Funzione trigonometrica inversa: differenze tra le versioni

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Versione delle 14:42, 8 dic 2017 modifica 2001:b07:af5:a2b1:6486:ad54:611d:947b (discussione) →Serie infinite ← Differenza precedente		Versione attuale delle 21:29, 2 set 2024 modifica annulla Alexaboutangels (discussione \| contributi) 168 modifiche Corretta grafia Etichette: Modifica visuale Modifica da mobile Modifica da web per mobile
(29 versioni intermedie di 3 utenti non mostrate)
Riga 9: !Codominio \|- \| [[arcoseno]] \|\| <math>y = \arcsin(x)</math> \|\| <math>x = \sin(y)</math>\|\|<math> \left[−1-1; +1\right] </math>\|\| ~~−π/~~<math>-\frac{\pi}{2}\leq ~~≤ ''~~y''\leq ~~≤ π~~\frac{\pi}{2}</2math> \|- \| [[arcocoseno]] \|\| <math>y = \arccos(x)</math>\|\| <math>x = \cos(y)</math>\|\| <math> \left[−1-1; +1\right] </math> \|\| <math>0 ≤\leq ''y'' ≤\leq π\pi</math> \|- \| [[arcotangente]] \|\| <math>y = \arctan(x)</math>\|\| <math>x = \tan(y)</math>\|\| ~~'''~~<math>\mathbb {R}</math>~~'''~~ \|\| ~~−π/~~<math>-\frac{\pi}{2 }< ''y'' < π/\frac{\pi}{2}</math> \|- \| [[arcocosecante]] \|\| <math>y = \arccsc(x)</math>\|\| <math>x = \operatorname{~~cosec~~csc}(y) , y = \arcsin\left(\frac{1/}{x}\right)</math> \| <math>\left(-\infty; -1\right] \cup \left[1; +\infty\right)</math> \|\| <math>-\frac{\pi}{2}\leq y < 0 \vee 0<y\leq\frac{\pi}{2}</math> ~~\|     (−∞; −1] e [1; ∞)     \|\| −π/2 ≤ ''y'' < 0, o<br /> 0 < ''y'' ≤ π/2~~ \|- \| [[arcosecante]] \|\| <math>y = \arcsec(x)</math>\|\| <math>x = \sec(y) , y = \arccos\left(\frac{1/}{x}\right)</math> \| <math>\left(-\infty; -1\right] \cup \left[1; +\infty\right)</math> \|\| <math>0 \leq y < \frac{\pi}{2} \vee \frac{\pi}{2}<y\leq \pi</math> ~~\|     (−∞; −1] e [1; ∞)     \|\| 0 ≤ ''y'' < π/2, o<br /> π/2 < ''y'' ≤ π~~ \|- \| [[arcocotangente]] \|\| <math>y = \arccot(x)</math>\|\|<math>x = \cot(y) , y = \arctan\left(\frac{1/}{x}\right)</math>\|\| ~~'''~~<math>\mathbb {R}</math>~~'''~~ \| <math> 0 < ''y'' < π\pi </math> \|- \|} Riga 33: Analogamente al seno ed al coseno, le funzioni trigonometriche inverse si possono in alternativa definire in termini di serie infinite. :<math> \arcsin z = z + \left( \frac {1} {2} \right) \frac {z^3} {3} + \left( \frac {1 \cdot 3} {2 \cdot 4} \right) \frac {z^5} {5} + \left( \frac{1 \cdot 3 \cdot 5} {2 \cdot 4 \cdot 6 } \right) \frac{z^7} {7} + \cdots = \sum_{n=0}^\infty ~~\left( \frac~~ {(2n~~)!}~~\choose ~~{2^{2n}(~~n~~!)^2~~} ~~\right)~~ \frac {z^{2n+1}} {4^{n}(2n+1)} \ , \quad \left\| z \right\| < 1 </math> <!-- linea bianca lasciata per leggibilità --> :<math> \arccos z = \frac {\pi} {2} - \arcsin z = \frac {\pi} {2} - (\left[z + \left( \frac {1} {2} \right) \frac {z^3} {3} + \left( \frac {1 \cdot 3} {2 \cdot 4} \right) \frac {z^5} {5} + \left( \frac{1 \cdot 3 \cdot 5} {2 \cdot 4 \cdot 6 } \right) \frac{z^7} {7} + \cdots )\right]= \frac {\pi} {2} - \sum_{n=0}^\infty ~~\left( \frac~~ {(2n~~)!}~~\choose ~~{2^{2n}(~~n~~!)^2~~} ~~\right)~~ \frac {z^{2n+1}} {4^{n}(2n+1)} \ , \quad \left\| z \right\| < 1 Riga 54 ⟶ 55: :<math> \arccsc z = \arcsin\left(\frac{1}{z}\right)= \frac{1}{z} + \left( \frac {1} {2} \right) \frac {1} {3z^{3}} + \left( \frac {1 \cdot 3} {2 \cdot 4 } \right) \frac {1} {5z^{5}} + \left( \frac {1 \cdot 3 \cdot 5} {2 \cdot 4 \cdot 6} \right) \frac {1} {7z^{7}} +\cdots = \sum_{n=0}^\infty ~~\left( \frac~~ {(2n~~)!}~~\choose ~~{2^{2n}(~~n~~!)^2~~} ~~\right)~~ \frac {1} {4^{n}(2n+1)z^{2n+1}} \ , \quad \left\| z \right\| > 1 </math> Riga 61 ⟶ 62: :<math> &\arcsec z = \arccos\left(\frac{1}{z}\right) = & \frac {\pi} {2} - ~~(z^~~\left[\frac{-1}{z} + \left( \frac {1} {2} \right) \frac {z1} {3z^{-3}~~} {3~~} + \left( \frac {1 \cdot 3} {2 \cdot 4} \right) \frac {z1} {5z^{-5}~~} {5~~} + \left( \frac{1 \cdot 3 \cdot 5} {2 \cdot 4 \cdot 6 } \right) \frac{z1} {7z^{-7}~~} {7~~} + \cdots )\right]= \frac {\pi} {2} - \sum_{n=0}^\infty {2n\choose n} \frac {1} {4^{n}(2n+1)z^{2n+1}} ▼ ~~\begin{matrix}~~ ~~\arcsec z & = & \arccos\left(z^{-1}\right) \\ \\~~ ▲& = & \frac {\pi} {2} - (z^{-1} + \left( \frac {1} {2} \right) \frac {z^{-3}} {3} + \left( \frac {1 \cdot 3} {2 \cdot 4} \right) \frac {z^{-5}} {5} + \left( \frac{1 \cdot 3 \cdot 5} {2 \cdot 4 \cdot 6 } \right) \frac{z^{-7}} {7} + \cdots ) \\ ~~& = & \frac {\pi} {2} - \sum_{n=0}^\infty \left( \frac {(2n)!} {2^{2n}(n!)^2} \right) \frac {z^{-(2n+1)}} {(2n+1)}~~ ~~\end{matrix}~~ \ , \quad \left\| z \right\| > 1 </math> Riga 72 ⟶ 69: :<math> &\arccot z = \arctan \left(\frac{1}{x}\right) = & \frac {\pi} {2} - (\left[ z - \frac {z^3} {3} +\frac {z^5} {5} -\frac {z^7} {7} +\cdots )\right] = \frac {\pi} {2} - \sum_{n=0}^\infty \frac {(-1)^n z^{2n+1}} {2n+1}▼ ~~\begin{matrix}~~ ~~\arccot z & = & \frac {\pi} {2} - \arctan z \\ \\~~ ▲& = & \frac {\pi} {2} - ( z - \frac {z^3} {3} +\frac {z^5} {5} -\frac {z^7} {7} +\cdots ) \\ \\ ~~& = & \frac {\pi} {2} - \sum_{n=0}^\infty \frac {(-1)^n z^{2n+1}} {2n+1}~~ ~~\end{matrix}~~ \ , \quad \left\| z \right\| < 1 </math> Riga 161 ⟶ 154: == Semplificazione somme == È possibile combinare la [[addizione\|somma]] o [[sottrazione\|differenza]] di due funzioni trigonometriche inverse in un'[[Espressione ~~aritmetica~~matematica\|espressione]] dove la funzione trigonometrica compare una sola volta:▼ ▲È possibile combinare la [[addizione\|somma]] o [[sottrazione\|differenza]] di due funzioni trigonometriche inverse in un'[[Espressione aritmetica\|espressione]] dove la funzione trigonometrica compare una sola volta: :<math> Riga 190 ⟶ 182: \displaystyle{\rm arctan}\left({x_1 \pm x_2 \over \; 1 \mp x_1 x_2\;}\right) & \pm x_1x_2<1 \\ \displaystyle{\rm sgn}\left(x_1\right)\,{\displaystyle\,\pi\; \over 2} \qquad & \pm x_1x_2=1 \\ \displaystyle{\rm arctan}\left({x_1 \pm x_2 \over \; 1 \mp x_1 x_2\;}\right) + {\rm ~~segno~~sgn}\left(x_1\right)\,\pi & \pm x_1x_2>1 \\ \end{cases} </math> == Altri progetti == {{interprogetto~~\|commons=Category:Inverse trigonometric functions~~}} ==Collegamenti esterni==