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a: \(y'=\left[tan\left(e^x+1\right)\right]'=\dfrac{\left(e^x+1\right)'}{cos^2\left(e^x+1\right)}=\dfrac{e^x}{cos^2\left(e^x+1\right)}\)
b: \(y'=\left(\sqrt{sin3x}\right)'\)
\(=\dfrac{\left(sin3x\right)'}{2\sqrt{sin3x}}=\dfrac{3\cdot cos3x}{2\sqrt{sin3x}}\)
c: \(y=cot\left(1-2^x\right)\)
=>\(y'=\left[cot\left(1-2^x\right)\right]'\)
\(=\dfrac{-2}{sin^2\left(1-2^x\right)}\cdot\left(-2^x\cdot ln2\right)\)
\(=\dfrac{2^{x+1}\cdot ln2}{sin^2\left(1-2^x\right)}\)
a: y=ln(x+1)
=>\(y'=\dfrac{1}{x+1}\)
=>\(y''=\dfrac{1'\left(x+1\right)-1\left(x+1\right)'}{\left(x+1\right)^2}=\dfrac{-1}{\left(x+1\right)^2}\)
b: y=tan 2x
=>\(y'=\dfrac{2}{cos^22x}\)
=>\(y''=\left(\dfrac{2}{cos^22x}\right)'=\dfrac{-2\cdot cos^22x'}{cos^42x}=\dfrac{-2\cdot2\cdot cos2x\left(cos2x\right)'}{cos^42x}\)
\(=\dfrac{4\cdot2\cdot sin2x}{cos^32x}=\dfrac{8\cdot sin2x}{cos^32x}\)
y'=\(\dfrac{1}{cos^2x}-\dfrac{1}{cos^2x}tan^2x+\dfrac{1}{cos^2x}tan^4x\)
=\(\dfrac{1}{cos^2x}-\dfrac{sin^2x}{\cos^4x}+\dfrac{\sin^4x}{\cos^8x}\)
=\(\dfrac{\cos^4x-\sin^2.\cos^2x+\sin^4x}{\cos^8x}\)
=\(\dfrac{\left(\cos^2x+\sin^2x\right)^2-3\sin^2x\cos^2x}{\cos^8x}\)
=\(\dfrac{-3\sin^2x}{\cos^6x}\)
a) Với bất kì \({x_0} \in \mathbb{R}\), ta có:
\(f'\left( {{x_0}} \right) = \mathop {\lim }\limits_{x \to {x_0}} \frac{{f\left( x \right) - f\left( {{x_0}} \right)}}{{x - {x_0}}} = \mathop {\lim }\limits_{x \to {x_0}} \frac{{x - {x_0}}}{{x - {x_0}}} = \mathop {\lim }\limits_{x \to {x_0}} 1 = 1\)
Vậy \(f'\left( x \right) = {\left( x \right)^\prime } = 1\) trên \(\mathbb{R}\).
b) Ta có:
\(\begin{array}{l}{\left( {{x^2}} \right)^\prime } = 2{\rm{x}}\\{\left( {{x^3}} \right)^\prime } = 3{{\rm{x}}^2}\\...\\{\left( {{x^n}} \right)^\prime } = n{{\rm{x}}^{n - 1}}\end{array}\)