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Greek mathematics

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An illustration of Euclid's proof of the Pythagorean theorem

Greek mathematics refers to mathematics texts and ideas stemming from the Archaic through the Hellenistic and Roman periods, mostly from the 5th century BC to the 6th century AD, around the shores of the Mediterranean.[1][2] Greek mathematicians lived in cities spread over the entire region, from Anatolia to Italy and North Africa, but were united by Greek culture and the Greek language.[3] The development of mathematics as a theoretical discipline and the use of deductive reasoning in proofs is an important difference between Greek mathematics and those of preceding civilizations.[4][5]

Origins and etymology

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Greek mathēmatikē ("mathematics") derives from the Ancient Greek: μάθημα, romanizedmáthēma, Attic Greek: [má.tʰɛː.ma] Koinē Greek: [ˈma.θi.ma], from the verb manthanein, "to learn". Strictly speaking, a máthēma could be any branch of learning, or anything learnt; however, since antiquity certain mathēmata (mainly arithmetic, geometry, astronomy, and harmonics) were granted special status.[6][7]

The origins of Greek mathematics are not well documented.[8][9] The earliest advanced civilizations in Greece and Europe were the Minoan and later Mycenaean civilizations, both of which flourished during the 2nd millennium BC. While these civilizations possessed writing and were capable of advanced engineering, including four-story palaces with drainage and beehive tombs, they left behind no mathematical documents.

Though no direct evidence is available, it is generally thought that the neighboring Babylonian and Egyptian civilizations had an influence on the younger Greek tradition.[10][11][8] Unlike the flourishing of Greek literature in the span of 800 to 600 BC, not much is known about Greek mathematics in this early period—nearly all of the information was passed down through later authors, beginning in the mid-4th century BC.[12][13]

Archaic and Classical periods

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Pythagoras with a tablet of ratios, detail from The School of Athens by Raphael (1509)

Greek mathematics allegedly began with Thales of Miletus (c. 624–548 BC). Very little is known about his life, although it is generally agreed that he was one of the Seven Wise Men of Greece. According to Proclus, he traveled to Babylon from where he learned mathematics and other subjects, coming up with the proof of what is now called Thales' Theorem.[14][15]

An equally enigmatic figure is Pythagoras of Samos (c. 580–500 BC), who supposedly visited Egypt and Babylon,[13][16] and ultimately settled in Croton, Magna Graecia, where he started a kind of brotherhood. Pythagoreans supposedly believed that "all is number" and were keen in looking for mathematical relations between numbers and things.[17] Pythagoras himself was given credit for many later discoveries, including the construction of the five regular solids. However, Aristotle refused to attribute anything specifically to Pythagoras and only discussed the work of the Pythagoreans as a group.[18][19]

Almost half of the material in Euclid's Elements is customarily attributed to the Pythagoreans, including the discovery of irrationals, attributed to Hippasus (c. 530–450 BC) and Theodorus (fl. 450 BC).[20] The greatest mathematician associated with the group, however, may have been Archytas (c. 435-360 BC), who solved the problem of doubling the cube, identified the harmonic mean, and possibly contributed to optics and mechanics.[20][21] Other mathematicians active in this period, not fully affiliated with any school, include Hippocrates of Chios (c. 470–410 BC), Theaetetus (c. 417–369 BC), and Eudoxus (c. 408–355 BC).

Greek mathematics also drew the attention of philosophers during the Classical period. Plato (c. 428–348 BC), the founder of the Platonic Academy, mentions mathematics in several of his dialogues.[22] While not considered a mathematician, Plato seems to have been influenced by Pythagorean ideas about number and believed that the elements of matter could be broken down into geometric solids.[23] He also believed that geometrical proportions bound the cosmos together rather than physical or mechanical forces.[24] Aristotle (c. 384–322 BC), the founder of the Peripatetic school, often used mathematics to illustrate many of his theories, as when he used geometry in his theory of the rainbow and the theory of proportions in his analysis of motion.[24] Much of the knowledge about ancient Greek mathematics in this period is thanks to records referenced by Aristotle in his own works.[13][25]

Hellenistic and Roman periods

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A fragment from Euclid's Elements (c. 300 BC), considered the most influential mathematics textbook of all time[26]

The Hellenistic era began in the late 4th century BC, following Alexander the Great's conquest of the Eastern Mediterranean, Egypt, Mesopotamia, the Iranian plateau, Central Asia, and parts of India, leading to the spread of the Greek language and culture across these regions. Greek became the lingua franca of scholarship throughout the Hellenistic world, and the mathematics of the Classical period merged with Egyptian and Babylonian mathematics to give rise to Hellenistic mathematics.[27][28]

Greek mathematics[a] reached its acme during the Hellenistic and early Roman periods, and much of the work represented by authors such as Euclid (fl. 300 BC), Archimedes (c. 287–212 BC), Apollonius (c. 240–190 BC), Hipparchus (c. 190–120 BC), and Ptolemy (c. 100–170 AD) was of a very advanced level and rarely mastered outside a small circle.[29] Examples of applied mathematics around this time include the construction of analogue computers like the Antikythera mechanism,[30][31] the accurate measurement of the circumference of the Earth by Eratosthenes (276–194 BC), and the mathematical and mechanical works of Heron (c. 10–70 AD).[32]

Several centers of learning appeared during the Hellenistic period, of which the most important one was the Mouseion in Alexandria, Egypt, which attracted scholars from across the Hellenistic world (mostly Greek, but also Egyptian, Jewish, Persian, among others).[33][34] Although few in number, Hellenistic mathematicians actively communicated with each other; publication consisted of passing and copying someone's work among colleagues.[35]

Later mathematicians in the Roman era include Diophantus (c. 214–298 AD), who wrote on polygonal numbers and a work in pre-modern algebra (Arithmetica),[36][37] Pappus of Alexandria (c. 290–350 AD), who compiled many important results in the Collection,[38] Theon of Alexandria (c. 335–405 AD) and his daughter Hypatia (c. 370–415 AD), who edited Ptolemy's Almagest and other works,[39][40] and Eutocius of Ascalon (c. 480–540 AD), who wrote commentaries on treatises by Archimedes and Apollonius.[41] Although none of these mathematicians, save perhaps Diophantus, had notable original works, they are distinguished for their commentaries and expositions. These commentaries have preserved valuable extracts from works which have perished, or historical allusions which, in the absence of original documents, are precious because of their rarity.[42][43]

Most of the mathematical texts written in Greek survived through the copying of manuscripts over the centuries. While some fragments dating from antiquity have been found above all in Egypt, as a rule they do not add anything significant to our knowledge of Greek mathematics preserved in the manuscript tradition.[29]

Achievements

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Greek mathematics constitutes an important period in the history of mathematics: fundamental in respect of geometry and for the idea of formal proof.[44] Greek mathematicians also contributed to number theory, mathematical astronomy, combinatorics, mathematical physics, and, at times, approached ideas close to the integral calculus.[45][46]

Eudoxus of Cnidus developed a theory of proportion that bears resemblance to the modern theory of real numbers using the Dedekind cut, developed by Richard Dedekind, who acknowledged Eudoxus as inspiration.[47][48][49][50]

Euclid, who presumably wrote on optics, astronomy, and harmonics, collected many previous mathematical results and theorems in the Elements, a canon of geometry and elementary number theory for many centuries.[51][52][53] Menelaus, a later geometer and astronomer, wrote a standard work on spherical geometry in the style of the Elements, the Spherics, arguably considered the first treatise in non-Euclidean geometry.[54][55]

Archimedes made use of a technique dependent on a form of proof by contradiction to reach answers to problems with an arbitrary degree of accuracy, while specifying the limits within which the answers lay. Known as the method of exhaustion, Archimedes employed it in several of his works, including an approximation to π (Measurement of the Circle),[56] and a proof that the area enclosed by a parabola and a straight line is 4/3 times the area of a triangle with equal base and height (Quadrature of the Parabola).[57] Archimedes also showed that the number of grains of sand filling the universe was not uncountable, devising his own counting scheme based on the myriad, which denoted 10,000 (The Sand-Reckoner).[58]

The most characteristic product of Greek mathematics may be the theory of conic sections, which was largely developed in the Hellenistic period, starting with the work of Menaechmus and perfected primarily under Apollonius in his work Conics.[59][60][61] The methods employed in these works made no explicit use of algebra, nor trigonometry, the latter appearing around the time of Hipparchus.[62][63]

Ancient Greek mathematics was not limited to theoretical works but was also used in other activities, such as business transactions and in land mensuration, as evidenced by extant texts where computational procedures and practical considerations took more of a central role.[11][64]

Transmission and the manuscript tradition

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Cover of Diophantus' Arithmetica in Latin

Although the earliest Greek mathematical texts that have been found were written after the Hellenistic period, most are considered to be copies of works written during and before the Hellenistic period.[65] The two major sources are

Despite the lack of original manuscripts, the dates for some Greek mathematicians are more certain than the dates of surviving Babylonian or Egyptian sources because a number of overlapping chronologies exist, though many dates remain uncertain.

Netz (2011) has counted 144 ancient authors in the mathematical or exact sciences, from whom only 29 works are extant in Greek: Aristarchus, Autolycus, Philo of Byzantium, Biton, Apollonius, Archimedes, Euclid, Theodosius, Hypsicles, Athenaeus, Geminus, Heron, Apollodorus, Theon of Smyrna, Cleomedes, Nicomachus, Ptolemy, Gaudentius, Anatolius, Aristides Quintilian, Porphyry, Diophantus, Alypius, Damianus, Pappus, Serenus, Theon of Alexandria, Anthemius, and Eutocius.[66]

The following works are extant only in Arabic translations:[67][68]

  • Apollonius, Conics books V to VII
  • Apollonius, Cutting Off of a Ratio
  • Archimedes, Book of Lemmas
  • Archimedes, Construction of the Regular Heptagon
  • Diocles, On Burning Mirrors
  • Diophantus, Arithmetica books IV to VII
  • Euclid, On Divisions of Figures
  • Euclid, On Weights
  • Heron, Catoptrica
  • Heron, Mechanica
  • Menelaus, Sphaerica
  • Pappus, Commentary on Euclid's Elements book X
  • Ptolemy, Optics (extant in Latin from an Arabic translation of the Greek)
  • Ptolemy, Planisphaerium

See also

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References

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Note

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  1. ^ Inclusive of astronomy, harmonics, optics, and mechanics.

Citations

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  1. ^ Sidoli, Nathan (2020). Taub, Liba (ed.). "Ancient Greek Mathematics" (PDF). The Cambridge Companion to Ancient Greek and Roman Science: 190–191. doi:10.1017/9781316136096.010.
  2. ^ Netz, Reviel (2002). "Greek mathematics: A group picture". Science and Mathematics in Ancient Greek Culture. pp. 196–216. Retrieved 2024-03-04.
  3. ^ Boyer, C.B. (1991). A History of Mathematics (2nd ed.). New York: Wiley. p. 48. ISBN 0-471-09763-2.
  4. ^ Knorr, W. (2000). Mathematics. Greek Thought: A Guide to Classical Knowledge: Harvard University Press. pp. 386–413.
  5. ^ Schiefsky, Mark (2012-07-20), "The Creation of Second-Order Knowledge in Ancient Greek Science as a Process in the Globalization of Knowledge", The Globalization of Knowledge in History, MPRL – Studies, Berlin: Max-Planck-Gesellschaft zur Förderung der Wissenschaften, ISBN 978-3-945561-23-2, retrieved 2021-03-27
  6. ^ Heath (1931). "A Manual of Greek Mathematics". Nature. 128 (3235): 5. Bibcode:1931Natur.128..739T. doi:10.1038/128739a0. S2CID 3994109.
  7. ^ Furner, J. (2020). "Classification of the sciences in Greco-Roman antiquity". www.isko.org. Retrieved 2023-01-09.
  8. ^ a b Hodgkin, Luke (2005). "Greeks and origins". A History of Mathematics: From Mesopotamia to Modernity. Oxford University Press. ISBN 978-0-19-852937-8.
  9. ^ Knorr, W. (1981). On the early history of axiomatics: The interaction of mathematics and philosophy in Greek Antiquity. D. Reidel Publishing Co. pp. 145–186. Theory Change, Ancient Axiomatics, and Galileo's Methodology, Vol. 1
  10. ^ Kahn, C. H. (1991). Some remarks on the origins of Greek science and philosophy. Science and Philosophy in Classical Greece: Garland Publishing Inc. pp. 1–10.
  11. ^ a b Høyrup, J. (1990). "Sub-scientific mathematics: Undercurrents and missing links in the mathematical technology of the Hellenistic and Roman world" (PDF) (Unpublished manuscript, written for Aufstieg und Niedergang der römischen Welt).
  12. ^ Zhmud, Leonid (2008-08-22). The Origin of the History of Science in Classical Antiquity. Peripatoi. De Gruyter. pp. 23–44. doi:10.1515/9783110194326. ISBN 978-3-11-019432-6.
  13. ^ a b c Boyer & Merzbach (2011) pp. 40–89.
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  35. ^ Acerbi, F. (2018). Keyser, Paul T; Scarborough, John (eds.). "Hellenistic Mathematics". Oxford Handbook of Science and Medicine in the Classical World. pp. 268–292. doi:10.1093/oxfordhb/9780199734146.013.69. ISBN 978-0-19-973414-6. Retrieved 2021-05-26.
  36. ^ Acerbi, F. (2011). "Completing Diophantus, De polygonis numeris, prop. 5". Historia Mathematica. 38 (4): 548–560. doi:10.1016/j.hm.2011.05.002. ISSN 0315-0860.
  37. ^ Christianidis, J.; Oaks, J. (2013). "Practicing algebra in late antiquity: The problem-solving of Diophantus of Alexandria". Historia Mathematica. 40 (2): 127–163. doi:10.1016/j.hm.2012.09.001. ISSN 0315-0860.
  38. ^ Rideout, Bronwyn (2008). Pappus Reborn : Pappus of Alexandria and the Changing Face of Analysis and Synthesis in Late Antiquity (Thesis). doi:10.26021/3834.
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  42. ^ Mansfeld, J. (2016). Prolegomena Mathematica: From Apollonius of Perga to the Late Neoplatonism. With an Appendix on Pappus and the History of Platonism. Brill. ISBN 978-90-04-32105-2.
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Further reading

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