Proving equality of 3 sets












0












$begingroup$


$A, B, C$ are sets. I have to prove equality of this:



$$A cap C = B cap C land A cup C = B cup C ⇒ A = B$$



I did this, but I don't know what to do next and whether I even did the right thing:



$A cap C = x in A land x in C$



$B cap C ∧ A cup C = (x in B land x in C) land (x in A lor x in C)$



$B cup C implies A = x in B lor x in C ⇒ A $



$B$



Any ideas what to do next? Or maybe how to solve this somehow else?










share|cite|improve this question











$endgroup$












  • $begingroup$
    You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:12










  • $begingroup$
    I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:15
















0












$begingroup$


$A, B, C$ are sets. I have to prove equality of this:



$$A cap C = B cap C land A cup C = B cup C ⇒ A = B$$



I did this, but I don't know what to do next and whether I even did the right thing:



$A cap C = x in A land x in C$



$B cap C ∧ A cup C = (x in B land x in C) land (x in A lor x in C)$



$B cup C implies A = x in B lor x in C ⇒ A $



$B$



Any ideas what to do next? Or maybe how to solve this somehow else?










share|cite|improve this question











$endgroup$












  • $begingroup$
    You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:12










  • $begingroup$
    I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:15














0












0








0





$begingroup$


$A, B, C$ are sets. I have to prove equality of this:



$$A cap C = B cap C land A cup C = B cup C ⇒ A = B$$



I did this, but I don't know what to do next and whether I even did the right thing:



$A cap C = x in A land x in C$



$B cap C ∧ A cup C = (x in B land x in C) land (x in A lor x in C)$



$B cup C implies A = x in B lor x in C ⇒ A $



$B$



Any ideas what to do next? Or maybe how to solve this somehow else?










share|cite|improve this question











$endgroup$




$A, B, C$ are sets. I have to prove equality of this:



$$A cap C = B cap C land A cup C = B cup C ⇒ A = B$$



I did this, but I don't know what to do next and whether I even did the right thing:



$A cap C = x in A land x in C$



$B cap C ∧ A cup C = (x in B land x in C) land (x in A lor x in C)$



$B cup C implies A = x in B lor x in C ⇒ A $



$B$



Any ideas what to do next? Or maybe how to solve this somehow else?







elementary-set-theory proof-writing






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Dec 5 '18 at 21:14









platty

3,370320




3,370320










asked Dec 5 '18 at 21:09









qwerty1qwerty1

11




11












  • $begingroup$
    You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:12










  • $begingroup$
    I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:15


















  • $begingroup$
    You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:12










  • $begingroup$
    I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
    $endgroup$
    – JMoravitz
    Dec 5 '18 at 21:15
















$begingroup$
You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
$endgroup$
– JMoravitz
Dec 5 '18 at 21:12




$begingroup$
You are mixing logical statements and expressions in ways they should not be. Do try to be more consistent. For example your fourth line should read $xin Acap Ciff xin Awedge xin C$ or it should read $Acap C = {x~:~xin Awedge xin C}$.
$endgroup$
– JMoravitz
Dec 5 '18 at 21:12












$begingroup$
I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
$endgroup$
– JMoravitz
Dec 5 '18 at 21:15




$begingroup$
I recommend approaching via contrapositive. Suppose that $Aneq B$. Without loss of generality, then there is some $ain A$ such that $anotin B$. There are two possibilities to continue, either $anotin C$ or $ain C$. In the first case then can you see and explain why $Acup Cneq Bcup C$? In the second case can you see and explain why $Acap Cneq Bcap C$? Do you see why showing this proves what you want?
$endgroup$
– JMoravitz
Dec 5 '18 at 21:15










2 Answers
2






active

oldest

votes


















0












$begingroup$

Partition $A$ into the two sets $A'=Acap C$ and $A''=Abackslash (Acap C)$, and partition $B$ into the two sets $B'=Bcap C$ and $B''=Bbackslash (Bcap C)$. The first equality
$$Acap C=Bcap C$$
tells us that $A'=B'$. Since $(Acup C)backslash C=A''$ and $(Bcup C)backslash C=B''$, the second equality
$$Acup C=Bcup C$$
tells us that $A''=B''$. Thus, since the corresponding parts of the partitions of $A$ and $B$ are equal, $A=B$.



I leave it to you to make this more rigorous/formal as needed.






share|cite|improve this answer









$endgroup$





















    0












    $begingroup$

    Consider for any $x$ in the universal set you have four possibilities for whether $x$ is in $A$ or $C$.



    1) $x in A$ and $x in C$.



    2) $x in A$ and $x not in C$.



    3) $x not in A$ and $x in C$.



    4) $x not in A$ and $ xnot in C$



    For each of those cases we ask: Is $xin B$?



    If we discover that $x in B iff x in A$ the we determine that $A = B$.



    If we discover anything else or any ambiguous situation then we determine $A ne B$ or that $A$ need not equal $B$



    So



    1) $x in A$ and $x in C$.



    So $x in Acap C = Bcap C$ so $xin B$.



    2) $x in A$ and $x not in C$.



    So $xin Acup C= Bcup C$ so $x$ is in either $B$ or $C$. But $x not in C$ so $x in B$.



    3) $x not in A$ and $x in C$.



    So $x not in Acap C = Bcap C$. So $x$ is not in both $B$ and $C$. But $x in C$ so $x$ can't be in $B$.



    4) $x not in A$ and $ xnot in C$



    $xnot in Acup C = Bcup C$ so $x$ is in neither $B$ nor $C$. So $xnot in B$.



    So $xin B$ precisely when $x in A$ and $x not in B$ precisely what $x not in A$. So $A$ an $B$ have precisely the same elements and $A = B$.






    share|cite|improve this answer









    $endgroup$













      Your Answer





      StackExchange.ifUsing("editor", function () {
      return StackExchange.using("mathjaxEditing", function () {
      StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
      StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
      });
      });
      }, "mathjax-editing");

      StackExchange.ready(function() {
      var channelOptions = {
      tags: "".split(" "),
      id: "69"
      };
      initTagRenderer("".split(" "), "".split(" "), channelOptions);

      StackExchange.using("externalEditor", function() {
      // Have to fire editor after snippets, if snippets enabled
      if (StackExchange.settings.snippets.snippetsEnabled) {
      StackExchange.using("snippets", function() {
      createEditor();
      });
      }
      else {
      createEditor();
      }
      });

      function createEditor() {
      StackExchange.prepareEditor({
      heartbeatType: 'answer',
      autoActivateHeartbeat: false,
      convertImagesToLinks: true,
      noModals: true,
      showLowRepImageUploadWarning: true,
      reputationToPostImages: 10,
      bindNavPrevention: true,
      postfix: "",
      imageUploader: {
      brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
      contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
      allowUrls: true
      },
      noCode: true, onDemand: true,
      discardSelector: ".discard-answer"
      ,immediatelyShowMarkdownHelp:true
      });


      }
      });














      draft saved

      draft discarded


















      StackExchange.ready(
      function () {
      StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3027653%2fproving-equality-of-3-sets%23new-answer', 'question_page');
      }
      );

      Post as a guest















      Required, but never shown

























      2 Answers
      2






      active

      oldest

      votes








      2 Answers
      2






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes









      0












      $begingroup$

      Partition $A$ into the two sets $A'=Acap C$ and $A''=Abackslash (Acap C)$, and partition $B$ into the two sets $B'=Bcap C$ and $B''=Bbackslash (Bcap C)$. The first equality
      $$Acap C=Bcap C$$
      tells us that $A'=B'$. Since $(Acup C)backslash C=A''$ and $(Bcup C)backslash C=B''$, the second equality
      $$Acup C=Bcup C$$
      tells us that $A''=B''$. Thus, since the corresponding parts of the partitions of $A$ and $B$ are equal, $A=B$.



      I leave it to you to make this more rigorous/formal as needed.






      share|cite|improve this answer









      $endgroup$


















        0












        $begingroup$

        Partition $A$ into the two sets $A'=Acap C$ and $A''=Abackslash (Acap C)$, and partition $B$ into the two sets $B'=Bcap C$ and $B''=Bbackslash (Bcap C)$. The first equality
        $$Acap C=Bcap C$$
        tells us that $A'=B'$. Since $(Acup C)backslash C=A''$ and $(Bcup C)backslash C=B''$, the second equality
        $$Acup C=Bcup C$$
        tells us that $A''=B''$. Thus, since the corresponding parts of the partitions of $A$ and $B$ are equal, $A=B$.



        I leave it to you to make this more rigorous/formal as needed.






        share|cite|improve this answer









        $endgroup$
















          0












          0








          0





          $begingroup$

          Partition $A$ into the two sets $A'=Acap C$ and $A''=Abackslash (Acap C)$, and partition $B$ into the two sets $B'=Bcap C$ and $B''=Bbackslash (Bcap C)$. The first equality
          $$Acap C=Bcap C$$
          tells us that $A'=B'$. Since $(Acup C)backslash C=A''$ and $(Bcup C)backslash C=B''$, the second equality
          $$Acup C=Bcup C$$
          tells us that $A''=B''$. Thus, since the corresponding parts of the partitions of $A$ and $B$ are equal, $A=B$.



          I leave it to you to make this more rigorous/formal as needed.






          share|cite|improve this answer









          $endgroup$



          Partition $A$ into the two sets $A'=Acap C$ and $A''=Abackslash (Acap C)$, and partition $B$ into the two sets $B'=Bcap C$ and $B''=Bbackslash (Bcap C)$. The first equality
          $$Acap C=Bcap C$$
          tells us that $A'=B'$. Since $(Acup C)backslash C=A''$ and $(Bcup C)backslash C=B''$, the second equality
          $$Acup C=Bcup C$$
          tells us that $A''=B''$. Thus, since the corresponding parts of the partitions of $A$ and $B$ are equal, $A=B$.



          I leave it to you to make this more rigorous/formal as needed.







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered Dec 5 '18 at 21:14









          FrpzzdFrpzzd

          22.4k840108




          22.4k840108























              0












              $begingroup$

              Consider for any $x$ in the universal set you have four possibilities for whether $x$ is in $A$ or $C$.



              1) $x in A$ and $x in C$.



              2) $x in A$ and $x not in C$.



              3) $x not in A$ and $x in C$.



              4) $x not in A$ and $ xnot in C$



              For each of those cases we ask: Is $xin B$?



              If we discover that $x in B iff x in A$ the we determine that $A = B$.



              If we discover anything else or any ambiguous situation then we determine $A ne B$ or that $A$ need not equal $B$



              So



              1) $x in A$ and $x in C$.



              So $x in Acap C = Bcap C$ so $xin B$.



              2) $x in A$ and $x not in C$.



              So $xin Acup C= Bcup C$ so $x$ is in either $B$ or $C$. But $x not in C$ so $x in B$.



              3) $x not in A$ and $x in C$.



              So $x not in Acap C = Bcap C$. So $x$ is not in both $B$ and $C$. But $x in C$ so $x$ can't be in $B$.



              4) $x not in A$ and $ xnot in C$



              $xnot in Acup C = Bcup C$ so $x$ is in neither $B$ nor $C$. So $xnot in B$.



              So $xin B$ precisely when $x in A$ and $x not in B$ precisely what $x not in A$. So $A$ an $B$ have precisely the same elements and $A = B$.






              share|cite|improve this answer









              $endgroup$


















                0












                $begingroup$

                Consider for any $x$ in the universal set you have four possibilities for whether $x$ is in $A$ or $C$.



                1) $x in A$ and $x in C$.



                2) $x in A$ and $x not in C$.



                3) $x not in A$ and $x in C$.



                4) $x not in A$ and $ xnot in C$



                For each of those cases we ask: Is $xin B$?



                If we discover that $x in B iff x in A$ the we determine that $A = B$.



                If we discover anything else or any ambiguous situation then we determine $A ne B$ or that $A$ need not equal $B$



                So



                1) $x in A$ and $x in C$.



                So $x in Acap C = Bcap C$ so $xin B$.



                2) $x in A$ and $x not in C$.



                So $xin Acup C= Bcup C$ so $x$ is in either $B$ or $C$. But $x not in C$ so $x in B$.



                3) $x not in A$ and $x in C$.



                So $x not in Acap C = Bcap C$. So $x$ is not in both $B$ and $C$. But $x in C$ so $x$ can't be in $B$.



                4) $x not in A$ and $ xnot in C$



                $xnot in Acup C = Bcup C$ so $x$ is in neither $B$ nor $C$. So $xnot in B$.



                So $xin B$ precisely when $x in A$ and $x not in B$ precisely what $x not in A$. So $A$ an $B$ have precisely the same elements and $A = B$.






                share|cite|improve this answer









                $endgroup$
















                  0












                  0








                  0





                  $begingroup$

                  Consider for any $x$ in the universal set you have four possibilities for whether $x$ is in $A$ or $C$.



                  1) $x in A$ and $x in C$.



                  2) $x in A$ and $x not in C$.



                  3) $x not in A$ and $x in C$.



                  4) $x not in A$ and $ xnot in C$



                  For each of those cases we ask: Is $xin B$?



                  If we discover that $x in B iff x in A$ the we determine that $A = B$.



                  If we discover anything else or any ambiguous situation then we determine $A ne B$ or that $A$ need not equal $B$



                  So



                  1) $x in A$ and $x in C$.



                  So $x in Acap C = Bcap C$ so $xin B$.



                  2) $x in A$ and $x not in C$.



                  So $xin Acup C= Bcup C$ so $x$ is in either $B$ or $C$. But $x not in C$ so $x in B$.



                  3) $x not in A$ and $x in C$.



                  So $x not in Acap C = Bcap C$. So $x$ is not in both $B$ and $C$. But $x in C$ so $x$ can't be in $B$.



                  4) $x not in A$ and $ xnot in C$



                  $xnot in Acup C = Bcup C$ so $x$ is in neither $B$ nor $C$. So $xnot in B$.



                  So $xin B$ precisely when $x in A$ and $x not in B$ precisely what $x not in A$. So $A$ an $B$ have precisely the same elements and $A = B$.






                  share|cite|improve this answer









                  $endgroup$



                  Consider for any $x$ in the universal set you have four possibilities for whether $x$ is in $A$ or $C$.



                  1) $x in A$ and $x in C$.



                  2) $x in A$ and $x not in C$.



                  3) $x not in A$ and $x in C$.



                  4) $x not in A$ and $ xnot in C$



                  For each of those cases we ask: Is $xin B$?



                  If we discover that $x in B iff x in A$ the we determine that $A = B$.



                  If we discover anything else or any ambiguous situation then we determine $A ne B$ or that $A$ need not equal $B$



                  So



                  1) $x in A$ and $x in C$.



                  So $x in Acap C = Bcap C$ so $xin B$.



                  2) $x in A$ and $x not in C$.



                  So $xin Acup C= Bcup C$ so $x$ is in either $B$ or $C$. But $x not in C$ so $x in B$.



                  3) $x not in A$ and $x in C$.



                  So $x not in Acap C = Bcap C$. So $x$ is not in both $B$ and $C$. But $x in C$ so $x$ can't be in $B$.



                  4) $x not in A$ and $ xnot in C$



                  $xnot in Acup C = Bcup C$ so $x$ is in neither $B$ nor $C$. So $xnot in B$.



                  So $xin B$ precisely when $x in A$ and $x not in B$ precisely what $x not in A$. So $A$ an $B$ have precisely the same elements and $A = B$.







                  share|cite|improve this answer












                  share|cite|improve this answer



                  share|cite|improve this answer










                  answered Dec 5 '18 at 21:47









                  fleabloodfleablood

                  68.8k22685




                  68.8k22685






























                      draft saved

                      draft discarded




















































                      Thanks for contributing an answer to Mathematics Stack Exchange!


                      • Please be sure to answer the question. Provide details and share your research!

                      But avoid



                      • Asking for help, clarification, or responding to other answers.

                      • Making statements based on opinion; back them up with references or personal experience.


                      Use MathJax to format equations. MathJax reference.


                      To learn more, see our tips on writing great answers.




                      draft saved


                      draft discarded














                      StackExchange.ready(
                      function () {
                      StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3027653%2fproving-equality-of-3-sets%23new-answer', 'question_page');
                      }
                      );

                      Post as a guest















                      Required, but never shown





















































                      Required, but never shown














                      Required, but never shown












                      Required, but never shown







                      Required, but never shown

































                      Required, but never shown














                      Required, but never shown












                      Required, but never shown







                      Required, but never shown







                      Popular posts from this blog

                      Wiesbaden

                      Marschland

                      Dieringhausen