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IMC / 1995 / Problems / Day 1, P3

IMC 1995 · Day 1 · P3

real analysisworth 15 pts

Let ff be twice continuously differentiable on (0,+)(0, +\infty) such that limx0+f(x)=\lim\limits_{x \to 0+} f'(x) = -\infty and limx0+f(x)=+\lim\limits_{x \to 0+} f''(x) = +\infty. Show that limx0+f(x)f(x)=0.\lim_{x \to 0+} \frac{f(x)}{f'(x)} = 0.

Solution (official)

Since ff' tends to -\infty and ff'' tends to ++\infty as xx tends to 0+0+, there exists an interval (0,r)(0,r) such that f(x)<0f'(x) < 0 and f(x)>0f''(x) > 0 for all x(0,r)x \in (0,r). Hence ff is decreasing and ff' is increasing on (0,r)(0,r). By the mean value theorem for every 0<x<x0<r0 < x < x_0 < r we obtain f(x)f(x0)=f(ξ)(xx0)>0,f(x) - f(x_0) = f'(\xi)(x - x_0) > 0, for some ξ(x,x0)\xi \in (x, x_0). Taking into account that ff' is increasing, f(x)<f(ξ)<0f'(x) < f'(\xi) < 0, we get xx0<f(ξ)f(x)(xx0)=f(x)f(x0)f(x)<0.x - x_0 < \frac{f'(\xi)}{f'(x)} (x - x_0) = \frac{f(x) - f(x_0)}{f'(x)} < 0. Taking limits as xx tends to 0+0+ we obtain x0lim infx0+f(x)f(x)lim supx0+f(x)f(x)0.-x_0 \le \liminf_{x \to 0+} \frac{f(x)}{f'(x)} \le \limsup_{x \to 0+} \frac{f(x)}{f'(x)} \le 0. Since this happens for all x0(0,r)x_0 \in (0,r) we deduce that limx0+f(x)f(x)\lim\limits_{x \to 0+} \dfrac{f(x)}{f'(x)} exists and limx0+f(x)f(x)=0.\lim_{x \to 0+} \frac{f(x)}{f'(x)} = 0.

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