Ta có:

\(\left\{{}\begin{matrix}sin^2x+cos^2x=1\\4sin^4x+3cos^4x=\dfrac{7}{4}\end{matrix}\right.\)

\(\Rightarrow4sin^4x+3\left(1-sin^2x\right)^2=\dfrac{7}{4}\)

\(\Leftrightarrow7sin^4x-6sin^2x+\dfrac{5}{4}=0\) \(\Rightarrow\left[{}\begin{matrix}sin^2x=\dfrac{1}{2}\Rightarrow cos^2x=\dfrac{1}{2}\\sin^2x=\dfrac{5}{14}\Rightarrow cos^2x=\dfrac{9}{14}\end{matrix}\right.\)

Do đó: \(\left[{}\begin{matrix}A=\dfrac{7}{4}\\A=\dfrac{57}{28}\end{matrix}\right.\)

Đáp án là B

Chọn B

tham khảo:

a)\(y'=xsin2x+sin^2x\)

\(y'=sin^2x+xsin2x\)

b)\(y'=-2sin2x+2cosx\\ y'=2\left(cosx-sin2x\right)\)

c)\(y=sin3x-3sinx\)

\(y'=3cos3x-3cosx\)

d)\(y'=\dfrac{1}{cos^2x}-\dfrac{1}{sin^2x}\)

\(y'=\dfrac{sin^2x-cos^2x}{sin^2x.cos^2x}\)

a) Đặt \(u = 3{\rm{x}}\) thì \(y = \sin u\). Ta có: \(u{'_x} = {\left( {3{\rm{x}}} \right)^\prime } = 3\) và \(y{'_u} = {\left( {\sin u} \right)^\prime } = \cos u\).

Suy ra \(y{'_x} = y{'_u}.u{'_x} = \cos u.3 = 3\cos 3{\rm{x}}\).

Vậy \(y' = 3\cos 3{\rm{x}}\).

b) Đặt \(u = \cos 2{\rm{x}}\) thì \(y = {u^3}\). Ta có: \(u{'_x} = {\left( {\cos 2{\rm{x}}} \right)^\prime } =  - 2\sin 2{\rm{x}}\) và \(y{'_u} = {\left( {{u^3}} \right)^\prime } = 3{u^2}\).

Suy ra \(y{'_x} = y{'_u}.u{'_x} = 3{u^2}.\left( { - 2\sin 2{\rm{x}}} \right) = 3{\left( {\cos 2{\rm{x}}} \right)^2}.\left( { - 2\sin 2{\rm{x}}} \right) =  - 6\sin 2{\rm{x}}{\cos ^2}2{\rm{x}}\).

Vậy \(y' =  - 6\sin 2{\rm{x}}{\cos ^2}2{\rm{x}}\).

c) Đặt \(u = \tan {\rm{x}}\) thì \(y = {u^2}\). Ta có: \(u{'_x} = {\left( {\tan {\rm{x}}} \right)^\prime } = \frac{1}{{{{\cos }^2}x}}\) và \(y{'_u} = {\left( {{u^2}} \right)^\prime } = 2u\).

Suy ra \(y{'_x} = y{'_u}.u{'_x} = 2u.\frac{1}{{{{\cos }^2}x}} = 2\tan x\left( {{{\tan }^2}x + 1} \right)\).

Vậy \(y' = 2\tan x\left( {{{\tan }^2}x + 1} \right)\).

d) Đặt \(u = 4 - {x^2}\) thì \(y = \cot u\). Ta có: \(u{'_x} = {\left( {4 - {x^2}} \right)^\prime } =  - 2{\rm{x}}\) và \(y{'_u} = {\left( {\cot u} \right)^\prime } =  - \frac{1}{{{{\sin }^2}u}}\).

Suy ra \(y{'_x} = y{'_u}.u{'_x} =  - \frac{1}{{{{\sin }^2}u}}.\left( { - 2{\rm{x}}} \right) = \frac{{2{\rm{x}}}}{{{{\sin }^2}\left( {4 - {x^2}} \right)}}\).

Vậy \(y' = \frac{{2{\rm{x}}}}{{{{\sin }^2}\left( {4 - {x^2}} \right)}}\).

a: \(y'=4\cdot3x^2-3\cdot2x+2=12x^2-6x+2\)

b: \(y'=\dfrac{\left(x+1\right)'\left(x-1\right)-\left(x+1\right)\left(x-1\right)'}{\left(x-1\right)^2}=\dfrac{x-1-x-1}{\left(x-1\right)^2}=\dfrac{-2}{\left(x-1\right)^2}\)

c: \(y'=-2\cdot\left(\sqrt{x}\cdot x\right)'\)

\(=-2\cdot\left(\dfrac{x+x}{2\sqrt{x}}\right)=-2\cdot\dfrac{2x}{2\sqrt{x}}=-2\sqrt{x}\)

d: \(y'=\left(3sinx+4cosx-tanx\right)\)'

\(=3cosx-4sinx+\dfrac{1}{cos^2x}\)

e: \(y'=\left(4^x+2e^x\right)'\)

\(=4^x\cdot ln4+2\cdot e^x\)

f: \(y'=\left(x\cdot lnx\right)'=lnx+1\)

b: \(y=\dfrac{1}{2}\sin4x-1\)

\(-1< =\sin4x< =1\)

\(\Leftrightarrow-\dfrac{1}{2}< =\dfrac{1}{2}\cdot\sin4x< =\dfrac{1}{2}\)

\(\Leftrightarrow-\dfrac{3}{2}< =\dfrac{1}{2}\cdot\sin4x-1< =-\dfrac{1}{2}\)

Do đó: \(y_{max}=\dfrac{-1}{2}\) khi \(4x=\dfrac{\Pi}{2}+k\Pi\)

hay \(x=\dfrac{\Pi}{8}+\dfrac{k\Pi}{4}\)

\(y_{min}=\dfrac{-3}{2}\) khi \(4x=-\dfrac{\Pi}{2}+k\Pi\)

hay \(x=-\dfrac{\Pi}{8}+\dfrac{k\Pi}{4}\)

g: \(0>=-2\left|\cos x\right|>=-2\)

\(\Leftrightarrow5>=-2\left|\cos x\right|+5>=3\)

Do đó: \(y_{max}=5\) khi \(\)\(\cos x=0\)

hay \(x=\dfrac{\Pi}{2}+k\Pi\)

\(y_{min}=3\) khi \(\cos x=-1\)

hay \(x=-\Pi+k2\Pi\)