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Geography and cartography in the medieval Islamic world

February 02, 2023

Medieval Islamic geography and cartography refer to the study of geography and cartography in the Muslim world during the Islamic Golden Age (variously dated between the 8th century and 16th century). Muslim scholars made advances to the map-making traditions of earlier cultures,[1] particularly the Hellenistic geographers Ptolemy and Marinus of Tyre,[2]: 193  combined with what explorers and merchants learned in their travels across the Old World (Afro-Eurasia).[1] Islamic geography had three major fields: exploration and navigation, physical geography, and cartography and mathematical geography.[1] Islamic geography reached its apex with Muhammad al-Idrisi in the 12th century.[3]

History

Islamic geography began in the 8th century, influenced by Hellenistic geography,[4] combined with what explorers and merchants learned in their travels across the Old World (Afro-Eurasia).[1] Muslim scholars engaged in extensive exploration and navigation during the 9th-12th centuries, including journeys across the Muslim world, in addition to regions such as China, Southeast Asia and Southern Africa.[1] Various Islamic scholars contributed to the development of geography and cartography, with the most notable including Al-Khwārizmī, Abū Zayd al-Balkhī (founder of the "Balkhi school"), Al-Masudi, Abu Rayhan Biruni and Muhammad al-Idrisi.

Islamic geography was patronized by the Abbasid caliphs of Baghdad. An important influence in the development of cartography was the patronage of the Abbasid caliph al-Ma'mun, who reigned from 813 to 833. He commissioned several geographers to perform an arc measurement, determining the distance on earth that corresponds to one degree of latitude along a meridian (al-Ma'mun's arc measurement). Thus his patronage resulted in the refinement of the definition of the Arabic mile (mīl in Arabic) in comparison to the stadion used in the Hellenistic world. These efforts also enabled Muslims to calculate the circumference of the earth. Al-Mamun also commanded the production of a large map of the world, which has not survived,[5]: 61–63  though it is known that its map projection type was based on Marinus of Tyre rather than Ptolemy.[2]: 193 

Islamic cartographers inherited Ptolemy's Almagest and Geography in the 9th century. These works stimulated an interest in geography (particularly gazetteers) but were not slavishly followed.[6] Instead, Arabian and Persian cartography followed Al-Khwārizmī in adopting a rectangular projection, shifting Ptolemy's Prime Meridian several degrees eastward, and modifying many of Ptolemy's geographical coordinates.

Having received Greek writings directly and without Latin intermediation, Arabian and Persian geographers made no use of T-O maps.[6]

In the 9th century, the Persian mathematician and geographer, Habash al-Hasib al-Marwazi, employed spherical trigonometry and map projection methods in order to convert polar coordinates to a different coordinate system centred on a specific point on the sphere, in this the Qibla, the direction to Mecca.[7] Abū Rayhān Bīrūnī (973–1048) later developed ideas which are seen as an anticipation of the polar coordinate system.[8] Around 1025, he describes a polar equi-azimuthal equidistant projection of the celestial sphere.[9]: 153  However, this type of projection had been used in ancient Egyptian star-maps and was not to be fully developed until the 15 and 16th centuries.[10]

In the early 10th century, Abū Zayd al-Balkhī, originally from Balkh, founded the "Balkhī school" of terrestrial mapping in Baghdad. The geographers of this school also wrote extensively of the peoples, products, and customs of areas in the Muslim world, with little interest in the non-Muslim realms.[5] The "Balkhī school", which included geographers such as Estakhri, al-Muqaddasi and Ibn Hawqal, produced world atlases, each one featuring a world map and twenty regional maps.[2]: 194 

Suhrāb, a late 10th-century Muslim geographer, accompanied a book of geographical coordinates with instructions for making a rectangular world map, with equirectangular projection or cylindrical equidistant projection.[5] The earliest surviving rectangular coordinate map is dated to the 13th century and is attributed to Hamdallah al-Mustaqfi al-Qazwini, who based it on the work of Suhrāb. The orthogonal parallel lines were separated by one degree intervals, and the map was limited to Southwest Asia and Central Asia. The earliest surviving world maps based on a rectangular coordinate grid are attributed to al-Mustawfi in the 14th or 15th century (who used invervals of ten degrees for the lines), and to Hafiz-i Abru (died 1430).[2]: 200–01 

In the 11th century, the Karakhanid Turkic scholar Mahmud al-Kashgari was the first to draw a unique Islamic world map,[11] where he illuminated the cities and places of the Turkic peoples of Central and Inner Asia. He showed the lake Issyk-Kul (in nowadays Kyrgyzstan) as the centre of the world.

Ibn Battuta (1304–1368?) wrote "Rihlah" (Travels) based on three decades of journeys, covering more than 120,000 km through northern Africa, southern Europe, and much of Asia.

Muslim astronomers and geographers were aware of magnetic declination by the 15th century, when the Egyptian astronomer 'Abd al-'Aziz al-Wafa'i (d. 1469/1471) measured it as 7 degrees from Cairo.[12]

Regional cartography

 
Map of Fars from the Kitab al-Masalik wa'l-Mamalik (Book of postal routes and kingdoms) of al-Istakhri

Islamic regional cartography is usually categorized into three groups: that produced by the "Balkhī school", the type devised by Muhammad al-Idrisi, and the type that are uniquely found in the Book of curiosities.[5]

The maps by the Balkhī schools were defined by political, not longitudinal boundaries and covered only the Muslim world. In these maps the distances between various "stops" (cities or rivers) were equalized. The only shapes used in designs were verticals, horizontals, 90-degree angles, and arcs of circles; unnecessary geographical details were eliminated. This approach is similar to that used in subway maps, most notable used in the "London Underground Tube Map" in 1931 by Harry Beck.[5]: 85–87 

Al-Idrīsī defined his maps differently. He considered the extent of the known world to be 160° and had to symbolize 50 dogs in longitude and divided the region into ten parts, each 16° wide. In terms of latitude, he portioned the known world into seven 'climes', determined by the length of the longest day. In his maps, many dominant geographical features can be found.[5]

Book on the appearance of the Earth

Muhammad ibn Mūsā al-Khwārizmī's Kitāb ṣūrat al-Arḍ ("Book on the appearance of the Earth") was completed in 833. It is a revised and completed version of Ptolemy's Geography, consisting of a list of 2402 coordinates of cities and other geographical features following a general introduction.[13]

Al-Khwārizmī, Al-Ma'mun's most famous geographer, corrected Ptolemy's gross overestimate for the length of the Mediterranean Sea[2]: 188  (from the Canary Islands to the eastern shores of the Mediterranean); Ptolemy overestimated it at 63 degrees of longitude, while al-Khwarizmi almost correctly estimated it at nearly 50 degrees of longitude. Al-Ma'mun's geographers "also depicted the Atlantic and Indian Oceans as open bodies of water, not land-locked seas as Ptolemy had done. "[14] Al-Khwarizmi thus set the Prime Meridian of the Old World at the eastern shore of the Mediterranean, 10–13 degrees to the east of Alexandria (the prime meridian previously set by Ptolemy) and 70 degrees to the west of Baghdad. Most medieval Muslim geographers continued to use al-Khwarizmi's prime meridian.[2]: 188  Other prime meridians used were set by Abū Muhammad al-Hasan al-Hamdānī and Habash al-Hasib al-Marwazi at Ujjain, a centre of Indian astronomy, and by another anonymous writer at Basra.[2]: 189 

Al-Biruni

 
Diagram illustrating a method proposed and used by Al-Biruni to estimate the radius and circumference of the Earth in the 11th century.

Abu Rayhan al-Biruni (973–1048) devised a novel method of determining the earth's radius by means of the observation of the height of a mountain. He carried it out at Nandana in Pind Dadan Khan (present-day Pakistan).[15] He used trigonometry to calculate the radius of the Earth using measurements of the height of a hill and measurement of the dip in the horizon from the top of that hill. His calculated radius for the Earth of 3928.77 miles was 2% higher than the actual mean radius of 3847.80 miles.[16] His estimate was given as 12,803,337 cubits, so the accuracy of his estimate compared to the modern value depends on what conversion is used for cubits. The exact length of a cubit is not clear; with an 18 inch cubit his estimate would be 3,600 miles, whereas with a 22 inch cubit his estimate would be 4,200 miles.[17] One significant problem with this approach is that Al-Biruni was not aware of atmospheric refraction and made no allowance for it. He used a dip angle of 34 arc minutes in his calculations, but refraction can typically alter the measured dip angle by about 1/6, making his calculation only accurate to within about 20% of the true value.[18]

In his Codex Masudicus (1037), Al-Biruni theorized the existence of a landmass along the vast ocean between Asia and Europe, or what is today known as the Americas. He argued for its existence on the basis of his accurate estimations of the Earth's circumference and Afro-Eurasia's size, which he found spanned only two-fifths of the Earth's circumference, reasoning that the geological processes that gave rise to Eurasia must surely have given rise to lands in the vast ocean between Asia and Europe. He also theorized that at least some of the unknown landmass would lie within the known latitudes which humans could inhabit, and therefore would be inhabited.[19]

Tabula Rogeriana

Main article: Tabula Rogeriana

The Arab geographer, Muhammad al-Idrisi, produced his medieval atlas, Tabula Rogeriana or The Recreation for Him Who Wishes to Travel Through the Countries, in 1154. He incorporated the knowledge of Africa, the Indian Ocean and the Far East gathered by Arab merchants and explorers with the information inherited from the classical geographers to create the most accurate map of the world in pre-modern times.[20] With funding from Roger II of Sicily (1097–1154), al-Idrisi drew on the knowledge collected at the University of Cordoba and paid draftsmen to make journeys and map their routes. The book describes the earth as a sphere with a circumference of 22,900 miles (36,900 km) but maps it in 70 rectangular sections. Notable features include the correct dual sources of the Nile, the coast of Ghana and mentions of Norway. Climate zones were a chief organizational principle. A second and shortened copy from 1192 called Garden of Joys is known by scholars as the Little Idrisi.[21]

On the work of al-Idrisi, S. P. Scott commented:[20]

The compilation of Edrisi marks an era in the history of science. Not only is its historical information most interesting and valuable, but its descriptions of many parts of the earth are still authoritative. For three centuries geographers copied his maps without alteration. The relative position of the lakes which form the Nile, as delineated in his work, does not differ greatly from that established by Baker and Stanley more than seven hundred years afterwards, and their number is the same. The mechanical genius of the author was not inferior to his erudition. The celestial and terrestrial planisphere of silver which he constructed for his royal patron was nearly six feet in diameter, and weighed four hundred and fifty pounds; upon the one side the zodiac and the constellations, upon the other—divided for convenience into segments—the bodies of land and water, with the respective situations of the various countries, were engraved.

— S. P. Scott, History of the Moorish Empire in Europe

Al-Idrisi's atlas, originally called the Nuzhat in Arabic, served as a major tool for Italian, Dutch and French mapmakers from the 16th century to the 18th century.[22]

Piri Reis map

Main article: Piri Reis map

The Piri Reis map is a world map compiled in 1513 by the Ottoman admiral and cartographer Piri Reis. Approximately one third of the map survives; it shows the western coasts of Europe and North Africa and the coast of Brazil with reasonable accuracy. Various Atlantic islands, including the Azores and Canary Islands, are depicted, as is the mythical island of Antillia and possibly Japan.

Instruments

 
Astrolabe from 9th century North Africa

Muslim scholars invented and refined a number of scientific instruments in mathematical geography and cartography. These included the astrolabe, quadrant, gnomon, celestial sphere, sundial, and compass.[1]

Astrolabe

Astrolabes were adopted and further developed in the medieval Islamic world, where Muslim astronomers introduced angular scales to the design,[23] adding circles indicating azimuths on the horizon.[24] It was widely used throughout the Muslim world, chiefly as an aid to navigation and as a way of finding the Qibla, the direction of Mecca. Eighth-century mathematician Muhammad al-Fazari is the first person credited with building the astrolabe in the Islamic world.[25]

The mathematical background was established by Muslim astronomer Albatenius in his treatise Kitab az-Zij (c. 920 AD), which was translated into Latin by Plato Tiburtinus (De Motu Stellarum). The earliest surviving astrolabe is dated AH 315 (927–28 AD). In the Islamic world, astrolabes were used to find the times of sunrise and the rising of fixed stars, to help schedule morning prayers (salat). In the 10th century, al-Sufi first described over 1,000 different uses of an astrolabe, in areas as diverse as astronomy, astrology, navigation, surveying, timekeeping, prayer, Salat, Qibla, etc.[26][27]

Compass

See also: History of the compass
 
Al-Ashraf's diagram of the compass and Qibla. From MS Cairo TR 105, copied in Yemen, 1293.[28]

The earliest reference to a compass in the Muslim world occurs in a Persian talebook from 1232,[29][30] where a compass is used for navigation during a trip in the Red Sea or the Persian Gulf.[31] The fish-shaped iron leaf described indicates that this early Chinese design has spread outside of China.[32] The earliest Arabic reference to a compass, in the form of magnetic needle in a bowl of water, comes from a work by Baylak al-Qibjāqī, written in 1282 while in Cairo.[29][33] Al-Qibjāqī described a needle-and-bowl compass used for navigation on a voyage he took from Syria to Alexandria in 1242.[29] Since the author describes having witnessed the use of a compass on a ship trip some forty years earlier, some scholars are inclined to antedate its first appearance in the Arab world accordingly.[29] Al-Qibjāqī also reports that sailors in the Indian Ocean used iron fish instead of needles.[34]

Late in the 13th century, the Yemeni Sultan and astronomer al-Malik al-Ashraf described the use of the compass as a "Qibla indicator" to find the direction to Mecca.[35] In a treatise about astrolabes and sundials, al-Ashraf includes several paragraphs on the construction of a compass bowl (ṭāsa). He then uses the compass to determine the north point, the meridian (khaṭṭ niṣf al-nahār), and the Qibla. This is the first mention of a compass in a medieval Islamic scientific text and its earliest known use as a Qibla indicator, although al-Ashraf did not claim to be the first to use it for this purpose.[28][36]

In 1300, an Arabic treatise written by the Egyptian astronomer and muezzin Ibn Simʿūn describes a dry compass used for determining qibla. Like Peregrinus' compass, however, Ibn Simʿūn's compass did not feature a compass card.[28] In the 14th century, the Syrian astronomer and timekeeper Ibn al-Shatir (1304–1375) invented a timekeeping device incorporating both a universal sundial and a magnetic compass. He invented it for the purpose of finding the times of prayers.[37] Arab navigators also introduced the 32-point compass rose during this time.[38] In 1399, an Egyptian reports two different kinds of magnetic compass. One instrument is a “fish” made of willow wood or pumpkin, into which a magnetic needle is inserted and sealed with tar or wax to prevent the penetration of water. The other instrument is a dry compass.[34]

In the 15th century, the description given by Ibn Majid while aligning the compass with the pole star indicates that he was aware of magnetic declination. An explicit value for the declination is given by ʿIzz al-Dīn al-Wafāʾī (fl. 1450s in Cairo).[31]

Pre modern Arabic sources refer to the compass using the term ṭāsa (lit. "bowl") for the floating compass, or ālat al-qiblah ("qibla instrument") for a device used for orienting towards Mecca.[31]

Friedrich Hirth suggested that Arab and Persian traders, who learned about the polarity of the magnetic needle from the Chinese, applied the compass for navigation before the Chinese did.[39] However, Needham described this theory as "erroneous" and "it originates because of a mistranslation" of the term chia-ling found in Zhu Yu's book Pingchow Table Talks.[40]

Notable geographers

Gallery

See also

References

Citations

  1. ^ a b c d e f Buang, Amriah (2014). "Geography in the Islamic World". Encyclopaedia of the History of Science, Technology, and Medicine in Non-Western Cultures. Springer. pp. 1–5. doi:10.1007/978-94-007-3934-5_8611-2. ISBN 978-94-007-3934-5. A prominent feature of the achievement of Muslim scholars in mathematical geography and cartography was the invention of scientific instruments of measurement. Among these were the astrolab (astrolabe), the ruba (quadrant), the gnomon, the celestial sphere, the sundial, and the compass.
  2. ^ a b c d e f g Kennedy, Edward S. (1996). "Mathematical Geography". In Rashed, Roshdi; Morelon, Régis (eds.). Encyclopedia of the History of Arabic Science. Vol. 3. Routledge. pp. 185–201. ISBN 978-0-415-12410-2.
  3. ^ "Muhammad ibn Muhammad al-Idrisi".
  4. ^ Gerald R. Tibbetts, The Beginnings of a Cartographic Tradition, in: John Brian Harley, David Woodward: Cartography in the Traditional Islamic and South Asian Societies, Chicago, 1992, pp. 90–107 (97-100), ISBN 0-226-31635-1
  5. ^ a b c d e f Edson and Savage-Smith (2004)[full citation needed]
  6. ^ a b Edson & Savage-Smith 2004, pp. 61–63.
  7. ^ Koetsier, T.; Bergmans, L. (2005). Mathematics and the Divine. Elsevier. p. 169. ISBN 978-0-444-50328-2.
  8. ^ O'Connor, John J.; Robertson, Edmund F., "Abu Arrayhan Muhammad ibn Ahmad al-Biruni", MacTutor History of Mathematics archive, University of St Andrews
  9. ^ King, David A. (1996). "Astronomy and Islamic society: Qibla, gnomics and timekeeping". In Rashed, Roshdi (ed.). Encyclopedia of the History of Arabic Science. Vol. 1. London, UK and New York, USA: Routledge. pp. 128–184.
  10. ^ Rankin, Bill (2006). "Projection Reference". Radical Cartography.
  11. ^ Hermann A. Die älteste türkische Weltkarte (1076 η. Ch.) // Imago Mundi: Jahrbuch der Alten Kartographie. — Berlin, 1935. — Bd.l. — S. 21—28.
  12. ^ Barmore, Frank E. (April 1985), "Turkish Mosque Orientation and the Secular Variation of the Magnetic Declination", Journal of Near Eastern Studies, University of Chicago Press, 44 (2): 81–98 [98], doi:10.1086/373112, S2CID 161732080
  13. ^ O'Connor, John J.; Robertson, Edmund F., "Cartography", MacTutor History of Mathematics archive, University of St Andrews
  14. ^ Covington, Richard (2007). . Saudi Aramco World, May–June 2007. 10 (3): 17–21. doi:10.1177/1367877907080149. S2CID 145173935. Archived from the original on 2008-05-12. Retrieved 2008-07-06.
  15. ^ Pingree 2010b.
  16. ^ Sparavigna, Amelia (2013). "The Science of Al-Biruni". International Journal of Sciences. 2 (12): 52–60. arXiv:1312.7288. doi:10.18483/ijSci.364. S2CID 119230163.
  17. ^ Douglas (1973, p.211)
  18. ^ Huth, John Edward (2013). The Lost Art of Finding Our Way. Harvard University Press. pp. 216–217. ISBN 9780674072824.
  19. ^ Starr, S. Frederick (12 December 2013). "So, Who Did Discover America? | History Today". www.historytoday.com. Retrieved 2018-07-06.
  20. ^ a b Scott, S. P. (1904). History of the Moorish Empire in Europe. Harvard University Press. pp. 461–2.
  21. ^ "Slide #219: World Maps of al-Idrisi". Henry Davis Consulting.
  22. ^ Glick, Thomas F.; Livesey, Steven; Wallis, Faith (2014). Medieval Science, Technology, and Medicine: An Encyclopedia. Routledge. p. 261. ISBN 9781135459321.
  23. ^ See p. 289 of Martin, L. C. (1923), "Surveying and navigational instruments from the historical standpoint", Transactions of the Optical Society, 24 (5): 289–303, Bibcode:1923TrOS...24..289M, doi:10.1088/1475-4878/24/5/302, ISSN 1475-4878.
  24. ^ Berggren, J. Lennart (2007), "Mathematics in Medieval Islam", in Katz, Victor J. (ed.), The Mathematics of Egypt, Mesopotamia, China, India, and Islam: a Sourcebook, Princeton University Press, p. 519, ISBN 978-0-691-11485-9
  25. ^ Richard Nelson Frye: Golden Age of Persia. p. 163
  26. ^ Dr. Emily Winterburn (National Maritime Museum), Using an Astrolabe, Foundation for Science Technology and Civilisation, 2005.
  27. ^ Lachièz-Rey, Marc; Luminet, Jean-Pierre (2001). Celestial Treasury: From the Music of Spheres to the Conquest of Space. Trans. Joe Laredo. Cambridge, UK: Cambridge University Press. p. 74. ISBN 978-0-521-80040-2.
  28. ^ a b c Schmidl, Petra G. (1996–97). "Two Early Arabic Sources On The Magnetic Compass". Journal of Arabic and Islamic Studies. 1: 81–132. doi:10.5617/jais.4547. http://www.uib.no/jais/v001ht/01-081-132schmidl1.htm#_ftn4 2014-09-02 at the Wayback Machine
  29. ^ a b c d Kreutz, Barbara M. (1973) "Mediterranean Contributions to the Medieval Mariner's Compass", Technology and Culture, 14 (3: July), p. 367–383 JSTOR 3102323
  30. ^ Jawāmeʿ al-ḥekāyāt wa-lawāmeʿ al-rewāyāt by Muhammad al-ʿAwfī
  31. ^ a b c Schmidl, Petra G. (2014-05-08). "Compass". In Ibrahim Kalin (ed.). The Oxford Encyclopedia of Philosophy, Science, and Technology in Islam. Oxford University Press. pp. 144–6. ISBN 978-0-19-981257-8.
  32. ^ Needham p. 12-13 "...that the floating fish-shaped iron leaf spread outside China as a technique, we know from the description of Muhammad al' Awfi just two hundred years later"
  33. ^ Kitāb Kanz al-tujjār fī maʿrifat al-aḥjār
  34. ^ a b "Early Arabic Sources on the Magnetic Compass" (PDF). Lancaster.ac.uk. Retrieved 2016-08-02.
  35. ^ Savage-Smith, Emilie (1988). "Gleanings from an Arabist's Workshop: Current Trends in the Study of Medieval Islamic Science and Medicine". Isis. 79 (2): 246–266 [263]. doi:10.1086/354701. PMID 3049439. S2CID 33884974.
  36. ^ Schmidl, Petra G. (2007). "Ashraf: al‐Malik al‐Ashraf (Mumahhid al‐Dīn) ʿUmar ibn Yūsuf ibn ʿUmar ibn ʿAlī ibn Rasūl". In Thomas Hockey; et al. (eds.). The Biographical Encyclopedia of Astronomers. New York: Springer. pp. 66–7. ISBN 9780387310220. (PDF version)
  37. ^ (King 1983, pp. 547–8)
  38. ^ Tibbetts, G. R. (1973). "Comparisons between Arab and Chinese Navigational Techniques". Bulletin of the School of Oriental and African Studies. 36 (1): 97–108 [105–6]. doi:10.1017/s0041977x00098013. S2CID 120284234.
  39. ^ Hirth, Friedrich (1908). Ancient history of China to the end of the Chóu dynasty. New York, The Columbia university press. p. 134.
  40. ^ Needham, Joseph (1962). Science and Civilisation in China: Volume 4, Physics and Physical Technology, Part 1, Physics. Cambridge University Press. pp. 279–80. ISBN 978-0-521-05802-5.

Sources

  • Alavi, S. M. Ziauddin (1965), Arab geography in the ninth and tenth centuries, Aligarh: Aligarh University Press
  • Douglas, A. Vibert (1973), "Al-Biruni, Persian Scholar, 973–1048", Journal of the Royal Astronomical Society of Canada, 67: 209–211, Bibcode:1973JRASC..67..209D
  • Edson, Evelyn; Savage-Smith, Emilie (2004). Savage-Smith, Emilie (ed.). Medieval Views of the Cosmos. Oxford: Bodleian Library. ISBN 978-1-85124-184-2.
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  • King, David A. (December 2003), "14th-Century England or 9th-Century Baghdad? New Insights on the Elusive Astronomical Instrument Called Navicula de Venetiis", Centaurus, 45 (1–4): 204–226, doi:10.1111/j.1600-0498.2003.450117.x
  • King, David A. (2005), In Synchrony with the Heavens, Studies in Astronomical Timekeeping and Instrumentation in Medieval Islamic Civilization: Instruments of Mass Calculation, Brill Publishers, ISBN 90-04-14188-X
  • McGrail, Sean (2004), Boats of the World, Oxford University Press, ISBN 0-19-927186-0
  • Pingree, David (2010b). "BĪRŪNĪ, ABŪ RAYḤĀN iv. Geography". www.iranicaonline.org. Retrieved 4 July 2018.
  • Mott, Lawrence V. (May 1991), The Development of the Rudder, A.D. 100-1337: A Technological Tale, Thesis, Texas A&M University
  • Rashed, Roshdi; Morelon, Régis (1996), Encyclopedia of the History of Arabic Science, vol. 1 & 3, Routledge, ISBN 0-415-12410-7
  • Sezgin, Fuat (2000), Geschichte Des Arabischen Schrifttums X–XII: Mathematische Geographie und Kartographie im Islam und ihr Fortleben im Abendland, Historische Darstellung, Teil 1–3 (in German), Frankfurt am Main

External links

  • "How Greek Science Passed to the Arabs" by De Lacy O'Leary
  • Islamic Geography in the Middle Ages

February 02, 2023
geography, cartography, medieval, islamic, world, this, article, lead, section, short, adequately, summarize, points, please, consider, expanding, lead, provide, accessible, overview, important, aspects, article, february, 2019, medieval, islamic, geography, c. This article s lead section may be too short to adequately summarize the key points Please consider expanding the lead to provide an accessible overview of all important aspects of the article February 2019 Medieval Islamic geography and cartography refer to the study of geography and cartography in the Muslim world during the Islamic Golden Age variously dated between the 8th century and 16th century Muslim scholars made advances to the map making traditions of earlier cultures 1 particularly the Hellenistic geographers Ptolemy and Marinus of Tyre 2 193 combined with what explorers and merchants learned in their travels across the Old World Afro Eurasia 1 Islamic geography had three major fields exploration and navigation physical geography and cartography and mathematical geography 1 Islamic geography reached its apex with Muhammad al Idrisi in the 12th century 3 Contents 1 History 1 1 Regional cartography 1 2 Book on the appearance of the Earth 1 3 Al Biruni 1 4 Tabula Rogeriana 1 5 Piri Reis map 2 Instruments 2 1 Astrolabe 2 2 Compass 3 Notable geographers 4 Gallery 5 See also 6 References 6 1 Citations 6 2 Sources 7 External linksHistory EditIslamic geography began in the 8th century influenced by Hellenistic geography 4 combined with what explorers and merchants learned in their travels across the Old World Afro Eurasia 1 Muslim scholars engaged in extensive exploration and navigation during the 9th 12th centuries including journeys across the Muslim world in addition to regions such as China Southeast Asia and Southern Africa 1 Various Islamic scholars contributed to the development of geography and cartography with the most notable including Al Khwarizmi Abu Zayd al Balkhi founder of the Balkhi school Al Masudi Abu Rayhan Biruni and Muhammad al Idrisi Islamic geography was patronized by the Abbasid caliphs of Baghdad An important influence in the development of cartography was the patronage of the Abbasid caliph al Ma mun who reigned from 813 to 833 He commissioned several geographers to perform an arc measurement determining the distance on earth that corresponds to one degree of latitude along a meridian al Ma mun s arc measurement Thus his patronage resulted in the refinement of the definition of the Arabic mile mil in Arabic in comparison to the stadion used in the Hellenistic world These efforts also enabled Muslims to calculate the circumference of the earth Al Mamun also commanded the production of a large map of the world which has not survived 5 61 63 though it is known that its map projection type was based on Marinus of Tyre rather than Ptolemy 2 193 Islamic cartographers inherited Ptolemy s Almagest and Geography in the 9th century These works stimulated an interest in geography particularly gazetteers but were not slavishly followed 6 Instead Arabian and Persian cartography followed Al Khwarizmi in adopting a rectangular projection shifting Ptolemy s Prime Meridian several degrees eastward and modifying many of Ptolemy s geographical coordinates Having received Greek writings directly and without Latin intermediation Arabian and Persian geographers made no use of T O maps 6 In the 9th century the Persian mathematician and geographer Habash al Hasib al Marwazi employed spherical trigonometry and map projection methods in order to convert polar coordinates to a different coordinate system centred on a specific point on the sphere in this the Qibla the direction to Mecca 7 Abu Rayhan Biruni 973 1048 later developed ideas which are seen as an anticipation of the polar coordinate system 8 Around 1025 he describes a polar equi azimuthal equidistant projection of the celestial sphere 9 153 However this type of projection had been used in ancient Egyptian star maps and was not to be fully developed until the 15 and 16th centuries 10 In the early 10th century Abu Zayd al Balkhi originally from Balkh founded the Balkhi school of terrestrial mapping in Baghdad The geographers of this school also wrote extensively of the peoples products and customs of areas in the Muslim world with little interest in the non Muslim realms 5 The Balkhi school which included geographers such as Estakhri al Muqaddasi and Ibn Hawqal produced world atlases each one featuring a world map and twenty regional maps 2 194 Suhrab a late 10th century Muslim geographer accompanied a book of geographical coordinates with instructions for making a rectangular world map with equirectangular projection or cylindrical equidistant projection 5 The earliest surviving rectangular coordinate map is dated to the 13th century and is attributed to Hamdallah al Mustaqfi al Qazwini who based it on the work of Suhrab The orthogonal parallel lines were separated by one degree intervals and the map was limited to Southwest Asia and Central Asia The earliest surviving world maps based on a rectangular coordinate grid are attributed to al Mustawfi in the 14th or 15th century who used invervals of ten degrees for the lines and to Hafiz i Abru died 1430 2 200 01 In the 11th century the Karakhanid Turkic scholar Mahmud al Kashgari was the first to draw a unique Islamic world map 11 where he illuminated the cities and places of the Turkic peoples of Central and Inner Asia He showed the lake Issyk Kul in nowadays Kyrgyzstan as the centre of the world Ibn Battuta 1304 1368 wrote Rihlah Travels based on three decades of journeys covering more than 120 000 km through northern Africa southern Europe and much of Asia Muslim astronomers and geographers were aware of magnetic declination by the 15th century when the Egyptian astronomer Abd al Aziz al Wafa i d 1469 1471 measured it as 7 degrees from Cairo 12 Regional cartography Edit Map of Fars from the Kitab al Masalik wa l Mamalik Book of postal routes and kingdoms of al Istakhri Islamic regional cartography is usually categorized into three groups that produced by the Balkhi school the type devised by Muhammad al Idrisi and the type that are uniquely found in the Book of curiosities 5 The maps by the Balkhi schools were defined by political not longitudinal boundaries and covered only the Muslim world In these maps the distances between various stops cities or rivers were equalized The only shapes used in designs were verticals horizontals 90 degree angles and arcs of circles unnecessary geographical details were eliminated This approach is similar to that used in subway maps most notable used in the London Underground Tube Map in 1931 by Harry Beck 5 85 87 Al Idrisi defined his maps differently He considered the extent of the known world to be 160 and had to symbolize 50 dogs in longitude and divided the region into ten parts each 16 wide In terms of latitude he portioned the known world into seven climes determined by the length of the longest day In his maps many dominant geographical features can be found 5 Book on the appearance of the Earth Edit Muhammad ibn Musa al Khwarizmi s Kitab ṣurat al Arḍ Book on the appearance of the Earth was completed in 833 It is a revised and completed version of Ptolemy s Geography consisting of a list of 2402 coordinates of cities and other geographical features following a general introduction 13 Al Khwarizmi Al Ma mun s most famous geographer corrected Ptolemy s gross overestimate for the length of the Mediterranean Sea 2 188 from the Canary Islands to the eastern shores of the Mediterranean Ptolemy overestimated it at 63 degrees of longitude while al Khwarizmi almost correctly estimated it at nearly 50 degrees of longitude Al Ma mun s geographers also depicted the Atlantic and Indian Oceans as open bodies of water not land locked seas as Ptolemy had done 14 Al Khwarizmi thus set the Prime Meridian of the Old World at the eastern shore of the Mediterranean 10 13 degrees to the east of Alexandria the prime meridian previously set by Ptolemy and 70 degrees to the west of Baghdad Most medieval Muslim geographers continued to use al Khwarizmi s prime meridian 2 188 Other prime meridians used were set by Abu Muhammad al Hasan al Hamdani and Habash al Hasib al Marwazi at Ujjain a centre of Indian astronomy and by another anonymous writer at Basra 2 189 Al Biruni Edit Diagram illustrating a method proposed and used by Al Biruni to estimate the radius and circumference of the Earth in the 11th century Abu Rayhan al Biruni 973 1048 devised a novel method of determining the earth s radius by means of the observation of the height of a mountain He carried it out at Nandana in Pind Dadan Khan present day Pakistan 15 He used trigonometry to calculate the radius of the Earth using measurements of the height of a hill and measurement of the dip in the horizon from the top of that hill His calculated radius for the Earth of 3928 77 miles was 2 higher than the actual mean radius of 3847 80 miles 16 His estimate was given as 12 803 337 cubits so the accuracy of his estimate compared to the modern value depends on what conversion is used for cubits The exact length of a cubit is not clear with an 18 inch cubit his estimate would be 3 600 miles whereas with a 22 inch cubit his estimate would be 4 200 miles 17 One significant problem with this approach is that Al Biruni was not aware of atmospheric refraction and made no allowance for it He used a dip angle of 34 arc minutes in his calculations but refraction can typically alter the measured dip angle by about 1 6 making his calculation only accurate to within about 20 of the true value 18 In his Codex Masudicus 1037 Al Biruni theorized the existence of a landmass along the vast ocean between Asia and Europe or what is today known as the Americas He argued for its existence on the basis of his accurate estimations of the Earth s circumference and Afro Eurasia s size which he found spanned only two fifths of the Earth s circumference reasoning that the geological processes that gave rise to Eurasia must surely have given rise to lands in the vast ocean between Asia and Europe He also theorized that at least some of the unknown landmass would lie within the known latitudes which humans could inhabit and therefore would be inhabited 19 Tabula Rogeriana Edit Main article Tabula Rogeriana The Arab geographer Muhammad al Idrisi produced his medieval atlas Tabula Rogeriana or The Recreation for Him Who Wishes to Travel Through the Countries in 1154 He incorporated the knowledge of Africa the Indian Ocean and the Far East gathered by Arab merchants and explorers with the information inherited from the classical geographers to create the most accurate map of the world in pre modern times 20 With funding from Roger II of Sicily 1097 1154 al Idrisi drew on the knowledge collected at the University of Cordoba and paid draftsmen to make journeys and map their routes The book describes the earth as a sphere with a circumference of 22 900 miles 36 900 km but maps it in 70 rectangular sections Notable features include the correct dual sources of the Nile the coast of Ghana and mentions of Norway Climate zones were a chief organizational principle A second and shortened copy from 1192 called Garden of Joys is known by scholars as the Little Idrisi 21 On the work of al Idrisi S P Scott commented 20 The compilation of Edrisi marks an era in the history of science Not only is its historical information most interesting and valuable but its descriptions of many parts of the earth are still authoritative For three centuries geographers copied his maps without alteration The relative position of the lakes which form the Nile as delineated in his work does not differ greatly from that established by Baker and Stanley more than seven hundred years afterwards and their number is the same The mechanical genius of the author was not inferior to his erudition The celestial and terrestrial planisphere of silver which he constructed for his royal patron was nearly six feet in diameter and weighed four hundred and fifty pounds upon the one side the zodiac and the constellations upon the other divided for convenience into segments the bodies of land and water with the respective situations of the various countries were engraved S P Scott History of the Moorish Empire in Europe Al Idrisi s atlas originally called the Nuzhat in Arabic served as a major tool for Italian Dutch and French mapmakers from the 16th century to the 18th century 22 Piri Reis map Edit Main article Piri Reis map The Piri Reis map is a world map compiled in 1513 by the Ottoman admiral and cartographer Piri Reis Approximately one third of the map survives it shows the western coasts of Europe and North Africa and the coast of Brazil with reasonable accuracy Various Atlantic islands including the Azores and Canary Islands are depicted as is the mythical island of Antillia and possibly Japan Instruments Edit Astrolabe from 9th century North Africa Muslim scholars invented and refined a number of scientific instruments in mathematical geography and cartography These included the astrolabe quadrant gnomon celestial sphere sundial and compass 1 Astrolabe Edit Astrolabes were adopted and further developed in the medieval Islamic world where Muslim astronomers introduced angular scales to the design 23 adding circles indicating azimuths on the horizon 24 It was widely used throughout the Muslim world chiefly as an aid to navigation and as a way of finding the Qibla the direction of Mecca Eighth century mathematician Muhammad al Fazari is the first person credited with building the astrolabe in the Islamic world 25 The mathematical background was established by Muslim astronomer Albatenius in his treatise Kitab az Zij c 920 AD which was translated into Latin by Plato Tiburtinus De Motu Stellarum The earliest surviving astrolabe is dated AH 315 927 28 AD In the Islamic world astrolabes were used to find the times of sunrise and the rising of fixed stars to help schedule morning prayers salat In the 10th century al Sufi first described over 1 000 different uses of an astrolabe in areas as diverse as astronomy astrology navigation surveying timekeeping prayer Salat Qibla etc 26 27 Compass Edit See also History of the compass Al Ashraf s diagram of the compass and Qibla From MS Cairo TR 105 copied in Yemen 1293 28 The earliest reference to a compass in the Muslim world occurs in a Persian talebook from 1232 29 30 where a compass is used for navigation during a trip in the Red Sea or the Persian Gulf 31 The fish shaped iron leaf described indicates that this early Chinese design has spread outside of China 32 The earliest Arabic reference to a compass in the form of magnetic needle in a bowl of water comes from a work by Baylak al Qibjaqi written in 1282 while in Cairo 29 33 Al Qibjaqi described a needle and bowl compass used for navigation on a voyage he took from Syria to Alexandria in 1242 29 Since the author describes having witnessed the use of a compass on a ship trip some forty years earlier some scholars are inclined to antedate its first appearance in the Arab world accordingly 29 Al Qibjaqi also reports that sailors in the Indian Ocean used iron fish instead of needles 34 Late in the 13th century the Yemeni Sultan and astronomer al Malik al Ashraf described the use of the compass as a Qibla indicator to find the direction to Mecca 35 In a treatise about astrolabes and sundials al Ashraf includes several paragraphs on the construction of a compass bowl ṭasa He then uses the compass to determine the north point the meridian khaṭṭ niṣf al nahar and the Qibla This is the first mention of a compass in a medieval Islamic scientific text and its earliest known use as a Qibla indicator although al Ashraf did not claim to be the first to use it for this purpose 28 36 In 1300 an Arabic treatise written by the Egyptian astronomer and muezzin Ibn Simʿun describes a dry compass used for determining qibla Like Peregrinus compass however Ibn Simʿun s compass did not feature a compass card 28 In the 14th century the Syrian astronomer and timekeeper Ibn al Shatir 1304 1375 invented a timekeeping device incorporating both a universal sundial and a magnetic compass He invented it for the purpose of finding the times of prayers 37 Arab navigators also introduced the 32 point compass rose during this time 38 In 1399 an Egyptian reports two different kinds of magnetic compass One instrument is a fish made of willow wood or pumpkin into which a magnetic needle is inserted and sealed with tar or wax to prevent the penetration of water The other instrument is a dry compass 34 In the 15th century the description given by Ibn Majid while aligning the compass with the pole star indicates that he was aware of magnetic declination An explicit value for the declination is given by ʿIzz al Din al Wafaʾi fl 1450s in Cairo 31 Pre modern Arabic sources refer to the compass using the term ṭasa lit bowl for the floating compass or alat al qiblah qibla instrument for a device used for orienting towards Mecca 31 Friedrich Hirth suggested that Arab and Persian traders who learned about the polarity of the magnetic needle from the Chinese applied the compass for navigation before the Chinese did 39 However Needham described this theory as erroneous and it originates because of a mistranslation of the term chia ling found in Zhu Yu s book Pingchow Table Talks 40 Notable geographers EditAl Kindi Alkindus 801 873 Ya qubi died 897 Ibn Khordadbeh 820 912 Al Dinawari 820 898 Ahmed ibn Sahl al Balkhi 850 934 Khashkhash Ibn Saeed Ibn Aswad fl 889 Hamdani 893 945 Ali al Masudi 896 956 Ibn al Faqih 10th century Ahmad ibn Fadlan 10th century Ahmad ibn Rustah 10th century Istakhri 10th century Al Muqaddasi 945 1000 Ibn Hawqal died after 977 Ibn al Haytham Alhazen 965 1039 Abu Rayhan Biruni 973 1048 Ibn Sina Avicenna 980 1037 Abu Said Gardezi died 1061 Abu Abdullah al Bakri 1014 1094 Muhammad al Idrisi Dreses 1100 1165 Ibn Rushd Averroes 1126 1198 Ibn Jubayr 1145 1217 Yaqut al Hamawi 1179 1229 Abu al Fida Abulfeda 1273 1331 Hamdollah Mostowfi 1281 1349 Ibn al Wardi 1291 1348 Ibn Battuta 1304 1370s Ibn Khaldun 1332 1406 Ahmad Bin Majid born 1432 Mahmud al Kashgari 1005 1102 Piri Reis 1465 1554 Amin Razi 16th century Gallery Edit Al Masudi s world map 10th century Schematic map of Sicily in the Arabic Book of Curiosities 10th century map of the World by Ibn Hawqal The Persian Gulf in a regional map of the Atlas of Islam Map from Mahmud al Kashgari s Diwan 11th century Muhammad al Idrisi s Tabula Rogeriana 1154 one of the most advanced early world maps Ibn al Wardi s atlas of the world 14th century a manuscript copied in the 17th century Surviving fragment of the first World Map of Piri Reis 1513 showing parts of the AmericasSee also EditHistory of geography History of cartography Cartography of PalestineReferences EditCitations Edit a b c d e f Buang Amriah 2014 Geography in the Islamic World Encyclopaedia of the History of Science Technology and Medicine in Non Western Cultures Springer pp 1 5 doi 10 1007 978 94 007 3934 5 8611 2 ISBN 978 94 007 3934 5 A prominent feature of the achievement of Muslim scholars in mathematical geography and cartography was the invention of scientific instruments of measurement Among these were the astrolab astrolabe the ruba quadrant the gnomon the celestial sphere the sundial and the compass a b c d e f g Kennedy Edward S 1996 Mathematical Geography In Rashed Roshdi Morelon Regis eds Encyclopedia of the History of Arabic Science Vol 3 Routledge pp 185 201 ISBN 978 0 415 12410 2 Muhammad ibn Muhammad al Idrisi Gerald R Tibbetts The Beginnings of a Cartographic Tradition in John Brian Harley David Woodward Cartography in the Traditional Islamic and South Asian Societies Chicago 1992 pp 90 107 97 100 ISBN 0 226 31635 1 a b c d e f Edson and Savage Smith 2004 full citation needed a b Edson amp Savage Smith 2004 pp 61 63 Koetsier T Bergmans L 2005 Mathematics and the Divine Elsevier p 169 ISBN 978 0 444 50328 2 O Connor John J Robertson Edmund F Abu Arrayhan Muhammad ibn Ahmad al Biruni MacTutor History of Mathematics archive University of St Andrews King David A 1996 Astronomy and Islamic society Qibla gnomics and timekeeping In Rashed Roshdi ed Encyclopedia of the History of Arabic Science Vol 1 London UK and New York USA Routledge pp 128 184 Rankin Bill 2006 Projection Reference Radical Cartography Hermann A Die alteste turkische Weltkarte 1076 h Ch Imago Mundi Jahrbuch der Alten Kartographie Berlin 1935 Bd l S 21 28 Barmore Frank E April 1985 Turkish Mosque Orientation and the Secular Variation of the Magnetic Declination Journal of Near Eastern Studies University of Chicago Press 44 2 81 98 98 doi 10 1086 373112 S2CID 161732080 O Connor John J Robertson Edmund F Cartography MacTutor History of Mathematics archive University of St Andrews Covington Richard 2007 Nation identity and the fascination with forensic science in Sherlock Holmes and CSI Saudi Aramco World May June 2007 10 3 17 21 doi 10 1177 1367877907080149 S2CID 145173935 Archived from the original on 2008 05 12 Retrieved 2008 07 06 Pingree 2010b Sparavigna Amelia 2013 The Science of Al Biruni International Journal of Sciences 2 12 52 60 arXiv 1312 7288 doi 10 18483 ijSci 364 S2CID 119230163 Douglas 1973 p 211 Huth John Edward 2013 The Lost Art of Finding Our Way Harvard University Press pp 216 217 ISBN 9780674072824 Starr S Frederick 12 December 2013 So Who Did Discover America History Today www historytoday com Retrieved 2018 07 06 a b Scott S P 1904 History of the Moorish Empire in Europe Harvard University Press pp 461 2 Slide 219 World Maps of al Idrisi Henry Davis Consulting Glick Thomas F Livesey Steven Wallis Faith 2014 Medieval Science Technology and Medicine An Encyclopedia Routledge p 261 ISBN 9781135459321 See p 289 of Martin L C 1923 Surveying and navigational instruments from the historical standpoint Transactions of the Optical Society 24 5 289 303 Bibcode 1923TrOS 24 289M doi 10 1088 1475 4878 24 5 302 ISSN 1475 4878 Berggren J Lennart 2007 Mathematics in Medieval Islam in Katz Victor J ed The Mathematics of Egypt Mesopotamia China India and Islam a Sourcebook Princeton University Press p 519 ISBN 978 0 691 11485 9 Richard Nelson Frye Golden Age of Persia p 163 Dr Emily Winterburn National Maritime Museum Using an Astrolabe Foundation for Science Technology and Civilisation 2005 Lachiez Rey Marc Luminet Jean Pierre 2001 Celestial Treasury From the Music of Spheres to the Conquest of Space Trans Joe Laredo Cambridge UK Cambridge University Press p 74 ISBN 978 0 521 80040 2 a b c Schmidl Petra G 1996 97 Two Early Arabic Sources On The Magnetic Compass Journal of Arabic and Islamic Studies 1 81 132 doi 10 5617 jais 4547 http www uib no jais v001ht 01 081 132schmidl1 htm ftn4 Archived 2014 09 02 at the Wayback Machine a b c d Kreutz Barbara M 1973 Mediterranean Contributions to the Medieval Mariner s Compass Technology and Culture 14 3 July p 367 383 JSTOR 3102323 Jawameʿ al ḥekayat wa lawameʿ al rewayat by Muhammad al ʿAwfi a b c Schmidl Petra G 2014 05 08 Compass In Ibrahim Kalin ed The Oxford Encyclopedia of Philosophy Science and Technology in Islam Oxford University Press pp 144 6 ISBN 978 0 19 981257 8 Needham p 12 13 that the floating fish shaped iron leaf spread outside China as a technique we know from the description of Muhammad al Awfi just two hundred years later Kitab Kanz al tujjar fi maʿrifat al aḥjar a b Early Arabic Sources on the Magnetic Compass PDF Lancaster ac uk Retrieved 2016 08 02 Savage Smith Emilie 1988 Gleanings from an Arabist s Workshop Current Trends in the Study of Medieval Islamic Science and Medicine Isis 79 2 246 266 263 doi 10 1086 354701 PMID 3049439 S2CID 33884974 Schmidl Petra G 2007 Ashraf al Malik al Ashraf Mumahhid al Din ʿUmar ibn Yusuf ibn ʿUmar ibn ʿAli ibn Rasul In Thomas Hockey et al eds The Biographical Encyclopedia of Astronomers New York Springer pp 66 7 ISBN 9780387310220 PDF version King 1983 pp 547 8 Tibbetts G R 1973 Comparisons between Arab and Chinese Navigational Techniques Bulletin of the School of Oriental and African Studies 36 1 97 108 105 6 doi 10 1017 s0041977x00098013 S2CID 120284234 Hirth Friedrich 1908 Ancient history of China to the end of the Chou dynasty New York The Columbia university press p 134 Needham Joseph 1962 Science and Civilisation in China Volume 4 Physics and Physical Technology Part 1 Physics Cambridge University Press pp 279 80 ISBN 978 0 521 05802 5 Sources Edit Alavi S M Ziauddin 1965 Arab geography in the ninth and tenth centuries Aligarh Aligarh University Press Douglas A Vibert 1973 Al Biruni Persian Scholar 973 1048 Journal of the Royal Astronomical Society of Canada 67 209 211 Bibcode 1973JRASC 67 209D Edson Evelyn Savage Smith Emilie 2004 Savage Smith Emilie ed Medieval Views of the Cosmos Oxford Bodleian Library ISBN 978 1 85124 184 2 King David A 1983 The Astronomy of the Mamluks Isis 74 4 531 555 doi 10 1086 353360 S2CID 144315162 King David A 2002 A Vetustissimus Arabic Text on the Quadrans Vetus Journal for the History of Astronomy 33 237 255 doi 10 1177 002182860203300302 S2CID 125329755 King David A December 2003 14th Century England or 9th Century Baghdad New Insights on the Elusive Astronomical Instrument Called Navicula de Venetiis Centaurus 45 1 4 204 226 doi 10 1111 j 1600 0498 2003 450117 x King David A 2005 In Synchrony with the Heavens Studies in Astronomical Timekeeping and Instrumentation in Medieval Islamic Civilization Instruments of Mass Calculation Brill Publishers ISBN 90 04 14188 X McGrail Sean 2004 Boats of the World Oxford University Press ISBN 0 19 927186 0 Pingree David 2010b BiRuNi ABu RAYḤAN iv Geography www iranicaonline org Retrieved 4 July 2018 Mott Lawrence V May 1991 The Development of the Rudder A D 100 1337 A Technological Tale Thesis Texas A amp M University Rashed Roshdi Morelon Regis 1996 Encyclopedia of the History of Arabic Science vol 1 amp 3 Routledge ISBN 0 415 12410 7 Sezgin Fuat 2000 Geschichte Des Arabischen Schrifttums X XII Mathematische Geographie und Kartographie im Islam und ihr Fortleben im Abendland Historische Darstellung Teil 1 3 in German Frankfurt am MainExternal links Edit How Greek Science Passed to the Arabs by De Lacy O Leary Islamic Geography in the Middle Ages Retrieved from https en wikipedia org w index php title Geography and cartography in the medieval Islamic world amp oldid 1129931608, wikipedia, wiki, book, books, library,

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