Understanding 2nd Derivative Max/Min Points

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A negative second derivative indicates a maximum point because it shows that the slope of the function is decreasing, while a positive second derivative indicates a minimum point as it reflects an increasing slope. The first derivative provides the slope at any point, and when it equals zero, the second derivative helps determine the nature of that critical point. If the second derivative is negative, the function bends downward, confirming a maximum; if positive, it bends upward, confirming a minimum. The discussion also highlights that while the first derivative is commonly used to find maxima and minima, the second derivative test can simplify calculations, especially for functions with rapid slope changes. Understanding these concepts is essential for analyzing the behavior of functions in calculus.
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I've always wondered why a negative second derivative indicates a maximum point, and a positive one indicates a minimum.

I figured this was because a second derivative is the rate of change of gradient, and because near the maximum point the gradient becomes negative, and vice versa. Am I right?
 
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devious_ said:
I've always wondered why a negative second derivative indicates a maximum point, and a positive one indicates a minimum.

I figured this was because a second derivative is the rate of change of gradient, and because near the maximum point the gradient becomes negative, and vice versa. Am I right?

I don't think you're using the usual mathematical notion of gradient.

Consider that the derivative is related to the slope, and that the sign of the second derivative affects the sign of the derivative if it just hit zero.
 
That's what I was trying to say.

At the maximum point, the gradient decreases until it becomes zero (negative gradient). At the minimum point, the gradient increases until it becomes zero (positive gradient).
 
Just to state it a slightly different way:

The first derivative of a function gives the slope of that function at any point.
The second derivative of a function tells you how the first derivative (the slope) changes as you move to the right.

If the second derivative is negative, the slope of the function becomes more negative as you move to the right. It is bending downward.

If the second derivative is positive, the slope of the function becomes more positive as you move to the right. It is bending upward.

For example, suppose you have some function, and you know you're looking at either a maximum or a minimum, but you don't know which. However, you see that the function is bending upward there. In that case, it has already gone as low as it can. That means it's a minimum.

If I can slip a question in here, directed at anyone who knows the answer: How, if at all, does the gradient of a single-variable function differ from the derivative of that function? Offhand, I'd think the only difference is that the gradient is considered to be a vector quantity, but since it's a one-dimensional vector, that still might be the exact same thing.
 
We always just found mins and maxes by using the 1st derivative. The 1st deriv. tells you the slope of the tangent line at a specific point. You can find the mins and maxes by setting the slope=0 of the tangent line. From there all you have to do is test points to the left and right of the critical points. If the derivative goes from + 0 - then you have a maximum, or - 0 + you have a minimum at the critical point. This obviously makes sense intuitively.
 
gravenewworld said:
We always just found mins and maxes by using the 1st derivative. The 1st deriv. tells you the slope of the tangent line at a specific point. You can find the mins and maxes by setting the slope=0 of the tangent line. From there all you have to do is test points to the left and right of the critical points. If the derivative goes from + 0 - then you have a maximum, or - 0 + you have a minimum at the critical point. This obviously makes sense intuitively.
The second derivative test is easier to calculuate, especially where the function is changing slope rapidly.
 

Thread 'Area of Overlapping Squares'

Here is a little puzzle from the book 100 Geometric Games by Pierre Berloquin. The side of a small square is one meter long and the side of a larger square one and a half meters long. One vertex of the large square is at the center of the small square. The side of the large square cuts two sides of the small square into one- third parts and two-thirds parts. What is the area where the squares overlap?
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