Is there a way to find this limit algebraically?












3














I'm a Calculus I student and my teacher has given me a set of problems to solve with L'Hoptial's rule. Most of them have been pretty easy, but this one has me stumped.



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



You'll notice that using L'Hopital's rule flips the value of the top to the bottom. For example, using it once returns:



$$limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



And doing it again returns you to the beginning:



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



I of course plugged it into my calculator to find the limit to evaluate to 1, but I was wondering if there was a better way to do this algebraically?










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  • 6




    $frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
    – Mason
    2 hours ago






  • 1




    The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
    – Andreas Rejbrand
    1 hour ago


















3














I'm a Calculus I student and my teacher has given me a set of problems to solve with L'Hoptial's rule. Most of them have been pretty easy, but this one has me stumped.



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



You'll notice that using L'Hopital's rule flips the value of the top to the bottom. For example, using it once returns:



$$limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



And doing it again returns you to the beginning:



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



I of course plugged it into my calculator to find the limit to evaluate to 1, but I was wondering if there was a better way to do this algebraically?










share|cite|improve this question







New contributor




Jae Swanepoel is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
















  • 6




    $frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
    – Mason
    2 hours ago






  • 1




    The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
    – Andreas Rejbrand
    1 hour ago
















3












3








3







I'm a Calculus I student and my teacher has given me a set of problems to solve with L'Hoptial's rule. Most of them have been pretty easy, but this one has me stumped.



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



You'll notice that using L'Hopital's rule flips the value of the top to the bottom. For example, using it once returns:



$$limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



And doing it again returns you to the beginning:



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



I of course plugged it into my calculator to find the limit to evaluate to 1, but I was wondering if there was a better way to do this algebraically?










share|cite|improve this question







New contributor




Jae Swanepoel is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











I'm a Calculus I student and my teacher has given me a set of problems to solve with L'Hoptial's rule. Most of them have been pretty easy, but this one has me stumped.



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



You'll notice that using L'Hopital's rule flips the value of the top to the bottom. For example, using it once returns:



$$limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



And doing it again returns you to the beginning:



$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$$



I of course plugged it into my calculator to find the limit to evaluate to 1, but I was wondering if there was a better way to do this algebraically?







calculus






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New contributor




Jae Swanepoel is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











share|cite|improve this question







New contributor




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Check out our Code of Conduct.









share|cite|improve this question




share|cite|improve this question






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asked 2 hours ago









Jae Swanepoel

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161




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New contributor





Jae Swanepoel is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.






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Check out our Code of Conduct.








  • 6




    $frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
    – Mason
    2 hours ago






  • 1




    The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
    – Andreas Rejbrand
    1 hour ago
















  • 6




    $frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
    – Mason
    2 hours ago






  • 1




    The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
    – Andreas Rejbrand
    1 hour ago










6




6




$frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
– Mason
2 hours ago




$frac{x}{sqrt{x^2 + 1}}=frac{sqrt{x^2}}{sqrt{x^2+1}}=sqrt{frac{x^2}{x^2+1}}$
– Mason
2 hours ago




1




1




The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
– Andreas Rejbrand
1 hour ago






The "right" way to solve this is as Thomas Shelby wrote in his answer. However, you can almost intuitively see that the limit is $1$ even without using a calculator. Indeed, if $x$ is a huge positive number, say $10^{5863}$, the difference between $x^2$ and $x^2 + 1$ is extremely tiny. So the expression is essentially indistinguishable from ${xoversqrt{x^2}} = {xover x} = 1$.
– Andreas Rejbrand
1 hour ago












4 Answers
4






active

oldest

votes


















8














Hint: Divide the numerator and denominator by $x $ and apply the limit.



$$frac{x}{sqrt{x^2 + 1}}=frac{1}{sqrt{1 + frac{1}{x^2}}}$$






share|cite|improve this answer



















  • 5




    In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
    – Arthur
    2 hours ago





















7














Hint



Simply use $${xover x+1}={xover sqrt{x^2+2x+1}}<{xover sqrt{x^2+1}}<1$$for large enough $x>0$.






share|cite|improve this answer

















  • 1




    Mostafa.Very nice+.
    – Peter Szilas
    1 hour ago










  • But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
    – Milan Stojanovic
    1 hour ago










  • @PeterSzilas thank you!
    – Mostafa Ayaz
    1 hour ago






  • 1




    @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
    – Mostafa Ayaz
    1 hour ago



















3














By your own reasoning, you have the following:
$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



Now, the left side is clearly the reciprocal of the right side, so we have:
$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=frac{1}{limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}}$$



(Note that doing this manipulation assumes that $limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$ converges to a real number. However, you can use the first derivative to show this is an always increasing function and then use basic algebra to show that $frac{x}{sqrt{x^2 + 1}} < 1$ for all $xinBbb{R}$. Thus, because this is a bounded, always increasing function, the limit as $xto infty$ must converge to some real number, so our assumption in this manipulation is valid.)



Cross-multiply:
$$left(limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}right)^2=1$$



Take the square root:
$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=pm 1$$



However, it is easy to show that $frac{x}{sqrt{x^2 + 1}}>0$ for all $x > 0$. Therefore, there's no way the limit can be a negative number like $-1$. Thus, the only possibility we have left is $+1$, so:
$$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=1$$






share|cite|improve this answer





















  • Nide overkill :)
    – Milan Stojanovic
    1 hour ago



















3














When computing the limit of rational functions, as is the case for $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}},$$ you want to divide the top and bottom by the highest degree in the denominator, which in this case is $x$. Since $x rightarrow +infty$, so $x$ is always positive (at least, near where we are worried about) I claim that $x = sqrt{x^2}$. So, if we divide the top and bottom by $x$, we get $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}} = lim_{x rightarrow infty} frac{1}{sqrt{1 + 1/x^2}}.$$ You should be able to compute the limit from here.



Whenever you see a monomial in the numerator with the square root of a polynomial in the denominator, you should consider this method. Of course, keep in mind that you'll have to tweak it slightly if $x rightarrow -infty$! Try to see if you can figure out what would change in that case.






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    4 Answers
    4






    active

    oldest

    votes








    4 Answers
    4






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    8














    Hint: Divide the numerator and denominator by $x $ and apply the limit.



    $$frac{x}{sqrt{x^2 + 1}}=frac{1}{sqrt{1 + frac{1}{x^2}}}$$






    share|cite|improve this answer



















    • 5




      In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
      – Arthur
      2 hours ago


















    8














    Hint: Divide the numerator and denominator by $x $ and apply the limit.



    $$frac{x}{sqrt{x^2 + 1}}=frac{1}{sqrt{1 + frac{1}{x^2}}}$$






    share|cite|improve this answer



















    • 5




      In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
      – Arthur
      2 hours ago
















    8












    8








    8






    Hint: Divide the numerator and denominator by $x $ and apply the limit.



    $$frac{x}{sqrt{x^2 + 1}}=frac{1}{sqrt{1 + frac{1}{x^2}}}$$






    share|cite|improve this answer














    Hint: Divide the numerator and denominator by $x $ and apply the limit.



    $$frac{x}{sqrt{x^2 + 1}}=frac{1}{sqrt{1 + frac{1}{x^2}}}$$







    share|cite|improve this answer














    share|cite|improve this answer



    share|cite|improve this answer








    edited 2 hours ago

























    answered 2 hours ago









    Thomas Shelby

    1,790216




    1,790216








    • 5




      In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
      – Arthur
      2 hours ago
















    • 5




      In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
      – Arthur
      2 hours ago










    5




    5




    In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
    – Arthur
    2 hours ago






    In other words, actually do the division you see written down in $lim_{xtoinfty}frac{sqrt{x^2+1}}x$.
    – Arthur
    2 hours ago













    7














    Hint



    Simply use $${xover x+1}={xover sqrt{x^2+2x+1}}<{xover sqrt{x^2+1}}<1$$for large enough $x>0$.






    share|cite|improve this answer

















    • 1




      Mostafa.Very nice+.
      – Peter Szilas
      1 hour ago










    • But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
      – Milan Stojanovic
      1 hour ago










    • @PeterSzilas thank you!
      – Mostafa Ayaz
      1 hour ago






    • 1




      @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
      – Mostafa Ayaz
      1 hour ago
















    7














    Hint



    Simply use $${xover x+1}={xover sqrt{x^2+2x+1}}<{xover sqrt{x^2+1}}<1$$for large enough $x>0$.






    share|cite|improve this answer

















    • 1




      Mostafa.Very nice+.
      – Peter Szilas
      1 hour ago










    • But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
      – Milan Stojanovic
      1 hour ago










    • @PeterSzilas thank you!
      – Mostafa Ayaz
      1 hour ago






    • 1




      @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
      – Mostafa Ayaz
      1 hour ago














    7












    7








    7






    Hint



    Simply use $${xover x+1}={xover sqrt{x^2+2x+1}}<{xover sqrt{x^2+1}}<1$$for large enough $x>0$.






    share|cite|improve this answer












    Hint



    Simply use $${xover x+1}={xover sqrt{x^2+2x+1}}<{xover sqrt{x^2+1}}<1$$for large enough $x>0$.







    share|cite|improve this answer












    share|cite|improve this answer



    share|cite|improve this answer










    answered 1 hour ago









    Mostafa Ayaz

    14k3936




    14k3936








    • 1




      Mostafa.Very nice+.
      – Peter Szilas
      1 hour ago










    • But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
      – Milan Stojanovic
      1 hour ago










    • @PeterSzilas thank you!
      – Mostafa Ayaz
      1 hour ago






    • 1




      @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
      – Mostafa Ayaz
      1 hour ago














    • 1




      Mostafa.Very nice+.
      – Peter Szilas
      1 hour ago










    • But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
      – Milan Stojanovic
      1 hour ago










    • @PeterSzilas thank you!
      – Mostafa Ayaz
      1 hour ago






    • 1




      @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
      – Mostafa Ayaz
      1 hour ago








    1




    1




    Mostafa.Very nice+.
    – Peter Szilas
    1 hour ago




    Mostafa.Very nice+.
    – Peter Szilas
    1 hour ago












    But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
    – Milan Stojanovic
    1 hour ago




    But how so we know the limit is 1. Based on what you wrote couldnt the answer be 1/2
    – Milan Stojanovic
    1 hour ago












    @PeterSzilas thank you!
    – Mostafa Ayaz
    1 hour ago




    @PeterSzilas thank you!
    – Mostafa Ayaz
    1 hour ago




    1




    1




    @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
    – Mostafa Ayaz
    1 hour ago




    @MilanStojanovic No since $$lim_{xto infty}{xover x+1}=1$$and $$lim_{xto infty}1=1$$so the Squeeze theorem is applicable here....
    – Mostafa Ayaz
    1 hour ago











    3














    By your own reasoning, you have the following:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



    Now, the left side is clearly the reciprocal of the right side, so we have:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=frac{1}{limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}}$$



    (Note that doing this manipulation assumes that $limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$ converges to a real number. However, you can use the first derivative to show this is an always increasing function and then use basic algebra to show that $frac{x}{sqrt{x^2 + 1}} < 1$ for all $xinBbb{R}$. Thus, because this is a bounded, always increasing function, the limit as $xto infty$ must converge to some real number, so our assumption in this manipulation is valid.)



    Cross-multiply:
    $$left(limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}right)^2=1$$



    Take the square root:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=pm 1$$



    However, it is easy to show that $frac{x}{sqrt{x^2 + 1}}>0$ for all $x > 0$. Therefore, there's no way the limit can be a negative number like $-1$. Thus, the only possibility we have left is $+1$, so:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=1$$






    share|cite|improve this answer





















    • Nide overkill :)
      – Milan Stojanovic
      1 hour ago
















    3














    By your own reasoning, you have the following:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



    Now, the left side is clearly the reciprocal of the right side, so we have:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=frac{1}{limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}}$$



    (Note that doing this manipulation assumes that $limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$ converges to a real number. However, you can use the first derivative to show this is an always increasing function and then use basic algebra to show that $frac{x}{sqrt{x^2 + 1}} < 1$ for all $xinBbb{R}$. Thus, because this is a bounded, always increasing function, the limit as $xto infty$ must converge to some real number, so our assumption in this manipulation is valid.)



    Cross-multiply:
    $$left(limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}right)^2=1$$



    Take the square root:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=pm 1$$



    However, it is easy to show that $frac{x}{sqrt{x^2 + 1}}>0$ for all $x > 0$. Therefore, there's no way the limit can be a negative number like $-1$. Thus, the only possibility we have left is $+1$, so:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=1$$






    share|cite|improve this answer





















    • Nide overkill :)
      – Milan Stojanovic
      1 hour ago














    3












    3








    3






    By your own reasoning, you have the following:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



    Now, the left side is clearly the reciprocal of the right side, so we have:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=frac{1}{limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}}$$



    (Note that doing this manipulation assumes that $limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$ converges to a real number. However, you can use the first derivative to show this is an always increasing function and then use basic algebra to show that $frac{x}{sqrt{x^2 + 1}} < 1$ for all $xinBbb{R}$. Thus, because this is a bounded, always increasing function, the limit as $xto infty$ must converge to some real number, so our assumption in this manipulation is valid.)



    Cross-multiply:
    $$left(limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}right)^2=1$$



    Take the square root:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=pm 1$$



    However, it is easy to show that $frac{x}{sqrt{x^2 + 1}}>0$ for all $x > 0$. Therefore, there's no way the limit can be a negative number like $-1$. Thus, the only possibility we have left is $+1$, so:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=1$$






    share|cite|improve this answer












    By your own reasoning, you have the following:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=limlimits_{xto infty} frac{sqrt{x^2 + 1}}{x}$$



    Now, the left side is clearly the reciprocal of the right side, so we have:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=frac{1}{limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}}$$



    (Note that doing this manipulation assumes that $limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}$ converges to a real number. However, you can use the first derivative to show this is an always increasing function and then use basic algebra to show that $frac{x}{sqrt{x^2 + 1}} < 1$ for all $xinBbb{R}$. Thus, because this is a bounded, always increasing function, the limit as $xto infty$ must converge to some real number, so our assumption in this manipulation is valid.)



    Cross-multiply:
    $$left(limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}right)^2=1$$



    Take the square root:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=pm 1$$



    However, it is easy to show that $frac{x}{sqrt{x^2 + 1}}>0$ for all $x > 0$. Therefore, there's no way the limit can be a negative number like $-1$. Thus, the only possibility we have left is $+1$, so:
    $$limlimits_{xto infty} frac{x}{sqrt{x^2 + 1}}=1$$







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    answered 2 hours ago









    Noble Mushtak

    15.1k1735




    15.1k1735












    • Nide overkill :)
      – Milan Stojanovic
      1 hour ago


















    • Nide overkill :)
      – Milan Stojanovic
      1 hour ago
















    Nide overkill :)
    – Milan Stojanovic
    1 hour ago




    Nide overkill :)
    – Milan Stojanovic
    1 hour ago











    3














    When computing the limit of rational functions, as is the case for $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}},$$ you want to divide the top and bottom by the highest degree in the denominator, which in this case is $x$. Since $x rightarrow +infty$, so $x$ is always positive (at least, near where we are worried about) I claim that $x = sqrt{x^2}$. So, if we divide the top and bottom by $x$, we get $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}} = lim_{x rightarrow infty} frac{1}{sqrt{1 + 1/x^2}}.$$ You should be able to compute the limit from here.



    Whenever you see a monomial in the numerator with the square root of a polynomial in the denominator, you should consider this method. Of course, keep in mind that you'll have to tweak it slightly if $x rightarrow -infty$! Try to see if you can figure out what would change in that case.






    share|cite|improve this answer










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      3














      When computing the limit of rational functions, as is the case for $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}},$$ you want to divide the top and bottom by the highest degree in the denominator, which in this case is $x$. Since $x rightarrow +infty$, so $x$ is always positive (at least, near where we are worried about) I claim that $x = sqrt{x^2}$. So, if we divide the top and bottom by $x$, we get $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}} = lim_{x rightarrow infty} frac{1}{sqrt{1 + 1/x^2}}.$$ You should be able to compute the limit from here.



      Whenever you see a monomial in the numerator with the square root of a polynomial in the denominator, you should consider this method. Of course, keep in mind that you'll have to tweak it slightly if $x rightarrow -infty$! Try to see if you can figure out what would change in that case.






      share|cite|improve this answer










      New contributor




      kkc is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.





















        3












        3








        3






        When computing the limit of rational functions, as is the case for $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}},$$ you want to divide the top and bottom by the highest degree in the denominator, which in this case is $x$. Since $x rightarrow +infty$, so $x$ is always positive (at least, near where we are worried about) I claim that $x = sqrt{x^2}$. So, if we divide the top and bottom by $x$, we get $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}} = lim_{x rightarrow infty} frac{1}{sqrt{1 + 1/x^2}}.$$ You should be able to compute the limit from here.



        Whenever you see a monomial in the numerator with the square root of a polynomial in the denominator, you should consider this method. Of course, keep in mind that you'll have to tweak it slightly if $x rightarrow -infty$! Try to see if you can figure out what would change in that case.






        share|cite|improve this answer










        New contributor




        kkc is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
        Check out our Code of Conduct.









        When computing the limit of rational functions, as is the case for $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}},$$ you want to divide the top and bottom by the highest degree in the denominator, which in this case is $x$. Since $x rightarrow +infty$, so $x$ is always positive (at least, near where we are worried about) I claim that $x = sqrt{x^2}$. So, if we divide the top and bottom by $x$, we get $$lim_{x rightarrow infty} frac{x}{sqrt{x^2 +1}} = lim_{x rightarrow infty} frac{1}{sqrt{1 + 1/x^2}}.$$ You should be able to compute the limit from here.



        Whenever you see a monomial in the numerator with the square root of a polynomial in the denominator, you should consider this method. Of course, keep in mind that you'll have to tweak it slightly if $x rightarrow -infty$! Try to see if you can figure out what would change in that case.







        share|cite|improve this answer










        New contributor




        kkc is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
        Check out our Code of Conduct.









        share|cite|improve this answer



        share|cite|improve this answer








        edited 1 hour ago









        Noble Mushtak

        15.1k1735




        15.1k1735






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        Check out our Code of Conduct.









        answered 1 hour ago









        kkc

        1208




        1208




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        New contributor





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        kkc is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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