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Euclid

January 10, 2024

For the philosopher, see Euclid of Megara. For other uses, see Euclid (disambiguation).

Euclid (/ˈjklɪd/; Greek: Εὐκλείδης; fl. 300 BC) was an ancient Greek mathematician active as a geometer and logician.[2] Considered the "father of geometry",[3] he is chiefly known for the Elements treatise, which established the foundations of geometry that largely dominated the field until the early 19th century. His system, now referred to as Euclidean geometry, involved new innovations in combination with a synthesis of theories from earlier Greek mathematicians, including Eudoxus of Cnidus, Hippocrates of Chios, and Theaetetus. With Archimedes and Apollonius of Perga, Euclid is generally considered among the greatest mathematicians of antiquity, and one of the most influential in the history of mathematics.

Euclid
Εὐκλείδης
Euclid by Jusepe de Ribera, c. 1630–1635[1]
Known for
Various concepts
Scientific career
FieldsMathematics

Very little is known of Euclid's life, and most information comes from the scholars Proclus and Pappus of Alexandria many centuries later. Medieval Islamic mathematicians invented a fanciful biography, and medieval Byzantine and early Renaissance scholars mistook him for the earlier philosopher Euclid of Megara. It is now generally accepted that he spent his career in Alexandria and lived around 300 BC, after Plato's students and before Archimedes. There is some speculation that Euclid studied at the Platonic Academy and later taught at the Musaeum; he is regarded as bridging the earlier Platonic tradition in Athens with the later tradition of Alexandria.

In the Elements, Euclid deduced the theorems from a small set of axioms. He also wrote works on perspective, conic sections, spherical geometry, number theory, and mathematical rigour. In addition to the Elements, Euclid wrote a central early text in the optics field, Optics, and lesser-known works including Data and Phaenomena. Euclid's authorship of two other texts—On Divisions of Figures, Catoptrics—has been questioned. He is thought to have written many now lost works.

Life

Traditional narrative

 
Detail of Raphael's impression of Euclid, teaching students in The School of Athens (1509–1511)

The English name 'Euclid' is the anglicized version of the Ancient Greek name Eukleídes (Εὐκλείδης).[4][a] It is derived from 'eu-' (εὖ; 'well') and 'klês' (-κλῆς; 'fame'), meaning "renowned, glorious".[6] In English, by metonymy, 'Euclid' can mean his most well-known work, Euclid's Elements, or a copy thereof,[5] and is sometimes synonymous with 'geometry'.[2]

Like many ancient Greek mathematicians, the details of Euclid's life are mostly unknown.[7] He is accepted as the author of four mostly extant treatises—the Elements, Optics, Data, Phaenomena—but besides this, there is nothing known for certain of him.[8][b] The traditional narrative mainly follows the 5th century AD account by Proclus in his Commentary on the First Book of Euclid's Elements, as well as a few anecdotes from Pappus of Alexandria in the early 4th century.[4][c]

According to Proclus, Euclid lived shortly after several of Plato's (d. 347 BC) followers and before the mathematician Archimedes (c. 287 – c. 212 BC);[d] specifically, Proclus placed Euclid during the rule of Ptolemy I (r. 305/304–282 BC).[8][7][e] Euclid's birthdate is unknown; some scholars estimate around 330[11][12] or 325 BC,[2][13] but others refrain from speculating.[14] It is presumed that he was of Greek descent,[11] but his birthplace is unknown.[15][f]

Proclus held that Euclid followed the Platonic tradition, but there is no definitive confirmation for this.[17] It is unlikely he was contemporary with Plato, so it is often presumed that he was educated by Plato's disciples at the Platonic Academy in Athens.[18] Historian Thomas Heath supported this theory, noting that most capable geometers lived in Athens, including many of those whose work Euclid built on;[19] Sialaros considers this a mere conjecture.[20][4] In any event, the contents of Euclid's work demonstrate familiarity with the Platonic geometry tradition.[11]

In his Collection, Pappus mentions that Apollonius studied with Euclid's students in Alexandria, and this has been taken to imply that Euclid worked and founded a mathematical tradition there.[8][21][19] The city was founded by Alexander the Great in 331 BC,[22] and the rule of Ptolemy I from 306 BC onwards gave it a stability which was relatively unique amid the chaotic wars over dividing Alexander's empire.[23] Ptolemy began a process of hellenization and commissioned numerous constructions, building the massive Musaeum institution, which was a leading center of education.[15][g] Euclid is speculated to have been among the Musaeum's first scholars.[22]

Euclid's date of death is unknown; it has been speculated that he died c. 270 BC.[22]

Identity and historicity

 
Domenico Maroli's 1650s painting Euclide di Megara si traveste da donna per recarsi ad Atene a seguire le lezioni di Socrate [Euclid of Megara Dressing as a Woman to Hear Socrates Teach in Athens]. At the time, Euclid the philosopher and Euclid the mathematician were wrongly considered the same person, so this painting includes mathematical objects on the table.[25]

Euclid is often referred to as 'Euclid of Alexandria' to differentiate him from the earlier philosopher Euclid of Megara, a pupil of Socrates included in dialogues of Plato with whom he was historically conflated.[4][14] Valerius Maximus, the 1st century AD Roman compiler of anecdotes, mistakenly substituted Euclid's name for Eudoxus (4th century BC) as the mathematician to whom Plato sent those asking how to double the cube.[26] Perhaps on the basis of this mention of a mathematical Euclid roughly a century early, Euclid became mixed up with Euclid of Megara in medieval Byzantine sources (now lost),[27] eventually leading Euclid the mathematician to be ascribed details of both men's biographies and described as Megarensis (lit.'of Megara').[4][28] The Byzantine scholar Theodore Metochites (c. 1300) explicitly conflated the two Euclids, as did printer Erhard Ratdolt's 1482 editio princeps of Campanus of Novara's Latin translation of the Elements.[27] After the mathematician Bartolomeo Zamberti [fr; de] appended most of the extant biographical fragments about either Euclid to the preface of his 1505 translation of the Elements, subsequent publications passed on this identification.[27] Later Renaissance scholars, particularly Peter Ramus, reevaluated this claim, proving it false via issues in chronology and contradiction in early sources.[27]

Medieval Arabic sources give vast amounts of information concerning Euclid's life, but are completely unverifiable.[4] Most scholars consider them of dubious authenticity;[8] Heath in particular contends that the fictionalization was done to strengthen the connection between a revered mathematician and the Arab world.[17] There are also numerous anecdotal stories concerning to Euclid, all of uncertain historicity, which "picture him as a kindly and gentle old man".[29] The best known of these is Proclus' story about Ptolemy asking Euclid if there was a quicker path to learning geometry than reading his Elements, which Euclid replied with "there is no royal road to geometry".[29] This anecdote is questionable since a very similar interaction between Menaechmus and Alexander the Great is recorded from Stobaeus.[30] Both the accounts were written in the 5th century AD, neither indicate their source, and neither story appears in ancient Greek literature.[31]

Any firm dating of Euclid's activity c. 300 BC is called into question by a lack of contemporary references.[4] The earliest original reference to Euclid is in Apollonius' prefatory letter to the Conics (early 2nd century BC): "The third book of the Conics contains many astonishing theorems that are useful for both the syntheses and the determinations of number of solutions of solid loci. Most of these, and the finest of them, are novel. And when we discovered them we realized that Euclid had not made the synthesis of the locus on three and four lines but only an accidental fragment of it, and even that was not felicitously done."[26] The Elements is speculated to have been at least partly in circulation by the 3rd century BC, as Archimedes and Apollonius take several of its propositions for granted;[4] however, Archimedes employs an older variant of the theory of proportions than the one found in the Elements.[8] The oldest physical copies of material included in the Elements, dating from roughly 100 AD, can be found on papyrus fragments unearthed in an ancient rubbish heap from Oxyrhynchus, Roman Egypt. The oldest extant direct citations to the Elements in works whose dates are firmly known are not until the 2nd century AD, by Galen and Alexander of Aphrodisias; by this time it was a standard school text.[26] Some ancient Greek mathematicians mention Euclid by name, but he is usually referred to as "ὁ στοιχειώτης" ("the author of Elements").[32] In the Middle Ages, some scholars contended Euclid was not a historical personage and that his name arose from a corruption of Greek mathematical terms.[33]

Works

Elements

Main article: Euclid's Elements
 
A papyrus fragment of Euclid's Elements dated to c. 75–125 AD. Found at Oxyrhynchus, the diagram accompanies Book II, Proposition 5.[34]

Euclid is best known for his thirteen-book treatise, the Elements (Greek: Στοιχεῖα; Stoicheia), considered his magnum opus.[3][35] Much of its content originates from earlier mathematicians, including Eudoxus, Hippocrates of Chios, Thales and Theaetetus, while other theorems are mentioned by Plato and Aristotle.[36] It is difficult to differentiate the work of Euclid from that of his predecessors, especially because the Elements essentially superseded much earlier and now-lost Greek mathematics.[37][h] The classicist Markus Asper concludes that "apparently Euclid's achievement consists of assembling accepted mathematical knowledge into a cogent order and adding new proofs to fill in the gaps" and the mathematician Serafina Cuomo described it as a "reservoir of results".[38][36] Despite this, Sialaros furthers that "the remarkably tight structure of the Elements reveals authorial control beyond the limits of a mere editor".[9]

The Elements does not exclusively discuss geometry as is sometimes believed.[37] It is traditionally divided into three topics: plane geometry (books 1–6), basic number theory (books 7–10:) and solid geometry (books 11–13)—though book 5 (on proportions) and 10 (on irrational lines) do not exactly fit this scheme.[39][40] The heart of the text is the theorems scattered throughout.[35] Using Aristotle's terminology, these may be generally separated into two categories: "first principles" and "second principles".[41] The first group includes statements labeled as a "definition" (Greek: ὅρος or ὁρισμός), "postulate" (αἴτημα‎), or a "common notion" (κοινὴ ἔννοια);[41][42] only the first book includes postulates—later known as axioms—and common notions.[37][i] The second group consists of propositions, presented alongside mathematical proofs and diagrams.[41][j] It is unknown if Euclid intended the Elements as a textbook, but its method of presentation makes it a natural fit.[9] As a whole, the authorial voice remains general and impersonal.[36]

Contents

Euclid's postulates and common notions[44]
No. Postulates
Let the following be postulated:
1 To draw a straight line from any point to any point[k]
2 To produce a finite straight line continuously in a straight line
3 To describe a circle with any centre and distance
4 That all right angles are equal to one another
5 That, if a straight line falling on two straight lines make the
interior angles on the same side less than two right angles,
the two straight lines, if produced indefinitely, meet on that side
on which are the angles less than the two right angles
No. Common notions
1 Things which are equal to the same thing are also equal to one another
2 If equals be added to equals, the wholes are equal
3 If equals be subtracted from equals, the remainders are equal
4 Things which coincide with one another are equal to one another
5 The whole is greater than the part
See also: Foundations of geometry

Book 1 of the Elements is foundational for the entire text.[37] It begins with a series of 20 definitions for basic geometric concepts such as lines, angles and various regular polygons.[45] Euclid then presents 10 assumptions (see table, right), grouped into five postulates (axioms) and five common notions.[46][l] These assumptions are intended to provide the logical basis for every subsequent theorem, i.e. serve as an axiomatic system.[47][m] The common notions exclusively concern the comparison of magnitudes.[49] While postulates 1 through 4 are relatively straight forward,[n] the 5th is known as the parallel postulate and particularly famous.[49][o]

Book 1 also includes 48 propositions, which can be loosely divided into those concerning basic theorems and constructions of plane geometry and triangle congruence (1–26); parallel lines (27–34); the area of triangles and parallelograms (35–45); and the Pythagorean theorem (46–48).[49] The last of these includes the earliest surviving proof of the Pythagorean theorem, described by Sialaros as "remarkably delicate".[41]

Book 2 is traditionally understood as concerning "geometric algebra", though this interpretation has been heavily debated since the 1970s; critics describe the characterization as anachronistic, since the foundations of even nascent algebra occurred many centuries later.[41] The second book has a more focused scope and mostly provides algebraic theorems to accompany various geometric shapes.[37][49] It focuses on the area of rectangles and squares (see Quadrature), and leads up to a geometric precursor of the law of cosines.

Book 3 focuses on circles, while the 4th discusses regular polygons, especially the pentagon.[37][51] Book 5 is among the work's most important sections and presents what is usually termed as the "general theory of proportion".[52][p] Book 6 utilizes the "theory of ratios" in the context of plane geometry.[37] It is built almost entirely of its first proposition:[53] "Triangles and parallelograms which are under the same height are to one another as their bases".[54]

From Book 7 onwards, the mathematician Benno Artmann [de] notes that "Euclid starts afresh. Nothing from the preceding books is used".[55] Number theory is covered by books 7 to 10, the former beginning with a set of 22 definitions for parity, prime numbers and other arithmetic-related concepts.[37] Book 7 includes the Euclidean algorithm, a method for finding the greatest common divisor of two numbers.[55] The 8th book discusses geometric progressions, while book 9 includes the proposition, now called Euclid's theorem, that there are infinitely many prime numbers.[37]

Of the Elements, book 10 is by far the largest and most complex, dealing with irrational numbers in the context of magnitudes.[41]

 
The five Platonic solids, foundational components of solid geometry which feature in Books 11–13

The final three books (11–13) primarily discuss solid geometry.[39] By introducing a list of 37 definitions, Book 11 contextualizes the next two.[56] Although its foundational character resembles Book 1, unlike the latter it features no axiomatic system or postulates.[56] The three sections of Book 11 include content on solid geometry (1–19), solid angles (20–23) and parallelepipedal solids (24–37).[56]

Other works

 
Euclid's construction of a regular dodecahedron

In addition to the Elements, at least five works of Euclid have survived to the present day. They follow the same logical structure as Elements, with definitions and proved propositions.

  • Catoptrics concerns the mathematical theory of mirrors, particularly the images formed in plane and spherical concave mirrors, though the attribution is sometimes questioned.[57]
  • The Data (Greek: Δεδομένα), is a somewhat short text which deals with the nature and implications of "given" information in geometrical problems.[57]
  • On Divisions (Greek: Περὶ Διαιρέσεων‎) survives only partially in Arabic translation, and concerns the division of geometrical figures into two or more equal parts or into parts in given ratios. It includes thirty-six propositions and is similar to Apollonius' Conics.[57]
  • The Optics (Greek: Ὀπτικά‎) is the earliest surviving Greek treatise on perspective. It includes an introductory discussion of geometrical optics and basic rules of perspective.[57]
  • The Phaenomena (Greek: Φαινόμενα) is a treatise on spherical astronomy, survives in Greek; it is similar to On the Moving Sphere by Autolycus of Pitane, who flourished around 310 BC.[57]

Lost works

Four other works are credibly attributed to Euclid, but have been lost.[9]

  • The Conics (Greek: Κωνικά‎) was a four-book survey on conic sections, which was later superseded by Apollonius' more comprehensive treatment of the same name.[58][57] The work's existence is known primarily from Pappus, who asserts that the first four books of Apollonius' Conics are largely based on Euclid's earlier work.[59] Doubt has been cast on this assertion by the historian Alexander Jones [de], owing to sparse evidence and no other corroboration of Pappus' account.[59]
  • The Pseudaria (Greek: Ψευδάρια‎; lit.'Fallacies'), was—according to Proclus in (70.1–18)—a text in geometrical reasoning, written to advise beginners in avoiding common fallacies.[58][57] Very little is known of its specific contents aside from its scope and a few extant lines.[60]
  • The Porisms (Greek: Πορίσματα; lit.'Corollaries') was, based on accounts from Pappus and Proclus, probably a three-book treatise with approximately 200 propositions.[58][57] The term 'porism' in this context does not refer to a corollary, but to "a third type of proposition—an intermediate between a theorem and a problem—the aim of which is to discover a feature of an existing geometrical entity, for example, to find the centre of a circle".[57] The mathematician Michel Chasles speculated that these now-lost propositions included content related to the modern theories of transversals and projective geometry.[58][q]
  • The Surface Loci (Greek: Τόποι πρὸς ἐπιφανείᾳ) is of virtually unknown contents, aside from speculation based on the work's title.[58] Conjecture based on later accounts has suggested it discussed cones and cylinders, among other subjects.[57]

Collections

Euclid's works can be found in cultural institutions across the world. Many of these editions are digitised and available for public consultation.

  • University College London holds c.500 works of Euclid, including 63 editions published before 1580. The majority of the collection is from the library of John Thomas Graves, who bequeathed his books to the University in 1870. The collection has been digitised through the Stavros Niarchos Foundation Library.[61] [62]

Legacy

See also: List of things named after Euclid
 
The cover page of Oliver Byrne's 1847 colored edition of the Elements

Euclid is generally considered with Archimedes and Apollonius of Perga as among the greatest mathematicians of antiquity.[11] Many commentators cite him as one of the most influential figures in the history of mathematics.[2] The geometrical system established by the Elements long dominated the field; however, today that system is often referred to as 'Euclidean geometry' to distinguish it from other non-Euclidean geometries discovered in the early 19th century.[63] Among Euclid's many namesakes are the European Space Agency's (ESA) Euclid spacecraft,[64] the lunar crater Euclides,[65] and the minor planet 4354 Euclides.[66]

The Elements is often considered after the Bible as the most frequently translated, published, and studied book in the Western World's history.[63] With Aristotle's Metaphysics, the Elements is perhaps the most successful ancient Greek text, and was the dominant mathematical textbook in the Medieval Arab and Latin worlds.[63]

The first English edition of the Elements was published in 1570 by Henry Billingsley and John Dee.[27] The mathematician Oliver Byrne published a well-known version of the Elements in 1847 entitled The First Six Books of the Elements of Euclid in Which Coloured Diagrams and Symbols Are Used Instead of Letters for the Greater Ease of Learners, which included colored diagrams intended to increase its pedagogical effect.[67] David Hilbert authored a modern axiomatization of the Elements.[68]

References

Notes

  1. ^ In modern English, 'Euclid' is pronounced as /ˈjklɪd/.[5]
  2. ^ Euclid's oeuvre also includes the treatise On Divisions, which survives fragmented in a later Arabic source.[9] He authored numerous lost works as well.
  3. ^ Some of the information from Pappus of Alexandria on Euclid is now lost and was preserved in Proclus's Commentary on the First Book of Euclid's Elements.[10]
  4. ^ Proclus was likely working from (now-lost) 4th-century BC histories of mathematics written by Theophrastus and Eudemus of Rhodes. Proclus explicitly mentions Amyclas of Heracleia, Menaechmus and his brother Dinostratus, Theudius of Magnesia, Athenaeus of Cyzicus, Hermotimus of Colophon, and Philippus of Mende, and says that Euclid came "not long after" these men.
  5. ^ See Heath 1981, p. 354 for an English translation on Proclus's account of Euclid's life.
  6. ^ Later Arab sources state he was a Greek born in modern-day Tyre, Lebanon, though these accounts are considered dubious and speculative.[8][4] See Heath 1981, p. 355 for an English translation of the Arab account. He was long held to have been born in Megara, but by the Renaissance it was concluded that he had been confused with the philosopher Euclid of Megara,[16] see §Identity and historicity
  7. ^ The Musaeum would later include the famous Library of Alexandria, but it was likely founded later, during the reign of Ptolemy II Philadelphus (285–246 BC).[24]
  8. ^ The Elements version available today also includes "post-Euclidean" mathematics, probably added later by later editors such as the mathematician Theon of Alexandria in the 4th century.[36]
  9. ^ The use of the term "axiom" instead of "postulate" derives from the choice of Proclus to do so in his highly influential commentary on the Elements. Proclus also substituted the term "hypothesis" instead of "common notion", though preserved "postulate".[42]
  10. ^ Euclid includes Q.E.D. (quod erat demonstrandum; lit.'what was to be demonstrated') at the end of each proof, which has since become a long-standing tradition in the presentation of mathematical proofs.[43]
  11. ^ See also: Euclidean relation
  12. ^ The distinction between these categories is not immediately clear; postulates may simply refer to geometry specifically, while common notions are more general in scope.[46]
  13. ^ The mathematician Gerard Venema notes that this axiomatic system is not complete: "Euclid assumed more than just what he stated in the postulates".[48]
  14. ^ See Heath 1908, pp. 195–201 for a detailed overview of postulates 1 through 4
  15. ^ Since antiquity, enormous amounts of scholarship have been written about the 5th postulate, usually from mathematicians attempting to prove the postulate—which would make it different from the other, unprovable, four postulates.[50]
  16. ^ Much of Book 5 was probably ascertained from earlier mathematicians, perhaps Eudoxus.[41]
  17. ^ See Jones 1986, pp. 547–572 for further information on the Porisms

Citations

  1. ^ Getty.
  2. ^ a b c d Bruno 2003, p. 125.
  3. ^ a b Sialaros 2021, § "Summary".
  4. ^ a b c d e f g h i Sialaros 2021, § "Life".
  5. ^ a b OEDa.
  6. ^ OEDb.
  7. ^ a b Heath 1981, p. 354.
  8. ^ a b c d e f Asper 2010, § para. 1.
  9. ^ a b c d Sialaros 2021, § "Works".
  10. ^ Heath 1911, p. 741.
  11. ^ a b c d Ball 1960, p. 52.
  12. ^ Sialaros 2020, p. 141.
  13. ^ Goulding 2010, p. 125.
  14. ^ a b Smorynski 2008, p. 2.
  15. ^ a b Boyer 1991, p. 100.
  16. ^ Goulding 2010, p. 118.
  17. ^ a b Heath 1981, p. 355.
  18. ^ Goulding 2010, p. 126.
  19. ^ a b Heath 1908, p. 2.
  20. ^ Sialaros 2020, pp. 147–148.
  21. ^ Sialaros 2020, p. 142.
  22. ^ a b c Bruno 2003, p. 126.
  23. ^ Ball 1960, p. 51.
  24. ^ Tracy 2000, pp. 343–344.
  25. ^ Sialaros 2021, § "Life" and Note 5.
  26. ^ a b c Jones 2005.
  27. ^ a b c d e Goulding 2010, p. 120.
  28. ^ Taisbak & Van der Waerden 2021, § "Life".
  29. ^ a b Boyer 1991, p. 101.
  30. ^ Boyer 1991, p. 96.
  31. ^ Sialaros 2018, p. 90.
  32. ^ Heath 1981, p. 357.
  33. ^ Ball 1960, pp. 52–53.
  34. ^ Fowler 1999, pp. 210–211.
  35. ^ a b Asper 2010, § para. 2.
  36. ^ a b c d Asper 2010, § para. 6.
  37. ^ a b c d e f g h i Taisbak & Van der Waerden 2021, § "Sources and contents of the Elements".
  38. ^ Cuomo 2005, p. 131.
  39. ^ a b Artmann 2012, p. 3.
  40. ^ Asper 2010, § para. 4.
  41. ^ a b c d e f g Sialaros 2021, § "The Elements".
  42. ^ a b Jahnke 2010, p. 18.
  43. ^ Asper 2010, § para. 5.
  44. ^ Heath 1908, pp. 154–155.
  45. ^ Artmann 2012, p. 3–4.
  46. ^ a b Wolfe 1945, p. 4.
  47. ^ Pickover 2009, p. 56.
  48. ^ Venema 2006, p. 10.
  49. ^ a b c d Artmann 2012, p. 4.
  50. ^ Heath 1908, p. 202.
  51. ^ Artmann 2012, p. 5.
  52. ^ Artmann 2012, pp. 5–6.
  53. ^ Artmann 2012, p. 6.
  54. ^ Heath 1908b, p. 191.
  55. ^ a b Artmann 2012, p. 7.
  56. ^ a b c Artmann 2012, p. 9.
  57. ^ a b c d e f g h i j Sialaros 2021, § "Other Works".
  58. ^ a b c d e Taisbak & Van der Waerden 2021, § "Other writings".
  59. ^ a b Jones 1986, pp. 399–400.
  60. ^ Acerbi 2008, p. 511.
  61. ^ UCL Special Collections (23 August 2018). "Euclid Collection". UCL Special Collections. Retrieved 12 December 2023.
  62. ^ UCL Special Collections (23 August 2018). "Graves Library". UCL Special Collections. Retrieved 12 December 2023.
  63. ^ a b c Taisbak & Van der Waerden 2021, § "Legacy".
  64. ^ "NASA Delivers Detectors for ESA's Euclid Spacecraft". Jet Propulsion Laboratory. 9 May 2017.
  65. ^ "Gazetteer of Planetary Nomenclature | Euclides". usgs.gov. International Astronomical Union. Retrieved 3 September 2017.
  66. ^ "4354 Euclides (2142 P-L)". Minor Planet Center. Retrieved 27 May 2018.
  67. ^ Hawes, Susan M.; Kolpas, Sid. "Oliver Byrne: The Matisse of Mathematics – Biography 1810–1829". Mathematical Association of America. Retrieved 10 August 2022.
  68. ^ Hähl & Peters 2022, § para. 1.

Sources

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The Elements
  • PDF copy, with the original Greek and an English translation on facing pages, University of Texas.
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January 10, 2024
euclid, philosopher, megara, other, uses, disambiguation, greek, Εὐκλείδης, ancient, greek, mathematician, active, geometer, logician, considered, father, geometry, chiefly, known, elements, treatise, which, established, foundations, geometry, that, largely, d. For the philosopher see Euclid of Megara For other uses see Euclid disambiguation Euclid ˈ j uː k l ɪ d Greek Eὐkleidhs fl 300 BC was an ancient Greek mathematician active as a geometer and logician 2 Considered the father of geometry 3 he is chiefly known for the Elements treatise which established the foundations of geometry that largely dominated the field until the early 19th century His system now referred to as Euclidean geometry involved new innovations in combination with a synthesis of theories from earlier Greek mathematicians including Eudoxus of Cnidus Hippocrates of Chios and Theaetetus With Archimedes and Apollonius of Perga Euclid is generally considered among the greatest mathematicians of antiquity and one of the most influential in the history of mathematics EuclidEὐkleidhsEuclid by Jusepe de Ribera c 1630 1635 1 Known forThe ElementsOpticsData Various concepts Euclidean geometry Euclidean algorithm Euclid s theorem Euclidean relation Euclid s formula Numerous other namesakesScientific careerFieldsMathematicsVery little is known of Euclid s life and most information comes from the scholars Proclus and Pappus of Alexandria many centuries later Medieval Islamic mathematicians invented a fanciful biography and medieval Byzantine and early Renaissance scholars mistook him for the earlier philosopher Euclid of Megara It is now generally accepted that he spent his career in Alexandria and lived around 300 BC after Plato s students and before Archimedes There is some speculation that Euclid studied at the Platonic Academy and later taught at the Musaeum he is regarded as bridging the earlier Platonic tradition in Athens with the later tradition of Alexandria In the Elements Euclid deduced the theorems from a small set of axioms He also wrote works on perspective conic sections spherical geometry number theory and mathematical rigour In addition to the Elements Euclid wrote a central early text in the optics field Optics and lesser known works including Data and Phaenomena Euclid s authorship of two other texts On Divisions of Figures Catoptrics has been questioned He is thought to have written many now lost works Contents 1 Life 1 1 Traditional narrative 1 2 Identity and historicity 2 Works 2 1 Elements 2 1 1 Contents 2 2 Other works 2 3 Lost works 2 4 Collections 3 Legacy 4 References 4 1 Notes 4 2 Citations 4 3 Sources 5 External linksLifeTraditional narrative nbsp Detail of Raphael s impression of Euclid teaching students in The School of Athens 1509 1511 The English name Euclid is the anglicized version of the Ancient Greek name Eukleides Eὐkleidhs 4 a It is derived from eu eὖ well and kles klῆs fame meaning renowned glorious 6 In English by metonymy Euclid can mean his most well known work Euclid s Elements or a copy thereof 5 and is sometimes synonymous with geometry 2 Like many ancient Greek mathematicians the details of Euclid s life are mostly unknown 7 He is accepted as the author of four mostly extant treatises the Elements Optics Data Phaenomena but besides this there is nothing known for certain of him 8 b The traditional narrative mainly follows the 5th century AD account by Proclus in his Commentary on the First Book of Euclid s Elements as well as a few anecdotes from Pappus of Alexandria in the early 4th century 4 c According to Proclus Euclid lived shortly after several of Plato s d 347 BC followers and before the mathematician Archimedes c 287 c 212 BC d specifically Proclus placed Euclid during the rule of Ptolemy I r 305 304 282 BC 8 7 e Euclid s birthdate is unknown some scholars estimate around 330 11 12 or 325 BC 2 13 but others refrain from speculating 14 It is presumed that he was of Greek descent 11 but his birthplace is unknown 15 f Proclus held that Euclid followed the Platonic tradition but there is no definitive confirmation for this 17 It is unlikely he was contemporary with Plato so it is often presumed that he was educated by Plato s disciples at the Platonic Academy in Athens 18 Historian Thomas Heath supported this theory noting that most capable geometers lived in Athens including many of those whose work Euclid built on 19 Sialaros considers this a mere conjecture 20 4 In any event the contents of Euclid s work demonstrate familiarity with the Platonic geometry tradition 11 In his Collection Pappus mentions that Apollonius studied with Euclid s students in Alexandria and this has been taken to imply that Euclid worked and founded a mathematical tradition there 8 21 19 The city was founded by Alexander the Great in 331 BC 22 and the rule of Ptolemy I from 306 BC onwards gave it a stability which was relatively unique amid the chaotic wars over dividing Alexander s empire 23 Ptolemy began a process of hellenization and commissioned numerous constructions building the massive Musaeum institution which was a leading center of education 15 g Euclid is speculated to have been among the Musaeum s first scholars 22 Euclid s date of death is unknown it has been speculated that he died c 270 BC 22 Identity and historicity nbsp Domenico Maroli s 1650s painting Euclide di Megara si traveste da donna per recarsi ad Atene a seguire le lezioni di Socrate Euclid of Megara Dressing as a Woman to Hear Socrates Teach in Athens At the time Euclid the philosopher and Euclid the mathematician were wrongly considered the same person so this painting includes mathematical objects on the table 25 Euclid is often referred to as Euclid of Alexandria to differentiate him from the earlier philosopher Euclid of Megara a pupil of Socrates included in dialogues of Plato with whom he was historically conflated 4 14 Valerius Maximus the 1st century AD Roman compiler of anecdotes mistakenly substituted Euclid s name for Eudoxus 4th century BC as the mathematician to whom Plato sent those asking how to double the cube 26 Perhaps on the basis of this mention of a mathematical Euclid roughly a century early Euclid became mixed up with Euclid of Megara in medieval Byzantine sources now lost 27 eventually leading Euclid the mathematician to be ascribed details of both men s biographies and described as Megarensis lit of Megara 4 28 The Byzantine scholar Theodore Metochites c 1300 explicitly conflated the two Euclids as did printer Erhard Ratdolt s 1482 editio princeps of Campanus of Novara s Latin translation of the Elements 27 After the mathematician Bartolomeo Zamberti fr de appended most of the extant biographical fragments about either Euclid to the preface of his 1505 translation of the Elements subsequent publications passed on this identification 27 Later Renaissance scholars particularly Peter Ramus reevaluated this claim proving it false via issues in chronology and contradiction in early sources 27 Medieval Arabic sources give vast amounts of information concerning Euclid s life but are completely unverifiable 4 Most scholars consider them of dubious authenticity 8 Heath in particular contends that the fictionalization was done to strengthen the connection between a revered mathematician and the Arab world 17 There are also numerous anecdotal stories concerning to Euclid all of uncertain historicity which picture him as a kindly and gentle old man 29 The best known of these is Proclus story about Ptolemy asking Euclid if there was a quicker path to learning geometry than reading his Elements which Euclid replied with there is no royal road to geometry 29 This anecdote is questionable since a very similar interaction between Menaechmus and Alexander the Great is recorded from Stobaeus 30 Both the accounts were written in the 5th century AD neither indicate their source and neither story appears in ancient Greek literature 31 Any firm dating of Euclid s activity c 300 BC is called into question by a lack of contemporary references 4 The earliest original reference to Euclid is in Apollonius prefatory letter to the Conics early 2nd century BC The third book of the Conics contains many astonishing theorems that are useful for both the syntheses and the determinations of number of solutions of solid loci Most of these and the finest of them are novel And when we discovered them we realized that Euclid had not made the synthesis of the locus on three and four lines but only an accidental fragment of it and even that was not felicitously done 26 The Elements is speculated to have been at least partly in circulation by the 3rd century BC as Archimedes and Apollonius take several of its propositions for granted 4 however Archimedes employs an older variant of the theory of proportions than the one found in the Elements 8 The oldest physical copies of material included in the Elements dating from roughly 100 AD can be found on papyrus fragments unearthed in an ancient rubbish heap from Oxyrhynchus Roman Egypt The oldest extant direct citations to the Elements in works whose dates are firmly known are not until the 2nd century AD by Galen and Alexander of Aphrodisias by this time it was a standard school text 26 Some ancient Greek mathematicians mention Euclid by name but he is usually referred to as ὁ stoixeiwths the author of Elements 32 In the Middle Ages some scholars contended Euclid was not a historical personage and that his name arose from a corruption of Greek mathematical terms 33 WorksElements Main article Euclid s Elements nbsp A papyrus fragment of Euclid s Elements dated to c 75 125 AD Found at Oxyrhynchus the diagram accompanies Book II Proposition 5 34 Euclid is best known for his thirteen book treatise the Elements Greek Stoixeῖa Stoicheia considered his magnum opus 3 35 Much of its content originates from earlier mathematicians including Eudoxus Hippocrates of Chios Thales and Theaetetus while other theorems are mentioned by Plato and Aristotle 36 It is difficult to differentiate the work of Euclid from that of his predecessors especially because the Elements essentially superseded much earlier and now lost Greek mathematics 37 h The classicist Markus Asper concludes that apparently Euclid s achievement consists of assembling accepted mathematical knowledge into a cogent order and adding new proofs to fill in the gaps and the mathematician Serafina Cuomo described it as a reservoir of results 38 36 Despite this Sialaros furthers that the remarkably tight structure of the Elements reveals authorial control beyond the limits of a mere editor 9 The Elements does not exclusively discuss geometry as is sometimes believed 37 It is traditionally divided into three topics plane geometry books 1 6 basic number theory books 7 10 and solid geometry books 11 13 though book 5 on proportions and 10 on irrational lines do not exactly fit this scheme 39 40 The heart of the text is the theorems scattered throughout 35 Using Aristotle s terminology these may be generally separated into two categories first principles and second principles 41 The first group includes statements labeled as a definition Greek ὅros or ὁrismos postulate aἴthma or a common notion koinὴ ἔnnoia 41 42 only the first book includes postulates later known as axioms and common notions 37 i The second group consists of propositions presented alongside mathematical proofs and diagrams 41 j It is unknown if Euclid intended the Elements as a textbook but its method of presentation makes it a natural fit 9 As a whole the authorial voice remains general and impersonal 36 Contents Euclid s postulates and common notions 44 No PostulatesLet the following be postulated 1 To draw a straight line from any point to any point k 2 To produce a finite straight line continuously in a straight line3 To describe a circle with any centre and distance4 That all right angles are equal to one another5 That if a straight line falling on two straight lines make the interior angles on the same side less than two right angles the two straight lines if produced indefinitely meet on that side on which are the angles less than the two right anglesNo Common notions1 Things which are equal to the same thing are also equal to one another2 If equals be added to equals the wholes are equal3 If equals be subtracted from equals the remainders are equal4 Things which coincide with one another are equal to one another5 The whole is greater than the partSee also Foundations of geometry Book 1 of the Elements is foundational for the entire text 37 It begins with a series of 20 definitions for basic geometric concepts such as lines angles and various regular polygons 45 Euclid then presents 10 assumptions see table right grouped into five postulates axioms and five common notions 46 l These assumptions are intended to provide the logical basis for every subsequent theorem i e serve as an axiomatic system 47 m The common notions exclusively concern the comparison of magnitudes 49 While postulates 1 through 4 are relatively straight forward n the 5th is known as the parallel postulate and particularly famous 49 o Book 1 also includes 48 propositions which can be loosely divided into those concerning basic theorems and constructions of plane geometry and triangle congruence 1 26 parallel lines 27 34 the area of triangles and parallelograms 35 45 and the Pythagorean theorem 46 48 49 The last of these includes the earliest surviving proof of the Pythagorean theorem described by Sialaros as remarkably delicate 41 Book 2 is traditionally understood as concerning geometric algebra though this interpretation has been heavily debated since the 1970s critics describe the characterization as anachronistic since the foundations of even nascent algebra occurred many centuries later 41 The second book has a more focused scope and mostly provides algebraic theorems to accompany various geometric shapes 37 49 It focuses on the area of rectangles and squares see Quadrature and leads up to a geometric precursor of the law of cosines Book 3 focuses on circles while the 4th discusses regular polygons especially the pentagon 37 51 Book 5 is among the work s most important sections and presents what is usually termed as the general theory of proportion 52 p Book 6 utilizes the theory of ratios in the context of plane geometry 37 It is built almost entirely of its first proposition 53 Triangles and parallelograms which are under the same height are to one another as their bases 54 From Book 7 onwards the mathematician Benno Artmann de notes that Euclid starts afresh Nothing from the preceding books is used 55 Number theory is covered by books 7 to 10 the former beginning with a set of 22 definitions for parity prime numbers and other arithmetic related concepts 37 Book 7 includes the Euclidean algorithm a method for finding the greatest common divisor of two numbers 55 The 8th book discusses geometric progressions while book 9 includes the proposition now called Euclid s theorem that there are infinitely many prime numbers 37 Of the Elements book 10 is by far the largest and most complex dealing with irrational numbers in the context of magnitudes 41 nbsp The five Platonic solids foundational components of solid geometry which feature in Books 11 13The final three books 11 13 primarily discuss solid geometry 39 By introducing a list of 37 definitions Book 11 contextualizes the next two 56 Although its foundational character resembles Book 1 unlike the latter it features no axiomatic system or postulates 56 The three sections of Book 11 include content on solid geometry 1 19 solid angles 20 23 and parallelepipedal solids 24 37 56 Other works nbsp Euclid s construction of a regular dodecahedronIn addition to the Elements at least five works of Euclid have survived to the present day They follow the same logical structure as Elements with definitions and proved propositions Catoptrics concerns the mathematical theory of mirrors particularly the images formed in plane and spherical concave mirrors though the attribution is sometimes questioned 57 The Data Greek Dedomena is a somewhat short text which deals with the nature and implications of given information in geometrical problems 57 On Divisions Greek Perὶ Diairesewn survives only partially in Arabic translation and concerns the division of geometrical figures into two or more equal parts or into parts in given ratios It includes thirty six propositions and is similar to Apollonius Conics 57 The Optics Greek Ὀptika is the earliest surviving Greek treatise on perspective It includes an introductory discussion of geometrical optics and basic rules of perspective 57 The Phaenomena Greek Fainomena is a treatise on spherical astronomy survives in Greek it is similar to On the Moving Sphere by Autolycus of Pitane who flourished around 310 BC 57 Lost works Four other works are credibly attributed to Euclid but have been lost 9 The Conics Greek Kwnika was a four book survey on conic sections which was later superseded by Apollonius more comprehensive treatment of the same name 58 57 The work s existence is known primarily from Pappus who asserts that the first four books of Apollonius Conics are largely based on Euclid s earlier work 59 Doubt has been cast on this assertion by the historian Alexander Jones de owing to sparse evidence and no other corroboration of Pappus account 59 The Pseudaria Greek PSeydaria lit Fallacies was according to Proclus in 70 1 18 a text in geometrical reasoning written to advise beginners in avoiding common fallacies 58 57 Very little is known of its specific contents aside from its scope and a few extant lines 60 The Porisms Greek Porismata lit Corollaries was based on accounts from Pappus and Proclus probably a three book treatise with approximately 200 propositions 58 57 The term porism in this context does not refer to a corollary but to a third type of proposition an intermediate between a theorem and a problem the aim of which is to discover a feature of an existing geometrical entity for example to find the centre of a circle 57 The mathematician Michel Chasles speculated that these now lost propositions included content related to the modern theories of transversals and projective geometry 58 q The Surface Loci Greek Topoi prὸs ἐpifaneiᾳ is of virtually unknown contents aside from speculation based on the work s title 58 Conjecture based on later accounts has suggested it discussed cones and cylinders among other subjects 57 Collections Euclid s works can be found in cultural institutions across the world Many of these editions are digitised and available for public consultation University College London holds c 500 works of Euclid including 63 editions published before 1580 The majority of the collection is from the library of John Thomas Graves who bequeathed his books to the University in 1870 The collection has been digitised through the Stavros Niarchos Foundation Library 61 62 LegacySee also List of things named after Euclid nbsp The cover page of Oliver Byrne s 1847 colored edition of the ElementsEuclid is generally considered with Archimedes and Apollonius of Perga as among the greatest mathematicians of antiquity 11 Many commentators cite him as one of the most influential figures in the history of mathematics 2 The geometrical system established by the Elements long dominated the field however today that system is often referred to as Euclidean geometry to distinguish it from other non Euclidean geometries discovered in the early 19th century 63 Among Euclid s many namesakes are the European Space Agency s ESA Euclid spacecraft 64 the lunar crater Euclides 65 and the minor planet 4354 Euclides 66 The Elements is often considered after the Bible as the most frequently translated published and studied book in the Western World s history 63 With Aristotle s Metaphysics the Elements is perhaps the most successful ancient Greek text and was the dominant mathematical textbook in the Medieval Arab and Latin worlds 63 The first English edition of the Elements was published in 1570 by Henry Billingsley and John Dee 27 The mathematician Oliver Byrne published a well known version of the Elements in 1847 entitled The First Six Books of the Elements of Euclid in Which Coloured Diagrams and Symbols Are Used Instead of Letters for the Greater Ease of Learners which included colored diagrams intended to increase its pedagogical effect 67 David Hilbert authored a modern axiomatization of the Elements 68 ReferencesNotes In modern English Euclid is pronounced as ˈ j uː k l ɪ d 5 Euclid s oeuvre also includes the treatise On Divisions which survives fragmented in a later Arabic source 9 He authored numerous lost works as well Some of the information from Pappus of Alexandria on Euclid is now lost and was preserved in Proclus s Commentary on the First Book of Euclid s Elements 10 Proclus was likely working from now lost 4th century BC histories of mathematics written by Theophrastus and Eudemus of Rhodes Proclus explicitly mentions Amyclas of Heracleia Menaechmus and his brother Dinostratus Theudius of Magnesia Athenaeus of Cyzicus Hermotimus of Colophon and Philippus of Mende and says that Euclid came not long after these men See Heath 1981 p 354 for an English translation on Proclus s account of Euclid s life Later Arab sources state he was a Greek born in modern day Tyre Lebanon though these accounts are considered dubious and speculative 8 4 See Heath 1981 p 355 for an English translation of the Arab account He was long held to have been born in Megara but by the Renaissance it was concluded that he had been confused with the philosopher Euclid of Megara 16 see Identity and historicity The Musaeum would later include the famous Library of Alexandria but it was likely founded later during the reign of Ptolemy II Philadelphus 285 246 BC 24 The Elements version available today also includes post Euclidean mathematics probably added later by later editors such as the mathematician Theon of Alexandria in the 4th century 36 The use of the term axiom instead of postulate derives from the choice of Proclus to do so in his highly influential commentary on the Elements Proclus also substituted the term hypothesis instead of common notion though preserved postulate 42 Euclid includes Q E D quod erat demonstrandum lit what was to be demonstrated at the end of each proof which has since become a long standing tradition in the presentation of mathematical proofs 43 See also Euclidean relation The distinction between these categories is not immediately clear postulates may simply refer to geometry specifically while common notions are more general in scope 46 The mathematician Gerard Venema notes that this axiomatic system is not complete Euclid assumed more than just what he stated in the postulates 48 See Heath 1908 pp 195 201 for a detailed overview of postulates 1 through 4 Since antiquity enormous amounts of scholarship have been written about the 5th postulate usually from mathematicians attempting to prove the postulate which would make it different from the other unprovable four postulates 50 Much of Book 5 was probably ascertained from earlier mathematicians perhaps Eudoxus 41 See Jones 1986 pp 547 572 for further information on the Porisms Citations Getty a b c d Bruno 2003 p 125 a b Sialaros 2021 Summary a b c d e f g h i Sialaros 2021 Life a b OEDa OEDb a b Heath 1981 p 354 a b c d e f Asper 2010 para 1 a b c d Sialaros 2021 Works Heath 1911 p 741 a b c d Ball 1960 p 52 Sialaros 2020 p 141 Goulding 2010 p 125 a b Smorynski 2008 p 2 a b Boyer 1991 p 100 Goulding 2010 p 118 a b Heath 1981 p 355 Goulding 2010 p 126 a b Heath 1908 p 2 Sialaros 2020 pp 147 148 Sialaros 2020 p 142 a b c Bruno 2003 p 126 Ball 1960 p 51 Tracy 2000 pp 343 344 Sialaros 2021 Life and Note 5 a b c Jones 2005 a b c d e Goulding 2010 p 120 Taisbak amp Van der Waerden 2021 Life a b Boyer 1991 p 101 Boyer 1991 p 96 Sialaros 2018 p 90 Heath 1981 p 357 Ball 1960 pp 52 53 Fowler 1999 pp 210 211 a b Asper 2010 para 2 a b c d Asper 2010 para 6 a b c d e f g h i Taisbak amp Van der Waerden 2021 Sources and contents of the Elements Cuomo 2005 p 131 a b Artmann 2012 p 3 Asper 2010 para 4 a b c d e f g Sialaros 2021 The Elements a b Jahnke 2010 p 18 Asper 2010 para 5 Heath 1908 pp 154 155 Artmann 2012 p 3 4 a b Wolfe 1945 p 4 Pickover 2009 p 56 Venema 2006 p 10 a b c d Artmann 2012 p 4 Heath 1908 p 202 Artmann 2012 p 5 Artmann 2012 pp 5 6 Artmann 2012 p 6 Heath 1908b p 191 a b Artmann 2012 p 7 a b c Artmann 2012 p 9 a b c d e f g h i j Sialaros 2021 Other Works a b c d e Taisbak amp Van der Waerden 2021 Other writings a b Jones 1986 pp 399 400 Acerbi 2008 p 511 UCL Special Collections 23 August 2018 Euclid Collection UCL Special Collections Retrieved 12 December 2023 UCL Special Collections 23 August 2018 Graves Library UCL Special Collections Retrieved 12 December 2023 a b c Taisbak amp Van der Waerden 2021 Legacy NASA Delivers Detectors for ESA s Euclid Spacecraft Jet Propulsion Laboratory 9 May 2017 Gazetteer of Planetary Nomenclature Euclides usgs gov International Astronomical Union Retrieved 3 September 2017 4354 Euclides 2142 P L Minor Planet Center Retrieved 27 May 2018 Hawes Susan M Kolpas Sid Oliver Byrne The Matisse of Mathematics Biography 1810 1829 Mathematical Association of America Retrieved 10 August 2022 Hahl amp Peters 2022 para 1 Sources BooksArtmann Benno 2012 1999 Euclid The Creation of Mathematics New York Springer Publishing ISBN 978 1 4612 1412 0 Ball W W Rouse 1960 1908 A Short Account of the History of Mathematics 4th ed Mineola Dover Publications ISBN 978 0 486 20630 1 Bruno Leonard C 2003 1999 Math and Mathematicians The History of Math Discoveries Around the World Baker Lawrence W Detroit U X L ISBN 978 0 7876 3813 9 OCLC 41497065 Boyer Carl B 1991 1968 A History of Mathematics 2nd ed John Wiley amp Sons Inc ISBN 978 0 471 54397 8 Cuomo Serafina 2005 2001 Ancient Mathematics London and New York Routledge ISBN 978 1 134 71019 5 Fowler David 1999 The Mathematics of Plato s Academy 2nd ed Oxford Clarendon Press ISBN 978 0 19 850258 6 Goulding Robert 2010 Defending Hypatia Ramus Savile and the Renaissance Rediscovery of Mathematical History Dordrecht Springer Netherlands ISBN 978 90 481 3542 4 Heath Thomas ed 1908 The Thirteen Books of Euclid s Elements Vol 1 New York Dover Publications ISBN 978 0 486 60088 8 Heath Thomas ed 1908b The Thirteen Books of Euclid s Elements Vol 2 New York Dover Publications Heath Thomas L 1981 1921 A History of Greek Mathematics Vol 2 Vols New York Dover Publications ISBN 0 486 24073 8 0 486 24074 6 Jahnke Hans Niels 2010 The Conjoint Origin of Proof and Theoretical Physics In Hanna Gila Jahnke Hans Niels Pulte Helmut eds Explanation and Proof in Mathematics Philosophical and Educational Perspectives Berlin Springer US ISBN 978 1 4419 0576 5 Jones Alexander ed 1986 Pappus of Alexandria Book 7 of the Collection Vol Part 2 Commentary Index and Figures New York Springer Science Business Media ISBN 978 3 540 96257 1 Pickover Clifford A 2009 The Math Book From Pythagoras to the 57th Dimension 250 Milestones in the History of Mathematics New York Sterling Publishing ISBN 978 1 4027 5796 9 Sialaros Michalis 2018 How Much Does a Theorem Cost In Sialaros Michalis ed Revolutions and Continuity in Greek Mathematics Berlin De Gruyter pp 89 106 ISBN 978 3 11 056595 9 Sialaros Michalis 2020 Euclid of Alexandria A Child of the Academy In Kalligas Paul Balla Vassilis Baziotopoulou Valavani Chloe Karasmanis Effie eds Plato s Academy Cambridge Cambridge University Press pp 141 152 ISBN 978 1 108 42644 2 Smorynski Craig 2008 History of Mathematics A Supplement New York Springer Publishing ISBN 978 0 387 75480 2 Tracy Stephen V 2000 Demetrius of Phalerum Who was He and Who was He Not In Fortenbaugh William W Schutrumpf Eckhart eds Demetrius of Phalerum Text Translation and Discussion Rutgers University Studies in Classical Humanities Vol IX New Brunswick and London Transaction Publishers ISBN 978 1 3513 2690 2 Venema Gerard 2006 The Foundations of Geometry Hoboken Pearson Prentice Hall ISBN 978 0 13 143700 5 Wolfe Harold E 1945 Introduction To Non Euclidean Geometry New York Dryden Press ArticlesAcerbi Fabio September 2008 Euclid s Pseudaria Archive for History of Exact Sciences 62 5 511 551 doi 10 1007 s00407 007 0017 3 JSTOR 41134289 S2CID 120860272 Jones Alexander 2005 Euclid the Elusive Geometer PDF Euclid and His Heritage Meeting Clay Mathematics Institute Oxford 7 8 October 2005 Asper Markus 2010 Euclid In Gagarin Michael ed The Oxford Encyclopedia of Ancient Greece and Rome Oxford Oxford University Press ISBN 978 0 19 517072 6 Hahl Hermann Peters Hanna 10 June 2022 A Variation of Hilbert s Axioms for Euclidean Geometry Mathematische Semesterberichte 69 2 253 258 doi 10 1007 s00591 022 00320 3 S2CID 249581871 Heath Thomas Little 1911 Pappus of Alexandria In Chisholm Hugh ed Encyclopaedia Britannica Vol 20 11th ed Cambridge University Press pp 470 471 Sialaros Michalis 2021 2015 Euclid Oxford Classical Dictionary Oxford Oxford University Press doi 10 1093 acrefore 9780199381135 013 2521 ISBN 978 0 19 938113 5 Taisbak Christian Marinus van der Waerden Bartel Leendert 5 January 2021 Euclid Encyclopaedia Britannica Chicago Encyclopaedia Britannica Inc Online Euclid J Paul Getty Museum Retrieved 11 August 2022 Euclid n OED Online Oxford Oxford University Press Retrieved 10 August 2022 subscription required Euclidean adj Online Etymology Dictionary Retrieved 18 March 2015 External linksListen to this article 13 minutes source source nbsp This audio file was created from a revision of this article dated 29 September 2020 2020 09 29 and does not reflect subsequent edits Audio help More spoken articles WorksWorks by Euclid at Project Gutenberg Works by or about Euclid at Internet Archive Works by Euclid at LibriVox public domain audiobooks nbsp Euclid Collection at University College London c 500 editions of works by Euclid available online through the Stavros Niarchos Foundation Digital Library Scans of Johan Heiberg s edition of Euclid at wilbourhall orgThe ElementsPDF copy with the original Greek and an English translation on facing pages University of Texas All thirteen books in several languages as Spanish Catalan English German Portuguese Arabic Italian Russian and Chinese Portals nbsp Ancient Greece nbsp Biography nbsp MathematicsEuclid at Wikipedia s sister projects nbsp Media from Commons nbsp Quotations from Wikiquote nbsp Texts from Wikisource nbsp Textbooks from Wikibooks nbsp Resources from Wikiversity Retrieved from https en wikipedia org w index php title Euclid amp oldid 1192137631, wikipedia, wiki, book, books, library,

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