Prove the perpendicular bisector of chord passes through the centre of the circle












0












$begingroup$


enter image description here



Hello, can someone please give me a simple proof to the following theorem:



"The perpendicular bisector a chord passes through the centre of the circle."



I have attached a diagram of what I mean and web link of a proof that I did not understand below.



https://proofwiki.org/wiki/Perpendicular_Bisector_of_Chord_Passes_Through_Center



Please explain simply and fully because I have an exam on this tomorrow. Also, could you explain the converse theorem whereby a bisector passes through the centre of the circle, prove it's perpendicular and a perpendicular line passes through the centre, prove it bisects the chord.










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$endgroup$












  • $begingroup$
    What step do you not understand of the proof you linked to?
    $endgroup$
    – irh
    May 24 '17 at 20:00










  • $begingroup$
    the closing statment at the end
    $endgroup$
    – Inquirer
    May 24 '17 at 20:02








  • 1




    $begingroup$
    The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
    $endgroup$
    – Doug M
    May 24 '17 at 20:04












  • $begingroup$
    Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
    $endgroup$
    – irh
    May 24 '17 at 20:07










  • $begingroup$
    Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
    $endgroup$
    – Doug M
    May 24 '17 at 20:12


















0












$begingroup$


enter image description here



Hello, can someone please give me a simple proof to the following theorem:



"The perpendicular bisector a chord passes through the centre of the circle."



I have attached a diagram of what I mean and web link of a proof that I did not understand below.



https://proofwiki.org/wiki/Perpendicular_Bisector_of_Chord_Passes_Through_Center



Please explain simply and fully because I have an exam on this tomorrow. Also, could you explain the converse theorem whereby a bisector passes through the centre of the circle, prove it's perpendicular and a perpendicular line passes through the centre, prove it bisects the chord.










share|cite|improve this question











$endgroup$












  • $begingroup$
    What step do you not understand of the proof you linked to?
    $endgroup$
    – irh
    May 24 '17 at 20:00










  • $begingroup$
    the closing statment at the end
    $endgroup$
    – Inquirer
    May 24 '17 at 20:02








  • 1




    $begingroup$
    The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
    $endgroup$
    – Doug M
    May 24 '17 at 20:04












  • $begingroup$
    Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
    $endgroup$
    – irh
    May 24 '17 at 20:07










  • $begingroup$
    Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
    $endgroup$
    – Doug M
    May 24 '17 at 20:12
















0












0








0





$begingroup$


enter image description here



Hello, can someone please give me a simple proof to the following theorem:



"The perpendicular bisector a chord passes through the centre of the circle."



I have attached a diagram of what I mean and web link of a proof that I did not understand below.



https://proofwiki.org/wiki/Perpendicular_Bisector_of_Chord_Passes_Through_Center



Please explain simply and fully because I have an exam on this tomorrow. Also, could you explain the converse theorem whereby a bisector passes through the centre of the circle, prove it's perpendicular and a perpendicular line passes through the centre, prove it bisects the chord.










share|cite|improve this question











$endgroup$




enter image description here



Hello, can someone please give me a simple proof to the following theorem:



"The perpendicular bisector a chord passes through the centre of the circle."



I have attached a diagram of what I mean and web link of a proof that I did not understand below.



https://proofwiki.org/wiki/Perpendicular_Bisector_of_Chord_Passes_Through_Center



Please explain simply and fully because I have an exam on this tomorrow. Also, could you explain the converse theorem whereby a bisector passes through the centre of the circle, prove it's perpendicular and a perpendicular line passes through the centre, prove it bisects the chord.







geometry






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share|cite|improve this question













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edited May 24 '17 at 20:39









JonMark Perry

11.3k92238




11.3k92238










asked May 24 '17 at 19:52









InquirerInquirer

4251310




4251310












  • $begingroup$
    What step do you not understand of the proof you linked to?
    $endgroup$
    – irh
    May 24 '17 at 20:00










  • $begingroup$
    the closing statment at the end
    $endgroup$
    – Inquirer
    May 24 '17 at 20:02








  • 1




    $begingroup$
    The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
    $endgroup$
    – Doug M
    May 24 '17 at 20:04












  • $begingroup$
    Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
    $endgroup$
    – irh
    May 24 '17 at 20:07










  • $begingroup$
    Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
    $endgroup$
    – Doug M
    May 24 '17 at 20:12




















  • $begingroup$
    What step do you not understand of the proof you linked to?
    $endgroup$
    – irh
    May 24 '17 at 20:00










  • $begingroup$
    the closing statment at the end
    $endgroup$
    – Inquirer
    May 24 '17 at 20:02








  • 1




    $begingroup$
    The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
    $endgroup$
    – Doug M
    May 24 '17 at 20:04












  • $begingroup$
    Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
    $endgroup$
    – irh
    May 24 '17 at 20:07










  • $begingroup$
    Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
    $endgroup$
    – Doug M
    May 24 '17 at 20:12


















$begingroup$
What step do you not understand of the proof you linked to?
$endgroup$
– irh
May 24 '17 at 20:00




$begingroup$
What step do you not understand of the proof you linked to?
$endgroup$
– irh
May 24 '17 at 20:00












$begingroup$
the closing statment at the end
$endgroup$
– Inquirer
May 24 '17 at 20:02






$begingroup$
the closing statment at the end
$endgroup$
– Inquirer
May 24 '17 at 20:02






1




1




$begingroup$
The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
$endgroup$
– Doug M
May 24 '17 at 20:04






$begingroup$
The proof under link "enter image description here" is a false proof, because the concluding statement is not true.
$endgroup$
– Doug M
May 24 '17 at 20:04














$begingroup$
Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
$endgroup$
– irh
May 24 '17 at 20:07




$begingroup$
Since the triangles are right triangles, then $DF$ perpendicular to $AB$. Since $D$ by definition is the middle of $AB$, then $DF$ is a perpendicular bisector.
$endgroup$
– irh
May 24 '17 at 20:07












$begingroup$
Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
$endgroup$
– Doug M
May 24 '17 at 20:12






$begingroup$
Prove that the line from the center of the circle to the midpoint of the chord is the perpendicular bisector. And since the perpendicular bisector of any segment is unique the center lies on the perpendicular bisector of the chord.
$endgroup$
– Doug M
May 24 '17 at 20:12












5 Answers
5






active

oldest

votes


















0












$begingroup$

Consider the same figure to which you have linked.



In the figure, draw a line perpendicular to AB at the point B. Say, this intersects the circle at the point E. Let D be the mid point of AB. Join CD. We prove first that $triangle$ ACD and $triangle$ AEB are similar.
AC = CE = r (radius of the circle)
AD = DB (since D is the mid point of AB)
So we have,
$$ frac {AC}{AD} = frac{AE}{AB} = 2$$ $$angle CAD = angle EAB space (Common)$$
With these conditions, it is clear that these two triangles are similar. So, their corresponding angles are congruent. Specifically, $$ angle ADC = angle ABE = 90^0 space (by space construction)$$
This proves that the line CD is the perpendicular bisector, C being the center of the circle.






share|cite|improve this answer









$endgroup$





















    0












    $begingroup$

    The perpendicular bisector of a segment $[AB]$ is the locus of points $M$ equidistant from $A$ and $B$.



    This means $MA=MB$.



    But if we set $MA=R$ then this means $A,B$ are on the circle of centre $M$ and radius $R$.



    And since the chord in this case is precisely $[AB]$ and $M$ belongs to the perpendicular bisector, you have your result.





    If we define the perpendicular bisector by the line $perp[AB]$ and passing by $I=frac{A+B}2$ the middle of $[AB]$.



    Then for any point $M$ on the bissector, we can apply pythagoras' theorem.



    $begin{cases}
    MA^2=MI^2+AI^2\
    MB^2=MI^2+BI^2
    end{cases}$ but since $AI=BI$, because $I$ middle of $[AB]$ then $MA=MB$.



    And we can conclude like previously.






    share|cite|improve this answer









    $endgroup$





















      0












      $begingroup$

      Start with a diameter.



      Construct the two tangent lines to the circle at the endpoints of the diameter.



      Drop the diameter along the tangent lines until it matches with the chord.



      By symmetry, the line between the midpoint of the chord to the origin of the circle is perpendicular to the chord.






      share|cite|improve this answer









      $endgroup$





















        0












        $begingroup$

        For first part of question the position of $C$ is at first chosen arbitrarily in the plane. After $SAS$ is satisfied with givens, The triangles $ MAC, MBC $ are congruent, $C$ must lie on the bisector. No matter where the point $C$ is chosen on the perpendicular bisector, the circle through $A,B$ has to have its center somewhere on $MC$ line, it is sufficient for a proof.



        enter image description here






        share|cite|improve this answer









        $endgroup$





















          0












          $begingroup$

          The proof in the picture is the simplest possible one. All you have to do is write the conditions for congruence thus proving that the triangles in the above picture are congruent. This is the best possible approach to the given question.






          share|cite|improve this answer











          $endgroup$













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            5 Answers
            5






            active

            oldest

            votes








            5 Answers
            5






            active

            oldest

            votes









            active

            oldest

            votes






            active

            oldest

            votes









            0












            $begingroup$

            Consider the same figure to which you have linked.



            In the figure, draw a line perpendicular to AB at the point B. Say, this intersects the circle at the point E. Let D be the mid point of AB. Join CD. We prove first that $triangle$ ACD and $triangle$ AEB are similar.
            AC = CE = r (radius of the circle)
            AD = DB (since D is the mid point of AB)
            So we have,
            $$ frac {AC}{AD} = frac{AE}{AB} = 2$$ $$angle CAD = angle EAB space (Common)$$
            With these conditions, it is clear that these two triangles are similar. So, their corresponding angles are congruent. Specifically, $$ angle ADC = angle ABE = 90^0 space (by space construction)$$
            This proves that the line CD is the perpendicular bisector, C being the center of the circle.






            share|cite|improve this answer









            $endgroup$


















              0












              $begingroup$

              Consider the same figure to which you have linked.



              In the figure, draw a line perpendicular to AB at the point B. Say, this intersects the circle at the point E. Let D be the mid point of AB. Join CD. We prove first that $triangle$ ACD and $triangle$ AEB are similar.
              AC = CE = r (radius of the circle)
              AD = DB (since D is the mid point of AB)
              So we have,
              $$ frac {AC}{AD} = frac{AE}{AB} = 2$$ $$angle CAD = angle EAB space (Common)$$
              With these conditions, it is clear that these two triangles are similar. So, their corresponding angles are congruent. Specifically, $$ angle ADC = angle ABE = 90^0 space (by space construction)$$
              This proves that the line CD is the perpendicular bisector, C being the center of the circle.






              share|cite|improve this answer









              $endgroup$
















                0












                0








                0





                $begingroup$

                Consider the same figure to which you have linked.



                In the figure, draw a line perpendicular to AB at the point B. Say, this intersects the circle at the point E. Let D be the mid point of AB. Join CD. We prove first that $triangle$ ACD and $triangle$ AEB are similar.
                AC = CE = r (radius of the circle)
                AD = DB (since D is the mid point of AB)
                So we have,
                $$ frac {AC}{AD} = frac{AE}{AB} = 2$$ $$angle CAD = angle EAB space (Common)$$
                With these conditions, it is clear that these two triangles are similar. So, their corresponding angles are congruent. Specifically, $$ angle ADC = angle ABE = 90^0 space (by space construction)$$
                This proves that the line CD is the perpendicular bisector, C being the center of the circle.






                share|cite|improve this answer









                $endgroup$



                Consider the same figure to which you have linked.



                In the figure, draw a line perpendicular to AB at the point B. Say, this intersects the circle at the point E. Let D be the mid point of AB. Join CD. We prove first that $triangle$ ACD and $triangle$ AEB are similar.
                AC = CE = r (radius of the circle)
                AD = DB (since D is the mid point of AB)
                So we have,
                $$ frac {AC}{AD} = frac{AE}{AB} = 2$$ $$angle CAD = angle EAB space (Common)$$
                With these conditions, it is clear that these two triangles are similar. So, their corresponding angles are congruent. Specifically, $$ angle ADC = angle ABE = 90^0 space (by space construction)$$
                This proves that the line CD is the perpendicular bisector, C being the center of the circle.







                share|cite|improve this answer












                share|cite|improve this answer



                share|cite|improve this answer










                answered May 24 '17 at 20:28









                HikaruHikaru

                698615




                698615























                    0












                    $begingroup$

                    The perpendicular bisector of a segment $[AB]$ is the locus of points $M$ equidistant from $A$ and $B$.



                    This means $MA=MB$.



                    But if we set $MA=R$ then this means $A,B$ are on the circle of centre $M$ and radius $R$.



                    And since the chord in this case is precisely $[AB]$ and $M$ belongs to the perpendicular bisector, you have your result.





                    If we define the perpendicular bisector by the line $perp[AB]$ and passing by $I=frac{A+B}2$ the middle of $[AB]$.



                    Then for any point $M$ on the bissector, we can apply pythagoras' theorem.



                    $begin{cases}
                    MA^2=MI^2+AI^2\
                    MB^2=MI^2+BI^2
                    end{cases}$ but since $AI=BI$, because $I$ middle of $[AB]$ then $MA=MB$.



                    And we can conclude like previously.






                    share|cite|improve this answer









                    $endgroup$


















                      0












                      $begingroup$

                      The perpendicular bisector of a segment $[AB]$ is the locus of points $M$ equidistant from $A$ and $B$.



                      This means $MA=MB$.



                      But if we set $MA=R$ then this means $A,B$ are on the circle of centre $M$ and radius $R$.



                      And since the chord in this case is precisely $[AB]$ and $M$ belongs to the perpendicular bisector, you have your result.





                      If we define the perpendicular bisector by the line $perp[AB]$ and passing by $I=frac{A+B}2$ the middle of $[AB]$.



                      Then for any point $M$ on the bissector, we can apply pythagoras' theorem.



                      $begin{cases}
                      MA^2=MI^2+AI^2\
                      MB^2=MI^2+BI^2
                      end{cases}$ but since $AI=BI$, because $I$ middle of $[AB]$ then $MA=MB$.



                      And we can conclude like previously.






                      share|cite|improve this answer









                      $endgroup$
















                        0












                        0








                        0





                        $begingroup$

                        The perpendicular bisector of a segment $[AB]$ is the locus of points $M$ equidistant from $A$ and $B$.



                        This means $MA=MB$.



                        But if we set $MA=R$ then this means $A,B$ are on the circle of centre $M$ and radius $R$.



                        And since the chord in this case is precisely $[AB]$ and $M$ belongs to the perpendicular bisector, you have your result.





                        If we define the perpendicular bisector by the line $perp[AB]$ and passing by $I=frac{A+B}2$ the middle of $[AB]$.



                        Then for any point $M$ on the bissector, we can apply pythagoras' theorem.



                        $begin{cases}
                        MA^2=MI^2+AI^2\
                        MB^2=MI^2+BI^2
                        end{cases}$ but since $AI=BI$, because $I$ middle of $[AB]$ then $MA=MB$.



                        And we can conclude like previously.






                        share|cite|improve this answer









                        $endgroup$



                        The perpendicular bisector of a segment $[AB]$ is the locus of points $M$ equidistant from $A$ and $B$.



                        This means $MA=MB$.



                        But if we set $MA=R$ then this means $A,B$ are on the circle of centre $M$ and radius $R$.



                        And since the chord in this case is precisely $[AB]$ and $M$ belongs to the perpendicular bisector, you have your result.





                        If we define the perpendicular bisector by the line $perp[AB]$ and passing by $I=frac{A+B}2$ the middle of $[AB]$.



                        Then for any point $M$ on the bissector, we can apply pythagoras' theorem.



                        $begin{cases}
                        MA^2=MI^2+AI^2\
                        MB^2=MI^2+BI^2
                        end{cases}$ but since $AI=BI$, because $I$ middle of $[AB]$ then $MA=MB$.



                        And we can conclude like previously.







                        share|cite|improve this answer












                        share|cite|improve this answer



                        share|cite|improve this answer










                        answered May 24 '17 at 20:36









                        zwimzwim

                        11.7k729




                        11.7k729























                            0












                            $begingroup$

                            Start with a diameter.



                            Construct the two tangent lines to the circle at the endpoints of the diameter.



                            Drop the diameter along the tangent lines until it matches with the chord.



                            By symmetry, the line between the midpoint of the chord to the origin of the circle is perpendicular to the chord.






                            share|cite|improve this answer









                            $endgroup$


















                              0












                              $begingroup$

                              Start with a diameter.



                              Construct the two tangent lines to the circle at the endpoints of the diameter.



                              Drop the diameter along the tangent lines until it matches with the chord.



                              By symmetry, the line between the midpoint of the chord to the origin of the circle is perpendicular to the chord.






                              share|cite|improve this answer









                              $endgroup$
















                                0












                                0








                                0





                                $begingroup$

                                Start with a diameter.



                                Construct the two tangent lines to the circle at the endpoints of the diameter.



                                Drop the diameter along the tangent lines until it matches with the chord.



                                By symmetry, the line between the midpoint of the chord to the origin of the circle is perpendicular to the chord.






                                share|cite|improve this answer









                                $endgroup$



                                Start with a diameter.



                                Construct the two tangent lines to the circle at the endpoints of the diameter.



                                Drop the diameter along the tangent lines until it matches with the chord.



                                By symmetry, the line between the midpoint of the chord to the origin of the circle is perpendicular to the chord.







                                share|cite|improve this answer












                                share|cite|improve this answer



                                share|cite|improve this answer










                                answered May 24 '17 at 23:52









                                JonMark PerryJonMark Perry

                                11.3k92238




                                11.3k92238























                                    0












                                    $begingroup$

                                    For first part of question the position of $C$ is at first chosen arbitrarily in the plane. After $SAS$ is satisfied with givens, The triangles $ MAC, MBC $ are congruent, $C$ must lie on the bisector. No matter where the point $C$ is chosen on the perpendicular bisector, the circle through $A,B$ has to have its center somewhere on $MC$ line, it is sufficient for a proof.



                                    enter image description here






                                    share|cite|improve this answer









                                    $endgroup$


















                                      0












                                      $begingroup$

                                      For first part of question the position of $C$ is at first chosen arbitrarily in the plane. After $SAS$ is satisfied with givens, The triangles $ MAC, MBC $ are congruent, $C$ must lie on the bisector. No matter where the point $C$ is chosen on the perpendicular bisector, the circle through $A,B$ has to have its center somewhere on $MC$ line, it is sufficient for a proof.



                                      enter image description here






                                      share|cite|improve this answer









                                      $endgroup$
















                                        0












                                        0








                                        0





                                        $begingroup$

                                        For first part of question the position of $C$ is at first chosen arbitrarily in the plane. After $SAS$ is satisfied with givens, The triangles $ MAC, MBC $ are congruent, $C$ must lie on the bisector. No matter where the point $C$ is chosen on the perpendicular bisector, the circle through $A,B$ has to have its center somewhere on $MC$ line, it is sufficient for a proof.



                                        enter image description here






                                        share|cite|improve this answer









                                        $endgroup$



                                        For first part of question the position of $C$ is at first chosen arbitrarily in the plane. After $SAS$ is satisfied with givens, The triangles $ MAC, MBC $ are congruent, $C$ must lie on the bisector. No matter where the point $C$ is chosen on the perpendicular bisector, the circle through $A,B$ has to have its center somewhere on $MC$ line, it is sufficient for a proof.



                                        enter image description here







                                        share|cite|improve this answer












                                        share|cite|improve this answer



                                        share|cite|improve this answer










                                        answered Oct 5 '17 at 16:26









                                        NarasimhamNarasimham

                                        20.6k52158




                                        20.6k52158























                                            0












                                            $begingroup$

                                            The proof in the picture is the simplest possible one. All you have to do is write the conditions for congruence thus proving that the triangles in the above picture are congruent. This is the best possible approach to the given question.






                                            share|cite|improve this answer











                                            $endgroup$


















                                              0












                                              $begingroup$

                                              The proof in the picture is the simplest possible one. All you have to do is write the conditions for congruence thus proving that the triangles in the above picture are congruent. This is the best possible approach to the given question.






                                              share|cite|improve this answer











                                              $endgroup$
















                                                0












                                                0








                                                0





                                                $begingroup$

                                                The proof in the picture is the simplest possible one. All you have to do is write the conditions for congruence thus proving that the triangles in the above picture are congruent. This is the best possible approach to the given question.






                                                share|cite|improve this answer











                                                $endgroup$



                                                The proof in the picture is the simplest possible one. All you have to do is write the conditions for congruence thus proving that the triangles in the above picture are congruent. This is the best possible approach to the given question.







                                                share|cite|improve this answer














                                                share|cite|improve this answer



                                                share|cite|improve this answer








                                                edited Aug 15 '18 at 10:02









                                                Parth Chauhan

                                                616




                                                616










                                                answered Oct 24 '17 at 0:33









                                                LakshayLakshay

                                                114




                                                114






























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