Ali Qushji

Ala al-Dīn Ali ibn Muhammed

astronomer, mathematician, physicist, scientist and mutakallim (Muslim theologian)
Born 1403
Samarkand
Died 16 December 1474
Istanbul
Other names Ali Qushji
Ethnicity Turkic[1][2] or Persian[3][4]

Ala al-Dīn Ali ibn Muhammed (1403 – 16 December 1474), known as Ali Qushji (Ottoman Turkish/Persian language: علی قوشچی, kuşçu - falconer in Turkish;[5] Latin: Ali Kushgii), was a Turkic[1][2] or Persian[3] astronomer, mathematician and physicist originally from Samarkand, who settled in the Ottoman Empire some time before 1472.[6] As a disciple of Ulugh Beg, he is best known for the development of astronomical physics independent from natural philosophy, and for providing empirical evidence for the Earth's rotation in his treatise, Concerning the Supposed Dependence of Astronomy upon Philosophy. In addition to his contributions to Ulugh Beg's famous work Zij-i-Sultani and to the founding of Sahn-ı Seman University, one of the first madrasahs in the Ottoman Empire, Ali Qushji was also the author of several scientific works and textbooks on astronomy.[7]

Contents

Biography

Early life and works

Ali Qushji was born in 1403 in the city of Samarkand, in present-day Uzbekistan. His full name at birth was Ala al-Dīn Ali ibn Muhammed al-Qushji. The last name Qushji derived from the Turkish term kuşçu - the falconer[5] - due to the fact that Ali's father Muhammad was the royal falconer of Ulugh Beg.[7]

He attended the courses of Qazi zadeh Rumi, Ghiyāth al-Dīn Jamshīd Kāshānī and Muin al-Dīn Kashi. He moved to Kerman, Iran (Persia) and there he conducted some researches on the storms of Oman sea. He completed Hall-e Eshkal-i Ghammar (Explanations of the Periods of the Moon) and Sharh-e Tajrid in Kirman. He moved to Herat and taught Molla Cami about astronomy (1423). After professing in Herat for a while he went back to Samarkand and herald his works about moon to Ulugh Beg. Ulugh Beg was fascinated with the works and read the entire work while standing up. Ulugh Beg assigned him to Ulugh Beg Observatory which was called "Samarkand Observatory" at that time. He worked there till Ulugh Beg was assassinated.[8]

After Ulugh Beg's death, Ali Qushji went to Herat, Tashkent and finally Tabriz, where around 1470, the Ak Koyunlu ruler Uzun Hasan sent him as a delegate to the Ottoman Sultan Mehmed II. At that time Husayn Bayqarah had come to reign in Herat but Qushji preferred Constantinople rather than Herat because of Sultan Mehmed's attitude toward scientists and intellectuals.

Constantinople era

When he came to Constantinople (present-day Istanbul), his grandson Ghutb al-Dīn Muhammed had a son Mirim Chalabi who would be a great mathematician and astronomer in the future.[9] Ali Qushji composed "risalah dar hay’at" in Persian for Mehmed II at Constantinople in 1470.[10] Also he wrote "Sharh e resalye Fathiyeh",[11] "resalye Mohammadiye" in Constantinople, which are in Arabic on the topic of mathematics. Qushji's work made a great impact on the scientific community. The work has thousands of copies in handwriting libraries all around the world.

He then finished "Sharh e tejrid" on Nasir al-Din al-Tusi's "Tejrid al-kalam". That work is called "Sharh e Jadid" in scientific community. It is considered as the most important philosophical work on metaphysics, physics, optics and mathematics done within Islamic civilization.

Contributions to astronomy

Qushji improved on Nasir al-Din al-Tusi's planetary model and presented an alternative planetary model for Mercury.[12] He was also one of the astronomers that were part of Ulugh Beg's team of researchers working at the Samarqand observatory and contributed towards the Zij-i-Sultani compiled there. In addition to his contributions to Zij, Ali Qushji wrote nine works in astronomy, two of them in Persian and seven in Arabic.[7] A Latin translation of two of Qushji's works, the Tract on Arithmetic and Tract on Astronomy, was published by John Greaves in 1650.

Concerning the Supposed Dependence of Astronomy upon Philosophy

Qushji's most important astronomical work is Concerning the Supposed Dependence of Astronomy upon Philosophy. Under the influence of Islamic theologians who opposed the interference of Aristotelianism in astronomy, Qushji rejected Aristotelian physics and completely separated natural philosophy from Islamic astronomy, allowing astronomy to become a purely empirical and mathematical science. This allowed him to explore alternatives to the Aristotelian notion of a stationary Earth, as he explored the idea of a moving Earth instead. Though Savage-Smith asserts that no Islamic astronomers proposed a heliocentric universe.[13] He found empirical evidence for the Earth's rotation through his observation on comets and concluded, on the basis of empirical evidence rather than speculative philosophy, that the moving Earth theory is just as likely to be true as the stationary Earth theory.[14][15][16]

His predecessor al-Tusi had previously realized that "the monoformity of falling bodies, and the uniformity of celestial motions," both moved “in a single way,” though he still relied on Aristotelian physics to provide "certain principles that only the natural philosophers could provide the astronomer." Qushji took this concept further and proposed that "the astronomer had no need for Aristotelian physics and in fact should establish his own physical principles independently of the natural philosophers." Alongside his rejection of Aristotle's concept of a stationary Earth,[17] Qushji suggested that there was no need for astronomers to follow the Aristotelian notion of the heavenly bodies moving in uniform circular motion.[13]

Qushji's work was an important step away from Aristotelian physics and towards an independent astronomical physics.[18] This is considered to be a "conceptual revolution"[13][18] that had no precedent in European astronomy prior to the Copernican Revolution in the 16th century.[19] Qushji's view on the Earth's motion was similar to the later views of Nicolaus Copernicus on this issue, though it is uncertain whether the former had any influence on the latter. However, it is likely that they both may have arrived at similar conclusions due to using the earlier work of Nasir al-Din al-Tusi as a basis. This is more of a possibility considering "the remarkable coincidence between a passage in De revolutionibus (I.8) and one in Ṭūsī’s Tadhkira (II.1[6]) in which Copernicus follows Ṭūsī’s objection to Ptolemy’s “proofs” of the Earth’s immobility."[20]

His works

Astronomy[21][22]

Mathematics[23]

Kalam and Fiqh

Mechanics[24]

Linguistics[25]

Notes

  1. ^ a b Siddiqi, Amir Hasan (1970). Cultural centres of Islam. Jamiyat-ul-Falah Publications. p. 90. http://books.google.com/books?id=CbVWAAAAMAAJ&q=Cultural+centres+of+Islam&dq=Cultural+centres+of+Islam&ie=ISO-8859-1&output=html&pgis=1. "Among them, a Turk from Central Asia, Ali Kuscu, was one of the finest mathematicians and astronomers of his epoch" 
  2. ^ a b "During the fifteenth century thie method of representing decimal fracitons came to be known outside the Islamic world as the Turkish method, after a Turkish colleague of al-Kashi, known as Ali Qushji, who provided an explanation." Joseph, George Gheverghese (2010) The crest of the peacock: non-European roots of mathematics Princeton University Press, p. 469. ISBN 0691135266, 9780691135267
  3. ^ a b G. A. Russell, The 'Arabick' Interest of the Natural Philosophers in Seventeenth-century England, BRILL, 1994, ISBN 9004098887, p. 162;
    "Greaves quotes from Risala dar ‘ilm al-Hay’a of ‘Ali b. Muh. ‘Ala al-Din Qushji. This Persian author was the son of an official of Ulugh Beg, and also a student of Qadi Zadeh".
  4. ^ MEDIEVAL AND RENAISSANCE WORLD, www.physicsoftheuniverse.com
  5. ^ a b Vlahakis, George (2006). Imperialism and science: social impact and interaction. ABC-CLIO. p. 75. ISBN 9781851096732. http://books.google.com/books?id=LYbbZHvtJi8C&pg=PA75. 
  6. ^ Imber, Colin (1997). Ebu's-suůd: the Islamic legal tradition. Edinburgh University Press. p. 9. ISBN 9780748607679. http://books.google.com/books?id=CR-ZbjDAM0EC&pg=PA9. 
  7. ^ a b c Ágoston, Gábor; Masters, Bruce Alan (2009). Encyclopedia of the Ottoman Empire. Infobase Publishing. p. 35. ISBN 9780816062591. http://books.google.com/books?id=QjzYdCxumFcC&pg=PA35. 
  8. ^ Osmanlı imparatorluğunun doruğu 16. yüzyıl teknolojisi, Editor Prof. Dr. Kazım Çeçen, Istanbul 1999, Omaş ofset A.Ş.
  9. ^ G. Akovalı, Z. A. Mansūrov, The role of government and research institutes in the planning of research and development in some Central Asian and Caucasian republics, IOS Press, 2000,ISBN 1-58603-022-1, 9781586030223, p.230,[1]
  10. ^ Mahārājā Mānasiṃha Pustaka Prakāśa, David Edwin Pingree, ”A descriptive catalogue of the Sanskrit astronomical manuscripts preserved at the Maharaja Man Singh II Museum in Jaipur, India”, American Philosophical Society, 2003, p.138;
  11. ^ [2]
  12. ^ George Saliba, "Arabic planetary theories after the eleventh century AD", in Rushdī Rāshid and Régis Morelon (1996), Encyclopedia of the History of Arabic Science, pp. 58–127 [123–124], Routledge, ISBN 0-415-12410-7.
  13. ^ a b c Emilie Savage-Smith (November 2008), "Islamic Influence on Copernicus", Journal for the History of Astronomy 39 (4): 538–541 [541], Bibcode 2008JHA....39..538S, http://www.shpltd.co.uk/Journal%20for%20the%20History%20of%20Astronomy%20November.pdf, retrieved 2010-03-25 
  14. ^ (Ragep 2001a)
  15. ^ F. Jamil Ragep (2001), "Freeing Astronomy from Philosophy: An Aspect of Islamic Influence on Science", Osiris, 2nd Series, Vol. 16, Science in Theistic Contexts: Cognitive Dimensions, pp. 49–64, 66–71.
  16. ^ Edith Dudley Sylla (2003), "Creation and nature", in Arthur Stephen McGrade, The Cambridge Companion to Medieval Philosophy, Cambridge: Cambridge University Press, pp. 178–179, ISBN 978-0-521-00063-5 
  17. ^ Ragep, F. Jamil (2004), "Copernicus and his Islamic Predecessors: Some Historical Remarks", Filozofski vestnik XXV (2): 125–142 [138–9] 
  18. ^ a b Ragep, F. Jamil (2004), "Copernicus and his Islamic Predecessors: Some Historical Remarks", Filozofski vestnik XXV (2): 125–142 [139] 
  19. ^ F. Jamil Ragep (2004), "Copernicus and His Islamic Predecessors: Some Historical Remarks", Filozofski vestnik XXV (2): 125–142 [139], "Clearly there is more to the Copernican revolution than some clever astronomical models that arose in the context of a criticism of Ptolemy. There also needed to be a new conceptualization of astronomy that could allow for an astronomically-based physics. But there is hardly anything like this in the European tradition before Copernicus. The fact that we can find a long, vigorous discussion in Islam of this issue intricately-tied to the question of the Earth’s movement should indicate that such a conceptual foundation was there for the borrowing." 
  20. ^ Ragep, F. Jamil (2004), "Copernicus and his Islamic Predecessors: Some Historical Remarks", Filozofski vestnik XXV (2): 125–142 [137–9] 
  21. ^ Osmanlı Astronomi Literatürü Tarihi (Ed. Ekmeleddin İhsanoğlu), İstanbul 1997, I, 27–38
  22. ^ [3]
  23. ^ Seyyid Ali Paşa, Mir’âtu’l-Âlem (Haz. Yavuz Unat), Kültür Bakanlığı, Ankara 2001.
  24. ^ Sevim Tekeli, 16’ıncı Asırda Osmanlılarda Saat ve Takiyyuddîn’in “Mekanik Saat Konstrüksüyonuna Dair En Parlak Yıldızlar” Adlı Eseri, Ankara 1966.
  25. ^ Musa Yıldız, Bir Dilci Olarak Ali Kuşçu ve Risâle fî’l-İsti‘âre’si, Kültür Bakanlığı Yayınları, Ankara 2002, s. 10–14.

Yavuz Unat, Ali Kuşçu, Kaynak Yayınları, 2010.

References

External links