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International Year of Astronomy 400 Years of Astronomical Telescope

International Year of Astronomy 400 Years of Astronomical Telescope . T V Venkateswaran VIGYAN PRASAR, New Delhi. Galileo did not invent telescope Nor was he the first to use it for astronomy!. The telescope was unveiled in the Holland.

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International Year of Astronomy 400 Years of Astronomical Telescope

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  1. International Year of Astronomy400 Years of Astronomical Telescope T V Venkateswaran VIGYAN PRASAR, New Delhi

  2. Galileo did not invent telescopeNor was he the first to use it for astronomy! The telescope was unveiled in the Holland. In October 1608 patent application was filed by Hans Lipperhey

  3. First known use for astronomical purpose We know that Thomas Harriot observed the Moon with a six-powered instrument early in August 1609, months before Galileo

  4. Significance of Galileo • He did not just ‘use’ the telescope- he fabricated his own … • He did not just ‘see’ the heavens, but applied scientific method to interpret what he saw… The actual term "telescope" was coined on April 14, 1611 by Prince Frederick Cesi at a reception where Galileo was demonstrating one of his instruments.

  5. Development of Telescopeis linked to that of spectacles With age, the eye progressively loses its power to accommodate, that is to change its focus from faraway objects to nearby ones. This condition, becomes noticeable for most people in their forties, when they can no longer focus on letters/ books held at a comfortable distance from the eye. Magnifying glasses became common in the thirteenth century for reading

  6. Ancient Egyptian hieroglyphs dated back to the 8th century BC depict "simple glass meniscal lenses". A Tamil poet, Kapilar, of Sangam era (about 1 C BCE) states that a dewdrop on a grass could make the image as large as a Palmyra tree, thus indicating an understanding of the principles of magnification.

  7. The earliest evidence of "a magnifying device, a convex lens forming a magnified image," dates back the Book of Optics published by Alhazen (Ibn al-Haitham) in 1021. Its translation into Latin in the 12th century was instrumental to the invention of eyeglasses in 13th century Italy.

  8. At first the lenses (lens means lentil in Latin, so called because of the shape of the pieces of glass used) for the eyeglasses were made by cutting discs out of balls of blown glass. These were called as ‘Reading stones’.

  9. Venetian glass blowers, who had learned how to produce glass for reading stones, later constructed lenses that could be held in a frame in front of the eye instead of directly on the reading material. It was intended for use by one eye

  10. Around 1284 in Italy, SalvinoD'Armate is credited with inventing the first wearable eye glasses. Spectacles making and usage spread rapidly with the spread of literacy.

  11. The earliest pictorial evidence for the use of eyeglasses, however, is Tomaso da Modena's 1352 portrait of the cardinal Hugh de Provence reading in a scriptorium.

  12. Discovery of lenses Those with nearsighted had problem of seeing things at far. They needed concave lenses. Only after 15 century concave lenses were fabricated. Those with farsighted had problems of seeing things near. They needed convex lenses. Initially convex lenses were made.

  13. In the late 15th century the spectacle-makers of Nuremberg began however to cut the discs out of plates of flat glass and then grind one of the surfaces to either a concave or a convex shape. • Through this procedure, lenses with more accurate spherical curvature could be produced. • It was the spread of this perfecting technique that made the invention of the telescope possible.

  14. Lipperhey was one such spectacle maker in Holland. One story behind the creation of the telescope states that two children were playing with lenses in his shop. The children discovered that images were clearer when seen through two lenses, one in front of the other. Lipperhey was inspired by this and created a device very similar to today's telescope. Of course it was called ‘looker’ by him and not telescope.

  15. Lipperhey Lipperhey applied for patent in 1608 to the government. He was unable to get a patent, however, because his invention was deemed too easy to reproduce. He however produced number of opera glasses for viewing opera in the theatre.

  16. Soon telescope spread throughout Europe. English scientist Harriot bought one from Dutch and used it to observe moon

  17. Galileo’s telescope Galileo found out about this invention in the early 1609 and immediately set about improving it. • He realized that the magnification was proportional to the ratio of the power of the concave (eyepiece) lens to the convex (more distant) lens. • In other words he needed a weak convex lens and a strong concave lens. • Opticians only made glasses in a narrow range of strengths, and three or so was the best magnification available with off the shelf lenses.

  18. Galileo learned to grind his own lenses, and by August 1609, he had achieved about eight-fold linear magnification. He demonstrated his new invention to a gathering of officials on August 1609. Initially Galileo advocated its military potential as a spy glass.

  19. Galilean Telescope Galileo used a long focal length objective and a short focal length eye piece. If the focal length of the objective is Fo and the focal length of the eyelens is -Fe, the distance between them must be Fo - Fe, and the power (angular magnification) is Fo/Fe. Image is upright. "When there are no glasses in the tube, the rays proceed to the object FG along the straight lines ECF and EDG, but with the glasses put in they proceed along the refracted lines ECH and EDI. They are indeed squeezed together and where before, free, they were directed to the object FG, now they only grasp the part HI"

  20. Galileo’s revolution.. His initial version 8x but was soon refined to the 20x • Mountains on the moon • Jupiter’s satellite • Milky way • Gibbous phase of Venus

  21. Galileo could see stellar occultation, mountains on moon, calculate the height of the moon and so on. At one stroke he could change the way moon looked. January 19, 1610 stellar occultation

  22. He observe that some parts of the moon were illuminated well before its surroundings by the sunlight. We know that mountain tops are illuminated at the dawn well before the valleys. He built a convincing case for the reality of the mountains by sketching the appearance of parts of the Moon’s surface at different times of the month, that is, under different angles of lighting. Obviously this caused uproar. The orthodox were enraged, how can Galileo claim that moon, an celestial body to be ‘imperfect’

  23. Galileo’s next major discovery began with his observation on January 7, 1610, of what he took to be a rather odd set of three small fixed stars near Jupiter. These ‘stars’ were invisible to the naked eye. Observations over successive night revealed that actually four star-like objects in a line with it. The objects moved from night to night, sometimes disappearing behind or in front of the planet. Galileo correctly inferred that these objects were moons of Jupiter and orbited it just as our Moon orbits Earth. By the 15th January 1610 had realized that he was looking at moons of Jupiter.

  24. Through naked eye Through telescope Galileo then turned his attention to most numerous objects in the night sky- stars. Rather to his disappointment the stars showed no features- they were still point source, even through a telescope the stars still appeared as points of light. Galileo suggested that this was due to their immense distance from Earth. On turning his telescope to the band of the Milky Way Galileo saw it resolved into thousands of hitherto unseen stars. In like manner when ex explored the region of Pleiades, he found stars that were unseen to naked eye. His exploration of the Orion nebula also revealed unseen stars.

  25. Galileo Galilei published Sidereus Nuncius, or the 'Starry Messenger ' in March 1610. In it he provided a lively and accessible account of his telescopic observations. This revolutionized the astronomy as well as sciences.

  26. Latter… Copernicus Galileo’s drawing of the phases of Venus and modern photo-mosaic Ptolemy From observing the phases of Venus he could conclude heliocentric theory

  27. His telescopic observation of Saturn resulted in total shock. Initially Saturn appeared to have ears, and latter some kind of appendage. Galileo could not make sense of it. Few decades latter, Huygens using a better telescope resolved it as ring around Saturn. In any case Galileo’s observation showed that stellar objects need not be perfect sphere.

  28. Aristotle believed that a stone fell to the ground because the stone and the ground were similar in substance (in terms of the 4 basic elements, they were mostly "earth"). Likewise, smoke rose away from the Earth because in terms of the 4 basic elements it was primarily air (and some fire), and therefore the smoke wished to be closer to air. Likewise heavenly bodies were perfect without any blemish and moved in uniform circular motion. Contrary to reality, Aristotle claimed that heavier ball will fall first !

  29. To the first sight, for the Earth-bound observers, while rain, wind and erosion kept changing the features of the Earth’s terrain, hardly anything changed in the heavens. Day after day the sun rose in the east; month after month the moon waxed and waned in the same manner; year after year the sun appeared to go around the Earth, and all the while stars appeared to be fixed and immobile. Aristotle thus made a clear distinction between the heavenly (celestial) and terrestrial (sublunar) realms, the former being unchanging, perfect etc and the latter being changeable, imperfect and so on. Hence it was assumed that laws that were applicable to one realm would not apply to another and this cosmic divide lasted for centuries. This was held by the orthodoxy as an immutable dogma- to be taken as faith.

  30. Seeds of doubt Galileo had earlier observed a ‘new star’ in October 10, 1604. Today we know it as supernova- explosion of a star. It was first observed by Kepler on Oct 9, 1604 in the constellation Ophiuchus and hence called Kepler’s Nova. Galileo went a step further. He made parallax measurements and found it to be beyond Moon, in the starry realm. Therefore he had his first inkling that something was amiss in the Aristotelian idea of unchanging cosmos.

  31. Galileo's extensive telescopic observations of the heavens made it more and more plausible that they were not made from a perfect, unchanging substance. In particular, Galileo's observational confirmation of the Copernican hypothesis suggested that the Earth was just another planet, so maybe it was made from the same material as the other planets. It was radical and an epistemic rupture of celestial and terrestrial. Same laws of physics applied in both cases. One set of science is all that is required to explain ‘heaven and earth’!

  32. Just as Aryabhatta was condemned for his views against the purnaic myth of Rahu -Ketu, Galileo was punished by the orthodoxy in Europe for daring to put forth his theories. He was to suffer for many years for upholding science and sprit of quest against mindless dogma.

  33. In July 1633, he was imprisoned and latter his sentence was converted into life-long house arrest, because of health reasons. He was not allowed to have contact with the outside world. Until his death, even at his old age he kept working.

  34. Down but not Out Although Galileo was ill and mentally exhausted, he started to write a book about mechanics, based on his research in Padua. This book, Discorsi, or Dialogues Concerning Two New Sciences was published by Elzevier in Leiden, because it could, of course, not be published in Catholic lands. The book convincingly argued against the Earth centered universe and upheld the scientific sprit. No wonder the 400th annivesary of Galileo’s use of telescope is celebrated as International Year of Astronomy.

  35. The major goals of IYA2009 are to: • Increase scientific awareness. • Promote widespread access to new knowledge and observing experiences. • Empower astronomical communities in developing countries. • Support and improve formal and informal science education. • Provide a modern image of science and scientists. • Facilitate new networks and strengthen existing ones. • Improve the gender-balanced representation of scientists at all levels and promote greater involvement by underrepresented minorities in scientific and engineering careers. • Facilitate the preservation and protection of the world's cultural and natural heritage of dark skies in places such as urban oases, national parks and astronomical sites.

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