1. ----------------------
f'(c)= [f(b)-f(a)]/(b-a)
- This means that the slope of the secant line at 2 points A and B, on a continuous and differentiable function between the intervals [a,b], is guaranteed to be equal to the slope of the tangent line at one point, c. On the graph, c may be the midpoint of [a,b].
- Because the slopes of the tangent and secant lines are equal, the lines will be PARALLEL to each other.
- Lets try another function that ISN'T f(x)=x^2, because Ms. Hwang doesn't like it's simplicity (:
- So this time, how about... f(x)=e^x
As you can see, the slope of the tangent line at c=0 is equal to the slope of the secant line between the interval (-1,1), so the lines are PARALLEL.
**I don't like how that one turned out, since the secant line looks weird...,so I shall use another example.. f(x)= -sin(x+pi)-1 between the interval (pi, 2pi).
The graph shows that between the interval (pi, 2pi), there is a tangent line at point c=3pi/2 with the equation y=-2 and a secant line, y=-1. The function, being both differentiable and continuous, allows the slope of the tangent line to be equal to the slope of the secant line, therefore allowing the Mean Value Theorem to apply. Both slopes are equal to 0.
2. -----------------------
It only works for continuous and differentiable functions because if between the interval [a,b] the function is discontinuous(because of a jump or asymptote,) or not differentiable (because of a jump, asymptote, cusp,corner...) then there may not be a tangent line at point c (or there may not even be a point c on the function if it is discontinuous where point c should be) that is parallel to the secant line going through points A and B.
- Since I had an equation involving abs of x, (f(x)=abs (x +1)+3), and im not sure whether I have to re-do this one, I will anyway.
- So... ANOTHER example of a CONTINUOUS but NOT DIFFERENTIABLE function is f(x)=x^(2/3)+1 on (-1,1).
There should be a tangent line (y=1) parallel to the secant line (y=2) at point c=0, but it is not possible for such a tangent line to exist due to the fact that the function is not differentiable at point c.(the slope of the line before c=-1 and the slope of the line after c=-1 are not equal) despite the continuity. Whenever there is a cusp at point c, the mean value theorem does not apply because f ' (c) does not exist.
Ohhhh AND to answer your question ms Hwang, related to my LAST post, the secant line of the second equation is y=1
hey i like your functions hahahaha. i used y=x^2 for my first question. hahahaha
ReplyDeletei got stuck at question two. but your explanation is much better than mmine. you made it seem so easy
" Lets try another function that ISN'T f(x)=x^2, because Ms. Hwang doesn't like it's simplicity (: "
ReplyDeleteIt funny how we all basically used the same graph for the 1st example. We all wanted it nice and easy.
Lol I know! But I graphed it during 4th period when we were in the computer lab! LOL so I just saved it to my blog,!
ReplyDeletehey I liked how you explained the sin one!. pretty clear!
ReplyDeleten yeahh!!! me too i miss first period!! it was cool!
ReplyDeletenice examples and explanations. kind of hard to see the graphs tho ><
ReplyDeleteyour explanations really helped me understand the mean value theorem
ReplyDeletevery clear
your explanations look good. you and Jesus are to smart, now the question is who is smarter?
ReplyDeletevery gooodd
ReplyDeletecant find anything bad to say about yours..
haha