Power series representation for $xarctan(x)$. How?
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I am supposed to start with the P.S representation for $dfrac{1}{1-x}$ and then figure out the P.S representation for $xtan^{-1}(x)$. I know the process of making it for just the $tan^{-1}x$. But wouldn't the fact that there is an extra $x$ at the front change everything dramatically? Or am I not getting something?
Can I just do the same process as for $tan^{-1}(x)$ and then just add an extra $x$ after sigma?
Thanks!
calculus power-series
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add a comment |
$begingroup$
I am supposed to start with the P.S representation for $dfrac{1}{1-x}$ and then figure out the P.S representation for $xtan^{-1}(x)$. I know the process of making it for just the $tan^{-1}x$. But wouldn't the fact that there is an extra $x$ at the front change everything dramatically? Or am I not getting something?
Can I just do the same process as for $tan^{-1}(x)$ and then just add an extra $x$ after sigma?
Thanks!
calculus power-series
$endgroup$
1
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35
add a comment |
$begingroup$
I am supposed to start with the P.S representation for $dfrac{1}{1-x}$ and then figure out the P.S representation for $xtan^{-1}(x)$. I know the process of making it for just the $tan^{-1}x$. But wouldn't the fact that there is an extra $x$ at the front change everything dramatically? Or am I not getting something?
Can I just do the same process as for $tan^{-1}(x)$ and then just add an extra $x$ after sigma?
Thanks!
calculus power-series
$endgroup$
I am supposed to start with the P.S representation for $dfrac{1}{1-x}$ and then figure out the P.S representation for $xtan^{-1}(x)$. I know the process of making it for just the $tan^{-1}x$. But wouldn't the fact that there is an extra $x$ at the front change everything dramatically? Or am I not getting something?
Can I just do the same process as for $tan^{-1}(x)$ and then just add an extra $x$ after sigma?
Thanks!
calculus power-series
calculus power-series
edited Dec 13 '18 at 4:06
Nosrati
26.6k62354
26.6k62354
asked Dec 13 '18 at 3:27
GlebGleb
82
82
1
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35
add a comment |
1
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35
1
1
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35
add a comment |
3 Answers
3
active
oldest
votes
$begingroup$
Recall that
$$arctan x=int_0^xfrac{dt}{1+t^2}$$
We also know that, for $|t|<1$,
$$frac1t=sum_{kgeq0}(1-t)^k$$
So we then have that
$$frac1{1+t^2}=sum_{kgeq0}(-1)^kt^{2k}$$
So for $|x|<1$,
$$
begin{align}
arctan x=&int_0^xsum_{kgeq0}(-1)^kt^{2k}dt\
=&sum_{kgeq0}(-1)^kint_0^xt^{2k}dt\
=&sum_{kgeq0}(-1)^kfrac{x^{2k+1}}{2k+1}\
end{align}
$$
Which means that
$$xarctan x=sum_{kgeq0}(-1)^kfrac{x^{2k+2}}{2k+1}$$
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add a comment |
$begingroup$
No, it doesn't change everything dramatically.
Just multiply each term of power series of $tan^{-1}x$ by $x$.
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$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
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– hardmath
Dec 13 '18 at 3:42
add a comment |
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$tan^{-1}x=intfrac1{1+x^2}=intsum_n(-x^2)^n=sum_nint(-x^2)^n=sum_n(-1)^nfrac{x^{2n+1}}{2n+1}$.
Thus $xcdottan^{-1}x=sum_n(-1)^nfrac{x^{2n+2}}{2n+1}$.
$endgroup$
add a comment |
Your Answer
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3 Answers
3
active
oldest
votes
3 Answers
3
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
Recall that
$$arctan x=int_0^xfrac{dt}{1+t^2}$$
We also know that, for $|t|<1$,
$$frac1t=sum_{kgeq0}(1-t)^k$$
So we then have that
$$frac1{1+t^2}=sum_{kgeq0}(-1)^kt^{2k}$$
So for $|x|<1$,
$$
begin{align}
arctan x=&int_0^xsum_{kgeq0}(-1)^kt^{2k}dt\
=&sum_{kgeq0}(-1)^kint_0^xt^{2k}dt\
=&sum_{kgeq0}(-1)^kfrac{x^{2k+1}}{2k+1}\
end{align}
$$
Which means that
$$xarctan x=sum_{kgeq0}(-1)^kfrac{x^{2k+2}}{2k+1}$$
$endgroup$
add a comment |
$begingroup$
Recall that
$$arctan x=int_0^xfrac{dt}{1+t^2}$$
We also know that, for $|t|<1$,
$$frac1t=sum_{kgeq0}(1-t)^k$$
So we then have that
$$frac1{1+t^2}=sum_{kgeq0}(-1)^kt^{2k}$$
So for $|x|<1$,
$$
begin{align}
arctan x=&int_0^xsum_{kgeq0}(-1)^kt^{2k}dt\
=&sum_{kgeq0}(-1)^kint_0^xt^{2k}dt\
=&sum_{kgeq0}(-1)^kfrac{x^{2k+1}}{2k+1}\
end{align}
$$
Which means that
$$xarctan x=sum_{kgeq0}(-1)^kfrac{x^{2k+2}}{2k+1}$$
$endgroup$
add a comment |
$begingroup$
Recall that
$$arctan x=int_0^xfrac{dt}{1+t^2}$$
We also know that, for $|t|<1$,
$$frac1t=sum_{kgeq0}(1-t)^k$$
So we then have that
$$frac1{1+t^2}=sum_{kgeq0}(-1)^kt^{2k}$$
So for $|x|<1$,
$$
begin{align}
arctan x=&int_0^xsum_{kgeq0}(-1)^kt^{2k}dt\
=&sum_{kgeq0}(-1)^kint_0^xt^{2k}dt\
=&sum_{kgeq0}(-1)^kfrac{x^{2k+1}}{2k+1}\
end{align}
$$
Which means that
$$xarctan x=sum_{kgeq0}(-1)^kfrac{x^{2k+2}}{2k+1}$$
$endgroup$
Recall that
$$arctan x=int_0^xfrac{dt}{1+t^2}$$
We also know that, for $|t|<1$,
$$frac1t=sum_{kgeq0}(1-t)^k$$
So we then have that
$$frac1{1+t^2}=sum_{kgeq0}(-1)^kt^{2k}$$
So for $|x|<1$,
$$
begin{align}
arctan x=&int_0^xsum_{kgeq0}(-1)^kt^{2k}dt\
=&sum_{kgeq0}(-1)^kint_0^xt^{2k}dt\
=&sum_{kgeq0}(-1)^kfrac{x^{2k+1}}{2k+1}\
end{align}
$$
Which means that
$$xarctan x=sum_{kgeq0}(-1)^kfrac{x^{2k+2}}{2k+1}$$
answered Dec 13 '18 at 3:53
clathratusclathratus
4,725337
4,725337
add a comment |
add a comment |
$begingroup$
No, it doesn't change everything dramatically.
Just multiply each term of power series of $tan^{-1}x$ by $x$.
$endgroup$
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
add a comment |
$begingroup$
No, it doesn't change everything dramatically.
Just multiply each term of power series of $tan^{-1}x$ by $x$.
$endgroup$
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
add a comment |
$begingroup$
No, it doesn't change everything dramatically.
Just multiply each term of power series of $tan^{-1}x$ by $x$.
$endgroup$
No, it doesn't change everything dramatically.
Just multiply each term of power series of $tan^{-1}x$ by $x$.
answered Dec 13 '18 at 3:36
MartundMartund
1,667213
1,667213
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
add a comment |
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
$begingroup$
If you want to make an Answer out of this idea (already mooted in the Question and a Comment), why not go beyond the mere claim by presenting a justification?
$endgroup$
– hardmath
Dec 13 '18 at 3:42
add a comment |
$begingroup$
$tan^{-1}x=intfrac1{1+x^2}=intsum_n(-x^2)^n=sum_nint(-x^2)^n=sum_n(-1)^nfrac{x^{2n+1}}{2n+1}$.
Thus $xcdottan^{-1}x=sum_n(-1)^nfrac{x^{2n+2}}{2n+1}$.
$endgroup$
add a comment |
$begingroup$
$tan^{-1}x=intfrac1{1+x^2}=intsum_n(-x^2)^n=sum_nint(-x^2)^n=sum_n(-1)^nfrac{x^{2n+1}}{2n+1}$.
Thus $xcdottan^{-1}x=sum_n(-1)^nfrac{x^{2n+2}}{2n+1}$.
$endgroup$
add a comment |
$begingroup$
$tan^{-1}x=intfrac1{1+x^2}=intsum_n(-x^2)^n=sum_nint(-x^2)^n=sum_n(-1)^nfrac{x^{2n+1}}{2n+1}$.
Thus $xcdottan^{-1}x=sum_n(-1)^nfrac{x^{2n+2}}{2n+1}$.
$endgroup$
$tan^{-1}x=intfrac1{1+x^2}=intsum_n(-x^2)^n=sum_nint(-x^2)^n=sum_n(-1)^nfrac{x^{2n+1}}{2n+1}$.
Thus $xcdottan^{-1}x=sum_n(-1)^nfrac{x^{2n+2}}{2n+1}$.
answered Dec 13 '18 at 3:53
Chris CusterChris Custer
13.9k3827
13.9k3827
add a comment |
add a comment |
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1
$begingroup$
Yes, you can just multiply. Get $x$ inside the sum and that's it.
$endgroup$
– Joaquin San
Dec 13 '18 at 3:35