Proving $lim_{xto-infty}x^{-k} = 0$
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Please prove $lim_{xto-infty}x^{-k} = 0$ for k a natural number using the definition of this limit. I am having problems discovering the proof.
calculus limits infinity
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
$endgroup$
add a comment |
$begingroup$
Please prove $lim_{xto-infty}x^{-k} = 0$ for k a natural number using the definition of this limit. I am having problems discovering the proof.
calculus limits infinity
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
$endgroup$
1
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
1
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55
add a comment |
$begingroup$
Please prove $lim_{xto-infty}x^{-k} = 0$ for k a natural number using the definition of this limit. I am having problems discovering the proof.
calculus limits infinity
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
$endgroup$
Please prove $lim_{xto-infty}x^{-k} = 0$ for k a natural number using the definition of this limit. I am having problems discovering the proof.
calculus limits infinity
calculus limits infinity
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
edited Jan 3 at 21:42
Eric Brown
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
asked Jan 3 at 21:30
Eric BrownEric Brown
11011
11011
1
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
1
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55
add a comment |
1
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
1
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55
1
1
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
1
1
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55
add a comment |
2 Answers
2
active
oldest
votes
$begingroup$
For all $k > 0$ there exists a $pinmathbb{N}$ such that $frac{1}{p} < k$. Then
$$0 < frac{1}{x^k} = left(frac{1}{x}right)^k < left(frac{1}{x}right)^{1/p}$$
Since $frac{1}{x}to 0$ and $f(u) = u^{1/p}$ is continuous at $0$, we have
$$lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{uto 0}u^{1/p} = 0^{1/p} = 0$$
Therefore
$$lim_{xto -infty}frac{1}{x^k} = 0 k > 0$$
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
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add a comment |
$begingroup$
The limit is equivalent to $lim_{xto -infty} frac{x^k}{x^{2k}}$, an indeterminate form of $frac{infty}{infty}$. By L'Hospitals rule, that is equivalent to $lim_{xto -infty} frac{kx^{k-1}}{2kx^{2k-1}}$. A little bit of algebraic manipulation shows that that is equal to $lim_{xto -infty} frac{1}{2}*x^{-k}$. Taking the 1/2 out of the limit, we have $lim_{xto -infty} x^{-k}=frac{1}{2}*lim_{xto -infty} x^{-k}$. Treating $lim_{xto -infty} x^{-k}$ as a variable in a linear equation to be solved for, we have $lim_{xto -infty} x^{-k}=0$
answered Jan 4 at 1:22
H HuangH Huang
89110
$endgroup$
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
add a comment |
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2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
For all $k > 0$ there exists a $pinmathbb{N}$ such that $frac{1}{p} < k$. Then
$$0 < frac{1}{x^k} = left(frac{1}{x}right)^k < left(frac{1}{x}right)^{1/p}$$
Since $frac{1}{x}to 0$ and $f(u) = u^{1/p}$ is continuous at $0$, we have
$$lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{uto 0}u^{1/p} = 0^{1/p} = 0$$
Therefore
$$lim_{xto -infty}frac{1}{x^k} = 0 k > 0$$
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
$endgroup$
add a comment |
$begingroup$
For all $k > 0$ there exists a $pinmathbb{N}$ such that $frac{1}{p} < k$. Then
$$0 < frac{1}{x^k} = left(frac{1}{x}right)^k < left(frac{1}{x}right)^{1/p}$$
Since $frac{1}{x}to 0$ and $f(u) = u^{1/p}$ is continuous at $0$, we have
$$lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{uto 0}u^{1/p} = 0^{1/p} = 0$$
Therefore
$$lim_{xto -infty}frac{1}{x^k} = 0 k > 0$$
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
$endgroup$
add a comment |
$begingroup$
For all $k > 0$ there exists a $pinmathbb{N}$ such that $frac{1}{p} < k$. Then
$$0 < frac{1}{x^k} = left(frac{1}{x}right)^k < left(frac{1}{x}right)^{1/p}$$
Since $frac{1}{x}to 0$ and $f(u) = u^{1/p}$ is continuous at $0$, we have
$$lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{uto 0}u^{1/p} = 0^{1/p} = 0$$
Therefore
$$lim_{xto -infty}frac{1}{x^k} = 0 k > 0$$
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
$endgroup$
For all $k > 0$ there exists a $pinmathbb{N}$ such that $frac{1}{p} < k$. Then
$$0 < frac{1}{x^k} = left(frac{1}{x}right)^k < left(frac{1}{x}right)^{1/p}$$
Since $frac{1}{x}to 0$ and $f(u) = u^{1/p}$ is continuous at $0$, we have
$$lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{xto -infty}left(frac{1}{x}right)^{1/p} = lim_{uto 0}u^{1/p} = 0^{1/p} = 0$$
Therefore
$$lim_{xto -infty}frac{1}{x^k} = 0 k > 0$$
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
answered Jan 3 at 21:56
WolfyWolfy
2,31811138
2,31811138
add a comment |
add a comment |
$begingroup$
The limit is equivalent to $lim_{xto -infty} frac{x^k}{x^{2k}}$, an indeterminate form of $frac{infty}{infty}$. By L'Hospitals rule, that is equivalent to $lim_{xto -infty} frac{kx^{k-1}}{2kx^{2k-1}}$. A little bit of algebraic manipulation shows that that is equal to $lim_{xto -infty} frac{1}{2}*x^{-k}$. Taking the 1/2 out of the limit, we have $lim_{xto -infty} x^{-k}=frac{1}{2}*lim_{xto -infty} x^{-k}$. Treating $lim_{xto -infty} x^{-k}$ as a variable in a linear equation to be solved for, we have $lim_{xto -infty} x^{-k}=0$
answered Jan 4 at 1:22
H HuangH Huang
89110
$endgroup$
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
add a comment |
$begingroup$
The limit is equivalent to $lim_{xto -infty} frac{x^k}{x^{2k}}$, an indeterminate form of $frac{infty}{infty}$. By L'Hospitals rule, that is equivalent to $lim_{xto -infty} frac{kx^{k-1}}{2kx^{2k-1}}$. A little bit of algebraic manipulation shows that that is equal to $lim_{xto -infty} frac{1}{2}*x^{-k}$. Taking the 1/2 out of the limit, we have $lim_{xto -infty} x^{-k}=frac{1}{2}*lim_{xto -infty} x^{-k}$. Treating $lim_{xto -infty} x^{-k}$ as a variable in a linear equation to be solved for, we have $lim_{xto -infty} x^{-k}=0$
answered Jan 4 at 1:22
H HuangH Huang
89110
$endgroup$
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
add a comment |
$begingroup$
The limit is equivalent to $lim_{xto -infty} frac{x^k}{x^{2k}}$, an indeterminate form of $frac{infty}{infty}$. By L'Hospitals rule, that is equivalent to $lim_{xto -infty} frac{kx^{k-1}}{2kx^{2k-1}}$. A little bit of algebraic manipulation shows that that is equal to $lim_{xto -infty} frac{1}{2}*x^{-k}$. Taking the 1/2 out of the limit, we have $lim_{xto -infty} x^{-k}=frac{1}{2}*lim_{xto -infty} x^{-k}$. Treating $lim_{xto -infty} x^{-k}$ as a variable in a linear equation to be solved for, we have $lim_{xto -infty} x^{-k}=0$
answered Jan 4 at 1:22
H HuangH Huang
89110
$endgroup$
The limit is equivalent to $lim_{xto -infty} frac{x^k}{x^{2k}}$, an indeterminate form of $frac{infty}{infty}$. By L'Hospitals rule, that is equivalent to $lim_{xto -infty} frac{kx^{k-1}}{2kx^{2k-1}}$. A little bit of algebraic manipulation shows that that is equal to $lim_{xto -infty} frac{1}{2}*x^{-k}$. Taking the 1/2 out of the limit, we have $lim_{xto -infty} x^{-k}=frac{1}{2}*lim_{xto -infty} x^{-k}$. Treating $lim_{xto -infty} x^{-k}$ as a variable in a linear equation to be solved for, we have $lim_{xto -infty} x^{-k}=0$
answered Jan 4 at 1:22
H HuangH Huang
89110
answered Jan 4 at 1:22
H HuangH Huang
89110
answered Jan 4 at 1:22
H HuangH Huang
89110
answered Jan 4 at 1:22
H HuangH Huang
89110
89110
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
add a comment |
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
$begingroup$
This works only after you have proven L'Hospitals rule as x decreases to negative infinity.
$endgroup$
– Eric Brown
Jan 5 at 2:18
add a comment |
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1
$begingroup$
I assume that $kinmathbb{N}$. In that case since $x^ktopm infty$ (as all polynomials of positive degree do) then $x^{-k}=1/x^kto 0$.
$endgroup$
– freakish
Jan 3 at 21:39
$begingroup$
Please use the definition of this limit at infinity.
$endgroup$
– Eric Brown
Jan 3 at 21:43
1
$begingroup$
Hint: prove it for $k=1$ and then use $|x^{-k}|<|x^{-1}|$ for $x<-1$ and $k>1$.
$endgroup$
– SmileyCraft
Jan 3 at 21:50
$begingroup$
But this requires the use of the squeeze theorem for functions as x→-∞, which has not been proven by me yet.
$endgroup$
– Eric Brown
Jan 3 at 21:55