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Doctrine of Triangles: A History of Modern Trigonometry [Kõva köide]

3.50/5 (3 hinnangut Goodreads-ist)
  • Formaat: Hardback, 392 pages, kõrgus x laius: 235x155 mm, 122 b/w illus. 6 tables.
  • Ilmumisaeg: 08-Jun-2021
  • Kirjastus: Princeton University Press
  • ISBN-10: 0691179417
  • ISBN-13: 9780691179414
Teised raamatud teemal:
Doctrine of Triangles: A History of Modern TrigonometrySuurem pilt
  • Formaat: Hardback, 392 pages, kõrgus x laius: 235x155 mm, 122 b/w illus. 6 tables.
  • Ilmumisaeg: 08-Jun-2021
  • Kirjastus: Princeton University Press
  • ISBN-10: 0691179417
  • ISBN-13: 9780691179414
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780691179414.html
Märksõnad:
"An interdisciplinary history of trigonometry from the mid-sixteenth century through to the early twentieth century The Doctrine of Triangles offers an interdisciplinary history of trigonometry that spans four centuries, starting in 1550 and concluding in the 1900s. Glen Van Brummelen tells the story of trigonometry as it evolved from an instrument for understanding the heavens to a practical tool, used in fields such as surveying and navigation. In Europe, China, and America, trigonometry aided and was itself transformed by concurrent mathematical revolutions, as well as the rise of science and technology. Following its uses in mid-sixteenth-century Europe as the "foot of the ladder to the stars" and the mathematical helpmate of astronomy, trigonometry became a ubiquitous tool for modeling various phenomena, including animal populations and sound waves. In the late sixteenth century, trigonometry increasingly entered the physical world through the practical disciplines, and its societal reach expanded with the invention of logarithms. Calculus shifted mathematical reasoning from geometric to algebraic patterns of thought, and trigonometry's participation in this new mathematical analysis grew, encouraging such innovations as complex numbers and non-Euclidean geometry. Meanwhile in China, trigonometry was evolving rapidly too, sometimes merging with indigenous forms of knowledge, and with Western discoveries. In the nineteenth century, trigonometry became even more integral to science and industry as a fundamental part of the science and engineering toolbox, and a staple subject in high school classrooms"--

An interdisciplinary history of trigonometry from the mid-sixteenth century to the early twentieth

The Doctrine of Triangles offers an interdisciplinary history of trigonometry that spans four centuries, starting in 1550 and concluding in the 1900s. Glen Van Brummelen tells the story of trigonometry as it evolved from an instrument for understanding the heavens to a practical tool, used in fields such as surveying and navigation. In Europe, China, and America, trigonometry aided and was itself transformed by concurrent mathematical revolutions, as well as the rise of science and technology.

Following its uses in mid-sixteenth-century Europe as the "foot of the ladder to the stars" and the mathematical helpmate of astronomy, trigonometry became a ubiquitous tool for modeling various phenomena, including animal populations and sound waves. In the late sixteenth century, trigonometry increasingly entered the physical world through the practical disciplines, and its societal reach expanded with the invention of logarithms. Calculus shifted mathematical reasoning from geometric to algebraic patterns of thought, and trigonometry’s participation in this new mathematical analysis grew, encouraging such innovations as complex numbers and non-Euclidean geometry. Meanwhile in China, trigonometry was evolving rapidly too, sometimes merging with indigenous forms of knowledge, and with Western discoveries. In the nineteenth century, trigonometry became even more integral to science and industry as a fundamental part of the science and engineering toolbox, and a staple subject in high school classrooms.

A masterful combination of scholarly rigor and compelling narrative, The Doctrine of Triangles brings trigonometry’s rich historical past full circle into the modern era.

Arvustused

"Glen van Brummelen has prepared a highly recommended, accessible and definitive history of the subject that will serve as a resource for scholars for decades to come."---Daniel Otero, MAA Reviews "The Doctrine of Triangles is an informative and valuable reference work.

"---Wallace A Ferguson, Institute of Mathematics and its Applications "A guided tour through the museum of mathematics. . . . [ The Doctrine of Triangles] takes the history of trigonometry, which is a formidable subject in its scope and size, and transforms it into something readable."---Daniel Mansfield, The Mathematical Intelligencer "Very easy to read, and there are lots of helpful diagrams, especially for the spherical trigonometry . . . [ The Doctrine of Triangles] is deeply enriched by extracts from contemporary texts, given first in fairly literal English translations, often accompanied by the original diagrams, and then explained in modern terms. So mathematical readers (and, I hope, their students) can experience a little of what trigonometry was actually like at each stage in its history."---John Hannah, Aestimatio

Preface xi
1 European Trigonometry Comes Of Age
1(61)
What's in a Name?
3(13)
Text 1.1 Regiomontanus, Denning the Basic Trigonometric Functions
4(2)
Text 1.2 Reinhold, a Calculation in a Planetary Model Using Sines and Tangents
6(10)
Trigonometric Tables Evolving
16(9)
Algebraic Gems by Viete
25(5)
Text 1.3 Viete, Finding a Recurrence Relation for sin nθ
25(5)
New Theorems, Plane and Spherical
30(9)
Text 1.4 Snell on Reciprocal Triangles
37(2)
Consolidating the Solutions of Triangles
39(6)
Widening Applications
45(17)
Text 1.5 Clavius on a Problem in Surveying
49(7)
Text 1.6 Gunter on Solving a Right-Angled Spherical Triangle with His Sector
56(6)
2 Logarithms
62(48)
Napier, Briggs, and the Birth of Logarithms
62(7)
Text 2.1 Napier, Solving a Problem in Spherical Trigonometry with His Logarithms
65(4)
Interlude: Joost Burgi's Surprising Method of Calculating a Sine Table
69(2)
The Explosion of Tables of Logarithms
71(5)
Computing Tables Effectively: Logarithms
76(2)
Computing Tables Effectively: Interpolation
78(6)
Text 2.2 Briggs, Completing a Table Using Finite Difference Interpolation
81(3)
Napier on Spherical Trigonometry
84(7)
Further Theoretical Developments
91(6)
Developments in Notation
97(2)
Practical and Scientific Applications
99(11)
Text 2.3 John Newton, Determining the Declination of an Arc of the Ecliptic with Logarithms
100(10)
3 Calculus
110(75)
Quadratures in Trigonometry Before Newton and Leibniz
110(10)
Text 3.1 Pascal, Finding the Integral of the Sine
118(2)
Tangents in Trigonometry Before Newton and Leibniz
120(6)
Text 3.2 Barrow, Finding the Derivative of the Tangent
122(4)
Infinite Sequences and Series in Trigonometry
126(9)
Text 3.3 Newton, Finding a Series for the Arc Sine
129(6)
Transforming the Construction of Trigonometric Tables with Series
135(8)
Geometric Derivatives and Integrals of Trigonometric Functions
143(2)
A Transition to Analytical Conceptions
145(16)
Text 3.4 Cotes, Estimating Errors in Triangles
149(6)
Text 3.5 Jakob Kresa, Relations Between the Sine and the Other Trigonometric Quantities
155(6)
Euler on the Analysis of Trigonometric Functions
161(16)
Text 3.6 Leonhard Euler, On Transcendental Quantities Which Arise from the Circle
165(10)
Text 3.7 Leonhard Euler, On the Derivative of the Sine
175(2)
Euler on Spherical Trigonometry
177(8)
4 China
185(58)
Indian and Islamic Trigonometry in China
185(6)
Text 4.1 Yixing, Description of a Table of Gnomon Shadow Lengths
188(3)
Indigenous Chinese Geometry
191(7)
Text 4.2 Liu Hui, Finding the Dimensions of an Inaccessible Walled City
192(6)
Indigenous Chinese Trigonometry
198(4)
The Jesuits Arrive
202(2)
Trigonometry in the Chongzhen lishu
204(4)
Logarithms in China
208(5)
The Kangxi Period and Mei Wending
213(9)
Dai Zhen: Philology Encounters Mathematics
222(5)
Infinite Series
227(16)
Text 4.3 Mei Juecheng, On Calculating the Circumference of a Circle from Its Diameter
228(3)
Text 4.4 Minggatu, On Calculating the Chord of a Given Arc
231(12)
5 Europe After Euler
243(74)
Normal Science: Gap Filling in Spherical Trigonometry
244(9)
Text 5.1 Pingre, Extending Napier's Rules to Oblique Spherical Triangles
245(8)
Symmetry and Unity
253(2)
The Return of Stereographic Projection
255(5)
Surveying and Legendre's Theorem
260(4)
Trigonometry in Navigation
264(9)
Text 5.2 James Andrew, Solving the PZX Triangle Using Haversines
268(5)
Tables
273(8)
Fourier Series
281(9)
Text 5.3 Jean Baptiste Joseph Fourier, A Trigonometric Series as a Function
287(3)
Concerns About Negativity
290(4)
Hyperbolic Trigonometry
294(9)
Text 5.4 Vincenzo Riccati, The Invention of the Hyperbolic Functions
294(9)
Education
303(11)
Concluding Remarks
314(3)
Bibliography 317(46)
Index 363
Glen Van Brummelen is dean of the faculty of natural and applied sciences at Trinity Western University, and a historian of mathematics and astronomy. His many books include The Mathematics of the Heavens and the Earth: The Early History of Trigonometry and Heavenly Mathematics: The Forgotten Art of Spherical Trigonometry (both Princeton).