For a convergent sequence $limsup b_n = lim b_n$












1












$begingroup$


Happy new year!
I wish to prove the following result to practice with $limsup:
$




For a convergent sequence$ (b_n)$ we know $limsup b_n = lim b_n$




If $b_n$ is convergent, the set of accumulation points is definitely nonempty as it must contain the limit of $b_n$ and we know that $b_n$ is bounded. Therefore if $V$ is the set of accumulation points of $(b_n)$, we know that $limsup(b_n)=sup(V)$.



Intuitively and by previous exercises I know that since limits are unique, there must be precisely one accumulation point and therefore $V$ contains one element, namely $lim(b_n)$. We now conclude that:
$$limsup b_n = lim b_n $$



Was this argument convincing? Was I a bit sloppy, can I make this argument more precise, is it correct?



After this question I will attempt to prove a similar result for a divergent sequence $(b_n)to infty$ then $limsup b_n = infty$.





Edit/addition: $limsup b_n = infty$ follows immediately from unboundedness (from above) of a divergent sequence and the definition of $limsup$, which is nice.










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$endgroup$












  • $begingroup$
    What is $sup b_n$?
    $endgroup$
    – El borito
    Jan 2 at 15:41








  • 1




    $begingroup$
    Oh, my bad, that's a typo
    $endgroup$
    – Wesley Strik
    Jan 2 at 15:44






  • 1




    $begingroup$
    Your argument is correct.
    $endgroup$
    – Song
    Jan 2 at 17:21


















1












$begingroup$


Happy new year!
I wish to prove the following result to practice with $limsup:
$




For a convergent sequence$ (b_n)$ we know $limsup b_n = lim b_n$




If $b_n$ is convergent, the set of accumulation points is definitely nonempty as it must contain the limit of $b_n$ and we know that $b_n$ is bounded. Therefore if $V$ is the set of accumulation points of $(b_n)$, we know that $limsup(b_n)=sup(V)$.



Intuitively and by previous exercises I know that since limits are unique, there must be precisely one accumulation point and therefore $V$ contains one element, namely $lim(b_n)$. We now conclude that:
$$limsup b_n = lim b_n $$



Was this argument convincing? Was I a bit sloppy, can I make this argument more precise, is it correct?



After this question I will attempt to prove a similar result for a divergent sequence $(b_n)to infty$ then $limsup b_n = infty$.





Edit/addition: $limsup b_n = infty$ follows immediately from unboundedness (from above) of a divergent sequence and the definition of $limsup$, which is nice.










share|cite|improve this question











$endgroup$












  • $begingroup$
    What is $sup b_n$?
    $endgroup$
    – El borito
    Jan 2 at 15:41








  • 1




    $begingroup$
    Oh, my bad, that's a typo
    $endgroup$
    – Wesley Strik
    Jan 2 at 15:44






  • 1




    $begingroup$
    Your argument is correct.
    $endgroup$
    – Song
    Jan 2 at 17:21
















1












1








1





$begingroup$


Happy new year!
I wish to prove the following result to practice with $limsup:
$




For a convergent sequence$ (b_n)$ we know $limsup b_n = lim b_n$




If $b_n$ is convergent, the set of accumulation points is definitely nonempty as it must contain the limit of $b_n$ and we know that $b_n$ is bounded. Therefore if $V$ is the set of accumulation points of $(b_n)$, we know that $limsup(b_n)=sup(V)$.



Intuitively and by previous exercises I know that since limits are unique, there must be precisely one accumulation point and therefore $V$ contains one element, namely $lim(b_n)$. We now conclude that:
$$limsup b_n = lim b_n $$



Was this argument convincing? Was I a bit sloppy, can I make this argument more precise, is it correct?



After this question I will attempt to prove a similar result for a divergent sequence $(b_n)to infty$ then $limsup b_n = infty$.





Edit/addition: $limsup b_n = infty$ follows immediately from unboundedness (from above) of a divergent sequence and the definition of $limsup$, which is nice.










share|cite|improve this question











$endgroup$




Happy new year!
I wish to prove the following result to practice with $limsup:
$




For a convergent sequence$ (b_n)$ we know $limsup b_n = lim b_n$




If $b_n$ is convergent, the set of accumulation points is definitely nonempty as it must contain the limit of $b_n$ and we know that $b_n$ is bounded. Therefore if $V$ is the set of accumulation points of $(b_n)$, we know that $limsup(b_n)=sup(V)$.



Intuitively and by previous exercises I know that since limits are unique, there must be precisely one accumulation point and therefore $V$ contains one element, namely $lim(b_n)$. We now conclude that:
$$limsup b_n = lim b_n $$



Was this argument convincing? Was I a bit sloppy, can I make this argument more precise, is it correct?



After this question I will attempt to prove a similar result for a divergent sequence $(b_n)to infty$ then $limsup b_n = infty$.





Edit/addition: $limsup b_n = infty$ follows immediately from unboundedness (from above) of a divergent sequence and the definition of $limsup$, which is nice.







real-analysis proof-verification limsup-and-liminf






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Jan 2 at 15:44







Wesley Strik

















asked Jan 2 at 15:33









Wesley StrikWesley Strik

2,194424




2,194424












  • $begingroup$
    What is $sup b_n$?
    $endgroup$
    – El borito
    Jan 2 at 15:41








  • 1




    $begingroup$
    Oh, my bad, that's a typo
    $endgroup$
    – Wesley Strik
    Jan 2 at 15:44






  • 1




    $begingroup$
    Your argument is correct.
    $endgroup$
    – Song
    Jan 2 at 17:21




















  • $begingroup$
    What is $sup b_n$?
    $endgroup$
    – El borito
    Jan 2 at 15:41








  • 1




    $begingroup$
    Oh, my bad, that's a typo
    $endgroup$
    – Wesley Strik
    Jan 2 at 15:44






  • 1




    $begingroup$
    Your argument is correct.
    $endgroup$
    – Song
    Jan 2 at 17:21


















$begingroup$
What is $sup b_n$?
$endgroup$
– El borito
Jan 2 at 15:41






$begingroup$
What is $sup b_n$?
$endgroup$
– El borito
Jan 2 at 15:41






1




1




$begingroup$
Oh, my bad, that's a typo
$endgroup$
– Wesley Strik
Jan 2 at 15:44




$begingroup$
Oh, my bad, that's a typo
$endgroup$
– Wesley Strik
Jan 2 at 15:44




1




1




$begingroup$
Your argument is correct.
$endgroup$
– Song
Jan 2 at 17:21






$begingroup$
Your argument is correct.
$endgroup$
– Song
Jan 2 at 17:21












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