How to arrive at $(f'(x))^2<2f(x)$?
$begingroup$
Let we see a problem ahead of I asking what I want to ask.
Define $f:mathbb{R}to(0,+infty)$ differentiable satisfying $|f'(x)-f'(y)|le|x-y|,, forall x,yinmathbb{R}$.
Prove: $(f'(x))^2<2f(x)$
I came up with a proof which is as follows:
In order to make the proof more rigorous, we pointed out in advance that $f'$ is (uniformly) continuous.
1. $,$ If $f'(x)=0$.
Then through $f>0$ we arrive at the conclusion.
2. $,$ If $f'(x)>0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=int_{x_0}^{x}f'(t),dt+f(x_0)>int_{x_0}^{x}f'(t),dtgeint_{x_0}^{x}(f'(x)+t-x),dt=frac{1}{2}(f'(x))^2$
3. $,$ If $f'(x)<0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=f(x_0)-int_{x}^{x_0}f'(t),dt>int_{x}^{x_0}-f'(t),dtgeint_{x}^{x_0}(-f'(x)+x-t),dt=frac{1}{2}(f'(x))^2$
Actually I got stuck on how to arrive at $(f'(x))^2<2f(x)$.
I thought $f(x)$ is influenced by $f'(t)$ where $t$ is around $x$, so I came up with the proof as mentioned above.
But at the same time I thought that for the similar questions such as $f(x)>f'(x)$ we can construct the auxiliary function $g(x)=frac{f(x)}{e^x}$.
So what I really want to ask is how to arrive at $(f'(x))^2<2f(x)$?
I thought this maybe relates to the solution of $(f'(x))^2=2f(x)$.
What's more, any new ideas for the above problem are welcomed. Thank you in advance!
real-analysis ordinary-differential-equations
asked Dec 18 '18 at 14:24
ZeroZero
34110
$endgroup$
add a comment |
$begingroup$
Let we see a problem ahead of I asking what I want to ask.
Define $f:mathbb{R}to(0,+infty)$ differentiable satisfying $|f'(x)-f'(y)|le|x-y|,, forall x,yinmathbb{R}$.
Prove: $(f'(x))^2<2f(x)$
I came up with a proof which is as follows:
In order to make the proof more rigorous, we pointed out in advance that $f'$ is (uniformly) continuous.
1. $,$ If $f'(x)=0$.
Then through $f>0$ we arrive at the conclusion.
2. $,$ If $f'(x)>0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=int_{x_0}^{x}f'(t),dt+f(x_0)>int_{x_0}^{x}f'(t),dtgeint_{x_0}^{x}(f'(x)+t-x),dt=frac{1}{2}(f'(x))^2$
3. $,$ If $f'(x)<0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=f(x_0)-int_{x}^{x_0}f'(t),dt>int_{x}^{x_0}-f'(t),dtgeint_{x}^{x_0}(-f'(x)+x-t),dt=frac{1}{2}(f'(x))^2$
Actually I got stuck on how to arrive at $(f'(x))^2<2f(x)$.
I thought $f(x)$ is influenced by $f'(t)$ where $t$ is around $x$, so I came up with the proof as mentioned above.
But at the same time I thought that for the similar questions such as $f(x)>f'(x)$ we can construct the auxiliary function $g(x)=frac{f(x)}{e^x}$.
So what I really want to ask is how to arrive at $(f'(x))^2<2f(x)$?
I thought this maybe relates to the solution of $(f'(x))^2=2f(x)$.
What's more, any new ideas for the above problem are welcomed. Thank you in advance!
real-analysis ordinary-differential-equations
asked Dec 18 '18 at 14:24
ZeroZero
34110
$endgroup$
add a comment |
$begingroup$
Let we see a problem ahead of I asking what I want to ask.
Define $f:mathbb{R}to(0,+infty)$ differentiable satisfying $|f'(x)-f'(y)|le|x-y|,, forall x,yinmathbb{R}$.
Prove: $(f'(x))^2<2f(x)$
I came up with a proof which is as follows:
In order to make the proof more rigorous, we pointed out in advance that $f'$ is (uniformly) continuous.
1. $,$ If $f'(x)=0$.
Then through $f>0$ we arrive at the conclusion.
2. $,$ If $f'(x)>0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=int_{x_0}^{x}f'(t),dt+f(x_0)>int_{x_0}^{x}f'(t),dtgeint_{x_0}^{x}(f'(x)+t-x),dt=frac{1}{2}(f'(x))^2$
3. $,$ If $f'(x)<0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=f(x_0)-int_{x}^{x_0}f'(t),dt>int_{x}^{x_0}-f'(t),dtgeint_{x}^{x_0}(-f'(x)+x-t),dt=frac{1}{2}(f'(x))^2$
Actually I got stuck on how to arrive at $(f'(x))^2<2f(x)$.
I thought $f(x)$ is influenced by $f'(t)$ where $t$ is around $x$, so I came up with the proof as mentioned above.
But at the same time I thought that for the similar questions such as $f(x)>f'(x)$ we can construct the auxiliary function $g(x)=frac{f(x)}{e^x}$.
So what I really want to ask is how to arrive at $(f'(x))^2<2f(x)$?
I thought this maybe relates to the solution of $(f'(x))^2=2f(x)$.
What's more, any new ideas for the above problem are welcomed. Thank you in advance!
real-analysis ordinary-differential-equations
asked Dec 18 '18 at 14:24
ZeroZero
34110
$endgroup$
Let we see a problem ahead of I asking what I want to ask.
Define $f:mathbb{R}to(0,+infty)$ differentiable satisfying $|f'(x)-f'(y)|le|x-y|,, forall x,yinmathbb{R}$.
Prove: $(f'(x))^2<2f(x)$
I came up with a proof which is as follows:
In order to make the proof more rigorous, we pointed out in advance that $f'$ is (uniformly) continuous.
1. $,$ If $f'(x)=0$.
Then through $f>0$ we arrive at the conclusion.
2. $,$ If $f'(x)>0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=int_{x_0}^{x}f'(t),dt+f(x_0)>int_{x_0}^{x}f'(t),dtgeint_{x_0}^{x}(f'(x)+t-x),dt=frac{1}{2}(f'(x))^2$
3. $,$ If $f'(x)<0$.$,,,$ Let $x_0=x-f'(x)$.
so $f(x)=f(x_0)-int_{x}^{x_0}f'(t),dt>int_{x}^{x_0}-f'(t),dtgeint_{x}^{x_0}(-f'(x)+x-t),dt=frac{1}{2}(f'(x))^2$
Actually I got stuck on how to arrive at $(f'(x))^2<2f(x)$.
I thought $f(x)$ is influenced by $f'(t)$ where $t$ is around $x$, so I came up with the proof as mentioned above.
But at the same time I thought that for the similar questions such as $f(x)>f'(x)$ we can construct the auxiliary function $g(x)=frac{f(x)}{e^x}$.
So what I really want to ask is how to arrive at $(f'(x))^2<2f(x)$?
I thought this maybe relates to the solution of $(f'(x))^2=2f(x)$.
What's more, any new ideas for the above problem are welcomed. Thank you in advance!
real-analysis ordinary-differential-equations
real-analysis ordinary-differential-equations
asked Dec 18 '18 at 14:24
ZeroZero
34110
asked Dec 18 '18 at 14:24
ZeroZero
34110
asked Dec 18 '18 at 14:24
ZeroZero
34110
asked Dec 18 '18 at 14:24
ZeroZero
34110
asked Dec 18 '18 at 14:24
ZeroZero
34110
34110
add a comment |
add a comment |
1 Answer
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$begingroup$
When exploring the values between $x$ and $x-f'(x)$, it usually makes sense to parametrize that segment as $x-sf'(x)$, $sin[0,1]$. This avoids discuss the different cases of the order between these points.
Let $L$ be the Lipschitz constant of $f'$, then we know from the fundamental theorem that
begin{align}
|f(x+u)-f(x)-f'(x)u|&leint_0^1|f'(x+su)-f'(x)|,ds,|u|
\
&le int_us,ds,L|u|^2
\
&=frac12L|u|^2
end{align}
Resolving the absolute value to one side it follows that
$$
f(x)+f'(x)uge f(x+u)-frac12L|u|^2.
$$
Now insert $u=-frac{f'(x)}{L}$ to find
$$
2f(x)ge 2fleft(x-frac{f'(x)}{L}right)+frac{f'(x)^2}{L}
$$
To conclude now use that $f>0$.
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
$endgroup$
add a comment |
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1 Answer
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$begingroup$
When exploring the values between $x$ and $x-f'(x)$, it usually makes sense to parametrize that segment as $x-sf'(x)$, $sin[0,1]$. This avoids discuss the different cases of the order between these points.
Let $L$ be the Lipschitz constant of $f'$, then we know from the fundamental theorem that
begin{align}
|f(x+u)-f(x)-f'(x)u|&leint_0^1|f'(x+su)-f'(x)|,ds,|u|
\
&le int_us,ds,L|u|^2
\
&=frac12L|u|^2
end{align}
Resolving the absolute value to one side it follows that
$$
f(x)+f'(x)uge f(x+u)-frac12L|u|^2.
$$
Now insert $u=-frac{f'(x)}{L}$ to find
$$
2f(x)ge 2fleft(x-frac{f'(x)}{L}right)+frac{f'(x)^2}{L}
$$
To conclude now use that $f>0$.
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
$endgroup$
add a comment |
$begingroup$
When exploring the values between $x$ and $x-f'(x)$, it usually makes sense to parametrize that segment as $x-sf'(x)$, $sin[0,1]$. This avoids discuss the different cases of the order between these points.
Let $L$ be the Lipschitz constant of $f'$, then we know from the fundamental theorem that
begin{align}
|f(x+u)-f(x)-f'(x)u|&leint_0^1|f'(x+su)-f'(x)|,ds,|u|
\
&le int_us,ds,L|u|^2
\
&=frac12L|u|^2
end{align}
Resolving the absolute value to one side it follows that
$$
f(x)+f'(x)uge f(x+u)-frac12L|u|^2.
$$
Now insert $u=-frac{f'(x)}{L}$ to find
$$
2f(x)ge 2fleft(x-frac{f'(x)}{L}right)+frac{f'(x)^2}{L}
$$
To conclude now use that $f>0$.
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
$endgroup$
add a comment |
$begingroup$
When exploring the values between $x$ and $x-f'(x)$, it usually makes sense to parametrize that segment as $x-sf'(x)$, $sin[0,1]$. This avoids discuss the different cases of the order between these points.
Let $L$ be the Lipschitz constant of $f'$, then we know from the fundamental theorem that
begin{align}
|f(x+u)-f(x)-f'(x)u|&leint_0^1|f'(x+su)-f'(x)|,ds,|u|
\
&le int_us,ds,L|u|^2
\
&=frac12L|u|^2
end{align}
Resolving the absolute value to one side it follows that
$$
f(x)+f'(x)uge f(x+u)-frac12L|u|^2.
$$
Now insert $u=-frac{f'(x)}{L}$ to find
$$
2f(x)ge 2fleft(x-frac{f'(x)}{L}right)+frac{f'(x)^2}{L}
$$
To conclude now use that $f>0$.
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
$endgroup$
When exploring the values between $x$ and $x-f'(x)$, it usually makes sense to parametrize that segment as $x-sf'(x)$, $sin[0,1]$. This avoids discuss the different cases of the order between these points.
Let $L$ be the Lipschitz constant of $f'$, then we know from the fundamental theorem that
begin{align}
|f(x+u)-f(x)-f'(x)u|&leint_0^1|f'(x+su)-f'(x)|,ds,|u|
\
&le int_us,ds,L|u|^2
\
&=frac12L|u|^2
end{align}
Resolving the absolute value to one side it follows that
$$
f(x)+f'(x)uge f(x+u)-frac12L|u|^2.
$$
Now insert $u=-frac{f'(x)}{L}$ to find
$$
2f(x)ge 2fleft(x-frac{f'(x)}{L}right)+frac{f'(x)^2}{L}
$$
To conclude now use that $f>0$.
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
edited Dec 18 '18 at 17:31
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
answered Dec 18 '18 at 16:16
LutzLLutzL
57.9k42054
57.9k42054
add a comment |
add a comment |
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