reb659 said:The MVT tells me that there exists some Xo in [d,c] such that f'(Xo) = [f(c)-f(d)]/(c-d).
reb659 said:It is negative. I'm still a bit puzzled as to how the mean value theorem relates to proving this problem.
reb659 said:If d>c then f'(xo)<0 and xo>c. f'(c)=0 and f'(xo)<0. But this contradicts that f'(x) is strictly increasing. So the statement must be true.
An "Intro to analysis proof" is a mathematical proof that uses principles from real analysis to show the validity of a statement or theorem.
In calculus, the first derivative of a function is the rate of change of that function at a specific point. The second derivative is the rate of change of the first derivative, or the rate of change of the rate of change of the original function.
The mean value theorem is a fundamental theorem in calculus that states that if a function is continuous on a closed interval and differentiable on the open interval, then there exists at least one point in the interval where the slope of the tangent line is equal to the slope of the secant line connecting the endpoints of the interval.
The mean value theorem is important because it provides a way to connect the average rate of change of a function to its instantaneous rate of change. This allows us to make conclusions about the behavior of a function without knowing its exact values at every point.
The mean value theorem is used in various fields, such as physics, economics, and engineering, to analyze and approximate the behavior of real-world phenomena. For example, it can be used to determine the average speed of an object given its initial and final positions and times, or to estimate the average growth rate of a population over a certain time period.