Sign In | Starter Of The Day | Tablesmaster | Fun Maths | Maths Map | Topics | More
Here are some specific activities, investigations or visual aids we have picked out. Click anywhere in the grey area to access the resource.
Here are some exam-style questions on this statement:
Click on a topic below for suggested lesson Starters, resources and activities from Transum.
The second derivative, denoted as \( f''(x) \), provides insight into the concavity of the original function \( f(x) \). If \( f''(x) > 0 \), the function \( f(x) \) is concave upwards in that interval, indicating a local minimum if \( f'(x) \) changes sign. Conversely, if \( f''(x) < 0 \), \( f(x) \) is concave downwards, hinting at a local maximum if \( f'(x) \) undergoes a sign change. The points where \( f''(x) = 0 \) or is undefined are potential inflection points, where the concavity of \( f(x) \) might change.
Let's consider an example to illustrate this relationship:
Suppose \( f(x) = x^3 - 3x^2 + 2 \).
The first derivative, \( f'(x) \), represents the slope of \( f(x) \) and is given by:
$$ f'(x) = 3x^2 - 6x $$The second derivative, \( f''(x) \), indicates the concavity of \( f(x) \) and is:
$$ f''(x) = 6x - 6 $$From \( f''(x) \), we can determine that the function is concave upwards when \( f''(x) > 0 \) (i.e., \( x > 1 \)) and concave downwards when \( f''(x) < 0 \) (i.e., \( x < 1 \)). The point \( x = 1 \) is an inflection point.
This video on Optimization and Calculus Curves is from Revision Village and is aimed at students taking the IB Maths AA SL/HL course.
How do you teach this topic? Do you have any tips or suggestions for other teachers? It is always useful to receive feedback and helps make these free resources even more useful for Maths teachers anywhere in the world. Click here to enter your comments.