Matematyka.pl

Skupimy się na praktyce oczywiście. Wszelkie definicje można sobie znaleźć w pierwszej lepszej książce z analizy.
Wzór podstawowy: \(\displaystyle{ f\left(x\right)=x}\)

\(\displaystyle{ f^\prime\left(x\right)=1}\) \(\displaystyle{ f\left(x\right)=x ^{2}}\)

\(\displaystyle{ f^\prime\left(x\right)=2 \cdot x}\) \(\displaystyle{ f\left(x\right)=x ^{3}}\)

\(\displaystyle{ f^\prime\left(x\right)=3 \cdot x ^{2}}\) \(\displaystyle{ f\left(x\right)= 10 \cdot x ^{5}}\)

\(\displaystyle{ f^\prime\left(x\right)=10 \cdot 5 \cdot x ^{4} =50 x ^{4}}\) \(\displaystyle{ f\left(x\right)= 10}\)

\(\displaystyle{ f^\prime\left(x\right)= 0}\)

I tak z każdą stałą np

\(\displaystyle{ \left(\ln 5\right) ^\prime=0}\)

\(\displaystyle{ \left( \sqrt{100} \right) ^\prime=0}\)

\(\displaystyle{ \left( 150 \right) ^\prime=0}\)

\(\displaystyle{ \left( \pi \right) ^\prime=0}\)

\(\displaystyle{ \left( e \right) ^\prime=0}\)

\(\displaystyle{ \left( e ^{2} \right) ^\prime=0}\)

\(\displaystyle{ \left( \sin \left(1\right) \right) ^\prime=0}\)
\(\displaystyle{ f\left(x\right)=\sin x}\)

\(\displaystyle{ f^\prime\left(x\right)= \cos x}\) \(\displaystyle{ f\left(x\right)=\cos x}\)

\(\displaystyle{ f^\prime\left(x\right)= -\sin x}\) \(\displaystyle{ f\left(x\right)= \ln x}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{x}}\) \(\displaystyle{ f\left(x\right)= \frac{1}{x} =x ^{-1}}\)

\(\displaystyle{ f^\prime\left(x\right)= -1 \cdot x ^{-1-1}= - x ^{-2}= \frac{-1}{x ^{2} }}\)

\(\displaystyle{ f ^{\prime\prime} \left(x\right)= 2 x ^{-2-1}= 2 x ^{-3}= \frac{ 2}{x ^{3} }}\)

\(\displaystyle{ f ^{\prime\prime\prime} \left(x\right)= 2 \cdot \left(-3 \right) x ^{-3-1}= -6 \cdot x ^{-4}= \frac{ -6}{x ^{4}} }\) \(\displaystyle{ f\left(x\right)= x \cdot \sin x}\)

\(\displaystyle{ f^\prime\left(x\right)= \left( x\right)^\prime \cdot \sin x + x \cdot \left( \sin x \right)^\prime= \sin x+ x \cdot \cos x}\) \(\displaystyle{ f\left(x\right)= x ^{8} \cdot \ln x}\)

\(\displaystyle{ f^\prime\left(x\right)= \left( x ^{8} \right)^\prime \cdot \ln x + x ^{8} \cdot \left( \ln x \right)^\prime= 8x ^{7} \cdot \ln x + x ^{8} \cdot \frac{1}{x}= 8x ^{7} \cdot \ln x + x ^{7}}\) \(\displaystyle{ f\left(x\right)= \sqrt{x}= x ^{ \frac{1}{2} }}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{2} x ^{ \frac{1}{2}-1 } = \frac{1}{2} \cdot x ^{ -\frac{1}{2} }= \frac{1}{2 \sqrt{x} }}\) \(\displaystyle{ f\left(x\right)= \sqrt[3]{x} = x ^{ \frac{1}{3} }}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{3} x ^{ \frac{1}{3}-1 } = \frac{1}{3} \cdot x ^{ -\frac{2}{3} }= \frac{1}{3 \sqrt[3]{x ^{2} } }}\) \(\displaystyle{ f\left(x\right)= \frac{ x+1}{x}}\)

1 sposób:

\(\displaystyle{ f\left(x\right)= \frac{ x+1}{x}= 1+ \frac{1}{x}}\)

\(\displaystyle{ f^\prime \left(x\right)= - \frac{1}{x ^{2} }}\)

2 sposób ( wzór na pochodną ilorazu ):
\(\displaystyle{ f^\prime\left(x\right)= \frac{ \left(x+1\right)^\prime \cdot x - \left(x+1\right) \cdot x\prime}{x ^{2} }= \frac{ x - \left(x+1\right) }{x ^{2} } = - \frac{1}{x ^{2} }}\)
\(\displaystyle{ f\left(x\right)= \left(x+1\right) ^{2}}\)

Sposób 1 ( wzór na pochodną funkcji złożonej):

\(\displaystyle{ f^\prime \left(x\right)= 2 \cdot \left(x+1\right) \cdot \left(x+1\right)^\prime= 2 \cdot \left(x+1\right) \cdot 1= 2 \cdot \left(x+1\right) =2x+2}\)

Sposób 2 ( wzór skróconego mnożenia):

\(\displaystyle{ f\left(x\right)= \left(x+1\right) ^{2}=x ^{2}+2x+1}\)

\(\displaystyle{ f^\prime\left(x\right)= \left(x ^{2}\right)^\prime+\left(2x\right)^\prime+\left(1 \right)^\prime= 2x +2+0=2x+2}\)
\(\displaystyle{ f\left(x\right)= \left(x ^{2} +1\right) ^{2}}\)

( wzór na pochodną funkcji złożonej):

\(\displaystyle{ f^\prime \left(x\right)= 2 \cdot \left(x ^{2} +1\right) \cdot \left(x ^{2} +1\right)^\prime= 2 \cdot \left(x ^{2} +1\right) \cdot 2x = 4x \cdot \left(x ^{2} +1\right)}\)
\(\displaystyle{ f\left(x\right)= \ln \left(x ^{2} +1\right)}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{ \left(x ^{2} +1\right) } \cdot \left(x ^{2} +1\right)^\prime =\frac{2x}{ \left(x ^{2} +1\right) }}\)
\(\displaystyle{ f\left(x\right)= \sqrt{ 2x }}\)
\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{2 \cdot \sqrt{ 2x } } \cdot \left(2x\right)^\prime= \frac{2}{2 \cdot \sqrt{ 2x } }= \frac{1}{ \sqrt{ 2x } }}\) \(\displaystyle{ f\left(x\right)= e^{g\left(x\right) }}\)

\(\displaystyle{ f^\prime\left(x\right)= e^{g\left(x\right) } \cdot g^\prime\left(x\right)}\)

1. \(\displaystyle{ f\left(x\right)= e^{ 2x }}\)

\(\displaystyle{ f^\prime\left(x\right)= e^{ 2x } \cdot \left(2x\right)^\prime=e^{ 2x } \cdot 2}\)

2. \(\displaystyle{ f\left(x\right)= e^{ x ^{2} }}\)

\(\displaystyle{ f^\prime\left(x\right)= e^{ x ^{2} } \cdot \left(x ^{2} \right)^\prime =e^{ x ^{2} } \cdot 2x}\)

3. \(\displaystyle{ f\left(x\right)= e^{ x ^{2}+x }}\)

\(\displaystyle{ f^\prime\left(x\right)= e^{ x ^{2} +x } \cdot \left(x ^{2}+x \right)^\prime =e^{ x ^{2}+x } \cdot \left(2x+1\right)}\)
\(\displaystyle{ f\left(x\right)=\frac{\left(x+1\right) ^{2} }{2x}}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{\left[\left(x+1\right) ^{2}\right]^\prime \cdot \left(2x\right) - \left(x+1\right) ^{2}\left(2x\right) \prime }{\left(2x\right) ^{2} }= \frac{ \left(2x+2\right) \cdot \left(2x\right) - \left(x+1\right) ^{2} \cdot 2 }{ 4x ^{2} }=\\ \\\\ = \frac{ 4 x ^{2} +4x - \left( 2x ^{2} + 4x +2 \right) }{ 4x ^{2} }=\frac{ 2 x ^{2} - 2 }{ 4x ^{2} }= \frac{ x ^{2} - 1 }{ 2 x ^{2} }}\)
\(\displaystyle{ f\left(x\right)= \frac{x}{2} + \frac{2}{x}}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{1}{2} - \frac{2}{x ^{2} }}\)
\(\displaystyle{ f\left(x\right)= x ^{2} + \frac{1}{x ^{2} }}\)

\(\displaystyle{ f^\prime\left(x\right)= 2 x - \frac{2}{x ^{3} }}\)

\(\displaystyle{ f\left(x\right)= x \cdot \sqrt{4-x ^{2} }}\)

\(\displaystyle{ f^\prime\left(x\right)=\sqrt{4-x ^{2} } + x \cdot \frac{ -2x}{2 \sqrt{4-x ^{2} }}=\sqrt{4-x ^{2} } - \frac{ x ^2 }{ \sqrt{4-x ^{2} }}}\)
\(\displaystyle{ f\left(x\right)= x \cdot \left(3-x \right) ^{2}}\)

\(\displaystyle{ f^\prime \left(x\right)= \left(3-x \right) ^{2} - x \cdot 2 \left(3-x \right)}\)

\(\displaystyle{ f\left(x\right)= \sqrt{ \sin \left(x ^{2}\right) }}\)

\(\displaystyle{ f^\prime\left(x\right)= \frac{ 2x \cdot \cos \left(x ^{2}\right)}{2 \sqrt{ \sin \left(x ^{2}\right) }}}\)
\(\displaystyle{ f\left(x\right)= \sin x \cdot \cos 2x}\)

\(\displaystyle{ f^\prime\left(x\right)= \cos x \cdot \cos 2x- 2 \sin x \cdot \sin 2x}\)
\(\displaystyle{ f\left(x\right)= \sin ^{2} x \cdot \cos x}\)

\(\displaystyle{ f^\prime\left(x\right)= 2\sin x \cdot \cos x \cdot \cos x - \sin ^{2} x \sin x}\)

\(\displaystyle{ f\left(x\right)= \sqrt{1-\cos x}}\)

\(\displaystyle{ f^\prime \left(x\right)= \frac{\sin x}{2 \sqrt{1-\cos x}}}\)
\(\displaystyle{ f\left(x\right)= x-2 \arctan x}\)

\(\displaystyle{ f\left(x\right)= 1-2 \frac{1}{1+x ^{2} }= \frac{1+ x ^{2} }{1+ x ^{2}} - \frac{2}{1+x ^{2} }= \frac{-1+x ^{2} }{1+x ^{2} }}\)

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Jeśli chcesz, aby tutaj trafiło jakieś zadanie
to też proszę napisać do mnie PW. Jak wniesie coś nowego do tematu to JA wrzucę je tutaj(edytując ten post )