Order of a Complex Number? [on hold]












-2














Bit stuck on this question: The aim of this exercise is to determine all elements of finite order in $mathbb{C}^{∗}$, the multiplicative group of non-zero complex numbers.



What is the order of $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})$?



I know $z$ can be of the form $z=re^{itheta}$ but don't know what to do to determine the 'order' or what I can do to the formula to solve this.



Any help would be great, thanks.










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put on hold as off-topic by Mark Viola, Did, metamorphy, José Carlos Santos, Holo 2 days ago


This question appears to be off-topic. The users who voted to close gave this specific reason:


  • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Did, metamorphy, José Carlos Santos, Holo

If this question can be reworded to fit the rules in the help center, please edit the question.













  • I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
    – John Doe
    2 days ago












  • This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
    – Reety
    2 days ago








  • 1




    Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
    – John Doe
    2 days ago
















-2














Bit stuck on this question: The aim of this exercise is to determine all elements of finite order in $mathbb{C}^{∗}$, the multiplicative group of non-zero complex numbers.



What is the order of $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})$?



I know $z$ can be of the form $z=re^{itheta}$ but don't know what to do to determine the 'order' or what I can do to the formula to solve this.



Any help would be great, thanks.










share|cite|improve this question















put on hold as off-topic by Mark Viola, Did, metamorphy, José Carlos Santos, Holo 2 days ago


This question appears to be off-topic. The users who voted to close gave this specific reason:


  • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Did, metamorphy, José Carlos Santos, Holo

If this question can be reworded to fit the rules in the help center, please edit the question.













  • I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
    – John Doe
    2 days ago












  • This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
    – Reety
    2 days ago








  • 1




    Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
    – John Doe
    2 days ago














-2












-2








-2


1





Bit stuck on this question: The aim of this exercise is to determine all elements of finite order in $mathbb{C}^{∗}$, the multiplicative group of non-zero complex numbers.



What is the order of $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})$?



I know $z$ can be of the form $z=re^{itheta}$ but don't know what to do to determine the 'order' or what I can do to the formula to solve this.



Any help would be great, thanks.










share|cite|improve this question















Bit stuck on this question: The aim of this exercise is to determine all elements of finite order in $mathbb{C}^{∗}$, the multiplicative group of non-zero complex numbers.



What is the order of $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})$?



I know $z$ can be of the form $z=re^{itheta}$ but don't know what to do to determine the 'order' or what I can do to the formula to solve this.



Any help would be great, thanks.







group-theory complex-numbers






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edited 2 days ago

























asked 2 days ago









Reety

13611




13611




put on hold as off-topic by Mark Viola, Did, metamorphy, José Carlos Santos, Holo 2 days ago


This question appears to be off-topic. The users who voted to close gave this specific reason:


  • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Did, metamorphy, José Carlos Santos, Holo

If this question can be reworded to fit the rules in the help center, please edit the question.




put on hold as off-topic by Mark Viola, Did, metamorphy, José Carlos Santos, Holo 2 days ago


This question appears to be off-topic. The users who voted to close gave this specific reason:


  • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Did, metamorphy, José Carlos Santos, Holo

If this question can be reworded to fit the rules in the help center, please edit the question.












  • I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
    – John Doe
    2 days ago












  • This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
    – Reety
    2 days ago








  • 1




    Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
    – John Doe
    2 days ago


















  • I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
    – John Doe
    2 days ago












  • This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
    – Reety
    2 days ago








  • 1




    Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
    – John Doe
    2 days ago
















I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
– John Doe
2 days ago






I haven't heard of complex numbers being referred to as having any such property. Do you have any more context? What did previous parts of the question say for instance?
– John Doe
2 days ago














This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
– Reety
2 days ago






This is the only previous part of the question, after it just states De Moivres Theorem. The aim of this exercise is to determine all elements of finite order in $C^{∗}$, the multiplicative group of non-zero complex numbers.@John Doe
– Reety
2 days ago






1




1




Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
– John Doe
2 days ago




Ahh ok - now that you mention group theory, this may make more sense. The order of a group element is the lowest (integer) power to which that element has to be raised for you to reach the identity. In your group, this is any $ainBbb C$ such that $a^n=1$ for $ninBbb N$. Then the order of your element $a$ will be $n$.
– John Doe
2 days ago










4 Answers
4






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Hint: $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{i2pi/3}$. You need to find the smallest $nin Bbb N $ such that $z^n=1$,i.e, $e^{in2pi/3}=1$. Note that $e^{i2pi}=1$. Can you find such an $n $?






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  • 1




    Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
    – Reety
    2 days ago










  • Yes. ${}{} {}{}{}$
    – Thomas Shelby
    2 days ago



















2














Let us define $e^{iA}= cos A +isin A$ when $Ain Bbb R$ without any thought to the motivation for it. By DeMoivre's Theorem we have $e^{inA}=(e^{iA})^n$ for $nin Bbb Z^+ $ and $Ain Bbb R.$



Let $0ne zin Bbb C.$ Then $z=re^{it}$ where $|z|=rin Bbb R^+$ and $t$ is some member of $Bbb R.$



(1). Suppose $z^n=1$ for some $nin Bbb Z^+.$ Then $1=|z^n|=|r^n(e^{it})^n|=|r^ne^{nit}|=r^n,$ so $r=1.$ So $1=z^n=e^{nit},$ which requires $ntin {2pi m:min Bbb Z}.$ So $t/2pi in Bbb Q.$ So $zin {e^{2pi iq}:qin Bbb Q}.$



(2). Suppose $zin {e^{2pi iq}:qin Bbb Q}.$ Then $z=e^{2pi i m/n}$ for some $nin Bbb Z^+$ and some $min Bbb Z,$ so $z^n=e^{2pi i m}=1.$



(3). From (1) and (2), $z$ has a finite order iff $zin {e^{2pi i q}: qin Bbb Q}=$ $={cos 2pi q +isin 2pi q: qin Bbb Qcap [0,1)}.$



Note. For any real $u,v$ with $u^2+v^2=1$ there exists $tinBbb R$ such that $(cos t, sin t)=(u,v).$ So if $0ne zin Bbb C,$ let $z=x+iy$ with $x,y in Bbb R.$ Since $x,y$ are not both $0,$ we have $|z|=sqrt {x^2+y^2},>0.$ Now let $(u,v)=(x/|z|, y/|z|).$ Since $u^2+v^2=1,$ there exists $tin Bbb R$ with $(u,v)=(cos t,sin t). $ So $z=|z|(u+iv)=|z|(cos t +isin t)=|z|e^{it}.$






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    2














    If the order of $z$ is the smallest positive integer $n$ such that $z^{n}=1$, then this is fairly simple.



    $z$ has a finite order iff $vert z vert = 1$, and $arg (z)=pi cdot q$ where $q$ is a rational number. To find the order, just find the smallest positive integer n such that $q cdot n = 2k$ for some integer $k$. This is because multiplying the complex numbers, their arguments add together. Hopefully this makes sense and I interpreted the question right.






    share|cite|improve this answer










    New contributor




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


























      1














      Find the smallest natural $n$ so that $z^n = 1$.



      $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{ifrac {2pi}{3}}$



      So $z^n = e^{ifrac {2npi} 3}$



      Now $e^{i 2kpi} = 1$ for all integer $k$ and $e^{itheta} = 1$ only if $theta = 2kpi$ for some integer $k$.



      So $z^n = e^{ifrac {2npi} 3} = 1 iff frac {2npi}3 = 2pi*k$ for some integer $k$.



      So we need to find then smallest natural $n$ so and $frac {2npi}3 = 2pi *k$ for some integer value of $k$.



      That's.... not a hard question.






      share|cite|improve this answer




























        4 Answers
        4






        active

        oldest

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        4 Answers
        4






        active

        oldest

        votes









        active

        oldest

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        active

        oldest

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        4














        Hint: $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{i2pi/3}$. You need to find the smallest $nin Bbb N $ such that $z^n=1$,i.e, $e^{in2pi/3}=1$. Note that $e^{i2pi}=1$. Can you find such an $n $?






        share|cite|improve this answer



















        • 1




          Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
          – Reety
          2 days ago










        • Yes. ${}{} {}{}{}$
          – Thomas Shelby
          2 days ago
















        4














        Hint: $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{i2pi/3}$. You need to find the smallest $nin Bbb N $ such that $z^n=1$,i.e, $e^{in2pi/3}=1$. Note that $e^{i2pi}=1$. Can you find such an $n $?






        share|cite|improve this answer



















        • 1




          Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
          – Reety
          2 days ago










        • Yes. ${}{} {}{}{}$
          – Thomas Shelby
          2 days ago














        4












        4








        4






        Hint: $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{i2pi/3}$. You need to find the smallest $nin Bbb N $ such that $z^n=1$,i.e, $e^{in2pi/3}=1$. Note that $e^{i2pi}=1$. Can you find such an $n $?






        share|cite|improve this answer














        Hint: $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{i2pi/3}$. You need to find the smallest $nin Bbb N $ such that $z^n=1$,i.e, $e^{in2pi/3}=1$. Note that $e^{i2pi}=1$. Can you find such an $n $?







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited 2 days ago

























        answered 2 days ago









        Thomas Shelby

        1,445216




        1,445216








        • 1




          Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
          – Reety
          2 days ago










        • Yes. ${}{} {}{}{}$
          – Thomas Shelby
          2 days ago














        • 1




          Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
          – Reety
          2 days ago










        • Yes. ${}{} {}{}{}$
          – Thomas Shelby
          2 days ago








        1




        1




        Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
        – Reety
        2 days ago




        Thank you very much, its when n=3 so if I'm correct this must mean it is of order 3?
        – Reety
        2 days ago












        Yes. ${}{} {}{}{}$
        – Thomas Shelby
        2 days ago




        Yes. ${}{} {}{}{}$
        – Thomas Shelby
        2 days ago











        2














        Let us define $e^{iA}= cos A +isin A$ when $Ain Bbb R$ without any thought to the motivation for it. By DeMoivre's Theorem we have $e^{inA}=(e^{iA})^n$ for $nin Bbb Z^+ $ and $Ain Bbb R.$



        Let $0ne zin Bbb C.$ Then $z=re^{it}$ where $|z|=rin Bbb R^+$ and $t$ is some member of $Bbb R.$



        (1). Suppose $z^n=1$ for some $nin Bbb Z^+.$ Then $1=|z^n|=|r^n(e^{it})^n|=|r^ne^{nit}|=r^n,$ so $r=1.$ So $1=z^n=e^{nit},$ which requires $ntin {2pi m:min Bbb Z}.$ So $t/2pi in Bbb Q.$ So $zin {e^{2pi iq}:qin Bbb Q}.$



        (2). Suppose $zin {e^{2pi iq}:qin Bbb Q}.$ Then $z=e^{2pi i m/n}$ for some $nin Bbb Z^+$ and some $min Bbb Z,$ so $z^n=e^{2pi i m}=1.$



        (3). From (1) and (2), $z$ has a finite order iff $zin {e^{2pi i q}: qin Bbb Q}=$ $={cos 2pi q +isin 2pi q: qin Bbb Qcap [0,1)}.$



        Note. For any real $u,v$ with $u^2+v^2=1$ there exists $tinBbb R$ such that $(cos t, sin t)=(u,v).$ So if $0ne zin Bbb C,$ let $z=x+iy$ with $x,y in Bbb R.$ Since $x,y$ are not both $0,$ we have $|z|=sqrt {x^2+y^2},>0.$ Now let $(u,v)=(x/|z|, y/|z|).$ Since $u^2+v^2=1,$ there exists $tin Bbb R$ with $(u,v)=(cos t,sin t). $ So $z=|z|(u+iv)=|z|(cos t +isin t)=|z|e^{it}.$






        share|cite|improve this answer




























          2














          Let us define $e^{iA}= cos A +isin A$ when $Ain Bbb R$ without any thought to the motivation for it. By DeMoivre's Theorem we have $e^{inA}=(e^{iA})^n$ for $nin Bbb Z^+ $ and $Ain Bbb R.$



          Let $0ne zin Bbb C.$ Then $z=re^{it}$ where $|z|=rin Bbb R^+$ and $t$ is some member of $Bbb R.$



          (1). Suppose $z^n=1$ for some $nin Bbb Z^+.$ Then $1=|z^n|=|r^n(e^{it})^n|=|r^ne^{nit}|=r^n,$ so $r=1.$ So $1=z^n=e^{nit},$ which requires $ntin {2pi m:min Bbb Z}.$ So $t/2pi in Bbb Q.$ So $zin {e^{2pi iq}:qin Bbb Q}.$



          (2). Suppose $zin {e^{2pi iq}:qin Bbb Q}.$ Then $z=e^{2pi i m/n}$ for some $nin Bbb Z^+$ and some $min Bbb Z,$ so $z^n=e^{2pi i m}=1.$



          (3). From (1) and (2), $z$ has a finite order iff $zin {e^{2pi i q}: qin Bbb Q}=$ $={cos 2pi q +isin 2pi q: qin Bbb Qcap [0,1)}.$



          Note. For any real $u,v$ with $u^2+v^2=1$ there exists $tinBbb R$ such that $(cos t, sin t)=(u,v).$ So if $0ne zin Bbb C,$ let $z=x+iy$ with $x,y in Bbb R.$ Since $x,y$ are not both $0,$ we have $|z|=sqrt {x^2+y^2},>0.$ Now let $(u,v)=(x/|z|, y/|z|).$ Since $u^2+v^2=1,$ there exists $tin Bbb R$ with $(u,v)=(cos t,sin t). $ So $z=|z|(u+iv)=|z|(cos t +isin t)=|z|e^{it}.$






          share|cite|improve this answer


























            2












            2








            2






            Let us define $e^{iA}= cos A +isin A$ when $Ain Bbb R$ without any thought to the motivation for it. By DeMoivre's Theorem we have $e^{inA}=(e^{iA})^n$ for $nin Bbb Z^+ $ and $Ain Bbb R.$



            Let $0ne zin Bbb C.$ Then $z=re^{it}$ where $|z|=rin Bbb R^+$ and $t$ is some member of $Bbb R.$



            (1). Suppose $z^n=1$ for some $nin Bbb Z^+.$ Then $1=|z^n|=|r^n(e^{it})^n|=|r^ne^{nit}|=r^n,$ so $r=1.$ So $1=z^n=e^{nit},$ which requires $ntin {2pi m:min Bbb Z}.$ So $t/2pi in Bbb Q.$ So $zin {e^{2pi iq}:qin Bbb Q}.$



            (2). Suppose $zin {e^{2pi iq}:qin Bbb Q}.$ Then $z=e^{2pi i m/n}$ for some $nin Bbb Z^+$ and some $min Bbb Z,$ so $z^n=e^{2pi i m}=1.$



            (3). From (1) and (2), $z$ has a finite order iff $zin {e^{2pi i q}: qin Bbb Q}=$ $={cos 2pi q +isin 2pi q: qin Bbb Qcap [0,1)}.$



            Note. For any real $u,v$ with $u^2+v^2=1$ there exists $tinBbb R$ such that $(cos t, sin t)=(u,v).$ So if $0ne zin Bbb C,$ let $z=x+iy$ with $x,y in Bbb R.$ Since $x,y$ are not both $0,$ we have $|z|=sqrt {x^2+y^2},>0.$ Now let $(u,v)=(x/|z|, y/|z|).$ Since $u^2+v^2=1,$ there exists $tin Bbb R$ with $(u,v)=(cos t,sin t). $ So $z=|z|(u+iv)=|z|(cos t +isin t)=|z|e^{it}.$






            share|cite|improve this answer














            Let us define $e^{iA}= cos A +isin A$ when $Ain Bbb R$ without any thought to the motivation for it. By DeMoivre's Theorem we have $e^{inA}=(e^{iA})^n$ for $nin Bbb Z^+ $ and $Ain Bbb R.$



            Let $0ne zin Bbb C.$ Then $z=re^{it}$ where $|z|=rin Bbb R^+$ and $t$ is some member of $Bbb R.$



            (1). Suppose $z^n=1$ for some $nin Bbb Z^+.$ Then $1=|z^n|=|r^n(e^{it})^n|=|r^ne^{nit}|=r^n,$ so $r=1.$ So $1=z^n=e^{nit},$ which requires $ntin {2pi m:min Bbb Z}.$ So $t/2pi in Bbb Q.$ So $zin {e^{2pi iq}:qin Bbb Q}.$



            (2). Suppose $zin {e^{2pi iq}:qin Bbb Q}.$ Then $z=e^{2pi i m/n}$ for some $nin Bbb Z^+$ and some $min Bbb Z,$ so $z^n=e^{2pi i m}=1.$



            (3). From (1) and (2), $z$ has a finite order iff $zin {e^{2pi i q}: qin Bbb Q}=$ $={cos 2pi q +isin 2pi q: qin Bbb Qcap [0,1)}.$



            Note. For any real $u,v$ with $u^2+v^2=1$ there exists $tinBbb R$ such that $(cos t, sin t)=(u,v).$ So if $0ne zin Bbb C,$ let $z=x+iy$ with $x,y in Bbb R.$ Since $x,y$ are not both $0,$ we have $|z|=sqrt {x^2+y^2},>0.$ Now let $(u,v)=(x/|z|, y/|z|).$ Since $u^2+v^2=1,$ there exists $tin Bbb R$ with $(u,v)=(cos t,sin t). $ So $z=|z|(u+iv)=|z|(cos t +isin t)=|z|e^{it}.$







            share|cite|improve this answer














            share|cite|improve this answer



            share|cite|improve this answer








            edited 2 days ago

























            answered 2 days ago









            DanielWainfleet

            34.1k31647




            34.1k31647























                2














                If the order of $z$ is the smallest positive integer $n$ such that $z^{n}=1$, then this is fairly simple.



                $z$ has a finite order iff $vert z vert = 1$, and $arg (z)=pi cdot q$ where $q$ is a rational number. To find the order, just find the smallest positive integer n such that $q cdot n = 2k$ for some integer $k$. This is because multiplying the complex numbers, their arguments add together. Hopefully this makes sense and I interpreted the question right.






                share|cite|improve this answer










                New contributor




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























                  2














                  If the order of $z$ is the smallest positive integer $n$ such that $z^{n}=1$, then this is fairly simple.



                  $z$ has a finite order iff $vert z vert = 1$, and $arg (z)=pi cdot q$ where $q$ is a rational number. To find the order, just find the smallest positive integer n such that $q cdot n = 2k$ for some integer $k$. This is because multiplying the complex numbers, their arguments add together. Hopefully this makes sense and I interpreted the question right.






                  share|cite|improve this answer










                  New contributor




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





















                    2












                    2








                    2






                    If the order of $z$ is the smallest positive integer $n$ such that $z^{n}=1$, then this is fairly simple.



                    $z$ has a finite order iff $vert z vert = 1$, and $arg (z)=pi cdot q$ where $q$ is a rational number. To find the order, just find the smallest positive integer n such that $q cdot n = 2k$ for some integer $k$. This is because multiplying the complex numbers, their arguments add together. Hopefully this makes sense and I interpreted the question right.






                    share|cite|improve this answer










                    New contributor




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









                    If the order of $z$ is the smallest positive integer $n$ such that $z^{n}=1$, then this is fairly simple.



                    $z$ has a finite order iff $vert z vert = 1$, and $arg (z)=pi cdot q$ where $q$ is a rational number. To find the order, just find the smallest positive integer n such that $q cdot n = 2k$ for some integer $k$. This is because multiplying the complex numbers, their arguments add together. Hopefully this makes sense and I interpreted the question right.







                    share|cite|improve this answer










                    New contributor




                    Zachary Hunter 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 2 days ago









                    amWhy

                    191k28224439




                    191k28224439






                    New contributor




                    Zachary Hunter is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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                    answered 2 days ago









                    Zachary Hunter

                    3447




                    3447




                    New contributor




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





                    New contributor





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






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























                        1














                        Find the smallest natural $n$ so that $z^n = 1$.



                        $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{ifrac {2pi}{3}}$



                        So $z^n = e^{ifrac {2npi} 3}$



                        Now $e^{i 2kpi} = 1$ for all integer $k$ and $e^{itheta} = 1$ only if $theta = 2kpi$ for some integer $k$.



                        So $z^n = e^{ifrac {2npi} 3} = 1 iff frac {2npi}3 = 2pi*k$ for some integer $k$.



                        So we need to find then smallest natural $n$ so and $frac {2npi}3 = 2pi *k$ for some integer value of $k$.



                        That's.... not a hard question.






                        share|cite|improve this answer


























                          1














                          Find the smallest natural $n$ so that $z^n = 1$.



                          $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{ifrac {2pi}{3}}$



                          So $z^n = e^{ifrac {2npi} 3}$



                          Now $e^{i 2kpi} = 1$ for all integer $k$ and $e^{itheta} = 1$ only if $theta = 2kpi$ for some integer $k$.



                          So $z^n = e^{ifrac {2npi} 3} = 1 iff frac {2npi}3 = 2pi*k$ for some integer $k$.



                          So we need to find then smallest natural $n$ so and $frac {2npi}3 = 2pi *k$ for some integer value of $k$.



                          That's.... not a hard question.






                          share|cite|improve this answer
























                            1












                            1








                            1






                            Find the smallest natural $n$ so that $z^n = 1$.



                            $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{ifrac {2pi}{3}}$



                            So $z^n = e^{ifrac {2npi} 3}$



                            Now $e^{i 2kpi} = 1$ for all integer $k$ and $e^{itheta} = 1$ only if $theta = 2kpi$ for some integer $k$.



                            So $z^n = e^{ifrac {2npi} 3} = 1 iff frac {2npi}3 = 2pi*k$ for some integer $k$.



                            So we need to find then smallest natural $n$ so and $frac {2npi}3 = 2pi *k$ for some integer value of $k$.



                            That's.... not a hard question.






                            share|cite|improve this answer












                            Find the smallest natural $n$ so that $z^n = 1$.



                            $z=cos(frac{2pi}{3})+isin(frac{2pi}{3})=e^{ifrac {2pi}{3}}$



                            So $z^n = e^{ifrac {2npi} 3}$



                            Now $e^{i 2kpi} = 1$ for all integer $k$ and $e^{itheta} = 1$ only if $theta = 2kpi$ for some integer $k$.



                            So $z^n = e^{ifrac {2npi} 3} = 1 iff frac {2npi}3 = 2pi*k$ for some integer $k$.



                            So we need to find then smallest natural $n$ so and $frac {2npi}3 = 2pi *k$ for some integer value of $k$.



                            That's.... not a hard question.







                            share|cite|improve this answer












                            share|cite|improve this answer



                            share|cite|improve this answer










                            answered 2 days ago









                            fleablood

                            68.2k22684




                            68.2k22684















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