1.2 Ableitungsregeln

Beispiel 1

1. \displaystyle \frac{d}{dx}\,(x^2 e^x) = 2x\, e^x + x^2\, e^x = (2x +x^2)\,e^x\,.
   
   
2. \displaystyle (x \sin x)^\prime = (x)^\prime \cdot \sin x + x\,(\sin x)^\prime = 1 \cdot \sin x + x\,\cos x = \sin x + x \cos x\,.
   
   
3. \displaystyle \frac{d}{dx}\,(x \ln x -x) = 1 \cdot \ln x + x\, \frac{1}{x} - 1 = \ln x + 1 -1 = \ln x\,.
   
   
4. \displaystyle (\tan x)^\prime = \left( \frac{\sin x}{\cos x} \right)^\prime = \frac{ \cos x \, \cos x - \sin x \, (-\sin x)}{(\cos x)^2} = \frac{\cos^2 x + \sin^2 x }{ \cos^2 x} = \frac{1}{\cos^2 x}\,.
   
   
5. \displaystyle \frac{d}{dx}\,\frac{1+x}{\sqrt{x}} = \frac{\displaystyle 1 \cdot \sqrt{x} - (1+x) \, \frac{1}{2\sqrt{x}}}{(\sqrt{x}\,)^2} = \frac{\displaystyle\frac{2x}{2\sqrt{x}} - \frac{1}{2\sqrt{x}} - \frac{x}{2\sqrt{x}}}{x} = \frac {\displaystyle \frac {x-1}{2\sqrt{x}}}{x} = \frac{x-1}{2x\sqrt{x}}\,.
   
   
6. \displaystyle \begin{align} \frac{d}{dx}\,\frac{x\,e^x}{1+x} &= \frac{(1\cdot e^x + x\, e^x)(1+x) - x\,e^x \cdot 1}{(1+x)^2} = \frac{ e^x + x\,e^x + x\,e^x + x^2\,e^x - x\,e^x}{(1+x)^2} \\ &= \frac{(1 + x + x^2)\,e^x} {(1+x)^2} \end{align}\,.

Beispiel 2

\displaystyle y(x)=(x^2 + 2x)^4 ist eine verkettete Funktion. Wir benutzen die verkürzte Kettenregel:

Die Ableitung der Funktion y in Bezug auf x ist durch die Kettenregel gegeben

Beispiel 3

1. \displaystyle y(x) = \sin (3x^2 + 1)
   
   \displaystyle \begin{array}{llll} \text{Äußere Funktion:} & f(u) = \sin u & \text{Äußere Ableitung:} & f^{\, \prime}(u) = \cos (u)\\ \text{Innere Funktion:} & g(x) = 3 x^2 +1 & \text{Innere Ableitung:} & g^{\, \prime}(x) = 6x \end{array}
   
   \displaystyle \begin{align} y(x) &= f( g(x)) \\ y^{\,\prime}(x) &= f^{\, \prime}(g(x)) \, g^{\, \prime} (x) = \cos (3x^2 + 1) \cdot 6x = 6x \cos (3x^2 +1) \end{align}
   
   
2. \displaystyle y = 5 \, e^{x^2}
   
   \displaystyle \begin{array}{ll} \text{Äußere Ableitung:} & 5\,e^{x^2}\\ \text{Innere Ableitung:} & 2x \end{array}
   
   \displaystyle y' = 5 \, e^{x^2} \, 2x = 10x\, e^{x^2}
   
   
3. \displaystyle f(x) = e^{x\, \sin x}
   
   \displaystyle \begin{array}{ll} \text{Äußere Ableitung:} & e^{x\, \sin x}\\ \text{Innere Ableitung:} & 1\cdot \sin x + x \cos x \end{array}
   
   \displaystyle f^{\,\prime}(x) = e^{x\, \sin x} (\sin x + x \cos x)
   
   
4. \displaystyle s(t) = t^2 \cos (\ln t)
   
   \displaystyle s'(t) = 2t \, \cos (\ln t) + t^2 \,\Bigl(-\sin (\ln t) \,\frac{1}{t}\Bigr) = 2t \cos (\ln t) - t \sin (\ln t)
   
   
5. \displaystyle \frac{d}{dx}\,a^x = \frac{d}{dx}\,\bigl( e^{\ln a} \bigr)^x = \frac{d}{dx}\,e^{x\ln a} = e^{x\ln a} \, \ln a = a^x \, \ln a
   
   
6. \displaystyle \frac{d}{dx}\,x^a = \frac{d}{dx}\,\bigl( e^{\ln x} \bigr)^a = \frac{d}{dx}\,e^{ a \, \ln x } = e^{a \, \ln x} \cdot a \, \frac{1}{x} = x^a \cdot a \, x^{-1} = ax^{a-1}

Beispiel 4

1. \displaystyle \frac{d}{dx}\,\sin^3 2x = \frac{d}{dx}\,(\sin 2x)^3 = 3(\sin 2x)^2 \, \frac{d}{dx}\,\sin 2x = 3(\sin 2x)^2 \, \cos 2x \, \frac{d}{dx}\,(2x) \vphantom{\Bigl(}
   \displaystyle \phantom{\frac{d}{dx}\,\sin^3 2x}{}= 3 \sin^2 2x\,\cos 2x\cdot 2 = 6 \sin^2 2x\,\cos 2x
   
   
2. \displaystyle \left( \,\sin \bigl((x^2 -3x)^4 \bigr)\, \right)^{\, \prime} = \cos \bigl((x^2 -3x)^4\bigr) \,\left(\,(x^2 -3x)^4 \, \right)^{\, \prime} \vphantom{\Bigl(}
   \displaystyle \phantom{\left( \,\sin \bigl((x^2 -3x)^4 \bigr) \, \right)^{\, \prime} }{} = \cos \bigl((x^2 -3x)^4\bigr)\cdot 4 (x^2 -3x)^3 \,\left( \,(x^2-3x) \, \right)^{\, \prime} \vphantom{\Bigl(}
   \displaystyle \phantom{\frac{d}{dx}\,\sin \bigl((x^2 -3x)^4 \bigr)}{} = \cos \bigl((x^2 -3x)^4\bigr)\cdot 4 (x^2 -3x)^3 \, (2x-3)
   
   
3. \displaystyle \frac{d}{dx}\,\sin^4 (x^2 -3x) = \frac{d}{dx}\,\bigl( \sin (x^2 -3x) \bigr)^4 \vphantom{\Bigl(}
   \displaystyle \phantom{\frac{d}{dx}\,\sin^4 (x^2 -3x)}{} = 4 \sin^3 (x^2 - 3x) \, \frac{d}{dx}\,\sin(x^2-3x) \vphantom{\Bigl(}
   \displaystyle \phantom{\frac{d}{dx}\,\sin^4 (x^2 -3x)}{} = 4 \sin^3 (x^2 - 3x) \,\cos (x^2 -3x) \, \frac{d}{dx}(x^2 -3x) \vphantom{\Bigl(}
   \displaystyle \phantom{\frac{d}{dx}\,\sin^4 (x^2 -3x)}{} = 4 \sin^3 (x^2 - 3x) \,\cos (x^2 -3x)\, (2x-3)
   
   
4. \displaystyle \frac{d}{dx}\,\Bigl ( e^{\sqrt{x^3-1}}\,\Bigr) = e^{\sqrt{x^3-1}} \, \frac{d}{dx}\,\sqrt{x^3-1} = e^{\sqrt{x^3-1}} \, \frac{1}{2 \sqrt{x^3-1}} \, \frac{d}{dx}\,(x^3-1) \vphantom{\Biggl(}
   \displaystyle \phantom{\displaystyle \frac{d}{dx}\,\Bigl ( e^{\sqrt{x^3-1}}\,\Bigr)}{} = e^{\sqrt{x^3-1}} \, \frac{1}{2 \sqrt{x^3-1}} \cdot 3 x^2 = \frac { 3 x^2 e^{\sqrt{x^3-1}}} {2 \sqrt{x^3-1}} \vphantom{\dfrac{\dfrac{()^2}{()}}{()}}

Beispiel 5

1. \displaystyle f(x) = 3\,e^{x^2 -1}
   \displaystyle f^{\,\prime}(x) = 3\,e^{x^2 -1} \, \frac{d}{dx}\,(x^2-1) = 3\,e^{x^2 -1} \cdot 2x = 6x\,e^{x^2 -1}\vphantom{\biggl(}
   \displaystyle f^{\,\prime\prime}(x) = 6\,e^{x^2 -1} + 6x\,e^{x^2 -1} \cdot 2x = 6\,e^{x^2 -1}\,(1+ 2x^2)
2. \displaystyle y = \sin x\,\cos x
   \displaystyle \frac{dy}{dx} = \cos x\,\cos x + \sin x\,(- \sin x) = \cos^2 x - \sin^2 x\vphantom{\Biggl(}
   \displaystyle \frac{d^2 y}{dx^2} = 2 \cos x\,(-\sin x) - 2 \sin x \cos x = -4 \sin x \cos x
3. \displaystyle \frac{d}{dx}\,( e^x \sin x) = e^x \sin x + e^x \cos x = e^x (\sin x + \cos x) \vphantom{\Bigl(}
   \displaystyle \frac{d^2}{dx^2}(e^x\sin x) = \frac{d}{dx}\,\bigl(e^x (\sin x + \cos x)\bigr) \vphantom{\Bigl(} \displaystyle \phantom{\frac{d^2}{dx^2}(e^x\sin x)}{} = e^x (\sin x + \cos x) + e^x (\cos x - \sin x) = 2\,e^x \cos x \vphantom{\bigl(}
   \displaystyle \frac{d^3}{dx^3} ( e^x \sin x) = \frac{d}{dx}\,(2\,e^x \cos x) \vphantom{\Bigl(} \displaystyle \phantom{\frac{d^3}{dx^3} ( e^x \sin x)}{} = 2\,e^x \cos x + 2\,e^x (-\sin x) = 2\,e^x ( \cos x - \sin x )