Kamal al-Din al-Fārisī | |
---|---|
Born | 1265 |
Died | 12 January 1318 (aged 52–53) |
Scientific career | |
Fields | Optics, physics, mathematics, science |
Kamal al-Din Hasan ibn Ali ibn Hasan al-Farisi [1][2][3] or Abu Hasan Muhammad ibn Hasan (1267– 12 January 1319,[4][5] long assumed to be 1320)[6]) (Persian: كمالالدين فارسی) was a Persian[7][8][9] Muslim scientist. He made two major contributions to science, one on optics, the other on number theory. Farisi was a pupil of the astronomer and mathematician Qutb al-Din al-Shirazi, who in turn was a pupil of Nasir al-Din Tusi.
According to Encyclopædia Iranica, Kamal al-Din was the most advanced Persian author on optics.[10]
Optics
His work on optics was prompted by a question put to him concerning the refraction of light. Shirazi advised him to consult the Book of Optics of Ibn al-Haytham (Alhacen), and Farisi made such a deep study of this treatise that Shirazi suggested that he write what is essentially a revision of that major work, which came to be called the Tanqih. Qutb al-Din Al-Shirazi himself was writing a commentary on works of Avicenna at the time.
Farisi is known for giving the first mathematically satisfactory explanation of the rainbow, and an explication of the nature of colours that reformed the theory of Ibn al-Haytham Alhazen.[11] Farisi also "proposed a model where the ray of light from the sun was refracted twice by a water droplet, one or more reflections occurring between the two refractions." He verified this through extensive experimentation using a transparent sphere filled with water and a camera obscura.[12]
His research in this regard was based on theoretical investigations in dioptrics conducted on the so-called Burning Sphere (al-Kura al-muhriqa) in the tradition of Ibn Sahl (d. ca. 1000) and Ibn al-Haytham (d. ca. 1041) after him. As he noted in his Kitab Tanqih al-Manazir (The Revision of the Optics), Farisi used a large clear vessel of glass in the shape of a sphere, which was filled with water, in order to have an experimental large-scale model of a rain drop. He then placed this model within a camera obscura that has a controlled aperture for the introduction of light. He projected light unto the sphere and ultimately deducted through several trials and detailed observations of reflections and refractions of light that the colors of the rainbow are phenomena of the decomposition of light. His research had resonances with the studies of his contemporary Theodoric of Freiberg (without any contacts between them; even though they both relied on Ibn al-Haytham's legacy), and later with the experiments of Descartes and Newton in dioptrics (for instance, Newton conducted a similar experiment at Trinity College, though using a prism rather than a sphere).[13][14][15][16]
In his Kitab Tanqih al-Manazir (The Revision of the Optics), Farisi also saved the latest advancements in color theory by Nasir al-Din al-Tusi on color odering. In contrast to Aristotle (d. 322 BCE), who had suggested that all colors can be aligned on a single line from black to white, Ibn-Sina (d. 1037) had described that there were three paths from black to white, one path via grey, a second path via red and the third path via green. Al-Tusi (ca. 1258) elaborated on this by stating that there are no less than five of such paths, via lemon (yellow), blood (red), pistachio (green), indigo (blue) and grey. No less than 23 intermediate colors on these paths were explicitly mentioned in this text. Fortunately this text was saved since Farisi included it in his Kitab Tanqih al-Manazir (The Revision of the Optics), which was copied numerous times until at least the nineteenth century as part of the textbook Revision of the Optics (Tanqih al-Manazir). Tusi's description of the relations between various colors effectively made color space two-dimensional.[17] Robert Grosseteste (d. 1253) proposed an effectively three-dimensional model of color space.[18]
Number theory
Farisi made a number of important contributions to number theory. His most impressive work in number theory is on amicable numbers. In Tadhkira al-ahbab fi bayan al-tahabb ("Memorandum for friends on the proof of amicability") introduced a major new approach to a whole area of number theory, introducing ideas concerning factorization and combinatorial methods. In fact Farisi's approach is based on the unique factorization of an integer into powers of prime numbers. While the Greek mathematician Euclid took the first step on the way to the existence of prime factorization, al-Farisi took the final step[19] and stated for the first time the fundamental theorem of arithmetic.[20]
Works
- Asas al-qawa'id fi usul al-fawa'id (The base of the rules in the principles of uses) which comprises an introduction and five chapters dealing with arithmetic, notarial and sales rules, the areas of surfaces and solids, and the last two essays are on algebra. The book is a commentary on the treatise of Al-Baha'i uses in the arithmetic rules of Al-Khawam al-Baghdadi.
- Tanqih al-Manazir (Arabic: تنقيح المناظر ; The Revision of Ibn al-Haytham's Optics). He completed the writing of this book in Ramadan 708 H.E. (Feb-Mar 1309 A.D.).[21] The autograph manuscript of this work has newly discovered. Before the discovery, the completion date of the Tanqih had been controversial, placed from sometime before 1290 (M. Nazif)[22] to after 1302, but before Quṭb al-Dīn Shīrāzī's death in 710/1311 (Wiedemann).[23]
- Tadhkira al-ahbab fi bayan al-tahabb (Memorandum for friends on the proof of amicability)
- Al-Basa'ir fi 'ilm al-manazir (Insights Into the Sciences of Optics), a text book for students of optics, presenting the conclusion of the Tanqih without the proofs or experiments. He completed the writing of this book in 708 H.E. (1309 A.D.).
See also
Notes
- ↑ "Archived copy". Archived from the original on 2010-11-27. Retrieved 2010-04-21.
{{cite web}}
: CS1 maint: archived copy as title (link) - ↑ Library of the Madrasa Ali Shahid Mutahhari, Tehran: MS 554
- ↑ Tanqih al-Manazir, autograph manuscript, Adilnor Collection, Sweden.
- ↑ Library of the Madrasa Ali Shahid Mutahhari, Tehran: MS 554
- ↑ Ahmad Fuad Basha, Ahammiyat al-Makhtutat al-Ilmiyyah al-Sharihah (Kitab Tanqih al-Manazir Namuzajan)
- ↑ Sameen Ahmed Khan, "Arab Origins of the Discovery of the Refraction of Light", in Optics and Photonics News, October 2007, pp. 22–23
- ↑ Leaman, Oliver (2015). The biographical encyclopedia of Islamic philosophy. London: Bloomsbury Academic. p. 188. ISBN 9781472569455.
...of the Persian mathematician and astronomer, Kamal al-Din al-Farasi (d. 1320)...
- ↑ Hamilton Alexander Rosskeen Gibb (1991). The Encyclopaedia of Islam: MAHK-MID, Volume 6. Brill. p. 377. ISBN 9789004081123.
Towards the end of the 13th century, the Persian Kamal al-Dm al-FarisT...
- ↑ Ben-Menahem, Ari (2009). Historical Encyclopedia of Natural and Mathematical Sciences (1st ed.). Berlin: Springer. p. 1922. ISBN 978-3-540-68831-0.
Persian scholar Kamal al-Din al-Farisi
- ↑ "OPTICS – Encyclopaedia Iranica". www.iranicaonline.org.
- ↑ Nader El-Bizri, 'Ibn al-Haytham et le problème de la couleur', Oriens-Occidens: Cahiers du centre d'histoire des sciences et des philosophies arabes et médiévales, C.N.R.S. Vol. 7 (2009), pp. 201–226; see also: Nader El-Bizri, Grosseteste’s Meteorological Optics: Explications of the Phenomenon of the Rainbow after Ibn al-Haytham', in Robert Grosseteste and the Pursuit of Religious and Scientific Knowledge in the Middle Ages, eds. J. Cunningham and M. Hocknull (Dordrecht: Springer, 2016), pp. 21-39 .
- ↑ O'Connor, J. J.; Robertson, E. F. (November 1999). "Kamal al-Din Abu'l Hasan Muhammad Al-Farisi". University of St. Andrews. Retrieved 2007-06-07.
- ↑ Nader El-Bizri, "Ibn al-Haytham", in Medieval Science, Technology, and Medicine: An Encyclopedia, eds. Thomas F. Glick, Steven J. Livesey, and Faith Wallis (New York — London: Routledge, 2005), pp. 237–240.
- ↑ Nader El-Bizri, "Optics", in Medieval Islamic Civilization: An Encyclopedia, ed. Josef W. Meri (New York – London: Routledge, 2005), Vol. II, pp. 578–580
- ↑ Nader El-Bizri, "Al-Farisi, Kamal al-Din," in The Biographical Encyclopaedia of Islamic Philosophy, ed. Oliver Leaman (London — New York: Thoemmes Continuum, 2006), Vol. I, pp. 131–135
- ↑ Nader El-Bizri, "Ibn al-Haytham, al-Hasan", in The Biographical Encyclopaedia of Islamic Philosophy, ed. Oliver Leaman (London — New York: Thoemmes Continuum, 2006), Vol. I, pp. 248–255.
- ↑ Kirchner, E. (2013). "Color theory and color order in medieval Islam: A review". Color Research & Application. 40 (1): 5–16. doi:10.1002/col.21861.
- ↑ Smithson, H.E.; Dinkova-Bruun, G.; Gasper, G.E.M.; Huxtable, M.; McLeish, T.C.B.; Panti, C. (2012). "A three-dimensional color space from the 13th century". J. Opt. Soc. Am. A. 29 (2): A346–A352. doi:10.1364/josaa.29.00A346. PMC 3287286. PMID 22330399.
- ↑ A Historical Survey of the Fundamental Theorem of Arithmetic "One could say that Euclid takes the first step on the way of to the existence of prime factorization, and al-Farisi takes the final step by actually proving the existence of a finite prime factorisation in his first proposition"
- ↑ Rashed, Roshdi (2002-09-11). Encyclopedia of the History of Arabic Science. Routledge. p. 385. ISBN 9781134977246.
The famous physicist and mathematician Kamal al-Din al-Farisi compiled a paper in which he set out deliberately to prove the theorem of Ibn Qurra in an algebraic way. This forced him to an understanding of the first arithmetical functions and to a full preparation which led him to state for the first time the fundamental theorem of arithmetic.
- ↑ Tanqih al-Manazir, Farisi's Autograph manuscript, dated Ramadan 708 H.E./1309 A.D., Adilnor Collection.
- ↑ M. Naẓīf, al-Ḥasan b. al-Hayṯam, 2 vols., Cairo, 1942–43.
- ↑ E. Wiedemann, “Eine Zeichnung des Auges, ”Zentralblatt für Augenheilkunde 34, 1910a
Further reading
- A.G. Agargün and C.R. Fletcher, "al-Farisi and the Fundamental Theorem of Arithmetic", Historia Mathematica, 21 (1994), 162–173.
- M. Naẓīf, al-Ḥasan b. al-Hayṯam, 2 vols., Cairo, 1942–43.
- Roshdi Rashed, The Development of Arabic Mathematics: Between Arithmetic and Algebra (London, 1994).
- Roshdi Rashed, Entre arithmétique et algèbre: Recherches sur l'histoire des mathématiques arabes (Paris, 1984).
- Roshdi Rashed, "Materials for the Study of the History of Amicable Numbers and Combinatorial Analysis (Arabic)", J. Hist. Arabic Sci., 6 (1982), 278–209.
- Roshdi Rashed, "Nombres amiables, parties aliquotes et nombres figurés aux XIIIème et XIVème siècles", Archive for History of Exact Sciences, 28 (1983), 107–147.
- Roshdi Rashed, "Le modèle de la sphère transparente et l'explication de l'arc-en-ciel : Ibn al-Haytham – al-Farisi", Revue d'histoire des sciences, 22 (1970), 109–140.
- Moustafa Mawaldi, l' Algèbre de Kamal al-Din al-Farisi, présentée par Moustafa Mawaldi sous la direction de Monsieur le Professeur Roshdi Rashed. 1989, Université de la Sorbonne Nouvelle, Paris.
- Nader El-Bizri, 'Ibn al-Haytham et le problème de la couleur', Oriens-Occidens: Cahiers du centre d'histoire des sciences et des philosophies arabes et médiévales, C.N.R.S. 7 (2009), 201–226.
- Nader El-Bizri, 'Grosseteste's Meteorological Optics: Explications of the Phenomenon of the Rainbow after Ibn al-Haytham', in Robert Grosseteste and the Pursuit of Religious and Scientific Knowledge in the Middle Ages, eds. J. Cunningham and M. Hocknull (Dordrecht: Springer, 2016), 21-39
- E. Wiedemann, "Eine Zeichnung des Auges, Zentralblatt für Augenheilkunde, 34 (1910).
- Tanqīḥ al-manāẓer, MS Istanbul, Topkapı Kütüphanesi, Ahmet III 3340 (copied at Nīšāpūr, 15 Šaʿbān 716/1316)
- ed. as Ketāb Tanqīḥ al-manāẓer le-ḏawī al-abṣār wa’l-baṣāʾer, 2 vols, Hyderabad (Deccan), 1347–48/1928–30 (this edition did not use the Topkapı manuscript and contains errors in both text and diagrams).