^Ifrah 2000,第346頁 harvnb模板錯誤: 無指向目標: CITEREFIfrah2000 (幫助): "The measure of the genius of Indian civilisation, to which we owe our modern (number) system, is all the greater in that it was the only one in all history to have achieved this triumph. Some cultures succeeded, earlier than the Indian, in discovering one or at best two of the characteristics of this intellectual feat. But none of them managed to bring together into a complete and coherent system the necessary and sufficient conditions for a number-system with the same potential as our own."
^Bourbaki 1998,第46頁: "...our decimal system, which (by the agency of the Arabs) is derived from Hindu mathematics, where its use is attested already from the first centuries of our era. It must be noted moreover that the conception of zero as a number and not as a simple symbol of separation) and its introduction into calculations, also count amongst the original contribution of the Hindus."
^Bourbaki 1998,第49頁: Modern arithmetic was known during medieval times as "Modus Indorum" or method of the Indians. Leonardo of Pisa wrote that compared to method of the Indians all other methods is a mistake. This method of the Indians is none other than our very simple arithmetic of addition, subtraction, multiplication and division. Rules for these four simple procedures was first written down by Brahmagupta during 7th century AD. "On this point, the Hindus are already conscious of the interpretation that negative numbers must have in certain cases (a debt in a commercial problem, for instance). In the following centuries, as there is a diffusion into the West (by intermediary of the Arabs) of the methods and results of Greek and Hindu mathematics, one becomes more used to the handling of these numbers, and one begins to have other "representation" for them which are geometric or dynamic."
^ 7.07.1"algebra" 2007. Britannica Concise Encyclopedia (页面存档备份,存于互联网档案馆). Encyclopædia Britannica Online. 16 May 2007. Quote: "A full-fledged decimal, positional system certainly existed in India by the 9th century (AD), yet many of its central ideas had been transmitted well before that time to China and the Islamic world. Indian arithmetic, moreover, developed consistent and correct rules for operating with positive and negative numbers and for treating zero like any other number, even in problematic contexts such as division. Several hundred years passed before European mathematicians fully integrated such ideas into the developing discipline of algebra."
^(Pingree 2003,第45頁) Quote: "Geometry, and its branch trigonometry, was the mathematics Indian astronomers used most frequently. Greek mathematicians used the full chord and never imagined the half chord that we use today. Half chord was first used by Aryabhata which made trigonometry much more simple. In fact, the Indian astronomers in the third or fourth century, using a pre-Ptolemaic Greek table of chords, produced tables of sines and versines, from which it was trivial to derive cosines. This new system of trigonometry, produced in India, was transmitted to the Arabs in the late eighth century and by them, in an expanded form, to the Latin West and the Byzantine East in the twelfth century."
^(Bourbaki 1998,第126頁): "As for trigonometry, it is disdained by geometers and abandoned to surveyors and astronomers; it is these latter (Aristarchus, Hipparchus, Ptolemy) who establish the fundamental relations between the sides and angles of a right angled triangle (plane or spherical) and draw up the first tables (they consist of tables giving the chord of the arc cut out by an angle on a circle of radius r, in other words the number ; the introduction of the sine, more easily handled, is due to Hindu mathematicians of the Middle Ages)."
^Bressoud 2002,第12頁 Quote: "There is no evidence that the Indian work on series was known beyond India, or even outside Kerala, until the nineteenth century. Gold and Pingree assert [4] that by the time these series were rediscovered in Europe, they had, for all practical purposes, been lost to India. The expansions of the sine, cosine, and arc tangent had been passed down through several generations of disciples, but they remained sterile observations for which no one could find much use."
^Plofker 2001,第293頁 Quote: "It is not unusual to encounter in discussions of Indian mathematics such assertions as that “the concept of differentiation was understood [in India] from the time of Manjula (... in the 10th century)” [Joseph 1991, 300], or that "we may consider Madhava to have been the founder of mathematical analysis" (Joseph 1991, 293), or that Bhaskara II may claim to be "the precursor of Newton and Leibniz in the discovery of the principle of the differential calculus" (Bag 1979, 294). ... The points of resemblance, particularly between early European calculus and the Keralese work on power series, have even inspired suggestions of a possible transmission of mathematical ideas from the Malabar coast in or after the 15th century to the Latin scholarly world (e.g., in (Bag 1979, 285)). ... It should be borne in mind, however, that such an emphasis on the similarity of Sanskrit (or Malayalam) and Latin mathematics risks diminishing our ability fully to see and comprehend the former. To speak of the Indian "discovery of the principle of the differential calculus" somewhat obscures the fact that Indian techniques for expressing changes in the Sine by means of the Cosine or vice versa, as in the examples we have seen, remained within that specific trigonometric context. The differential "principle" was not generalised to arbitrary functions—in fact, the explicit notion of an arbitrary function, not to mention that of its
derivative or an algorithm for taking the derivative, is irrelevant here"
^Pingree 1992,第562頁 Quote:"One example I can give you relates to the Indian Mādhava's demonstration, in about 1400 A.D., of the infinite power series of trigonometrical functions using geometrical and algebraic arguments. When this was first described in English by Charles Matthew Whish, in the 1830s, it was heralded as the Indians' discovery of the calculus. This claim and Mādhava's achievements were ignored by Western historians, presumably at first because they could not admit that an Indian discovered the calculus, but later because no one read anymore the Transactions of the Royal Asiatic Society, in which Whish's article was published. The matter resurfaced in the 1950s, and now we have the Sanskrit texts properly edited, and we understand the clever way that Mādhava derived the series without the calculus; but many historians still find it impossible to conceive of the problem and its solution in terms of anything other than the calculus and proclaim that the calculus is what Mādhava found. In this case the elegance and brilliance of Mādhava's mathematics are being distorted as they are buried under the current mathematical solution to a problem to which he discovered an alternate and powerful solution."
^Katz 1995,第173–174頁 Quote:"How close did Islamic and Indian scholars come to inventing the calculus? Islamic scholars nearly developed a general formula for finding integrals of polynomials by A.D. 1000—and evidently could find such a formula for any polynomial in which they were interested. But, it appears, they were not interested in any polynomial of degree higher than four, at least in any of the material that has come down to us. Indian scholars, on the other hand, were by 1600 able to use ibn al-Haytham's sum formula for arbitrary integral powers in calculating power series for the functions in which they were interested. By the same time, they also knew how to calculate the differentials of these functions. So some of the basic ideas of calculus were known in Egypt and India many centuries before Newton. It does not appear, however, that either Islamic or Indian mathematicians saw the necessity of connecting some of the disparate ideas that we include under the name calculus. They were apparently only interested in specific cases in which these ideas were needed. ... There is no danger, therefore, that we will have to rewrite the history texts to remove the statement that Newton and Leibniz invented calculus. They were certainly the ones who were able to combine many differing ideas under the two unifying themes of the derivative and the integral, show the connection between them, and turn the calculus into the great problem-solving tool we have today."
^Bisht, R. S., Excavations at Banawali: 1974–77, Possehl, Gregory L. (编), Harappan Civilisation: A Contemporary Perspective, New Delhi: Oxford and IBH Publishing Co.: 113–124, 1982
Bressoud, David, Was Calculus Invented in India?, The College Mathematics Journal (Math. Assoc. Amer.), 2002, 33 (1): 2–13, JSTOR 1558972, doi:10.2307/1558972.
Bronkhorst, Johannes, Panini and Euclid: Reflections on Indian Geometry, Journal of Indian Philosophy (Springer Netherlands), 2001, 29 (1–2): 43–80, doi:10.1023/A:1017506118885.
Burnett, Charles, The Semantics of Indian Numerals in Arabic, Greek and Latin, Journal of Indian Philosophy (Springer-Netherlands), 2006, 34 (1–2): 15–30, doi:10.1007/s10781-005-8153-z.
Burton, David M., The History of Mathematics: An Introduction, The McGraw-Hill Companies, Inc.: 193–220, 1997.
Cooke, Roger, The History of Mathematics: A Brief Course, New York: Wiley-Interscience, 632 pages, 2005, ISBN 978-0-471-44459-6.
Datta, Bibhutibhusan, Early Literary Evidence of the Use of the Zero in India, The American Mathematical Monthly, December 1931, 38 (10): 566–572, JSTOR 2301384, doi:10.2307/2301384.
Datta, Bibhutibhusan; Singh, Avadesh Narayan, History of Hindu Mathematics : A source book, Bombay: Asia Publishing House, 1962.
De Young, Gregg, Euclidean Geometry in the Mathematical Tradition of Islamic India, Historia Mathematica, 1995, 22 (2): 138–153, doi:10.1006/hmat.1995.1014.
Encyclopædia Britannica (Kim Plofker), mathematics, South Asian, Encyclopædia Britannica Online, 2007: 1–12 [18 May 2007].
Fowler, David, Binomial Coefficient Function, The American Mathematical Monthly, 1996, 103 (1): 1–17, JSTOR 2975209, doi:10.2307/2975209.
Hayashi, Takao, The Bakhshali Manuscript, An ancient Indian mathematical treatise, Groningen: Egbert Forsten, 596 pages, 1995, ISBN 978-90-6980-087-5.
Hayashi, Takao, Aryabhata's Rule and Table of Sine-Differences, Historia Mathematica, 1997, 24 (4): 396–406, doi:10.1006/hmat.1997.2160.
Hayashi, Takao, Indian Mathematics, Grattan-Guinness, Ivor (编), Companion Encyclopedia of the History and Philosophy of the Mathematical Sciences, 1, pp. 118–130, Baltimore, MD: The Johns Hopkins University Press, 976 pages, 2003, ISBN 978-0-8018-7396-6.
Hayashi, Takao, Indian Mathematics, Flood, Gavin (编), The Blackwell Companion to Hinduism, Oxford: Basil Blackwell, 616 pages, pp. 360–375: 360–375, 2005, ISBN 978-1-4051-3251-0.
Katz, Victor J., Ideas of Calculus in Islam and India, Mathematics Magazine (Math. Assoc. Amer.), 1995, 68 (3): 163–174, JSTOR 2691411, doi:10.2307/2691411.
Katz, Victor J. (编), The Mathematics of Egypt, Mesopotamia, China, India, and Islam: A Sourcebook, Princeton, NJ: Princeton University Press, 685 pages, pp 385–514, 2007, ISBN 978-0-691-11485-9.
Keller, Agathe, Making diagrams speak, in Bhāskara I's commentary on the Aryabhaṭīya, Historia Mathematica, 2005, 32 (3): 275–302, doi:10.1016/j.hm.2004.09.001.
Kichenassamy, Satynad, Baudhāyana's rule for the quadrature of the circle, Historia Mathematica, 2006, 33 (2): 149–183, doi:10.1016/j.hm.2005.05.001.
Pingree, David, On the Greek Origin of the Indian Planetary Model Employing a Double Epicycle, Journal of Historical Astronomy, 1971, 2 (1): 80–85, doi:10.1177/002182867100200202.
Pingree, David, The Mesopotamian Origin of Early Indian Mathematical Astronomy, Journal of Historical Astronomy, 1973, 4 (1): 1–12, doi:10.1177/002182867300400102.
Pingree, David; Staal, Frits, Reviewed Work(s): The Fidelity of Oral Tradition and the Origins of Science by Frits Staal, Journal of the American Oriental Society, 1988, 108 (4): 637–638, JSTOR 603154, doi:10.2307/603154.
Plofker, Kim, An Example of the Secant Method of Iterative Approximation in a Fifteenth-Century Sanskrit Text, Historia Mathematica, 1996, 23 (3): 246–256, doi:10.1006/hmat.1996.0026.
Plofker, Kim, The "Error" in the Indian "Taylor Series Approximation" to the Sine, Historia Mathematica, 2001, 28 (4): 283–295, doi:10.1006/hmat.2001.2331.
Plofker, K., Mathematics of India, Katz, Victor J. (编), The Mathematics of Egypt, Mesopotamia, China, India, and Islam: A Sourcebook, Princeton, NJ: Princeton University Press, 685 pages, pp 385–514: 385–514, 2007, ISBN 978-0-691-11485-9.
Plofker, Kim, Mathematics in India: 500 BCE–1800 CE, Princeton, NJ: Princeton University Press. Pp. 384., 2009, ISBN 978-0-691-12067-6.
Price, John F., Applied geometry of the Sulba Sutras(PDF), Gorini, Catherine A. (编), Geometry at Work: Papers in Applied Geometry, 53, pp. 46–58, Washington DC: Mathematical Association of America Notes, 236 pages: 46–58, 2000 [2019-08-11], ISBN 978-0-88385-164-7, (原始内容(PDF)存档于2007-09-27).
Roy, Ranjan, Discovery of the Series Formula for by Leibniz, Gregory, and Nilakantha, Mathematics Magazine (Math. Assoc. Amer.), 1990, 63 (5): 291–306, JSTOR 2690896, doi:10.2307/2690896.
Staal, Frits, The Fidelity of Oral Tradition and the Origins of Science, Mededelingen der Koninklijke Nederlandse Akademie von Wetenschappen, Afd. Letterkunde, NS 49, 8. Amsterdam: North Holland Publishing Company, 40 pages, 1986.
Staal, Frits, The Sanskrit of science, Journal of Indian Philosophy (Springer Netherlands), 1995, 23 (1): 73–127, doi:10.1007/BF01062067.
Staal, Frits, Greek and Vedic Geometry, Journal of Indian Philosophy, 1999, 27 (1–2): 105–127, doi:10.1023/A:1004364417713.
Staal, Frits, Squares and oblongs in the Veda, Journal of Indian Philosophy (Springer Netherlands), 2001, 29 (1–2): 256–272, doi:10.1023/A:1017527129520.
Staal, Frits, Artificial Languages Across Sciences and Civilisations, Journal of Indian Philosophy (Springer Netherlands), 2006, 34 (1): 89–141, doi:10.1007/s10781-005-8189-0.
Thibaut, George, Mathematics in the Making in Ancient India: reprints of 'On the Sulvasutras' and 'Baudhyayana Sulva-sutra', Calcutta and Delhi: K. P. Bagchi and Company (orig. Journal of Asiatic Society of Bengal), 133 pages, 1984 [1875].
van der Waerden, B. L., Geometry and Algebra in Ancient Civilisations, Berlin and New York: Springer, 223 pages, 1983, ISBN 978-0-387-12159-8
van der Waerden, B. L., On the Romaka-Siddhānta, Archive for History of Exact Sciences, 1988, 38 (1): 1–11, doi:10.1007/BF00329976
van der Waerden, B. L., Reconstruction of a Greek table of chords, Archive for History of Exact Sciences, 1988, 38 (1): 23–38, doi:10.1007/BF00329978
Van Nooten, B., Binary numbers in Indian antiquity, Journal of Indian Philosophy (Springer Netherlands), 1993, 21 (1): 31–50, doi:10.1007/BF01092744
Whish, Charles, On the Hindú Quadrature of the Circle, and the infinite Series of the proportion of the circumference to the diameter exhibited in the four S'ástras, the Tantra Sangraham, Yucti Bháshá, Carana Padhati, and Sadratnamála, Transactions of the Royal Asiatic Society of Great Britain and Ireland, 1835, 3 (3): 509–523, JSTOR 25581775, doi:10.1017/S0950473700001221
Yano, Michio, Oral and Written Transmission of the Exact Sciences in Sanskrit, Journal of Indian Philosophy (Springer Netherlands), 2006, 34 (1–2): 143–160, doi:10.1007/s10781-005-8175-6
延伸阅读
梵语文献
Keller, Agathe, Expounding the Mathematical Seed. Vol. 1: The Translation: A Translation of Bhaskara I on the Mathematical Chapter of the Aryabhatiya, Basel, Boston, and Berlin: Birkhäuser Verlag, 172 pages, 2006, ISBN 978-3-7643-7291-0.
Keller, Agathe, Expounding the Mathematical Seed. Vol. 2: The Supplements: A Translation of Bhaskara I on the Mathematical Chapter of the Aryabhatiya, Basel, Boston, and Berlin: Birkhäuser Verlag, 206 pages, 2006, ISBN 978-3-7643-7292-7.
Neugebauer, Otto; Pingree, David (编), The Pañcasiddhāntikā of Varāhamihira, New edition with translation and commentary, (2 Vols.), Copenhagen, 1970.
Pingree, David (编), The Yavanajātaka of Sphujidhvaja, edited, translated and commented by D. Pingree, Cambridge, MA: Harvard Oriental Series 48 (2 vols.), 1978.
Sarma, K. V. (编), Āryabhaṭīya of Āryabhaṭa with the commentary of Sūryadeva Yajvan, critically edited with Introduction and Appendices, New Delhi: Indian National Science Academy, 1976.
Sen, S. N.; Bag, A. K. (编), The Śulbasūtras of Baudhāyana, Āpastamba, Kātyāyana and Mānava, with Text, English Translation and Commentary, New Delhi: Indian National Science Academy, 1983.
Shukla, K. S. (编), Āryabhaṭīya of Āryabhaṭa with the commentary of Bhāskara I and Someśvara, critically edited with Introduction, English Translation, Notes, Comments and Indexes, New Delhi: Indian National Science Academy, 1976.
Shukla, K. S. (编), Āryabhaṭīya of Āryabhaṭa, critically edited with Introduction, English Translation, Notes, Comments and Indexes, in collaboration with K.V. Sarma, New Delhi: Indian National Science Academy, 1988.
InSIGHT 2009(页面存档备份,存于互联网档案馆), a workshop on traditional Indian sciences for school children conducted by the Computer Science department of Anna University, Chennai, India.
Untuk kegunaan lain, lihat Eni (disambiguasi). Eni S.p.A.Palazzo Eni, kantor pusat Eni di RomaJenisPerusahaan publikKode emitenBIT: ENINYSE: EKomponen FTSE MIBISINIT0003132476IndustriMinyak dan gasDidirikan10 Februari 1953; 71 tahun lalu (1953-02-10)KantorpusatRoma, ItaliaWilayah operasiSeluruh duniaTokohkunciLucia Calvosa [it] (Chairman)Claudio Descalzi (CEO)ProdukMinyak bumi, gas alam, produk minyak bumiPendapatan €44 milyar (2020)[1]Laba operasi -€3,275 m...
Ne doit pas être confondu avec Jean Ribit de la Rivière. Pour les articles homonymes, voir La Rivière. Jean de La RivièreBiographieActivité MilitaireBlasonmodifier - modifier le code - modifier Wikidata Jean IV de la Rivière (~1338 - † 1365) est chevalier du régent, diplomate et premier chambellan de Charles V. Seigneur de la Rivière près de Couloutre (Nièvre), il est aussi appelé Jean Bureau de la Rivière[1]. Biographie Il est le fils aîné de Jean II de la Rivière (? - † ...
Football group consisting of Portugal, Ghana, Uruguay, and South Korea The opening ceremony of the match between Uruguay and Portugal Group H of the 2022 FIFA World Cup took place from 24 November to 2 December 2022.[1] The group consisted of Portugal, Ghana, Uruguay and South Korea. The top two teams, Portugal and South Korea advanced to the round of 16.[2] Uruguay exited the tournament after failing to progress the group stage for the first time since 2002, with South Korea'...
Attempts to re-establish historical polytheistic religions Some of this article's listed sources may not be reliable. Please help improve this article by looking for better, more reliable sources. Unreliable citations may be challenged and removed. (September 2023) (Learn how and when to remove this template message) Nova Roma sacrifice to Concordia at Aquincum (Budapest), Floralia 2008 Polytheistic reconstructionism (or simply reconstructionism) is an approach to modern paganism first emergi...
Voce principale: Trophée des champions. Supercoppa di Francia 2003Trophée des champions 2003 Competizione Supercoppa di Francia Sport Calcio Edizione 27ª Organizzatore LFP Date 26 luglio 2003 Luogo Francia Partecipanti 2 Risultati Vincitore Olympique Lione(3º titolo) Secondo Auxerre Statistiche Incontri disputati 1 Gol segnati 3 (3 per incontro) Pubblico 18 254 (18 254 per incontro) Cronologia della competizione 2002 2004 Manuale La Supercoppa di Francia 2003 (uffici...
6th governor of United Provinces Sir Maurice Garnier HallettGovernor of United ProvincesIn office7 December 1939 – 6 December 1945Governor of Bihar ProvinceIn office1937–1939Home Secretary to the Government of British IndiaIn office12 April 1933 – 1936Preceded bySir H. W. EmersonSucceeded bySir R. M. MaxwellChief Secretary to the Government of Bihar and Orissa ProvinceIn office1930 – 11 April 1933Secretary to the Government of Bihar and Orissa ProvinceIn off...
Kazakhstani footballer Ulan Konysbayev Ulan Konysbayev during the match against Austria on 16 October 2012.Personal informationFull name Ulan Abirbekuly KonysbayevDate of birth (1989-05-28) 28 May 1989 (age 34)Place of birth Ust-Kamenogorsk, Kazakh SSR, Soviet UnionHeight 1.75 m (5 ft 9 in)Position(s) Attacking midfielderTeam informationCurrent team TarazNumber 68Youth career TarazSenior career*Years Team Apps (Gls)2006–2007 Zhambyl 42 (5)2008–2010 Taraz 82 (14)2011–...
2014 book by Donald Gutstein Harperism: How Stephen Harper and his think tank colleagues have transformed Canada AuthorDonald GutsteinPublisherJames Lorimer & CompanyPublication dateSeptember 3, 2014Pages288ISBN9781459406636 Harperism: How Stephen Harper and his think tank colleagues have transformed Canada is a non-fiction book written by Vancouver-based Donald Gutstein, media critic and professor emeritus at Simon Fraser University's School of Communication.[1] Gutstein's work f...
British political scientist This article has multiple issues. Please help improve it or discuss these issues on the talk page. (Learn how and when to remove these template messages) This biography of a living person needs additional citations for verification. Please help by adding reliable sources. Contentious material about living persons that is unsourced or poorly sourced must be removed immediately from the article and its talk page, especially if potentially libelous.Find sources: ...
German art book publisher For other uses, see Taschen (disambiguation). This article has multiple issues. Please help improve it or discuss these issues on the talk page. (Learn how and when to remove these template messages) A major contributor to this article appears to have a close connection with its subject. It may require cleanup to comply with Wikipedia's content policies, particularly neutral point of view. Please discuss further on the talk page. (September 2017) (Learn how and when ...
Pour les articles homonymes, voir Týnec. Cet article est une ébauche concernant une localité tchèque. Vous pouvez partager vos connaissances en l’améliorant (comment ?) selon les recommandations des projets correspondants. Týnec Administration Pays Tchéquie Région Moravie-du-Sud District Břeclav Région historique Moravie Maire Hana Zoubková Code postal 691 54 Indicatif téléphonique international +(420) Démographie Population 1 109 hab. (2020) Densité 96...
6th–3rd BC Arab kingdom in northwest Arabia Lihyanite and Dedanite redirect here. For the ancient script formerly known by these names, see Dadanitic. Dadan redirects here. For the island in Taiwan, see Dadan Island. Lihyanite Kingdomمملكة لحيان6th century BC–3rd century BCCapitalDedanCommon languagesDadaniticReligion North Arabian polytheismGovernmentMonarchyKing Historical eraAntiquity• Established 6th century BC• annexed by the Nabataean state 3rd cent...
Roman emperor in 193 Didius JulianusModern replica of an ancient bust in the Capitoline Museums[1]Roman emperorReign28 March – 2 June 193PredecessorPertinaxSuccessorSeptimius SeverusBorn29 January 133Mediolanum, ItalyDied2 June 193 (aged 60)Rome, ItalySpouseManlia ScantillaIssueDidia ClaraNamesMarcus Didius JulianusRegnal nameImperator Caesar Marcus Didius Severus Julianus Augustus[2][3]FatherQuintus Petronius Didius SeverusMotherAemilia Clara Roman imperial dynastie...
تاريخ بنغلاديشالتأثيراتأحد جوانب بنغلاديش فرع من تاريخ آسيا تعديل - تعديل مصدري - تعديل ويكي بيانات تاريخ آسيا الجنوبية و تاريخ الهند العصر الحجري 70,000–3300 ق. م · ثقافة مهرغاره · 7000–3300 ق. م حضارة وادي السند 3300–1700 ق. م ثقافة هارابان المتأخرة 1700–1300 ق. م العصر الفيدي 1500–500 ق. م · ...
Commander of the Imperial Fleet of the Byzantine navy Megas droungarios redirects here. For the judicial office megas droungarios tēs viglas, see Droungarios of the Watch. Gold solidus of Romanos I Lekapenos, who used his position as droungarios of the Fleet to become Emperor The droungarios of the Fleet (Greek: δρουγγάριος τοῦ πλοΐμου/τῶν πλοΐμων, droungarios tou ploïmou/tōn ploïmōn; after the 11th century δρουγγάριος τοῦ στόλου, dro...
Part of a series onCannons History Artillery in the Song dynasty Artillery in the Middle Ages Naval artillery in the Age of Sail Field artillery in the US Civil War Siege artillery in the US Civil War Operation Breech-loading List of cannon projectiles Muzzleloading By country English cannon Cannons of Maritime Southeast Asia Japanese cannon Filipino cannon Korean cannon Majapahit cannon Mughal cannon By type Anti-tank gun Artillery Autocannon Basilisk Bombard Breech-loading swivel gun Carron...
Transition of a liquid to vapor This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.Find sources: Vaporization – news · newspapers · books · scholar · JSTOR (September 2023) (Learn how and when to remove this message) Vaporization (or vapo(u)risation) of an element or compound is a phase transition from the liquid phase to va...
أبو أمامة الباهلي تخطيط لاسم أبو أمامة الباهلي معلومات شخصية اسم الولادة صُدَيُّ بنُ عَجْلانَ بن الحارث، وقيل: صُدَيُّ بنُ عجلان بن وهب، وقيل: صُدَيُّ بنُ عجلان بن عَمْرو الميلاد العقد 620 شبه الجزيرة العربية الوفاة 81 هـ أو 86 هـحمص مواطنة الخلافة الراشدة الدولة ال...
