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Francesco Maurolico  
  
2973   03:02 مساءاً   date: 22-10-2015
Author : A Masotti
Book or Source : Biography in Dictionary of Scientific Biography
Page and Part : ...


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Date: 25-10-2015 1414
Date: 25-10-2015 1365
Date: 22-10-2015 2045

Born: 16 September 1494 in Messina, Kingdom of Sicily (now Italy)
Died: 22 July 1575 in Messina, Kingdom of Sicily (now Italy)

 

Francesco Maurolico's name is Greek and is transcribed in a variety of different ways in addition to 'Francesco Maurolico' which is the most common. His first name is sometimes given as Francisco while other forms of his family name are Maurolyco, Maruli or Marulli. He used a Latin form of his name in his publications, giving again different forms: Maurolycus, Maurolicus or Maurolycius. His family were originally Greek but had fled to Messina, in Sicily, to escape from Turkish invasions of their homeland, so their first language was Greek. Francesco's father, Antonio Maurolico, had fled from Constantinople to Messina where he was tutored by the Greek scholar and grammarian Constantine Lascaris who had also fled from Constantinople, settling in Messina in 1466. Antonio became a physician and then Master of the Messina Mint (Sicily minted its own currency at this time). He married Penuccia and they had seven sons: Girolamo, Gio-Saluo, Silvestro, Matteo, Francesco, Gio-Pietro, and Giacomo, and one daughter Laurea. The family were well-off owning two homes in and around Messina, a town house and a villa outside the city. Much of Francesco's education came from his mother, described as a wise and noble women, and his father, who taught him Greek, mathematics and astronomy. However, he also learned much from Francesco Faraone, a priest in Messina, who taught him grammar and rhetoric. His education gave him the critical approach of the humanist Renaissance scholars. Thus Maurolico would believe in approaching problems using his intellect, and using his own practical experience.

Influenced by his upbringing he entered the Church and was ordained a priest in 1521. However, disease spread through Messina and many died during the next few years, including Maurolico's father, two of his brothers and his sister. Maurolico left the city for a while to escape from the deadly illness. Around 1525 he made a visit to Rome and spent some time there. After his father's death, Maurolico inherited sufficient wealth to allow him to live without working for several years. Although he was not the eldest of his parent's children, his older brothers died before his father so he inherited. Maurolico was able to concentrate on his scholarly pursuits during these years and he produced significant contributions in a broad range of different topics although his best work was done on mathematics. Certainly he was not a wealthy man and required patrons to be able to publish his work and several leading men of Messina appear to have put up funds since their names appear in dedications in Maurolico's work. For example, Grammatica rudimenta, which he published in 1528, was dedicated to Ettore Pignatelli. In the same year he was requested by the governor of Messina, Giovanni Marullo, to lecture on The Sphere of Sacrobosco and Euclid's Elements. In fact the governor attended Maurolico's lectures on these topics. Perhaps as a result of these lectures, Maurolico wrote up his rearrangement and translation of part of Euclid's Elements and completed the task on 9 July 1532. It was on that day that he signed the dedication but it remained unpublished for 43 years, only being printed and published in 1575 as part of Opuscula Mathematica which we say more about below. J-P Sutto [50] discusses Maurolico's work on Euclid:-

In his compendium of Euclid's 'Elements', Francesco Maurolico modifies the theory of proportions. The Sicilian concentrates on equalities of ratios of Book 5 and tries to avoid handling of equimultiples. He concentrates on isolating 'named' ratios - of a number to a number - and he constantly compares ratios and named ratios.

Another of Maurolico's patrons was Giovanni Ventimiglia, 6th Marchese di Geraci, Prince of Castelbuono (a town in the province of Palermo, Sicily), and Governor of Messina. He had married Dona Isabella de Montcada dei Conti di Aitona in 1527 and their son Simone Ventimiglia (1528-60) was also a patron of Maurolico who lived at their estate for long periods during 1547-50. He was able to use the tower of their Pollina Castle from which to make astronomical observations. In 1550, he became a Benedictine and Simone Ventimiglia conferred on him the Abbey of Santa Maria del Parto (today called the Santuario di San Guglielmo) in Castelbuono. At this time the Benedictine Order was one of the two main monastic orders which formed the basis of Christian life in Sicily, the other being the Franciscans. As a Benedictine, Maurolico would have a life of simplicity, a feature that was much loved by the people. However in a 1543 publication he describes events which took place in 1540 (see for example [29]):-

The insolence of the Spanish soldiers returning from the capture of Castelnuovo gave us a winter harsher than usual, so that the barbarians would not incur such consideration from us; among which tumults even I (who would not laugh?), having put down my ruler and compass, was driven to take up arms for a time. For the example of my Archimedes warned me that in such danger I should not be devoting myself to drawing lines and circles.

After several years in the Abbey in Castelbuono, Maurolico returned to Messina where he was appointed as an abbot in the cathedral. In fact he lived his whole life in Sicily except for short periods in Rome and Naples. In Messina, St Ignatius had founded the first ever Jesuit college in 1548. This later became the Studium Generale and is now the University of Messina. Maurolico was involved in the mathematical curriculum that was set up in the College being appointed as professor of mathematics in 1569. It is interesting to note that his contract specified that he was required to teach the theory of music as a branch of mathematics. He also served as head of the mint in Messina and he was in charge of the fortifications of Messina (in collaboration with Antonio Ferramolino worked for the Spanish crown in Sicily for during years 1530-50), largely dominated by the impressive San Salvatore fort, a task he was given by Charles V's viceroy Giovanni de Vega who was President of the Sicilian Parliament in 1546. Maurolico was also mathematics tutor to one of Giovanni de Vega's two sons. He was involved in designing churches in the city, and the building of two famous fountains, the Fontana di Orione in front of the cathedral and the Fontana del Nettuno designed by G Montorsoli. In addition he was appointed to write a history of Sicily which was published under the title Sicanicarum reum compendium in 1562. Ten years earlier he had received a salary for two years from the Senate of Messina to allow him to work on this History as well as his mathematics texts.

Maurolico wrote important books on Greek mathematics, restored many ancient works from scant information and translated many ancient texts such as those by Theodosius, Menelaus, Autolycus, Euclid, Apollonius and Archimedes. Some appeared in Theodosii Sphaericorum Elementorum Libri iii which he published in 1558. The work contains nine separate items by Maurolico, some translations, some commentaries, and a work of his own De Sphaera Sermo. The Theodosii also contains a table of secants and, although Delambre credited him with the first use of this function, it had appeared earlier in the work of Copernicus. However, Maurolico does prove secant = radius / cosine and secant = (radius × tangent) / sine and gives a table of secants from 0° to 45°. Maurolico also worked on geometry, the theory of numbers (L E Dickson notes some of his results), optics, conics and mechanics, writing important books on these topics which we will discuss in more detail below. Maurolico completed a restoration of books V and VI of Apollonius's Conics in 1547 working from the scant details that Apollonius gives in the Preface to the work. These were not published until 1654, about 80 years after his death, as Emendatio et restitutio conicorum Apollonii Pergaei. Both Guglielmo Libri and Gino Loria claimed that this achievement alone showed that Maurolico was a genius.

In 1535 he wrote Cosmographia in the form of three dialogues, which was published in 1543. In it he states that he completed the book:-

... on Thursday 21 October 1535, the day that the Emperor Charles V came to Messina on his return from the African campaign.

Maurolico gave methods for measuring the Earth in Cosmographia which were later used by Jean Picard in measuring the meridian in 1670. However, he believed that the Earth is the centre of the universe and he dismisses Copernicus's sun centred universe without mentioning him by name (see [14]):-

And it would not be necessary for astronomers to refute any other principles as regards the earth, if diversity of opinion and human fickleness had not so grown that it is doubted whether one may perhaps believe and say the earth turns on its axis whilst the heavens stay at rest.

Later, however, he made a much more personal attack on Copernicus which we quote below.

Maurolico made astronomical observations, in particular he observed the supernova which appeared in Cassiopeia in 1572 now known as 'Tycho's supernova'. Tycho Brahe published details of his observations in 1574. Some details of Maurolico's observations were published by Christopher Clavius but full details of Maurolico's observations were never published and only rediscovered in 1960 by C Doris Hellman. The manuscript that she discovered was dated 6 November 1572, five days before Brahe made his observations. Perhaps there is an argument for renaming 'Tycho's supernova' as 'Maurolico's supernova'. This would, if nothing else, give this important mathematician some wider recognition which he so clearly deserves.

By 1569 Maurolico was making considerable efforts to have a collection of his unpublished work printed. He wrote to Francisco Borgia, general of the Jesuit Order, on 16 April 1569 asking him to assist in publishing:-

... certain compendia, in which I have treated all the essentials compactly and inserted most of the topics omitted, ignored or overlooked by others.

The work, Opuscula Mathematica, was dedicated to the governor of Messina who had agreed to help with the expenses. Maurolico also wrote to Christopher Clavius:-

... requesting his aid in editing or correcting my essays.

The general of the Jesuit Order replied in a letter of 8 July 1569 saying that:-

... steps will be taken to see that the book is sent to Venice and recommended to the rector of our college, so that he may turn it over to a suitable printer for publication.

In fact the book went to the bookseller Giovanni Comisino in Venice but over five years later the work had still not been published and the general of the Jesuit Order (the successor to the one Maurolico wrote to in 1569) wrote to the Venetian governor:-

... please find out from the bookseller Giovanni Comisino what he has done about the printing of Abbot Maurolico's books, because Sicily asks us about them.

Christopher Clavius visited Maurolico in 1574 and Maurolico gave him various manuscripts of his optical works under the title Photismi de lumine, et umbra. These treatises were mostly written in 1554 and Clavius promised to have them published in Rome. One treatise discusses the rainbow about which Maurolico writes [10]:-

But how does it happen, you ask, that the altitude of the rainbow is not exactly 45°, but a little less as ascertained by observation? I do not know how to answer this or what reason I may offer, unless it be that the falling drops are somewhat elongated or somewhat flattened, and thus, varying from the spherical form, change the angle of reflection and hence also the straightness of the ray which in the case of a perfect sphere comes back at an angle of forty-five degrees.

Another treatise in Photismi de lumine, et umbra, called De conspiciliis, discusses lenses [23]:-

Having recognized that the humour crystallinus, assumed to be the seat of the visual power of the eye, is in fact a bi-convex lens, Maurolico included in this treatise a discussion of the working of the eye.

By November 1574 the Opuscula Mathematica was in press but there must have been a further delay since when the work was published it did not contain Maurolico's dedication to the governor of Messina but rather a dedication written by the publisher dated 26 July 1575, four days after Maurolico's death. TheOpuscula Mathematica contains seven of Maurolico's treatises including De instrumentis astronomicis on the theory and use of the principal astronomical instruments. Another of the treatises is De Sphaera Liber Unus and, in a postscript to this work, Maurolico addresses the reader (see [14]):-

I wrote the foregoing work, gentle reader, not so that you would peruse only my treatment and ignore all the others, but so that you would understand the others better because of my discussion, and from it learn what was omitted by the others. I have no doubt that on the basis of my elementary exposition you will read more circumspectly, and judge more perspicaciously, what you see in Sacrobosco, Robert Grosseteste or Campanus. Grosseteste did not put an end to the reading of Sacrobosco, nor did Campanus put an end to the reading of Grosseteste, as perhaps he thought he did. In like manner Peurbach's 'Theoricae', although extremely accurate and worked out in accordance with the Ptolemaic system, could not completely eliminate the teachings of Al-Bitruji (Alpetragius) and the ravings of Gerard of Cremona. Georg Peurbach and Regiomontanus contented themselves with warning their readers to learn to the best of their ability what to reject and what to accept. But not even Atlas, who supports the heavens, despite all his vigour would have the strength to correct every mistake that has been made and to lead everyone's mind to the path of truth. There is toleration even for Nicholas Copernicus, who maintained that the sun is still and the earth has a circular motion; and yet he deserves a whip or a scourge rather than a refutation. Let us therefore go on to the remaining topics, lest we waste our time for nothing.

Domenico Scinà writes in 1808 (see the new edition of his Elogio di Francesco Maurolico [5]):-

Nobody can reasonably find fault with Maurolico and chide him for not having sided with Copernicus. I do not thereby intend to excuse our Francesco. On the contrary I readily admit that he did not know how, and was unable, to save himself from the common contagion of his times.

A companion volume Arithmeticorum libri duo, written in 1557, was published at the same time as the Opuscula Mathematica. This work on number theory contains a proof by induction that is claimed to be the first genuine such proof [15]:-

Maurolycus in Book I of his arithmetic begins with the definitions of different kinds of numbers, namely, even, odd, triangular, square, numeri parte altera longiores, etc. By definition the nth triangular number is the sum of the integers from 1 to n inclusive and the nth numerus parte altera longior is n(n -1).

Defining the nth square number as n2 and the nth odd number as 2n - 1, Maurolico goes on to prove results such as:

Proposition VI. The nth integer plus the preceding integer equals the nth odd number.

Proposition VIII. The nth triangular number doubled equals the following numerus parte altera longior.

Proposition X. The nth numerus parte altera longior plus n equals the nth square number.

Proposition XI. The nth triangular number plus the preceding triangular number equals the nth square number.

Proposition XIII. The nth square number plus the following odd number equals the following square number.

Proposition XV. The sum of the first n odd integers is equal to the nth square number.

In the proof of this last Proposition, Maurolico makes clear use induction. After proving the first few cases he uses Proposition XIII to prove the inductive step from n to n + 1.

We have concentrated on Maurolico's mathematical work but Caterina Pirina writes [37]:-

... Maurolico's interests were not restricted to science. A list of his numerous writings appears in the "Index Lucubrationum" at the end of the volume of his 'Opuscula Mathematica' of 1575. It includes humanistic works, two libelli of carmina and epigrams, and his Latin verse translation from the Greek, Poemata Phocylidis et Pythagorae Moralia, as well as six books of Diodorus Siculus and six books of the elements of grammar.

In 1613 further mathematical works by Maurolico were published by his nephew Francesco, Barone della Foresta, and his brother Silvestro. They had inherited several of Maurolico's unpublished works which they published together with the biography Vita dell'Abbate del Parto D Francesco Maurolico written by Francesco. Perhaps the most significant of Maurolico's works to be published at this time was Problemata mechanica originally completed in 1569. W R Laird writes about this work in [30]:-

The first thinker to attempt to reconcile Archimedean statics and the 'Mechanical Problems' was the mathematician and abbot Francesco Maurolico ... Although Maurolico preferred to ground his mechanics in Archimedean statics, he nevertheless recognized the application of mechanics beyond conditions of equilibrium, to the motion of heavy bodies - the moving of weights with machines and the harnessing of impetus. His notion of the primacy of Archimedean statics in mechanics came to be shared by all the mathematical practitioners who followed.

In 1685 Maurolico's De momentis aequalibus, completed in 1548, was published in which he investigated the centre of gravity of a paraboloid (see [36] for more details). In 1876 Federico Napoli published further Maurolico manuscripts including:

Demonstratio algebrae, which is an elementary text looking at quadratic equations and problems whose solution reduces to solving a quadratic;

Geometricarum questionum (Books 1 and 2), which is a work on trigonometry and solid geometry but also discusses the method for measuring the Earth that Maurolico proposed earlier in Cosmographia;

Brevis demonstratio centri in parabola, a text dated 1565, which examines mechanics problems of the type considered in his commentary on Archimedes. In this work he determines the centre of gravity of a segment of a paraboloid of revolution bounded by a plane perpendicular to the axis.

We should not think that all these posthumous publications complete the printing of Maurolico's treatises. For example, in 1995 in [54], Roberta Tassora gives the previously unpublished text of Maurolico's reconstruction of the treatise De sectione cylindri originally written by Serenus of Antinoeia. Maurolico completed this work in 1534.


 

  1. A Masotti, Biography in Dictionary of Scientific Biography (New York 1970-1990). 
    http://www.encyclopedia.com/doc/1G2-2830902874.html

Books:

  1. R Bellè, L'ottica di Francesco Maurolico (Università di Pisa, Tesi di laurea, 2000-01).
  2. Commemorazione del IV centenario di Francesco Maurolico MDCCCXCIV (Messina, 1896).
  3. H Crew (trs.), The Photismi de lumine of Maurolycus. A chapter in late medieval optics (Macmillan, New York, 1940).
  4. D Scinà, Elogio di Francesco Maurolico (Salvatore Sciascia Editore, Rome, 1994).
  5. J-P Sutto, Francesco Maurolico, mathématicien italien de la Renaissance (1494-1575) (Thèse de doctorat, Université Paris VII-Denis Diderot, 1998).

Articles:

  1. F Amodeo, Il trattato delle coniche di Francesco Maurolico, Bibliotheca Mathematica IX (1908), 123-138.
  2. R Bellè, The Jesuits and the publication of Francesco Maurolico's works on optics (Italian), Boll. Stor. Sci. Mat. 26 (2) (2006), 211-243.
  3. D Bessot, Ellipse conique et cylindrique chez Francesco Maurolico, in Histoire et épistemologie dans l'éducation mathématique 2 (Université Catholique de Louvain, 2001), 147.
  4. C B Boyer, Descartes and the Radius of the Rainbow, Isis 43 (2) (1952), 95-98.
  5. A Brigaglia, La ricostruzione dei libri V e VI delle Coniche da parte di F Maurolico, Boll. Storia Sci. Mat. 17 (2) (1997), 267-307.
  6. A Brigaglia, Maurolico's reconstruction of the fifth and sixth book of Appolonius's Conics, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 47-57.
  7. A Brigaglia, Maurolico e le matematiche del secolo XVI, in C Dollo (ed.), Filosofia e scienze nella Sicilia dei secoli XVI e XVII 1 (Catania 1996), 15-27.
  8. W Burke-Gaffney, Celestial Mechanics in the Sixteenth Century, The Scientific Monthly 44 (2) (1937), 150-156.
  9. W H Bussey, The Origin of Mathematical Induction, Amer. Math. Monthly 24 (5) (1917), 199-207.
  10. J Cassinet, The first arithmetic book of Francisco Maurolico, written in 1557 and printed in 1575: a step towards a theory of numbers, in C Hay (ed.), Mathematics from manuscript to print 1300-1600 (Oxford, 1988), 162-179.
  11. M Clagett, The works of Francesco Maurolico, Physis - Riv. Internaz. Storia Sci. 16 (2) (1974), 149-198.
  12. M Clagett, Francesco Maurolico's use of Medieval archimedean texts: the 'De sphaera et cylindro', in Science and History: Studies in honour of Edward Rosen (Ossolineum, 1978), 37-52.
  13. I B Cohen, Review: The Photismi de lumine of Maurolycus translated by H Crew, Isis 33 (2) (1941), 251-253.
  14. P d'Alessandro and P D Napolitani, I primi contatti fra Maurolico et Clavio: una nuova edizione della lettera di Francesco Maurolico a Francisco Borgia, Nuncius Ann. Storia Sci. 16 (2) (2001), 520-522.
  15. L De Marchi, Una lettera inedita del Maurolico a proposito della battaglia di Lepanto, Rendiconti dell'Istituto Lombardo di scienze, lettere ed arti (2) 16 (1883), 466-467.
  16. C Dollo, Astrologia e astronomia in Sicilia: da Francesco Maurolico a G B Hodierna, 1535-1660, Giornale Critico della Filosofia Italiana 6 (3) (1986), 366-398.
  17. T Frangenberg, Perspectivist Aristotelianism: Three Case-Studies of Cinquecento Visual Theory, Journal of the Warburg and Courtauld Institutes 54 (1991), 137-158.
  18. A C Garibaldi, La doctrine des sections du cône appliquée à la gnomonique chez F Maurolico, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 93-98.
  19. R Gatto, Some aspects of Maurolico's optics, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 83-92.
  20. V Gavagna and R Moscheo, Francesco Maurolico's Theonis datorum libelli duo (Italian), Boll. Stor. Sci. Mat. 22 (2) (2002), 267-348.
  21. E Giusti, Maurolico et Archimède: sources et datation du premier livre du De momentis aequalibus, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 33-40.
  22. C D Hellman, Maurolyco's Lost Essay on the New Star of 1572, Isis 51 (1960), 322-336.
  23. W R Laird, Archimedes among the Humanists, Isis 82 (4) (1991), 628-638.
  24. W R Laird, The Scope of Renaissance Mechanics, Osiris (2) 2 (1986), 43-68.
  25. G Micheli, I 'Problemata Mechanica' di Francesco Maurolico, in C Dollo (ed.), Filosofia e scienze nella Sicilia dei secoli XVI e XVII 1 (Catania 1996), 29-37.
  26. R Moscheo, Greek heritage and the scientific work of Francesco Maurolico, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 15-22.
  27. F Napoli, Intorno alla vita ed ai lavoeri di Francesco Maurolico, Bullettino di bibliografia a di storia delle scienze mathematiche e fisiche 9 (1876), 1-121.
  28. P D Napolitani, Le edizioni dei Classici: Commandino e Maurolico, in W Moretti and L Pepe (eds.), Torquato Tasso and the University, Ferrara, 1995 (Olschki, Florence, 1997), 119-141.
  29. P D Napolitani, A l'aube de la révolution scientifique: de Galilée à Maurolico, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 9-13.
  30. P D Napolitani and J-P Sutto, Francesco Maurolico et le centre de gravité du parabolide, SCIAMVS 2 (2001), 187-250.
  31. C Pirina, Michelangelo and the Music and Mathematics of His Time, The Art Bulletin 67 (3) (1985), 368-382.
  32. S Pugliatti, Le Musicae Traditiones di Francesco Maurolico, Atti della Accademia Peloritana dei Pericolanti, classe di lettere, filosofia e belle arti 48 (1951-1967), 313-398.
  33. V Ronchi, Il Keplero conosceva l'ottica del Maurolico?, Atti della Fondazione Giorgio Ronchi 37 (1982), 153-197.
  34. V Ronchi, Ancora a proposito dei 'Photismi de lumine et umbra' dell'Abate Maurolico, Atti della Fondazione Giorgio Ronchi 37 (1982), 581-585.
  35. P L Rose, The Works of Francesco Maurolico, Physics 16 (1974), 149-198.
  36. E Rosen, The Date of Maurolico's Death, Scripta Mathematica 22 (1956), 285-286.
  37. E Rosen, Maurolico's Attitude toward Copernicus, Proc. Amer. Philos. Soc. 101 (2) (1957), 177-194.
  38. E Rosen, The Editions of Maurolyco's Mathematical Works, Scripta Mathematica 24 (1957), 59-76.
  39. E Rosen, The Title of Maurolico's 'Photismi', American Journal of Physics 25 (1957), 226-228.
  40. E Rosen, Maurolico was an Abbott, Archives internationales d'histoire des sciences 9 (1956), 349-350.
  41. E Rosen, Was Maurolico's essay on the nova of 1572 printed, Isis 48 (2) (1957), 171-175.
  42. K Saito, Quelques observations sur l'édition des 'Coniques' d'Apollonius de Francesco Maurolico, Boll. Storia Sci. Mat. 14 (2) (1994), 239-258.
  43. K Saito, Francesco Maurolico's edition of the Conics, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 41-46.
  44. J-P Sutto, Le compendium du 5e livre des Éléments d'Euclide de Francesco Maurolico, Rev. Histoire Math. 6 (1) (2000), 59-94.
  45. J-P Sutto, Les arithmétiques de Francesco Maurolico, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 73-81.
  46. A-K Taha and P Pinel, Sur les sources de la version de Francesco Maurolico des Sphériques de Ménélaos, Boll. Storia Sci. Mat. 17 (2) (1997), 149-198.
  47. A-K Taha and P Pinel, La version de Maurolico des Sphériques de Ménelaos et ses sources, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 59-72.
  48. R Tassora, The 'Sereni cylindricorum libelli duo' of Francesco Maurolico and an unknown treatise on conic sections (Italian), Boll. Storia Sci. Mat. 15 (2) (1995), 135-264.
  49. R Tassora, La formation du jeune Maurolico et les auteurs classiques, in Medieval and classical traditions and the renaissance of physico-mathematical sciences in the 16th century (Brepols, Turnhout, 2001), 23-32.
  50. T M Tonietti, The mathematical contributions of Francesco Maurolico to the theory of music of the 16th century (the problems of a manuscript), Centaurus 48 (3) (2006), 149-200.
  51. A Tripodi, Francesco Maurolico (Italian), Giorn. Mat. Battaglini (6) 2 (92) (1964), 126-131.
  52. G Vacca, Maurolycus, the first discoverer of the principle of mathematical induction, Bull. Amer. Math. Soc. 16 (2) (1909), 70-73.

 




الجبر أحد الفروع الرئيسية في الرياضيات، حيث إن التمكن من الرياضيات يعتمد على الفهم السليم للجبر. ويستخدم المهندسون والعلماء الجبر يومياً، وتعول المشاريع التجارية والصناعية على الجبر لحل الكثير من المعضلات التي تتعرض لها. ونظراً لأهمية الجبر في الحياة العصرية فإنه يدرّس في المدارس والجامعات في جميع أنحاء العالم. ويُعجب الكثير من الدارسين للجبر بقدرته وفائدته الكبيرتين، إذ باستخدام الجبر يمكن للمرء أن يحل كثيرًا من المسائل التي يتعذر حلها باستخدام الحساب فقط.وجاء اسمه من كتاب عالم الرياضيات والفلك والرحالة محمد بن موسى الخورازمي.


يعتبر علم المثلثات Trigonometry علماً عربياً ، فرياضيو العرب فضلوا علم المثلثات عن علم الفلك كأنهما علمين متداخلين ، ونظموه تنظيماً فيه لكثير من الدقة ، وقد كان اليونان يستعملون وتر CORDE ضعف القوسي قياس الزوايا ، فاستعاض رياضيو العرب عن الوتر بالجيب SINUS فأنت هذه الاستعاضة إلى تسهيل كثير من الاعمال الرياضية.

تعتبر المعادلات التفاضلية خير وسيلة لوصف معظم المـسائل الهندسـية والرياضـية والعلمية على حد سواء، إذ يتضح ذلك جليا في وصف عمليات انتقال الحرارة، جريان الموائـع، الحركة الموجية، الدوائر الإلكترونية فضلاً عن استخدامها في مسائل الهياكل الإنشائية والوصف الرياضي للتفاعلات الكيميائية.
ففي في الرياضيات, يطلق اسم المعادلات التفاضلية على المعادلات التي تحوي مشتقات و تفاضلات لبعض الدوال الرياضية و تظهر فيها بشكل متغيرات المعادلة . و يكون الهدف من حل هذه المعادلات هو إيجاد هذه الدوال الرياضية التي تحقق مشتقات هذه المعادلات.