#1
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FE
จงหา $f:R\rightarrow R$ ทั้งหมดที่
$f(xy+f(y)) = f(f(x))f(y)+y$ |
#2
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$P(x,y) แทน f(xy+f(y)) = f(f(x))f(y)+y $
$P(0,0) : f(f(0)) = f(f(0))f(0)$ $f(0) = 1$ หรือ $f(f(0)) = 0 $ ถ้า $f(0) = 1 $ $P(x,0) : 1 = f(f(x)) $ได้$ f(x) = c = 1$ แทนค่ากลับ แล้ว ไม่จริง ได้ $f(f(0)) = 0 $ $P(0,y) : f(f(y)) = y $ได้ f เป็น bijection $f(xy+f(y)) = xf(y)+y$ แทน $y = 1 $ได้ $f(x+f(1)) = xf(1)+1 $ ได้ $f(x) = x+c $ แทน ค่ากลับได้$ c = 0 $ ดังนั้น $f(x) = x $ |
#3
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อ้างอิง:
I would like to ask you to check the argument in red. From there, you missed a solution $f(x)=-x$. Other than that small point, your solution looks great! I will provide an alternative solution, which is almost the same as Euler-Fermat's solution above. First, substitution $(x,y) \mapsto (0,y)$ gives $f(f(y))=f(f(0))f(y)+y$___(1) which shows that $f$ is injective. Substitution $(x,y) \mapsto (x,0)$ gives $f(f(0))=f(f(x))f(0)$. Since $f$ is injective, $f(f(x))$ cannot be constant, and therefore $f(0)=0$. Using this in (1) above gives $f(f(x))=x, \forall x$. Substitution $(x,y) \mapsto (x-f(1),1)$ shows that $\forall x, f(x)= f(1) \cdot x + 1-f(1)^2$. A fortiori, $f$ is linear. Substituting linear $f$ back in the main equation shows that $f$ can be only $f(x) \equiv x, \forall x$ or $f(x) \equiv -x,\forall x$, both of which can be easily checked to satisfy the equation.
__________________
อยากให้ประเทศไทยได้หกเหรียญทอง |
#4
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อ้างอิง:
I think i might create some mistake in my substitution in my sol. |
#5
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อ้างอิง:
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#6
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It is straightforward to check injectivity from equation $(1)$.
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#7
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Ohh.. so sorry for my silly mistake.
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