Two questions about weakly convergent series related to $sin(n^2)$ and Weyl's inequality











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By using partial summation and Weyl's inequality, it is not hard to show that the series $sum_{ngeq 1}frac{sin(n^2)}{n}$ is convergent.




  • Is is true that $$frac{1}{2}=infleft{alphainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{n^alpha}mbox{ is convergent}right}?$$

  • In the case of a positive answer to the previous question, what is $$infleft{betainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{sqrt{n}(log n)^beta}mbox{ is convergent}right}?$$










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  • 2




    By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
    – blabler
    Nov 30 '12 at 4:13












  • A related question has popped up since this one was asked.
    – Douglas B. Staple
    Mar 29 '13 at 3:44






  • 1




    Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
    – i707107
    Jun 8 '13 at 17:33















up vote
53
down vote

favorite
15












By using partial summation and Weyl's inequality, it is not hard to show that the series $sum_{ngeq 1}frac{sin(n^2)}{n}$ is convergent.




  • Is is true that $$frac{1}{2}=infleft{alphainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{n^alpha}mbox{ is convergent}right}?$$

  • In the case of a positive answer to the previous question, what is $$infleft{betainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{sqrt{n}(log n)^beta}mbox{ is convergent}right}?$$










share|cite|improve this question


















  • 2




    By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
    – blabler
    Nov 30 '12 at 4:13












  • A related question has popped up since this one was asked.
    – Douglas B. Staple
    Mar 29 '13 at 3:44






  • 1




    Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
    – i707107
    Jun 8 '13 at 17:33













up vote
53
down vote

favorite
15









up vote
53
down vote

favorite
15






15





By using partial summation and Weyl's inequality, it is not hard to show that the series $sum_{ngeq 1}frac{sin(n^2)}{n}$ is convergent.




  • Is is true that $$frac{1}{2}=infleft{alphainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{n^alpha}mbox{ is convergent}right}?$$

  • In the case of a positive answer to the previous question, what is $$infleft{betainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{sqrt{n}(log n)^beta}mbox{ is convergent}right}?$$










share|cite|improve this question













By using partial summation and Weyl's inequality, it is not hard to show that the series $sum_{ngeq 1}frac{sin(n^2)}{n}$ is convergent.




  • Is is true that $$frac{1}{2}=infleft{alphainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{n^alpha}mbox{ is convergent}right}?$$

  • In the case of a positive answer to the previous question, what is $$infleft{betainmathbb{R}^+:sum_{ngeq 1}frac{sin(n^2)}{sqrt{n}(log n)^beta}mbox{ is convergent}right}?$$







real-analysis sequences-and-series number-theory uniform-distribution diophantine-approximation






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asked Oct 17 '12 at 9:08









Jack D'Aurizio

282k33274653




282k33274653








  • 2




    By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
    – blabler
    Nov 30 '12 at 4:13












  • A related question has popped up since this one was asked.
    – Douglas B. Staple
    Mar 29 '13 at 3:44






  • 1




    Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
    – i707107
    Jun 8 '13 at 17:33














  • 2




    By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
    – blabler
    Nov 30 '12 at 4:13












  • A related question has popped up since this one was asked.
    – Douglas B. Staple
    Mar 29 '13 at 3:44






  • 1




    Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
    – i707107
    Jun 8 '13 at 17:33








2




2




By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
– blabler
Nov 30 '12 at 4:13






By modelling $sin(n^2)$ as a sequence of independent random variables $X_n$, I would expect a positive answer to the first question, also I would expect the later series to be convergent when $beta > 1/2$ and divergent when $beta < 1/2$. Thus the answer to the second question would be $1/2$.
– blabler
Nov 30 '12 at 4:13














A related question has popped up since this one was asked.
– Douglas B. Staple
Mar 29 '13 at 3:44




A related question has popped up since this one was asked.
– Douglas B. Staple
Mar 29 '13 at 3:44




1




1




Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
– i707107
Jun 8 '13 at 17:33




Applying the argument here, math.stackexchange.com/questions/2270/… we obtain that the first quantity is $leq frac{7}{8}$
– i707107
Jun 8 '13 at 17:33










1 Answer
1






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up vote
0
down vote













I recall a generalization of partial summation formula:



Suppose that $lambda_1,lambda_2,ldots$ is a nondecreasing sequence of real numbers with limit infinity, that $c_1,c_2,ldots$ is an arbitrary sequence of real or complex numbers, and that $f(x)$ has a continuous derivative for $xgeq lambda_1$. Put
$$
C(x)=sum_{lambda_nleq x}c_n,
$$

where the summation is over all $n$ for which $lambda_nleq x$. Then for $xgeqlambda_1$,
$$
sum_{lambda_nleq x}c_nf(lambda_n)=C(x)f(x)-int^{x}_{lambda_1}C(t)f'(t)dt.tag 1
$$



Now we can write if $y=x^2$ and $lambda_n=n^2$ and $C(t)=[sqrt{t}]$ (integer part of $sqrt{t}$):
$$
S=sum_{1leq nleq x}frac{sin(n^2)}{n^a}=sum_{lambda_nleq y}frac{sin(lambda_n)}{lambda_n^{a/2}}=
$$

$$
=[sqrt{y}]frac{sin(y)}{y^{a/2}}-int^{y}_{1}[sqrt{t}]frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt.
$$

But it is $[sqrt{t}]=sqrt{t}-{sqrt{t}}$, where ${sqrt{t}}$ is the fractional part of $sqrt{t}$. Hence
$$
S=-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)-{sqrt{y}}frac{sin(y)}{y^{a/2}}+int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt,
$$

where
$$
E(a,z)=int^{infty}_{1}frac{e^{-tz}}{t^a}dt
$$

But when $a>0$ and $yrightarrow+infty$ we have
$$
lim_{yrightarrow+infty}left{-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]right}+sin(1)=
$$

$$
=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)
$$

Also $x$ is positive integer and ${sqrt{y}}=0$.



Hence when $a>0$, then
$$
lim_{xrightarrowinfty}sum^{x}_{n=1}frac{sin(n^2)}{n^a}=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)+lim_{yrightarrowinfty}int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt
$$

But
$$
int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)t^{a/2}-a/2sin(t)t^{a/2-1}}{t^a}dt=
$$

$$
int^{y}_{1}{sqrt{t}}left(cos(t)t^{-a/2}-a/2sin(t)t^{-a/2-1}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt-frac{a}{2}int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt.
$$

Clearly
$$
int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt=2int^{x}_{1}frac{sin(t^2)}{t^{a+1}}{t}dt<infty,
$$

for all $a>0$, since $0leq{t}<1$ and $-1leqsin(t^2)leq 1$, for all $t>0$.



Hence it remains to find under what condition on $a>0$ we have
$$
int^{infty}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt=2int^{infty}_{1}cos(t^2)t^{1-a}{t}dt<infty,
$$

knowinig already that for all $0<aleq 1$ we have
$$
int^{infty}_{1}cos(t^2)t^{1-a}dt<infty.
$$






share|cite|improve this answer























  • When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
    – i707107
    Jun 18 at 22:00










  • I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
    – i707107
    Nov 13 at 22:46










  • You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
    – i707107
    15 hours ago











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1 Answer
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up vote
0
down vote













I recall a generalization of partial summation formula:



Suppose that $lambda_1,lambda_2,ldots$ is a nondecreasing sequence of real numbers with limit infinity, that $c_1,c_2,ldots$ is an arbitrary sequence of real or complex numbers, and that $f(x)$ has a continuous derivative for $xgeq lambda_1$. Put
$$
C(x)=sum_{lambda_nleq x}c_n,
$$

where the summation is over all $n$ for which $lambda_nleq x$. Then for $xgeqlambda_1$,
$$
sum_{lambda_nleq x}c_nf(lambda_n)=C(x)f(x)-int^{x}_{lambda_1}C(t)f'(t)dt.tag 1
$$



Now we can write if $y=x^2$ and $lambda_n=n^2$ and $C(t)=[sqrt{t}]$ (integer part of $sqrt{t}$):
$$
S=sum_{1leq nleq x}frac{sin(n^2)}{n^a}=sum_{lambda_nleq y}frac{sin(lambda_n)}{lambda_n^{a/2}}=
$$

$$
=[sqrt{y}]frac{sin(y)}{y^{a/2}}-int^{y}_{1}[sqrt{t}]frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt.
$$

But it is $[sqrt{t}]=sqrt{t}-{sqrt{t}}$, where ${sqrt{t}}$ is the fractional part of $sqrt{t}$. Hence
$$
S=-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)-{sqrt{y}}frac{sin(y)}{y^{a/2}}+int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt,
$$

where
$$
E(a,z)=int^{infty}_{1}frac{e^{-tz}}{t^a}dt
$$

But when $a>0$ and $yrightarrow+infty$ we have
$$
lim_{yrightarrow+infty}left{-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]right}+sin(1)=
$$

$$
=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)
$$

Also $x$ is positive integer and ${sqrt{y}}=0$.



Hence when $a>0$, then
$$
lim_{xrightarrowinfty}sum^{x}_{n=1}frac{sin(n^2)}{n^a}=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)+lim_{yrightarrowinfty}int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt
$$

But
$$
int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)t^{a/2}-a/2sin(t)t^{a/2-1}}{t^a}dt=
$$

$$
int^{y}_{1}{sqrt{t}}left(cos(t)t^{-a/2}-a/2sin(t)t^{-a/2-1}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt-frac{a}{2}int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt.
$$

Clearly
$$
int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt=2int^{x}_{1}frac{sin(t^2)}{t^{a+1}}{t}dt<infty,
$$

for all $a>0$, since $0leq{t}<1$ and $-1leqsin(t^2)leq 1$, for all $t>0$.



Hence it remains to find under what condition on $a>0$ we have
$$
int^{infty}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt=2int^{infty}_{1}cos(t^2)t^{1-a}{t}dt<infty,
$$

knowinig already that for all $0<aleq 1$ we have
$$
int^{infty}_{1}cos(t^2)t^{1-a}dt<infty.
$$






share|cite|improve this answer























  • When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
    – i707107
    Jun 18 at 22:00










  • I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
    – i707107
    Nov 13 at 22:46










  • You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
    – i707107
    15 hours ago















up vote
0
down vote













I recall a generalization of partial summation formula:



Suppose that $lambda_1,lambda_2,ldots$ is a nondecreasing sequence of real numbers with limit infinity, that $c_1,c_2,ldots$ is an arbitrary sequence of real or complex numbers, and that $f(x)$ has a continuous derivative for $xgeq lambda_1$. Put
$$
C(x)=sum_{lambda_nleq x}c_n,
$$

where the summation is over all $n$ for which $lambda_nleq x$. Then for $xgeqlambda_1$,
$$
sum_{lambda_nleq x}c_nf(lambda_n)=C(x)f(x)-int^{x}_{lambda_1}C(t)f'(t)dt.tag 1
$$



Now we can write if $y=x^2$ and $lambda_n=n^2$ and $C(t)=[sqrt{t}]$ (integer part of $sqrt{t}$):
$$
S=sum_{1leq nleq x}frac{sin(n^2)}{n^a}=sum_{lambda_nleq y}frac{sin(lambda_n)}{lambda_n^{a/2}}=
$$

$$
=[sqrt{y}]frac{sin(y)}{y^{a/2}}-int^{y}_{1}[sqrt{t}]frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt.
$$

But it is $[sqrt{t}]=sqrt{t}-{sqrt{t}}$, where ${sqrt{t}}$ is the fractional part of $sqrt{t}$. Hence
$$
S=-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)-{sqrt{y}}frac{sin(y)}{y^{a/2}}+int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt,
$$

where
$$
E(a,z)=int^{infty}_{1}frac{e^{-tz}}{t^a}dt
$$

But when $a>0$ and $yrightarrow+infty$ we have
$$
lim_{yrightarrow+infty}left{-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]right}+sin(1)=
$$

$$
=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)
$$

Also $x$ is positive integer and ${sqrt{y}}=0$.



Hence when $a>0$, then
$$
lim_{xrightarrowinfty}sum^{x}_{n=1}frac{sin(n^2)}{n^a}=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)+lim_{yrightarrowinfty}int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt
$$

But
$$
int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)t^{a/2}-a/2sin(t)t^{a/2-1}}{t^a}dt=
$$

$$
int^{y}_{1}{sqrt{t}}left(cos(t)t^{-a/2}-a/2sin(t)t^{-a/2-1}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt-frac{a}{2}int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt.
$$

Clearly
$$
int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt=2int^{x}_{1}frac{sin(t^2)}{t^{a+1}}{t}dt<infty,
$$

for all $a>0$, since $0leq{t}<1$ and $-1leqsin(t^2)leq 1$, for all $t>0$.



Hence it remains to find under what condition on $a>0$ we have
$$
int^{infty}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt=2int^{infty}_{1}cos(t^2)t^{1-a}{t}dt<infty,
$$

knowinig already that for all $0<aleq 1$ we have
$$
int^{infty}_{1}cos(t^2)t^{1-a}dt<infty.
$$






share|cite|improve this answer























  • When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
    – i707107
    Jun 18 at 22:00










  • I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
    – i707107
    Nov 13 at 22:46










  • You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
    – i707107
    15 hours ago













up vote
0
down vote










up vote
0
down vote









I recall a generalization of partial summation formula:



Suppose that $lambda_1,lambda_2,ldots$ is a nondecreasing sequence of real numbers with limit infinity, that $c_1,c_2,ldots$ is an arbitrary sequence of real or complex numbers, and that $f(x)$ has a continuous derivative for $xgeq lambda_1$. Put
$$
C(x)=sum_{lambda_nleq x}c_n,
$$

where the summation is over all $n$ for which $lambda_nleq x$. Then for $xgeqlambda_1$,
$$
sum_{lambda_nleq x}c_nf(lambda_n)=C(x)f(x)-int^{x}_{lambda_1}C(t)f'(t)dt.tag 1
$$



Now we can write if $y=x^2$ and $lambda_n=n^2$ and $C(t)=[sqrt{t}]$ (integer part of $sqrt{t}$):
$$
S=sum_{1leq nleq x}frac{sin(n^2)}{n^a}=sum_{lambda_nleq y}frac{sin(lambda_n)}{lambda_n^{a/2}}=
$$

$$
=[sqrt{y}]frac{sin(y)}{y^{a/2}}-int^{y}_{1}[sqrt{t}]frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt.
$$

But it is $[sqrt{t}]=sqrt{t}-{sqrt{t}}$, where ${sqrt{t}}$ is the fractional part of $sqrt{t}$. Hence
$$
S=-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)-{sqrt{y}}frac{sin(y)}{y^{a/2}}+int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt,
$$

where
$$
E(a,z)=int^{infty}_{1}frac{e^{-tz}}{t^a}dt
$$

But when $a>0$ and $yrightarrow+infty$ we have
$$
lim_{yrightarrow+infty}left{-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]right}+sin(1)=
$$

$$
=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)
$$

Also $x$ is positive integer and ${sqrt{y}}=0$.



Hence when $a>0$, then
$$
lim_{xrightarrowinfty}sum^{x}_{n=1}frac{sin(n^2)}{n^a}=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)+lim_{yrightarrowinfty}int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt
$$

But
$$
int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)t^{a/2}-a/2sin(t)t^{a/2-1}}{t^a}dt=
$$

$$
int^{y}_{1}{sqrt{t}}left(cos(t)t^{-a/2}-a/2sin(t)t^{-a/2-1}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt-frac{a}{2}int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt.
$$

Clearly
$$
int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt=2int^{x}_{1}frac{sin(t^2)}{t^{a+1}}{t}dt<infty,
$$

for all $a>0$, since $0leq{t}<1$ and $-1leqsin(t^2)leq 1$, for all $t>0$.



Hence it remains to find under what condition on $a>0$ we have
$$
int^{infty}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt=2int^{infty}_{1}cos(t^2)t^{1-a}{t}dt<infty,
$$

knowinig already that for all $0<aleq 1$ we have
$$
int^{infty}_{1}cos(t^2)t^{1-a}dt<infty.
$$






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I recall a generalization of partial summation formula:



Suppose that $lambda_1,lambda_2,ldots$ is a nondecreasing sequence of real numbers with limit infinity, that $c_1,c_2,ldots$ is an arbitrary sequence of real or complex numbers, and that $f(x)$ has a continuous derivative for $xgeq lambda_1$. Put
$$
C(x)=sum_{lambda_nleq x}c_n,
$$

where the summation is over all $n$ for which $lambda_nleq x$. Then for $xgeqlambda_1$,
$$
sum_{lambda_nleq x}c_nf(lambda_n)=C(x)f(x)-int^{x}_{lambda_1}C(t)f'(t)dt.tag 1
$$



Now we can write if $y=x^2$ and $lambda_n=n^2$ and $C(t)=[sqrt{t}]$ (integer part of $sqrt{t}$):
$$
S=sum_{1leq nleq x}frac{sin(n^2)}{n^a}=sum_{lambda_nleq y}frac{sin(lambda_n)}{lambda_n^{a/2}}=
$$

$$
=[sqrt{y}]frac{sin(y)}{y^{a/2}}-int^{y}_{1}[sqrt{t}]frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt.
$$

But it is $[sqrt{t}]=sqrt{t}-{sqrt{t}}$, where ${sqrt{t}}$ is the fractional part of $sqrt{t}$. Hence
$$
S=-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)-{sqrt{y}}frac{sin(y)}{y^{a/2}}+int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt,
$$

where
$$
E(a,z)=int^{infty}_{1}frac{e^{-tz}}{t^a}dt
$$

But when $a>0$ and $yrightarrow+infty$ we have
$$
lim_{yrightarrow+infty}left{-frac{1}{2}Releft[iy^{1/2-a/2}Eleft(frac{1+a}{2},iyright)right]+frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]right}+sin(1)=
$$

$$
=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)
$$

Also $x$ is positive integer and ${sqrt{y}}=0$.



Hence when $a>0$, then
$$
lim_{xrightarrowinfty}sum^{x}_{n=1}frac{sin(n^2)}{n^a}=frac{1}{2}Releft[iEleft(frac{1+a}{2},iright)right]+sin(1)+lim_{yrightarrowinfty}int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt
$$

But
$$
int^{y}_{1}{sqrt{t}}frac{d}{dt}left(frac{sin(t)}{t^{a/2}}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)t^{a/2}-a/2sin(t)t^{a/2-1}}{t^a}dt=
$$

$$
int^{y}_{1}{sqrt{t}}left(cos(t)t^{-a/2}-a/2sin(t)t^{-a/2-1}right)dt=int^{y}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt-frac{a}{2}int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt.
$$

Clearly
$$
int^{y}_{1}frac{sin(t)}{t^{a/2+1}}{sqrt{t}}dt=2int^{x}_{1}frac{sin(t^2)}{t^{a+1}}{t}dt<infty,
$$

for all $a>0$, since $0leq{t}<1$ and $-1leqsin(t^2)leq 1$, for all $t>0$.



Hence it remains to find under what condition on $a>0$ we have
$$
int^{infty}_{1}{sqrt{t}}frac{cos(t)}{t^{a/2}}dt=2int^{infty}_{1}cos(t^2)t^{1-a}{t}dt<infty,
$$

knowinig already that for all $0<aleq 1$ we have
$$
int^{infty}_{1}cos(t^2)t^{1-a}dt<infty.
$$







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share|cite|improve this answer



share|cite|improve this answer








edited yesterday

























answered Jun 17 at 7:58









Nikos Bagis

1,967311




1,967311












  • When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
    – i707107
    Jun 18 at 22:00










  • I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
    – i707107
    Nov 13 at 22:46










  • You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
    – i707107
    15 hours ago


















  • When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
    – i707107
    Jun 18 at 22:00










  • I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
    – i707107
    Nov 13 at 22:46










  • You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
    – i707107
    15 hours ago
















When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
– i707107
Jun 18 at 22:00




When you applied the partial summation, it seems that you used $C(t)=sqrt t$. However, $C(t)=lfloor sqrt t rfloor$.
– i707107
Jun 18 at 22:00












I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
– i707107
Nov 13 at 22:46




I saw your edit. Then you have to show that the limit as $yrightarrowinfty$ exists. Otherwise, the proof is incomplete.
– i707107
Nov 13 at 22:46












You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
– i707107
15 hours ago




You cannot just ignore ${t}$ at the last step, since $cos(t^2)$ changes sign infinitely often.
– i707107
15 hours ago


















 

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