Let f:R→[0,∞) be a continuously differentiable
function. Prove that
∫01f3(x)dx−f2(0)∫01f(x)dx≤0≤x≤1max∣f′(x)∣(∫01f(x)dx)2.
Solution 1 of 2 (official)
Let M=0≤x≤1max∣f′(x)∣. By the inequality
−M≤f′(x)≤M, x∈[0,1] it follows:
−Mf(x)≤f(x)f′(x)≤Mf(x),x∈[0,1].
By integration
−M∫0xf(t)dt≤21f2(x)−21f2(0)≤M∫0xf(t)dt,x∈[0,1]−Mf(x)∫0xf(t)dt≤f3(x)−f2(0)f(x)≤Mf(x)∫0xf(t)dt,x∈[0,1].
Integrating the last inequality on [0,1] it follows that
−M(∫01f(x)dx)2≤∫01f3(x)dx−f2(0)∫01f(x)dx≤M(∫01f(x)dx)2⇔∫01f3(x)dx−f2(0)∫01f(x)dx≤M(∫01f(x)dx)2.
Solution 2 of 2 (official)
Let M=0≤x≤1max∣f′(x)∣ and
F(x)=−∫x1f; then F′=f, F(0)=−∫01f and
F(1)=0. Integrating by parts,
∫01f3=∫01f2⋅F′=[f2F]01−∫01(f2)′F=f2(1)F(1)−f2(0)F(0)−∫012Fff′=f2(0)∫01f−∫012Fff′.
Then
∫01f3(x)dx−f2(0)∫01f(x)dx=∫012Fff′≤∫012Ff∣f′∣≤M∫012Ff=M⋅[F2]01=M(∫01f)2.
How the field did
contestants scored
226
average (of 20)
5.23
solved (≥ 80%)
20.4%
near-0 (≤ 10%)
62.8%
discrimination
0.51
Score distribution (field cohort)
Computed on contestants with a meaningful total (field cohort); discrimination is the corrected item–total correlation.