The Solution:
given the derivative function below:
[tex]f^{\prime}(x)=x\cos (x^2+1)[/tex]
We are required to find the number of points of inflection of the graph of the function f(x) on the open interval -2 < x < 2
Recall:
At the point of inflection of a function, the second derivative of the function is equal to zero. That is,
[tex]f^{\doubleprime}(x)=0[/tex]
Differentiating f'(x) with respect to x using the Product Rule, we get
[tex]f^{\prime}\text{'(x)}=V\frac{dU}{dx}+U\frac{dV}{dx}=0[/tex]
Where:
[tex]\begin{gathered} U=x \\ V=\cos (x^2+1) \\ \frac{dU}{dx}=1 \\ \\ \frac{dV}{dx}=-2x\sin (x^2+1) \end{gathered}[/tex]
Substituting, we get
[tex]f^{\prime}\text{'(x)}=1\cdot\cos \mleft(x^2+1\mright)+\mleft(-\sin \mleft(x^2+1\mright)\cdot\: 2x\mright)x=0[/tex][tex]f^{\prime}\text{'(x)}=\cos \mleft(x^2+1\mright)-2x^2\sin \mleft(x^2+1\mright)=0[/tex]
To find the number of points of inflection of the function, we shall solve graphically for x .
[tex]\cos (x^2+1)=2x^2\sin (x^2+1)[/tex]
Solving graphically using the Desmos App, we have
From the graph, the points of inflection in the open interval - 2 < x < 2 exist at the points below:
[tex](-1.5333,-0.978)\text{ and (1.5333,-0.978)}[/tex]
Thus, the number of points of inflection of the function in the given interval is 2.
Therefore, the correct answer is two (2).
