4.9 Newton’s method  (Page 3/7)

For $f\left(x\right)=x^3-2x+2,$ the derivative is $f^{\prime }\left(x\right)=3x^2-2.$ Therefore,

In the next step,

Consequently, the numbers $x_0,x_1,x_2\text{,…}$ continue to bounce back and forth between $0$ and $1$ and never get closer to the root of $f$ which is over the interval $\left[\mathrm{-2},\mathrm{-1}\right]$ (see [link] ). Fortunately, if we choose an initial approximation $x_0$ closer to the actual root, we can avoid this situation.

If $x_0=0,$ then

From this list, we conjecture that the values $x_n$ approach $8.$

[link] provides a graphical argument that the values approach $8$ as $n\to \infty .$ Starting at the point $\left(x_0,x_0\right),$ we draw a vertical line to the point $\left(x_0,F\left(x_0\right)\right).$ The next number in our list is $x_1=F\left(x_0\right).$ We use $x_1$ to calculate $x_2.$ Therefore, we draw a horizontal line connecting $\left(x_0,x_1\right)$ to the point $\left(x_1,x_1\right)$ on the line $y=x,$ and then draw a vertical line connecting $\left(x_1,x_1\right)$ to the point $\left(x_1,F\left(x_1\right)\right).$ The output $F\left(x_1\right)$ becomes $x_2.$ Continuing in this way, we could create an infinite number of line segments. These line segments are trapped between the lines $F\left(x\right)=\frac{x}{2}+4$ and $y=x.$ The line segments get closer to the intersection point of these two lines, which occurs when $x=F\left(x\right).$ Solving the equation $x=\frac{x}{2}+4,$ we conclude they intersect at $x=8.$ Therefore, our graphical evidence agrees with our numerical evidence that the list of numbers $x_0,x_1,x_2\text{,…}$ approaches $x*=8$ as $n\to \infty .$