Revision as of 02:40, 15 April 2019 edit Myasuda (talk \| contribs) Autopatrolled, Extended confirmed users, Pending changes reviewers 62,542 edits m →Padé approximation: added missing diacritic ← Previous edit		Revision as of 18:50, 12 December 2021 edit undo 163.118.90.191 (talk) No edit summary Next edit →
Line 1: In mathematics, the '''Tanc function''' is defined as<ref>Weisstein, Eric W. "Tanc Function." From MathWorld--A Wolfram Web Resource. http://mathworld.wolfram.com/TancFunction.html</ref> : <math display="block">\operatorname{Tanc}(z)=\frac {\tan(z) }{z}</math>▼ ▲: <math>\operatorname{Tanc}(z)=\frac {\tan(z) }{z}</math> [[File:Tanc 2D plot.png\|thumb\|Tanc 2D plot]] [[File:Tanc'(z) 2D plot.png\|thumb\|Tanc'(z) 2D plot]] Line 8 ⟶ 7: ;Imaginary part in complex plane :<math> \operatorname{Im} \left( \frac {\tan(x+iy) }{x+iy} \right) </math> ;Real part in complex plane :<math> \operatorname{Re} \left( \frac {\tan \left( x+iy \right) }{x+iy} \right) </math> ;absolute magnitude :<math> \left\| \frac {\tan(x+iy) }{x+iy} \right\| </math> ;First-order derivative :<math> \frac {1- (\tan(z))^2}{z} - \frac {\tan(z)}{z^2} </math> ;Real part of derivative :<math> -\operatorname{Re} \left( -\frac {1- (\tan(x+iy))^2}{x+iy} +\frac{\tan(x+iy)}{(x+iy)^2} \right) </math> ~~</math>~~ ;Imaginary part of derivative :<math>-\operatorname{Im} \left( -\frac {1-(\tan(x+iy))^2}{x+iy} + \frac {\tan(x+iy)}{(x+iy)^2} \right) </math> ~~</math>~~ ;absolute value of derivative :<math> \left\| -\frac{1-(\tan(x+iy))^2}{x+iy}+\frac {\tan(x+iy)}{(x+iy)^2} \right\| </math> ==In terms of other special functions== Line 28 ⟶ 25: <math>\operatorname{Tanc}(z)={\frac {2\,i{{\rm KummerM}\left(1,\,2,\,2\,iz\right)}}{ \left( 2\,z+\pi \right) {{\rm KummerM}\left(1,\,2,\,i \left( 2\,z+\pi \right) \right)}}}</math> <math>\operatorname{Tanc}(z)= \frac {2i \operatorname{HeunB} \left( 2,0,0,0,\sqrt {2}\sqrt {iz} \right) }{(2z+\pi) \operatorname{HeunB} \left( 2,0,0,0,\sqrt {2}\sqrt {(i/2) (2z+\pi) } \right) } </math> <math>\operatorname{Tanc}(z)= \frac {{\rm WhittakerM}(0,\,1/2,\,2\,iz)}{{\rm WhittakerM}(0,\,1/2,\,i (2z+\pi)) z} </math> ~~</math>~~ ==Series expansion== : <math display="block">\operatorname{Tanc} z \approx \left(1+ \frac {1}{3} z^2 + \frac {2}{15} z^4 + \frac {17}{315} z^6 + \frac{62}{2835} z^8 + \frac {1382}{155925} z^{10} + \frac{21844}{6081075} z^{12}+ \frac {929569}{638512875} z^{14} + O(z^{16} ) \right)</math> : <math display="block">\int _0^z \frac {\tan(x) }{x} \, dx = \left(z+ \frac {1}{9} z^3 + \frac {2}{75} z^5 + \frac {17}{2205} z^7 + \frac {62}{25515} z^9+ \frac {1382}{1715175} z^{11}+ \frac {21844}{▼ ▲: <math>\int _0^z \frac {\tan(x) }{x} \, dx = \left(z+ \frac {1}{9} z^3 + \frac {2}{75} z^5 + \frac {17}{2205} z^7 + \frac {62}{25515} z^9+ \frac {1382}{1715175} z^{11}+ \frac {21844}{ 79053975} z^{13} + \frac{929569}{9577693125} z^{15}+ O (z^{17}) \right)</math> ==Padé approximation== <math display="block">\operatorname{Tanc} \left( z \right) = \left( 1-{\frac {7}{51}}\,{z}^{2} + {\frac {1}{255}}\,{z}^{4}-{\frac {2}{69615}}\,{z}^{6}+{\frac {1}{34459425}}\,{z}^{8} \right) \left( 1-{\frac {8}{17}}\,{z}^{2}+{\frac {7}{255}}\,{z}^{4}-{\frac {4}{9945}}\,{z}^{6}+{\frac {1}{765765}}\,{z}^{8} \right) ^{-1} </math> ~~\frac {1}{255}}\,{z}^{4}-{\frac {2}{69615}}\,{z}^{6}+{\frac {1}{~~ ~~34459425}}\,{z}^{8} \right) \left( 1-{\frac {8}{17}}\,{z}^{2}+{\frac~~ ~~{7}{255}}\,{z}^{4}-{\frac {4}{9945}}\,{z}^{6}+{\frac {1}{765765}}\,{z}~~ ~~^{8} \right) ^{-1}~~ ~~</math>~~ ==Gallery==

Tanc function: Difference between revisions