11.8.8 Limit camera warm-up
11.8.9 Mechanical mounting of the camera<\/p>\n
11.9.1 Introduction
11.9.2 Full-disk solar images
11.9.3 Close-up images of solar details
11.9.4 Using DSLR in video mode
11.9.5 Control of the DSLR by a PC
11.9.6 Using an external LCD screen with HDMI connection<\/p>\n
11.10.1 Conversion between dB and number of bits
11.10.2 Measuring the dynamic range and SNR of a camera
11.10.3 Approximate measurement of the focal length of a Barlow lens<\/p>\n
12.1.1 The basic principles<\/span><\/p>\n
12.2.1 A quick guide
12.2.2 The most important settings in more detail
12.2.3 AutoStakkert!: Additional parameters<\/p>\n
12.3.1 Correction of reflections
12.3.2 The different scale levels of detail in an image
12.3.3 Unsharp mask processing
12.3.4 Wavelet processing
12.3.5 Richardson \u2013 Lucy deconvolution treatment
12.3.6 Artifacts or real details, what is the limit to treatment?<\/p>\n
12.4.1 Highlighting details in sunspot umbrae
12.4.2 Harmonization between solar disk and prominences
12.4.3 \u201cCoronagraph\u201d effect<\/p>\n
12.5.1 Gamma and visualization thresholds<\/p>\n
12.7.1 Creating an animation with ImPPG and Photoshop
12.7.2 Animation of prominences<\/p>\n
12.8.1 SER Player
12.8.2 PIPP
12.8.3 ImPPG
12.8.4 RegiStax 6
12.8.5 Astrosurface<\/p>\n
13.2.1 The electromagnetic spectrum
13.2.2 The radio telescope
13.2.3 The dipole antenna
13.2.4 The parabolic antenna
13.2.5 The power received by a radio telescope
13.2.6 Antenna arrays<\/p>\n
13.3.1 Radio emission mechanisms
13.3.2 Emission from the disturbed or active Sun<\/p>\n
13.4.1 The different elements of the Lucie radio telescope
13.4.2 Constructing the Lucie Radio Telescope
13.4.3 A solar radiometry measurement
13.4.4 Some final words about the Lucie radio telescope<\/p>\n
14.1.1 Earth-Moon-Sun system
14.1.2 The saros
14.1.3 Different types of solar eclipses: partial, annular, hybrid, total
14.1.4 Points of contact during an eclipse<\/span><\/span><\/p>\n
14.2.1 Visual observation
14.2.2 Photographing the eclipse<\/p>\n
14.3.1 Visual observation
14.3.2 Photographing the eclipse<\/p>\n
14.5.1 Speed of the Moon\u2019s shadow
14.5.2 What is the duration of totality?
14.5.3 Visual observation
14.5.4 Photographing the eclipse
14.5.5 Making a video of the eclipse
14.5.6 Visual observation of the eclipse with an instrument
14.5.7 Additional tips<\/p>\n
14.9.1 Observation of stars and earthshine
14.9.2 High resolution observation of the corona
14.9.3 Possible scientific experiments<\/p>\n
14.10.1 Processing with Photoshop
14.10.2 Other processing methods
14.10.2.1 Registration of images on the solar disk
14.10.2.2 Correction of the radial brightness gradient<\/p>\n
15.2.1 Solar orientation in a telescope
15.2.2 Frame orientation with respect to the celestial coordinate system
15.2.3 Heliographic coordinates
15.2.4 Solar grid tools
15.2.5 Grids and various measurement tools
15.2.6 Useful links<\/p>\n
15.3.1 The program
15.3.2 Useful links<\/p>\n
15.4.1 The program
15.4.2 Useful links<\/p>\n
15.5.1 The program
15.5.2 Useful links<\/p>\n
15.6.1 The program
15.6.2 Useful links<\/p>\n
15.7.1 The program
15.7.2 Useful link<\/p>\n
15.8.1 The program
15.8.2 Useful link<\/p>\n
15.9.1 The program
15.9.2 Useful links<\/p>\n