Solving 2nd Derivative Rule: f"(x)=-3(x^2+3)/(x^2-9)^3

  • Thread starter Megz27
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In summary, the second derivative rule can be used to find when a graph is concave up or down, but it is not always possible to find the sign of the derivative.
  • #1
Megz27
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so to find when a graph is concave up or down you can use the 2nd derivative rule, but what happends if we have f"(x) = -3(x^2 +3)/(X^2-9)^3

what I am thinking is that we are looking for f"(x)=0 so x^2+3= O but that would give us x=(-3)^1/2...

any thoughts?
 
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  • #2
Your numerator is always negative, so f''(x) is never 0 (for real x). It is undefined at the points -3 and 3. If we look at the denominator, we see that on the open interval (-oo, -3), the change in the first derivative is negative and decreases without bound, while on the open interval (-3, 3) the change in the first derivative is positive and increases without bound. As the first derivative corresponds to the slopes of tangent lines to the graph, you can see why on the interval (-oo, -3) the graph is concave down while on the second interval, the graph is concave up (Start with an arbitrary tangent line and rotate it along a curve in the direction the second derivative gives).
Try to find the behavior of the graph of f as x decreases or increases without bound and on the third interval (3, oo).
 
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  • #3
how can we prove that tho? Cause wouldn't you have to find what x is when f '' (x) = O?
 
  • #4
Megz27 said:
how can we prove that tho? Cause wouldn't you have to find what x is when f '' (x) = O?

f''(x) is the derivative of the function f'(x), and thus inherits all the theorems about studying the behavior of f using f' (In this case we are studying the behavior of f' using f'').
As to finding when f''(x) = 0, that is only one way in which we can find where the sign of f'' changes. Another way the sign of f'' can change is if f''(x) is undefined when the sign changes, as f'' may not have removable discontinuities at these points. The sign of f''(x) is all we are concerned about when it comes to concave up or down. Note that f''(x) = 0 does not necessarily mean that the sign of f'' has changed; it may just be a minimum or maximum point for f'' so you still have to check the sign of f'' on both sides of that point. Ie., If f(x) = x6, then f''(0) = 0, but the graph never changes concavity. It is just "very flat" in the neighborhood of 0.
 
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  • #5
thanks
 

1. What is the second derivative rule?

The second derivative rule is a mathematical rule used to find the second derivative of a function. It is used to determine the concavity or curvature of a function at a given point, which can help in understanding the behavior of the function.

2. How do you solve for the second derivative of a function?

To solve for the second derivative of a function, you first need to find the first derivative of the function. Then, you can use the power rule and chain rule to find the second derivative. In this case, the given function f(x)=-3(x^2+3)/(x^2-9)^3 would require the use of quotient rule.

3. What is the purpose of finding the second derivative of a function?

The second derivative of a function helps in determining the concavity or curvature of the function at a given point. This information can be useful in understanding the behavior of the function, such as identifying maximum or minimum points, and determining the direction of the graph at a certain point.

4. What is the general formula for the second derivative rule?

The general formula for the second derivative rule is:
d^2/dx^2 (f(x)) = d/dx ( d/dx (f(x)) ) = d/dx (f'(x))

This means that the second derivative of a function is equal to the derivative of the first derivative of the function.

5. How do you apply the second derivative rule to real-life situations?

The second derivative rule can be applied to real-life situations in various fields such as physics, engineering, and economics. For example, in physics, the second derivative of a position function can be used to find the acceleration of an object at a given point. In economics, the second derivative of a cost function can help in determining the marginal cost of producing a good or service.

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