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Exsecant

January 01, 1970

The external secant function (exsecant, symbolized exsec) is a trigonometric function defined in terms of the secant function:

The exsecant and versine functions substitute for the expressions exsec x = sec x − 1 and vers x = 1 − sec x which appear frequently in certain applications.[1]
The names exsecant, versine, chord, etc. can also be applied to line segments related to a circular arc. The length of each segment is the radius times the corresponding trigonometric function of the angle.

It was introduced in 1855 by American civil engineer Charles Haslett, who used it in conjunction with the existing versine function, for designing and measuring circular sections of railroad track.[2] It was adopted by surveyors and civil engineers in the United States for railroad and road design, and since the early 20th century has sometimes been briefly mentioned in American trigonometry textbooks and general-purpose engineering manuals.[3] For completeness, a few books also defined a coexsecant or excosecant function (symbolized coexsec or excsc), the exsecant of the complementary angle,[4][5] though it was not used in practice. While the exsecant has occasionally found other applications, today it is obscure and mainly of historical interest.[6]

As a line segment, an external secant of a circle has one endpoint on the circumference, and then extends radially outward. The length of this segment is the radius of the circle times the trigonometric exsecant of the central angle between the segment's inner endpoint and the point of tangency for a line through the outer endpoint and tangent to the circle.

Etymology edit

The word secant comes from Latin for "to cut", and a general secant line "cuts" a circle, intersecting it twice; this concept dates to antiquity and can be found in Book 3 of Euclid's Elements, as used e.g. in the intersecting secants theorem. 18th century sources in Latin called any non-tangential line segment external to a circle with one endpoint on the circumference a secans exterior.[7]

The trigonometric secant, named by Thomas Fincke (1583), is more specifically based on a line segment with one endpoint at the center of a circle and the other endpoint outside the circle; the circle divides this segment into a radius and an external secant. The external secant segment was used by Galileo Galilei (1632) under the name secant.[8]

History and applications edit

In the 19th century, most railroad tracks were constructed out of arcs of circles, called simple curves.[9] Surveyors and civil engineers working for the railroad needed to make many repetitive trigonometrical calculations to measure and plan circular sections of track. In surveying, and more generally in practical geometry, tables of both "natural" trigonometric functions and their common logarithms were used, depending on the specific calculation. Using logarithms converts expensive multiplication of multi-digit numbers to cheaper addition, and logarithmic versions of trigonometric tables further saved labor by reducing the number of necessary table lookups.[10]

The external secant or external distance of a curved track section is the shortest distance between the track and the intersection of the tangent lines from the ends of the arc, which equals the radius times the trigonometric exsecant of half the central angle subtended by the arc,  [11] By comparison, the versed sine of a curved track section is the furthest distance from the long chord (the line segment between endpoints) to the track[12] – cf. Sagitta – which equals the radius times the trigonometric versine of half the central angle,   These are both natural quantities to measure or calculate when surveying circular arcs, which must subsequently be multiplied or divided by other quantities. Charles Haslett (1855) found that directly looking up the logarithm of the exsecant and versine saved significant effort and produced more accurate results compared to calculating the same quantity from values found in previously available trigonometric tables.[2] The same idea was adopted by other authors, such as Searles (1880).[13] By 1913 Haslett's approach was so widely adopted in the American railroad industry that, in that context, "tables of external secants and versed sines [were] more common than [were] tables of secants".[14]

In the late-19th and 20th century, railroads began using arcs of an Euler spiral as a track transition curve between straight or circular sections of differing curvature. These spiral curves can be approximately calculated using exsecants and versines.[14][15]

Solving the same types of problems is required when surveying circular sections of canals[16] and roads, and the exsecant was still used in mid-20th century books about road surveying.[17]

The exsecant has sometimes been used for other applications, such as beam theory[18] and depth sounding with a wire.[19]

In recent years, the availability of calculators and computers has removed the need for trigonometric tables of specialized functions such as this one.[20] Exsecant is generally not directly built into calculators or computing environments (though it has sometimes been included in software libraries),[21] and calculations in general are much cheaper than in the past, no longer requiring tedious manual labor.

Catastrophic cancellation for small angles edit

Naïvely evaluating the expressions   (versine) and   (exsecant) is problematic for small angles where   The difference of two nearby quantities results in catastrophic cancellation: because most of the digits of each quantity are the same, they cancel in the subtraction, yielding a lower-precision result.

For example, the secant of is sec 1° ≈ 1.000152, with the leading several digits wasted on zeros, while the common logarithm of the exsecant of is log exsec 1° ≈ −3.817220,[22] all of whose digits are meaningful. If the logarithm of exsecant is calculated by looking up the secant in a six-place trigonometric table and then subtracting 1, the difference sec 1° − 1 ≈ 0.000152 has only 3 significant digits, and after computing the logarithm only three digits are correct, log(sec 1° − 1) ≈ −3.818156.[23] For even smaller angles loss of precision is worse.

If a table or computer implementation of the exsecant function is not available, the exsecant can be accurately computed as   or using versine,   which can itself be computed as   ; Haslett used these identities to compute his 1855 exsecant and versine tables.[24][25]

For a sufficiently small angle, a circular arc is approximately shaped like a parabola, and the versine and exsecant are approximately equal to each-other and both proportional to the square of the arclength.[26]

Mathematical identities edit

Inverse function edit

The inverse of the exsecant function, which might be symbolized arcexsec,[5] is well defined if   or   and can be expressed in terms of other inverse trigonometric functions (using radians for the angle):

 

the arctangent expression is well behaved for small angles.[27]

Calculus edit

While historical uses of the exsecant did not explicitly involve calculus, its derivative and antiderivative (for x in radians) are:[28]

 

Double angle identity edit

The exsecant of twice an angle is:[5]

 

See also edit

  • Chord (geometry) – A line segment with endpoints on the circumference of a circle, historically used trigonometrically
  • Exponential minus 1 – The function   also used to improve precision for small inputs

References edit

  1. ^ Cajori, Florian (1929). A History of Mathematical Notations. Vol. 2. Chicago: Open Court. §527. "Less common trigonometric functions", pp. 171–172.
  2. ^ a b Haslett, Charles (1855). "The Engineer's Field Book". In Hackley, Charles W. (ed.). The Mechanic's, Machinist's, and Engineer's Practical Book of Reference; Together with the Engineer's Field Book. New York: James G. Gregory. pp. 371–512.
    As the book's editor Charles W. Hackley explains in the preface, "The use of the more common trigonometric functions, to wit, sines, cosines, tangents, and cotangents, which ordinary tables furnish, is not well adapted to the peculiar problems which are presented in the construction of Railroad curves. [...] Still there would be much labor of computation which may be saved by the use of tables of external secants and versed sines, which have been employed with great success recently by the Engineers on the Ohio and Mississippi Railroad, and which, with the formulas and rules necessary for their application to the laying down of curves, drawn up by Mr. Haslett, one of the Engineers of that Road, are now for the first time given to the public." (pp. vi–vii)
    Charles Haslett continues in his preface to the Engineer's Field Book: "Experience has shown, that versed sines and external secants as frequently enter into calculations on curves as sines and tangents; and by their use, as illustrated in the examples given in this work, it is believed that many of the rules in general use are much simplified, and many calculations concerning curves and running lines made less intricate, and results obtained with more accuracy and far less trouble, than by any methods laid down in works of this kind. [...] In addition to the tables generally found in books of this kind, the author has prepared, with great labor, a Table of Natural and Logarithmic Versed Sines and External Secants, calculated to degrees, for every minute; also, a Table of Radii and their Logarithms, from 1° to 60°." (pp. 373–374)

    Review: Poor, Henry Varnum, ed. (1856-03-22). "Practical Book of Reference, and Engineer's Field Book. By Charles Haslett". American Railroad Journal (Review). Second Quarto Series. XII (12): 184. Whole No. 1040, Vol. XXIX.

  3. ^ Kenyon, Alfred Monroe; Ingold, Louis (1913). Trigonometry. New York: The Macmillan Company. p. 5.
    Hudson, Ralph Gorton; Lipka, Joseph (1917). A Manual of Mathematics. New York: John Wiley & Sons. p. 68.
    McNeese, Donald C.; Hoag, Albert L. (1957). Engineering and Technical Handbook. Englewood Cliffs, NJ: Prentice-Hall. pp. 147, 315–325 (table 41). LCCN 57-6690.

    Zucker, Ruth (1964). "4.3.147: Elementary Transcendental Functions - Circular functions". In Abramowitz, Milton; Stegun, Irene A. (eds.). Handbook of Mathematical Functions. Washington, D.C.: National Bureau of Standards. p. 78. LCCN 64-60036.

  4. ^ Bohannan, Rosser Daniel (1904) [1903]. "$131. The Versed Sine, Exsecant and Coexsecant. §132. Exercises". Plane Trigonometry. Boston: Allyn and Bacon. pp. 235–236.
  5. ^ a b c Hall, Arthur Graham; Frink, Fred Goodrich (1909). "Review Exercises". Plane Trigonometry. New York: Henry Holt and Company. § "Secondary Trigonometric Functions", pp. 125–127.
  6. ^ Oldham, Keith B.; Myland, Jan C.; Spanier, Jerome (2009) [1987]. An Atlas of Functions (2nd ed.). Springer. Ch. 33, "The Secant sec(x) and Cosecant csc(x) functions", §33.13, p. 336. doi:10.1007/978-0-387-48807-3. ISBN 978-0-387-48806-6. Not appearing elsewhere in the Atlas, and not available through Equator, is the archaic exsecant function [...].
  7. ^ Patu, Andræâ-Claudio (André Claude); Le Tort, Bartholomæus (1745). Rivard, Franciscus (Dominique-François) [in French] (ed.). Theses Mathematicæ De Mathesi Generatim (in Latin). Paris: Ph. N. Lottin. p. 6.
    Lemonnier, Petro (Pierre) (1750). Genneau, Ludovicum (Ludovico); Rollin, Jacobum (Jacques) (eds.). Cursus Philosophicus Ad Scholarum Usum Accomodatus (in Latin). Vol. 3. Collegio Harcuriano (Collège d'Harcourt), Paris. pp. 303–.
    Thysbaert, Jan-Frans (1774). "Articulus II: De situ lineæ rectæ ad Circularem; & de mensura angulorum, quorum vertex non est in circuli centro. §1. De situ lineæ rectæ ad Circularem. Definitio II: [102]". Geometria elementaria et practica (in Latin). Lovanii, e typographia academica. p. 30, foldout.

    van Haecht, Joannes (1784). "Articulus III: De secantibus circuli: Corollarium III: [109]". Geometria elementaria et practica: quam in usum auditorum (in Latin). Lovanii, e typographia academica. p. 24, foldout.

  8. ^ Galileo used the Italian segante.
    Galilei, Galileo (1632). Dialogo di Galileo Galilei sopra i due massimi sistemi del mondo Tolemaico e Copernicano [Dialogue on the Two Chief World Systems, Ptolemaic and Copernican] (in Italian).
    Galilei, Galileo (1997) [1632]. Finocchiaro, Maurice A. (ed.). Galileo on the World Systems: A New Abridged Translation and Guide. University of California Press. pp. 184 (n130), 184 (n135), 192 (n158). ISBN 9780520918221. Galileo's word is segante (meaning secant), but he clearly intends exsecant; an exsecant is defined as the part of a secant external to the circle and thus between the circumference and the tangent.

    Finocchiaro, Maurice A. (2003). "Physical-Mathematical Reasoning: Galileo on the Extruding Power of Terrestrial Rotation". Synthese. 134 (1–2, Logic and Mathematical Reasoning): 217–244. JSTOR 20117331.

  9. ^ Allen, Calvin Frank (1894) [1889]. Railroad Curves and Earthwork. New York: Spon & Chamberlain. p. 20.
  10. ^ Van Brummelen, Glen (2021). "2. Logarithms". The Doctrine of Triangles. Princeton University Press. pp. 62–109. ISBN 9780691179414.
  11. ^ Frye, Albert I. (1918) [1913]. Civil engineer's pocket-book: a reference-book for engineers, contractors and students containing rules, data, methods, formulas and tables (2nd ed.). New York: D. Van Nostrand Company. p. 211.
  12. ^ Gillespie, William M. (1853). A Manual of the Principles and Practice of Road-Making. New York: A. S. Barnes & Co. pp. 140–141.
  13. ^ Searles, William Henry (1880). Field Engineering. A hand-book of the Theory and Practice of Railway Surveying, Location, and Construction. New York: John Wiley & Sons.

    Searles, William Henry; Ives, Howard Chapin (1915) [1880]. Field Engineering: A Handbook of the Theory and Practice of Railway Surveying, Location and Construction (17th ed.). New York: John Wiley & Sons.

  14. ^ a b Jordan, Leonard C. (1913). The Practical Railway Spiral. New York: D. Van Nostrand Company. p. 28.
  15. ^ Thornton-Smith, G. J. (1963). "Almost Exact Closed Expressions for Computing all the Elements of the Clothoid Transition Curve". Survey Review. 17 (127): 35–44. doi:10.1179/sre.1963.17.127.35.
  16. ^ Doolittle, H. J.; Shipman, C. E. (1911). "Economic Canal Location in Uniform Countries". Papers and Discussions. Proceedings of the American Society of Civil Engineers. 37 (8): 1161–1164.
  17. ^ For example:
    Hewes, Laurence Ilsley (1942). American Highway Practice. New York: John Wiley & Sons. p. 114.
    Ives, Howard Chapin (1966) [1929]. Highway Curves (4th ed.). New York: John Wiley & Sons. LCCN 52-9033.

    Meyer, Carl F. (1969) [1949]. Route Surveying and Design (4th ed.). Scranton, PA: International Textbook Co.

  18. ^ Wilson, T. R. C. (1929). "A Graphical Method for the Solution of Certain Types of Equations". Questions and Discussions. The American Mathematical Monthly. 36 (10): 526–528. JSTOR 2299964.
  19. ^ Johnson, Harry F. (1933). "Correction for inclination of sounding wire". The International Hydrographic Review. 10 (2): 176–179.
  20. ^ Calvert, James B. (2007) [2004]. . Archived from the original on 2007-10-02. Retrieved 2015-11-08.
  21. ^ Simpson, David G. (2001-11-08). "AUXTRIG" (Fortran 90 source code). Greenbelt, MD: NASA Goddard Space Flight Center. Retrieved 2015-10-26.
    van den Doel, Kees (2010-01-25). "jass.utils Class Fmath". JASS - Java Audio Synthesis System. 1.25. Retrieved 2015-10-26.

    "MIT/GNU Scheme – Scheme Arithmetic" (MIT/GNU Scheme source code). v. 12.1. Massachusetts Institute of Technology. 2023-09-01. exsec function, arith.scm lines 61–63. Retrieved 2024-04-01.

  22. ^ In a table of logarithmic exsecants such as Haslett 1855, p. 417 or Searles & Ives 1915, II. p. 135, the number given for log exsec 1° is 6.182780, which is the correct value plus 10, which is added to keep the entries in the table positive.
  23. ^ The incorrect digits are highlighted in red.
  24. ^ Haslett 1855, p. 415
  25. ^ Nagle, James C. (1897). "IV. Transition Curves". Field Manual for Railroad Engineers (1st ed.). New York: John Wiley and Sons. §§ 138–165, pp. 110–142; Table XIII: Natural Versines and Exsecants, pp. 332–354.

    Review: "Field Manual for Railroad Engineers. By J. C. Nagle". The Engineer (Review). 84: 540. 1897-12-03.

  26. ^ Shunk, William Findlay (1918) [1890]. The Field Engineer: A Handy Book of Practice in the Survey, Location, and Track-Work of Railroads (21st ed.). New York: D. Van Nostrand Company. p. 36.
  27. ^ "4.5 Numerical operations". MIT/GNU Scheme Documentation. v. 12.1. Massachusetts Institute of Technology. 2023-09-01. procedure: aexsec. Retrieved 2024-04-01.

    "MIT/GNU Scheme – Scheme Arithmetic" (MIT/GNU Scheme source code). v. 12.1. Massachusetts Institute of Technology. 2023-09-01. aexsec function, arith.scm lines 65–71. Retrieved 2024-04-01.

  28. ^ Weisstein, Eric W. (2015) [2005]. "Exsecant". MathWorld. Wolfram Research, Inc. Retrieved 2015-11-05.

January 01, 1970
exsecant, external, secant, function, exsecant, symbolized, exsec, trigonometric, function, defined, terms, secant, function, exsecant, versine, functions, substitute, expressions, exsec, vers, which, appear, frequently, certain, applications, names, exsecant,. The external secant function exsecant symbolized exsec is a trigonometric function defined in terms of the secant function The exsecant and versine functions substitute for the expressions exsec x sec x 1 and vers x 1 sec x which appear frequently in certain applications 1 The names exsecant versine chord etc can also be applied to line segments related to a circular arc The length of each segment is the radius times the corresponding trigonometric function of the angle exsec 8 sec 8 1 1 cos 8 1 displaystyle operatorname exsec theta sec theta 1 frac 1 cos theta 1 It was introduced in 1855 by American civil engineer Charles Haslett who used it in conjunction with the existing versine function vers 8 1 cos 8 displaystyle operatorname vers theta 1 cos theta for designing and measuring circular sections of railroad track 2 It was adopted by surveyors and civil engineers in the United States for railroad and road design and since the early 20th century has sometimes been briefly mentioned in American trigonometry textbooks and general purpose engineering manuals 3 For completeness a few books also defined a coexsecant or excosecant function symbolized coexsec or excsc coexsec 8 displaystyle operatorname coexsec theta csc 8 1 displaystyle csc theta 1 the exsecant of the complementary angle 4 5 though it was not used in practice While the exsecant has occasionally found other applications today it is obscure and mainly of historical interest 6 As a line segment an external secant of a circle has one endpoint on the circumference and then extends radially outward The length of this segment is the radius of the circle times the trigonometric exsecant of the central angle between the segment s inner endpoint and the point of tangency for a line through the outer endpoint and tangent to the circle Contents 1 Etymology 2 History and applications 3 Catastrophic cancellation for small angles 4 Mathematical identities 4 1 Inverse function 4 2 Calculus 4 3 Double angle identity 5 See also 6 ReferencesEtymology editThe word secant comes from Latin for to cut and a general secant line cuts a circle intersecting it twice this concept dates to antiquity and can be found in Book 3 of Euclid s Elements as used e g in the intersecting secants theorem 18th century sources in Latin called any non tangential line segment external to a circle with one endpoint on the circumference a secans exterior 7 The trigonometric secant named by Thomas Fincke 1583 is more specifically based on a line segment with one endpoint at the center of a circle and the other endpoint outside the circle the circle divides this segment into a radius and an external secant The external secant segment was used by Galileo Galilei 1632 under the name secant 8 History and applications editIn the 19th century most railroad tracks were constructed out of arcs of circles called simple curves 9 Surveyors and civil engineers working for the railroad needed to make many repetitive trigonometrical calculations to measure and plan circular sections of track In surveying and more generally in practical geometry tables of both natural trigonometric functions and their common logarithms were used depending on the specific calculation Using logarithms converts expensive multiplication of multi digit numbers to cheaper addition and logarithmic versions of trigonometric tables further saved labor by reducing the number of necessary table lookups 10 The external secant or external distance of a curved track section is the shortest distance between the track and the intersection of the tangent lines from the ends of the arc which equals the radius times the trigonometric exsecant of half the central angle subtended by the arc R exsec 1 2 D displaystyle R operatorname exsec tfrac 1 2 Delta nbsp 11 By comparison the versed sine of a curved track section is the furthest distance from the long chord the line segment between endpoints to the track 12 cf Sagitta which equals the radius times the trigonometric versine of half the central angle R vers 1 2 D displaystyle R operatorname vers tfrac 1 2 Delta nbsp These are both natural quantities to measure or calculate when surveying circular arcs which must subsequently be multiplied or divided by other quantities Charles Haslett 1855 found that directly looking up the logarithm of the exsecant and versine saved significant effort and produced more accurate results compared to calculating the same quantity from values found in previously available trigonometric tables 2 The same idea was adopted by other authors such as Searles 1880 13 By 1913 Haslett s approach was so widely adopted in the American railroad industry that in that context tables of external secants and versed sines were more common than were tables of secants 14 In the late 19th and 20th century railroads began using arcs of an Euler spiral as a track transition curve between straight or circular sections of differing curvature These spiral curves can be approximately calculated using exsecants and versines 14 15 Solving the same types of problems is required when surveying circular sections of canals 16 and roads and the exsecant was still used in mid 20th century books about road surveying 17 The exsecant has sometimes been used for other applications such as beam theory 18 and depth sounding with a wire 19 In recent years the availability of calculators and computers has removed the need for trigonometric tables of specialized functions such as this one 20 Exsecant is generally not directly built into calculators or computing environments though it has sometimes been included in software libraries 21 and calculations in general are much cheaper than in the past no longer requiring tedious manual labor Catastrophic cancellation for small angles editNaively evaluating the expressions 1 cos 8 displaystyle 1 cos theta nbsp versine and sec 8 1 displaystyle sec theta 1 nbsp exsecant is problematic for small angles where sec 8 cos 8 1 displaystyle sec theta approx cos theta approx 1 nbsp The difference of two nearby quantities results in catastrophic cancellation because most of the digits of each quantity are the same they cancel in the subtraction yielding a lower precision result For example the secant of 1 is sec 1 wbr 1 000152 with the leading several digits wasted on zeros while the common logarithm of the exsecant of 1 is log exsec 1 wbr 3 817220 22 all of whose digits are meaningful If the logarithm of exsecant is calculated by looking up the secant in a six place trigonometric table and then subtracting 1 the difference sec 1 1 wbr 0 000152 has only 3 significant digits and after computing the logarithm only three digits are correct log sec 1 1 wbr 3 818156 23 For even smaller angles loss of precision is worse If a table or computer implementation of the exsecant function is not available the exsecant can be accurately computed as exsec 8 tan 8 tan 1 2 8 textstyle operatorname exsec theta tan theta tan tfrac 1 2 theta vphantom Big nbsp or using versine exsec 8 vers 8 sec 8 textstyle operatorname exsec theta operatorname vers theta sec theta nbsp which can itself be computed as vers 8 2 sin 1 2 8 2 textstyle operatorname vers theta 2 bigl sin tfrac 1 2 theta bigr vphantom 2 vphantom Big nbsp wbr sin 8 tan 1 2 8 displaystyle sin theta tan tfrac 1 2 theta vphantom Big nbsp Haslett used these identities to compute his 1855 exsecant and versine tables 24 25 For a sufficiently small angle a circular arc is approximately shaped like a parabola and the versine and exsecant are approximately equal to each other and both proportional to the square of the arclength 26 Mathematical identities editInverse function edit The inverse of the exsecant function which might be symbolized arcexsec 5 is well defined if y 0 displaystyle y geq 0 nbsp or y 2 displaystyle y leq 2 nbsp and can be expressed in terms of other inverse trigonometric functions using radians for the angle arcexsec y arcsec y 1 arctan y 2 2 y if y 0 undefined if 2 lt y lt 0 p arctan y 2 2 y if y 2 displaystyle operatorname arcexsec y operatorname arcsec y 1 begin cases arctan bigl textstyle sqrt y 2 2y bigr amp text if y geq 0 6mu text undefined amp text if 2 lt y lt 0 4mu pi arctan bigl textstyle sqrt y 2 2y bigr amp text if y leq 2 end cases vphantom nbsp the arctangent expression is well behaved for small angles 27 Calculus edit While historical uses of the exsecant did not explicitly involve calculus its derivative and antiderivative for x in radians are 28 d d x exsec x tan x sec x exsec x d x ln cos 1 2 x sin 1 2 x ln cos 1 2 x sin 1 2 x x C displaystyle begin aligned frac mathrm d mathrm d x operatorname exsec x amp tan x sec x 10mu int operatorname exsec x mathrm d x amp ln bigl cos tfrac 1 2 x sin tfrac 1 2 x bigr ln bigl cos tfrac 1 2 x sin tfrac 1 2 x bigr x C vphantom int end aligned nbsp Double angle identity edit The exsecant of twice an angle is 5 exsec 2 8 2 sin 2 8 1 2 sin 2 8 displaystyle operatorname exsec 2 theta frac 2 sin 2 theta 1 2 sin 2 theta nbsp See also editChord geometry A line segment with endpoints on the circumference of a circle historically used trigonometrically Exponential minus 1 The function x e x 1 displaystyle x mapsto e x 1 nbsp also used to improve precision for small inputsReferences edit Cajori Florian 1929 A History of Mathematical Notations Vol 2 Chicago Open Court 527 Less common trigonometric functions pp 171 172 a b Haslett Charles 1855 The Engineer s Field Book In Hackley Charles W ed The Mechanic s Machinist s and Engineer s Practical Book of Reference Together with the Engineer s Field Book New York James G Gregory pp 371 512 As the book s editor Charles W Hackley explains in the preface The use of the more common trigonometric functions to wit sines cosines tangents and cotangents which ordinary tables furnish is not well adapted to the peculiar problems which are presented in the construction of Railroad curves Still there would be much labor of computation which may be saved by the use of tables of external secants and versed sines which have been employed with great success recently by the Engineers on the Ohio and Mississippi Railroad and which with the formulas and rules necessary for their application to the laying down of curves drawn up by Mr Haslett one of the Engineers of that Road are now for the first time given to the public pp vi vii Charles Haslett continues in his preface to the Engineer s Field Book Experience has shown that versed sines and external secants as frequently enter into calculations on curves as sines and tangents and by their use as illustrated in the examples given in this work it is believed that many of the rules in general use are much simplified and many calculations concerning curves and running lines made less intricate and results obtained with more accuracy and far less trouble than by any methods laid down in works of this kind In addition to the tables generally found in books of this kind the author has prepared with great labor a Table of Natural and Logarithmic Versed Sines and External Secants calculated to degrees for every minute also a Table of Radii and their Logarithms from 1 to 60 pp 373 374 Review Poor Henry Varnum ed 1856 03 22 Practical Book of Reference and Engineer s Field Book By Charles Haslett American Railroad Journal Review Second Quarto Series XII 12 184 Whole No 1040 Vol XXIX Kenyon Alfred Monroe Ingold Louis 1913 Trigonometry New York The Macmillan Company p 5 Hudson Ralph Gorton Lipka Joseph 1917 A Manual of Mathematics New York John Wiley amp Sons p 68 McNeese Donald C Hoag Albert L 1957 Engineering and Technical Handbook Englewood Cliffs NJ Prentice Hall pp 147 315 325 table 41 LCCN 57 6690 Zucker Ruth 1964 4 3 147 Elementary Transcendental Functions Circular functions In Abramowitz Milton Stegun Irene A eds Handbook of Mathematical Functions Washington D C National Bureau of Standards p 78 LCCN 64 60036 Bohannan Rosser Daniel 1904 1903 131 The Versed Sine Exsecant and Coexsecant 132 Exercises Plane Trigonometry Boston Allyn and Bacon pp 235 236 a b c Hall Arthur Graham Frink Fred Goodrich 1909 Review Exercises Plane Trigonometry New York Henry Holt and Company Secondary Trigonometric Functions pp 125 127 Oldham Keith B Myland Jan C Spanier Jerome 2009 1987 An Atlas of Functions 2nd ed Springer Ch 33 The Secant sec x and Cosecant csc x functions 33 13 p 336 doi 10 1007 978 0 387 48807 3 ISBN 978 0 387 48806 6 Not appearing elsewhere in the Atlas and not available through Equator is the archaic exsecant function Patu Andraea Claudio Andre Claude Le Tort Bartholomaeus 1745 Rivard Franciscus Dominique Francois in French ed Theses Mathematicae De Mathesi Generatim in Latin Paris Ph N Lottin p 6 Lemonnier Petro Pierre 1750 Genneau Ludovicum Ludovico Rollin Jacobum Jacques eds Cursus Philosophicus Ad Scholarum Usum Accomodatus in Latin Vol 3 Collegio Harcuriano College d Harcourt Paris pp 303 Thysbaert Jan Frans 1774 Articulus II De situ lineae rectae ad Circularem amp de mensura angulorum quorum vertex non est in circuli centro 1 De situ lineae rectae ad Circularem Definitio II 102 Geometria elementaria et practica in Latin Lovanii e typographia academica p 30 foldout van Haecht Joannes 1784 Articulus III De secantibus circuli Corollarium III 109 Geometria elementaria et practica quam in usum auditorum in Latin Lovanii e typographia academica p 24 foldout Galileo used the Italian segante Galilei Galileo 1632 Dialogo di Galileo Galilei sopra i due massimi sistemi del mondo Tolemaico e Copernicano Dialogue on the Two Chief World Systems Ptolemaic and Copernican in Italian Galilei Galileo 1997 1632 Finocchiaro Maurice A ed Galileo on the World Systems A New Abridged Translation and Guide University of California Press pp 184 n130 184 n135 192 n158 ISBN 9780520918221 Galileo s word is segante meaning secant but he clearly intends exsecant an exsecant is defined as the part of a secant external to the circle and thus between the circumference and the tangent Finocchiaro Maurice A 2003 Physical Mathematical Reasoning Galileo on the Extruding Power of Terrestrial Rotation Synthese 134 1 2 Logic and Mathematical Reasoning 217 244 JSTOR 20117331 Allen Calvin Frank 1894 1889 Railroad Curves and Earthwork New York Spon amp Chamberlain p 20 Van Brummelen Glen 2021 2 Logarithms The Doctrine of Triangles Princeton University Press pp 62 109 ISBN 9780691179414 Frye Albert I 1918 1913 Civil engineer s pocket book a reference book for engineers contractors and students containing rules data methods formulas and tables 2nd ed New York D Van Nostrand Company p 211 Gillespie William M 1853 A Manual of the Principles and Practice of Road Making New York A S Barnes amp Co pp 140 141 Searles William Henry 1880 Field Engineering A hand book of the Theory and Practice of Railway Surveying Location and Construction New York John Wiley amp Sons Searles William Henry Ives Howard Chapin 1915 1880 Field Engineering A Handbook of the Theory and Practice of Railway Surveying Location and Construction 17th ed New York John Wiley amp Sons a b Jordan Leonard C 1913 The Practical Railway Spiral New York D Van Nostrand Company p 28 Thornton Smith G J 1963 Almost Exact Closed Expressions for Computing all the Elements of the Clothoid Transition Curve Survey Review 17 127 35 44 doi 10 1179 sre 1963 17 127 35 Doolittle H J Shipman C E 1911 Economic Canal Location in Uniform Countries Papers and Discussions Proceedings of the American Society of Civil Engineers 37 8 1161 1164 For example Hewes Laurence Ilsley 1942 American Highway Practice New York John Wiley amp Sons p 114 Ives Howard Chapin 1966 1929 Highway Curves 4th ed New York John Wiley amp Sons LCCN 52 9033 Meyer Carl F 1969 1949 Route Surveying and Design 4th ed Scranton PA International Textbook Co Wilson T R C 1929 A Graphical Method for the Solution of Certain Types of Equations Questions and Discussions The American Mathematical Monthly 36 10 526 528 JSTOR 2299964 Johnson Harry F 1933 Correction for inclination of sounding wire The International Hydrographic Review 10 2 176 179 Calvert James B 2007 2004 Trigonometry Archived from the original on 2007 10 02 Retrieved 2015 11 08 Simpson David G 2001 11 08 AUXTRIG Fortran 90 source code Greenbelt MD NASA Goddard Space Flight Center Retrieved 2015 10 26 van den Doel Kees 2010 01 25 jass utils Class Fmath JASS Java Audio Synthesis System 1 25 Retrieved 2015 10 26 MIT GNU Scheme Scheme Arithmetic MIT GNU Scheme source code v 12 1 Massachusetts Institute of Technology 2023 09 01 exsec function arith scm lines 61 63 Retrieved 2024 04 01 In a table of logarithmic exsecants such as Haslett 1855 p 417 or Searles amp Ives 1915 II p 135 the number given for log exsec 1 is 6 182780 which is the correct value plus 10 which is added to keep the entries in the table positive The incorrect digits are highlighted in red Haslett 1855 p 415 Nagle James C 1897 IV Transition Curves Field Manual for Railroad Engineers 1st ed New York John Wiley and Sons 138 165 pp 110 142 Table XIII Natural Versines and Exsecants pp 332 354 Review Field Manual for Railroad Engineers By J C Nagle The Engineer Review 84 540 1897 12 03 Shunk William Findlay 1918 1890 The Field Engineer A Handy Book of Practice in the Survey Location and Track Work of Railroads 21st ed New York D Van Nostrand Company p 36 4 5 Numerical operations MIT GNU Scheme Documentation v 12 1 Massachusetts Institute of Technology 2023 09 01 procedure aexsec Retrieved 2024 04 01 MIT GNU Scheme Scheme Arithmetic MIT GNU Scheme source code v 12 1 Massachusetts Institute of Technology 2023 09 01 aexsec function arith scm lines 65 71 Retrieved 2024 04 01 Weisstein Eric W 2015 2005 Exsecant MathWorld Wolfram Research Inc Retrieved 2015 11 05 Retrieved from https en wikipedia org w index php title Exsecant amp oldid 1216848046, wikipedia, wiki, book, books, library,

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