question archive We use the first derivative to find all the critical points, and the second derivative to sort them in to maxima, minima and inflection points
Subject:MathPrice: Bought3
We use the first derivative to find all the critical points, and the second derivative to sort them in to maxima, minima and inflection points.
There are two things that we know about relative maxima and minima. The first is that the slope (first derivative) will be zero, but this alone is not sufficient. There are cases, known as inflection points where the slope is zero but the function continues to either increase or decrease.
This is why the second piece of information is so important - the curvature (second derivative) must be non-zero. We can start by finding all of the critical points of our function and then eliminating the inflection points:
##0=(del f(x)) / (del x)=6x^2-6x-12##
We use the quadratic equation to find the ##x## values of the critical points:
##x = (6 +- sqrt(6^2-4*6*(-12)))/(2*6) = 2, -1##
We then test these values in the second derivative:
##(del^2 f(x))/(del x^2)=12x-6##
##(del^2 f(2))/(del x^2) = 18, (del^2 f(-1))/(del x^2)=-18##
From this we determine that the critical point at ##x=-1## is a relative minimum and the critical point at ##x=2## is a relative maximum.
We can now use these ##x## values in the original polynomial to find the coordinates of these points:
##f(2)=-21, f(-1)=6##
So the points are:
relative minimum at ##(2,-21)## and relative maximum at ##(-1,6)##
graph{2x^3-3x^2-12x-1 [-5, 5, -25, 15]}