Iata o problema data la Putnam in 2006, cam usurica dupa umila-mi parere.
Enuntul problemei este urmatorul:
Fie \( f:[0,1]\to\mathbb{R} \) o functie continua. Consideram \( I(f)=\int_0^1 x^2 f(x)dx \) si \( J(x)=\int_0^1 xf^2(x)dx \). Sa se gaseasca
\( \max(I(f)-J(f)) \) si pentru ce functie \( f \) se realizeaza acest maxim.
max (I(f)-J(f))
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max (I(f)-J(f))
An infinite number of mathematicians walk into a bar. The first one orders a beer. The second orders half a beer. The third, a quarter of a beer. The bartender says “You’re all idiots”, and pours two beers.
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Doru Popovici
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Incercare
f:[0,1]->R
\( I(f)=\int_{0}^{1} x^2f(x)dx \)
\( J(f)=\int_{0}^{1} xf^2(x)dx \)
=> \( I(f)-J(f)=\int_{0}^{1} xf(x)(x-f(x)) \)
dar \( f(x)(x-f(x))\leq x^2/4 \), deoarece:
\( 4xf(x) - 4f^2(x)\leq x^2 \), trece tot in partea dreapta
=>\( 4f^2(x)-4xf(x)+x^2\geq 0 \)
=>\( (2f(x) - x)^2\geq 0 \) adevarat
=> \( I(f)-J(f)=\int_{0}^{1} xf(x)(x-f(x)) \leq \int_{0}^{1}x*x^2/4= (\int_{0}^{1}x^3)/4=((x^4/4)|_{0}^{1})/4=1/16 \)
=>max(I(f)-J(f))=1/16 si are loc agalitatea daca f(x)=x/2
QED
\( I(f)=\int_{0}^{1} x^2f(x)dx \)
\( J(f)=\int_{0}^{1} xf^2(x)dx \)
=> \( I(f)-J(f)=\int_{0}^{1} xf(x)(x-f(x)) \)
dar \( f(x)(x-f(x))\leq x^2/4 \), deoarece:
\( 4xf(x) - 4f^2(x)\leq x^2 \), trece tot in partea dreapta
=>\( 4f^2(x)-4xf(x)+x^2\geq 0 \)
=>\( (2f(x) - x)^2\geq 0 \) adevarat
=> \( I(f)-J(f)=\int_{0}^{1} xf(x)(x-f(x)) \leq \int_{0}^{1}x*x^2/4= (\int_{0}^{1}x^3)/4=((x^4/4)|_{0}^{1})/4=1/16 \)
=>max(I(f)-J(f))=1/16 si are loc agalitatea daca f(x)=x/2
QED