jm01 said:
I'm pulling hairs with this one!!! I cannot seem to factorise the second derivative and cannot find the point of inflexion. There's meant to be one at x=0, but...?!?!?!
Anyway, the question is:
Sketch, showing any stationary points, points of inflexion or asymptotes:
y=(2x+3)/(x2-4)
Cheers
y = (2x + 3) / (x² - 4)
u = 2x + 3, u' = 2
v = x² - 4, v' = 2x
dy/dx = [2(x² - 4) - 2x(2x + 3)] / (x² - 4)²
= [2x² - 8 - 4x² - 6x] / (x² - 4)²
= (- 2x² - 6x - 8) / (x² - 4)²
= - 2(x² + 3x + 4) / (x² - 4)²
u = x² + 3x + 4, u' = 2x + 3
v = (x² - 4)², v' = 4x(x² - 4)
d²y/dx² = - 2 [(2x + 3)(x² - 4)² - 4x(x² - 4)(x² + 3x + 4)] / (x² - 4)
4
Inflexion point occurs when d²y/dx² = 0
i.e. (2x + 3)(x² - 4)² - 4x(x² - 4)(x² + 3x + 4) = 0
(x² - 4)[(2x + 3)(x² - 4) - 4x(x² + 3x + 4)] = 0
(x² - 4)[(2x + 3)(x² - 4) - 4x(x² + 3x + 4)] = 0
(x² - 4)[2x³ - 8x + 3x² - 12 - 4x³ - 12x² - 16x)] = 0
(x² - 4)(- 2x³ - 9x² - 24x - 12) = 0
(x² - 4)(2x³ + 9x² + 24x + 12) = 0
x² - 4 = 0 yields x = ± 2 but the function is undefined for x = ±2
2x³ + 9x² + 24x + 12 = 0 yields an ugly number for x....lol
I've computed a sketch of the graph and can confirm the inflexion point doesn't occur at x = 0, so you may have typed the question wrong?
