Gallian's Exercise 4.76: a 2008 GRE practice exam question: “exactly two of $x^3$, $x^5$, and $x^9$ are...












1












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This question appears to be new here according to this and this.



I'm reading "Contemporary Abstract Algebra," by Gallian.



This is Exercise 4.76 ibid. and it's stated to be a problem from a 2008 GRE practice exam.



I would like to prove this result using the tools given in the textbook prior to this exercise. (A free copy of the book is available online.)



The Question:




If $x$ is an element of a cyclic group of order $15$ and exactly two of $x^3$, $x^5$, and $x^9$ are equal, determine $lvert x^{13}rvert$.




My Attempt:



My first concern is whether it's the order of the group, let's call it $G$, or of the element, called $x$, that is $15$. Nonetheless, here are some thoughts, since $x^{15}=e$ either way:




  • If $x^3=x^5$, then $x^2=e$, but then either $x=e$ or $lvert xrvert=2$; in the former case, $lvert x^{13}rvert=lvert ervert=0$, but in the latter, $$begin{align}0&=lvert x^{15}rvert\ &=lvert (x^2)^7xrvert \ &=lvert xrvert\ &=2;end{align}$$ thus $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)


  • If $x^3=x^9$, then $x^6=e$, so $e=x^{15}=(x^6)^2x^3=x^3$, which means $x=e$ or $lvert xrvert=3$; thus $lvert x^{13}rvert=0$ as before or $$boxed{begin{align}lvert x^{13}rvert &=lvert (x^3)^4xrvert \ &=lvert xrvert\ &=3.end{align}}$$ (EDIT: But $xneq e$.)


  • If $x^5=x^9$, then $x^4=e$, but now $e=x^{15}=(x^4)^3x^3=x^3$, so that $x^3=x^4$ implies $x=e$; hence $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)



[EDIT 2: The boxed bit is the only answer.]




Is this correct? What would be a better way of determining $lvert x^{13}rvert$?




Please help :)










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
    $endgroup$
    – hardmath
    Jan 20 at 18:36






  • 2




    $begingroup$
    I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
    $endgroup$
    – Shaun
    Jan 20 at 18:37
















1












$begingroup$


This question appears to be new here according to this and this.



I'm reading "Contemporary Abstract Algebra," by Gallian.



This is Exercise 4.76 ibid. and it's stated to be a problem from a 2008 GRE practice exam.



I would like to prove this result using the tools given in the textbook prior to this exercise. (A free copy of the book is available online.)



The Question:




If $x$ is an element of a cyclic group of order $15$ and exactly two of $x^3$, $x^5$, and $x^9$ are equal, determine $lvert x^{13}rvert$.




My Attempt:



My first concern is whether it's the order of the group, let's call it $G$, or of the element, called $x$, that is $15$. Nonetheless, here are some thoughts, since $x^{15}=e$ either way:




  • If $x^3=x^5$, then $x^2=e$, but then either $x=e$ or $lvert xrvert=2$; in the former case, $lvert x^{13}rvert=lvert ervert=0$, but in the latter, $$begin{align}0&=lvert x^{15}rvert\ &=lvert (x^2)^7xrvert \ &=lvert xrvert\ &=2;end{align}$$ thus $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)


  • If $x^3=x^9$, then $x^6=e$, so $e=x^{15}=(x^6)^2x^3=x^3$, which means $x=e$ or $lvert xrvert=3$; thus $lvert x^{13}rvert=0$ as before or $$boxed{begin{align}lvert x^{13}rvert &=lvert (x^3)^4xrvert \ &=lvert xrvert\ &=3.end{align}}$$ (EDIT: But $xneq e$.)


  • If $x^5=x^9$, then $x^4=e$, but now $e=x^{15}=(x^4)^3x^3=x^3$, so that $x^3=x^4$ implies $x=e$; hence $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)



[EDIT 2: The boxed bit is the only answer.]




Is this correct? What would be a better way of determining $lvert x^{13}rvert$?




Please help :)










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
    $endgroup$
    – hardmath
    Jan 20 at 18:36






  • 2




    $begingroup$
    I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
    $endgroup$
    – Shaun
    Jan 20 at 18:37














1












1








1


0



$begingroup$


This question appears to be new here according to this and this.



I'm reading "Contemporary Abstract Algebra," by Gallian.



This is Exercise 4.76 ibid. and it's stated to be a problem from a 2008 GRE practice exam.



I would like to prove this result using the tools given in the textbook prior to this exercise. (A free copy of the book is available online.)



The Question:




If $x$ is an element of a cyclic group of order $15$ and exactly two of $x^3$, $x^5$, and $x^9$ are equal, determine $lvert x^{13}rvert$.




My Attempt:



My first concern is whether it's the order of the group, let's call it $G$, or of the element, called $x$, that is $15$. Nonetheless, here are some thoughts, since $x^{15}=e$ either way:




  • If $x^3=x^5$, then $x^2=e$, but then either $x=e$ or $lvert xrvert=2$; in the former case, $lvert x^{13}rvert=lvert ervert=0$, but in the latter, $$begin{align}0&=lvert x^{15}rvert\ &=lvert (x^2)^7xrvert \ &=lvert xrvert\ &=2;end{align}$$ thus $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)


  • If $x^3=x^9$, then $x^6=e$, so $e=x^{15}=(x^6)^2x^3=x^3$, which means $x=e$ or $lvert xrvert=3$; thus $lvert x^{13}rvert=0$ as before or $$boxed{begin{align}lvert x^{13}rvert &=lvert (x^3)^4xrvert \ &=lvert xrvert\ &=3.end{align}}$$ (EDIT: But $xneq e$.)


  • If $x^5=x^9$, then $x^4=e$, but now $e=x^{15}=(x^4)^3x^3=x^3$, so that $x^3=x^4$ implies $x=e$; hence $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)



[EDIT 2: The boxed bit is the only answer.]




Is this correct? What would be a better way of determining $lvert x^{13}rvert$?




Please help :)










share|cite|improve this question











$endgroup$




This question appears to be new here according to this and this.



I'm reading "Contemporary Abstract Algebra," by Gallian.



This is Exercise 4.76 ibid. and it's stated to be a problem from a 2008 GRE practice exam.



I would like to prove this result using the tools given in the textbook prior to this exercise. (A free copy of the book is available online.)



The Question:




If $x$ is an element of a cyclic group of order $15$ and exactly two of $x^3$, $x^5$, and $x^9$ are equal, determine $lvert x^{13}rvert$.




My Attempt:



My first concern is whether it's the order of the group, let's call it $G$, or of the element, called $x$, that is $15$. Nonetheless, here are some thoughts, since $x^{15}=e$ either way:




  • If $x^3=x^5$, then $x^2=e$, but then either $x=e$ or $lvert xrvert=2$; in the former case, $lvert x^{13}rvert=lvert ervert=0$, but in the latter, $$begin{align}0&=lvert x^{15}rvert\ &=lvert (x^2)^7xrvert \ &=lvert xrvert\ &=2;end{align}$$ thus $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)


  • If $x^3=x^9$, then $x^6=e$, so $e=x^{15}=(x^6)^2x^3=x^3$, which means $x=e$ or $lvert xrvert=3$; thus $lvert x^{13}rvert=0$ as before or $$boxed{begin{align}lvert x^{13}rvert &=lvert (x^3)^4xrvert \ &=lvert xrvert\ &=3.end{align}}$$ (EDIT: But $xneq e$.)


  • If $x^5=x^9$, then $x^4=e$, but now $e=x^{15}=(x^4)^3x^3=x^3$, so that $x^3=x^4$ implies $x=e$; hence $lvert x^{13}rvert=0$. (EDIT: But $xneq e$.)



[EDIT 2: The boxed bit is the only answer.]




Is this correct? What would be a better way of determining $lvert x^{13}rvert$?




Please help :)







group-theory proof-verification cyclic-groups






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Jan 20 at 22:11







Shaun

















asked Jan 20 at 18:33









ShaunShaun

9,268113684




9,268113684








  • 1




    $begingroup$
    We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
    $endgroup$
    – hardmath
    Jan 20 at 18:36






  • 2




    $begingroup$
    I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
    $endgroup$
    – Shaun
    Jan 20 at 18:37














  • 1




    $begingroup$
    We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
    $endgroup$
    – hardmath
    Jan 20 at 18:36






  • 2




    $begingroup$
    I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
    $endgroup$
    – Shaun
    Jan 20 at 18:37








1




1




$begingroup$
We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
$endgroup$
– hardmath
Jan 20 at 18:36




$begingroup$
We should interpret that the order of the group is $15$. The properties asserted for $x$ rule out that it could have order $15$. Of course $x$ will generate a subgroup of the same order as $x$.
$endgroup$
– hardmath
Jan 20 at 18:36




2




2




$begingroup$
I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
$endgroup$
– Shaun
Jan 20 at 18:37




$begingroup$
I've just noticed that the "exactly two" specification of the powers eliminates the $x=e$ cases.
$endgroup$
– Shaun
Jan 20 at 18:37










1 Answer
1






active

oldest

votes


















4












$begingroup$

Since $x^3,,x^5,,x^9$ aren't all equal, $|x|$ is positive and not $2$. Instead, it divides $4$ or $6$ (and thus $12$) and also $15$ but not $2$, so $x^{13}=ximplies|x^{13}|=|x|=3$.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
    $endgroup$
    – Shaun
    Jan 20 at 21:26






  • 1




    $begingroup$
    @Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
    $endgroup$
    – J.G.
    Jan 20 at 21:29






  • 1




    $begingroup$
    Thank you. That's very clear now :)
    $endgroup$
    – Shaun
    Jan 20 at 21:31











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1 Answer
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1 Answer
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active

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4












$begingroup$

Since $x^3,,x^5,,x^9$ aren't all equal, $|x|$ is positive and not $2$. Instead, it divides $4$ or $6$ (and thus $12$) and also $15$ but not $2$, so $x^{13}=ximplies|x^{13}|=|x|=3$.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
    $endgroup$
    – Shaun
    Jan 20 at 21:26






  • 1




    $begingroup$
    @Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
    $endgroup$
    – J.G.
    Jan 20 at 21:29






  • 1




    $begingroup$
    Thank you. That's very clear now :)
    $endgroup$
    – Shaun
    Jan 20 at 21:31
















4












$begingroup$

Since $x^3,,x^5,,x^9$ aren't all equal, $|x|$ is positive and not $2$. Instead, it divides $4$ or $6$ (and thus $12$) and also $15$ but not $2$, so $x^{13}=ximplies|x^{13}|=|x|=3$.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
    $endgroup$
    – Shaun
    Jan 20 at 21:26






  • 1




    $begingroup$
    @Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
    $endgroup$
    – J.G.
    Jan 20 at 21:29






  • 1




    $begingroup$
    Thank you. That's very clear now :)
    $endgroup$
    – Shaun
    Jan 20 at 21:31














4












4








4





$begingroup$

Since $x^3,,x^5,,x^9$ aren't all equal, $|x|$ is positive and not $2$. Instead, it divides $4$ or $6$ (and thus $12$) and also $15$ but not $2$, so $x^{13}=ximplies|x^{13}|=|x|=3$.






share|cite|improve this answer











$endgroup$



Since $x^3,,x^5,,x^9$ aren't all equal, $|x|$ is positive and not $2$. Instead, it divides $4$ or $6$ (and thus $12$) and also $15$ but not $2$, so $x^{13}=ximplies|x^{13}|=|x|=3$.







share|cite|improve this answer














share|cite|improve this answer



share|cite|improve this answer








edited Jan 20 at 21:13









Shaun

9,268113684




9,268113684










answered Jan 20 at 19:12









J.G.J.G.

27.5k22843




27.5k22843












  • $begingroup$
    This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
    $endgroup$
    – Shaun
    Jan 20 at 21:26






  • 1




    $begingroup$
    @Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
    $endgroup$
    – J.G.
    Jan 20 at 21:29






  • 1




    $begingroup$
    Thank you. That's very clear now :)
    $endgroup$
    – Shaun
    Jan 20 at 21:31


















  • $begingroup$
    This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
    $endgroup$
    – Shaun
    Jan 20 at 21:26






  • 1




    $begingroup$
    @Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
    $endgroup$
    – J.G.
    Jan 20 at 21:29






  • 1




    $begingroup$
    Thank you. That's very clear now :)
    $endgroup$
    – Shaun
    Jan 20 at 21:31
















$begingroup$
This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
$endgroup$
– Shaun
Jan 20 at 21:26




$begingroup$
This seems very slick. Thank you. How did you get $lvert xrvert=3$ though?
$endgroup$
– Shaun
Jan 20 at 21:26




1




1




$begingroup$
@Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
$endgroup$
– J.G.
Jan 20 at 21:29




$begingroup$
@Shaun $|x|le 2$ contradicts the setup, and $3$ if the only other common factor of $12$ and $15$.
$endgroup$
– J.G.
Jan 20 at 21:29




1




1




$begingroup$
Thank you. That's very clear now :)
$endgroup$
– Shaun
Jan 20 at 21:31




$begingroup$
Thank you. That's very clear now :)
$endgroup$
– Shaun
Jan 20 at 21:31


















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