- #1
seniorhs9
- 22
- 0
Hi. I posted this in the Homework question but after 152 views with no right answer, my question looks analytical and rigorous enough to be posted here.
Thank you...
----
I am asking about part iv).
[PLAIN]http://img715.imageshack.us/img715/7977/113ivb.jpg
Attempt at a solution
In the given fact, I think x^3 - x - m(x - a) distance from the cubic function to the line. So for every point in (b, c), this would be negative.
I'm really not sure how to show c = -2b so I just tried to play with some algebra...
At x = b... b^3 - b - m(b - a) = 0
At x = c... c^3 - c - m(c - a) = 0
So they're both equal to 0...
b^3 - b - m(b - a) = c^3 - c - m(c - a)
so b^3 - b - mb = c^3 - c - mc
so by part i) b^3 - b - b(3b^2 - 1) = c^3 - c - c(3b^2 - 1)
so b^3 - b - 3b^3 + b = c^3 - c - 3b^2c + c
so -2b^3 = c^3 - 3b^2c
so b^2(3c - 2b) = c^3
but this doesn't look useful...
Thank you.
Thank you...
----
I am asking about part iv).
[PLAIN]http://img715.imageshack.us/img715/7977/113ivb.jpg
Attempt at a solution
In the given fact, I think x^3 - x - m(x - a) distance from the cubic function to the line. So for every point in (b, c), this would be negative.
I'm really not sure how to show c = -2b so I just tried to play with some algebra...
At x = b... b^3 - b - m(b - a) = 0
At x = c... c^3 - c - m(c - a) = 0
So they're both equal to 0...
b^3 - b - m(b - a) = c^3 - c - m(c - a)
so b^3 - b - mb = c^3 - c - mc
so by part i) b^3 - b - b(3b^2 - 1) = c^3 - c - c(3b^2 - 1)
so b^3 - b - 3b^3 + b = c^3 - c - 3b^2c + c
so -2b^3 = c^3 - 3b^2c
so b^2(3c - 2b) = c^3
but this doesn't look useful...
Thank you.
Last edited by a moderator:
