Figure 2 shows a sketch of the curve C with equation $y = f(x)$ where $f(x) = 4(2x^2 - 2)e^{-2x}$ for $x \, \in \, \mathbb{R}$ - Edexcel - A-Level Maths Pure - Question 10 - 2020 - Paper 1

To find the stationary points, we solve for $f'(x) = 0$:

$8(2 + x - x^2)e^{-2x} = 0$

Since $e^{-2x}$ is never zero, we solve:

$2 + x - x^2 = 0$

Rearranging gives:

$-x^2 + x + 2 = 0$

Factoring the equation:

$(x + 2)(x - 1) = 0$

Thus, the solutions are:

$x = -2 \, \text{or} \, x = 1$

Substituting these values back into $f(x)$ to find the $y$-coordinates:

1. For $x = -2$: $f(-2) = 4(2(-2)^2 - 2)e^{4} = 4(8 - 2)e^{4} = 24e^{4}$

2. For $x = 1$: $f(1) = 4(2(1^2) - 2)e^{-2} = 4(2 - 2)e^{-2} = 0$

Thus, the stationary points are $(-2, 24e^4)$ and $(1, 0)$.

Given the function $g(x) = 2f(x)$, we must determine its range:

Since $f(x) = 4(2x^2 - 2)e^{-2x}$, we inspect the range of $f(x)$:

• The minimum value of $f(x)$ occurs at $x = 1$, which gives $f(1) = 0$.
• As $x o - abla$, $f(x) o abla$.
• As $x o abla$, $f(x) o 0$ again.

Thus, the range of $f(x)$ is $[0, abla]$. Consequently, the range of $g(x) = 2f(x)$ is $[0, abla]$.

To determine the range of $h(x) = 2f(x) - 3$, we start with the range of $f(x)$:

As established previously, the range is $[0, abla]$. Therefore, applying the transformation for $h(x)$ leads to:

• The minimum value will be $2(0) - 3 = -3$.
• The maximum does not change as $2f(x)$ expands without limit:

So the range of $h(x)$ is: