Prove that BD bisects angle ABC Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)A geometry problem that involves congruence of triangles.Prove that: $S_XYZgeq frac14S_ABC$Prove that angle ACB > angle ABD.Let $D, E, F$ be the feet of the altitudes from $A, B, C$ in $triangle ABC$. Prove that the perpendicular bisector of $EF$ also bisects $BC$.In the following figure, prove that $AC$ bisects $GH$.In triangle $ABC$ find angle $angle BAC$ given that…Show that the altitude bisects the corresponding angleAngle bisector contains the Nine Point CentreProve sum of angles in problem involving bisectors in a given triangleHow to solve for $angle BDC$ given the information of other angles in the picture
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Prove that BD bisects angle ABC
Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)A geometry problem that involves congruence of triangles.Prove that: $S_XYZgeq frac14S_ABC$Prove that angle ACB > angle ABD.Let $D, E, F$ be the feet of the altitudes from $A, B, C$ in $triangle ABC$. Prove that the perpendicular bisector of $EF$ also bisects $BC$.In the following figure, prove that $AC$ bisects $GH$.In triangle $ABC$ find angle $angle BAC$ given that…Show that the altitude bisects the corresponding angleAngle bisector contains the Nine Point CentreProve sum of angles in problem involving bisectors in a given triangleHow to solve for $angle BDC$ given the information of other angles in the picture
$begingroup$
Given that $triangle ABC$ is an isosceles right triangle with $AC=BC$ and angle $ACB=90°$. $D$ is a point on $AC$ and $E$ is on the extension of $BD$ such that $AE$ is perpendicular to $BE$. If $AE=frac12BD$, prove that BD bisects angle $angle ABC$.
I have tried proving triangle $triangle AEB$ and triangle $triangle DCB$ similar but can't do so. After some angle chasing, I arrived at the result that somehow if I prove angle $angle CDB$ to be $67.5°$ then it could be proved. But I failed to do so.
geometry triangles
New contributor
$endgroup$
add a comment |
$begingroup$
Given that $triangle ABC$ is an isosceles right triangle with $AC=BC$ and angle $ACB=90°$. $D$ is a point on $AC$ and $E$ is on the extension of $BD$ such that $AE$ is perpendicular to $BE$. If $AE=frac12BD$, prove that BD bisects angle $angle ABC$.
I have tried proving triangle $triangle AEB$ and triangle $triangle DCB$ similar but can't do so. After some angle chasing, I arrived at the result that somehow if I prove angle $angle CDB$ to be $67.5°$ then it could be proved. But I failed to do so.
geometry triangles
New contributor
$endgroup$
$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago
add a comment |
$begingroup$
Given that $triangle ABC$ is an isosceles right triangle with $AC=BC$ and angle $ACB=90°$. $D$ is a point on $AC$ and $E$ is on the extension of $BD$ such that $AE$ is perpendicular to $BE$. If $AE=frac12BD$, prove that BD bisects angle $angle ABC$.
I have tried proving triangle $triangle AEB$ and triangle $triangle DCB$ similar but can't do so. After some angle chasing, I arrived at the result that somehow if I prove angle $angle CDB$ to be $67.5°$ then it could be proved. But I failed to do so.
geometry triangles
New contributor
$endgroup$
Given that $triangle ABC$ is an isosceles right triangle with $AC=BC$ and angle $ACB=90°$. $D$ is a point on $AC$ and $E$ is on the extension of $BD$ such that $AE$ is perpendicular to $BE$. If $AE=frac12BD$, prove that BD bisects angle $angle ABC$.
I have tried proving triangle $triangle AEB$ and triangle $triangle DCB$ similar but can't do so. After some angle chasing, I arrived at the result that somehow if I prove angle $angle CDB$ to be $67.5°$ then it could be proved. But I failed to do so.
geometry triangles
geometry triangles
New contributor
New contributor
edited 1 hour ago
Pushpa Kumari
New contributor
asked 2 hours ago
Pushpa KumariPushpa Kumari
334
334
New contributor
New contributor
$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago
add a comment |
$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago
add a comment |
3 Answers
3
active
oldest
votes
$begingroup$
Refer to the figure:
$hspace2cm$
From similarity of triangles $Delta ADE$ and $Delta BCD$ (corresponding angles are equal):
$$fracxy=fracy-z2x Rightarrow 2x^2=y^2-zy (1)$$
From the right $Delta BCD$:
$$z^2+y^2=(2x)^2 (2)$$
Now substitute $(1)$ to $(2)$:
$$z^2+y^2=2(y^2-zy) Rightarrow \
(y-z)^2=2z^2 Rightarrow \
y-z=zsqrt2 Rightarrow \
fracy-zz=fracysqrt2y,$$
which is consistent with the angle bisector theorem.
$endgroup$
add a comment |
$begingroup$
Let $M$ be the midpoint of $BD$ and $G$, $F$ be projections of $M$, $E$ onto $AC$ respectively.
First notice that $angle GMD = angle DAE = 90^circ -angle ADE$.
Now $triangle MGD$ and $triangle AFE$ are congruent as they are right triangle having equal hypothenuse ($MD=AE$) and a pair of equal angles. So $$FA = MG = BC/2 = AC/2.$$
Thus $F$ is the midpoint of $AC$ and $AE = EC$. Since $E$ lies on the circumcircle of $triangle ABC$, it follows that $E$ is the midpoint of arc $AC$. Hence, $BE$ is the angle bisector of $angle ABC$.
$endgroup$
add a comment |
$begingroup$
A simple geometric solution:
Extend BC and AE to intersect at F. Triangles AFC and BDC are similar. The side CB of triangle BDC is equal to side AC of triangle AFC, this results in that other sides of AFC and BDC are equal including AF and BD and we have $AE=frac 12DB=frac 12AF$. But AE is also perpendicular to BE, that means BE is the height of ABE and triangle ABF is isosceles and its height BE bisects the angle$ <ABC$.
$endgroup$
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
add a comment |
Your Answer
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3 Answers
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3 Answers
3
active
oldest
votes
active
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active
oldest
votes
$begingroup$
Refer to the figure:
$hspace2cm$
From similarity of triangles $Delta ADE$ and $Delta BCD$ (corresponding angles are equal):
$$fracxy=fracy-z2x Rightarrow 2x^2=y^2-zy (1)$$
From the right $Delta BCD$:
$$z^2+y^2=(2x)^2 (2)$$
Now substitute $(1)$ to $(2)$:
$$z^2+y^2=2(y^2-zy) Rightarrow \
(y-z)^2=2z^2 Rightarrow \
y-z=zsqrt2 Rightarrow \
fracy-zz=fracysqrt2y,$$
which is consistent with the angle bisector theorem.
$endgroup$
add a comment |
$begingroup$
Refer to the figure:
$hspace2cm$
From similarity of triangles $Delta ADE$ and $Delta BCD$ (corresponding angles are equal):
$$fracxy=fracy-z2x Rightarrow 2x^2=y^2-zy (1)$$
From the right $Delta BCD$:
$$z^2+y^2=(2x)^2 (2)$$
Now substitute $(1)$ to $(2)$:
$$z^2+y^2=2(y^2-zy) Rightarrow \
(y-z)^2=2z^2 Rightarrow \
y-z=zsqrt2 Rightarrow \
fracy-zz=fracysqrt2y,$$
which is consistent with the angle bisector theorem.
$endgroup$
add a comment |
$begingroup$
Refer to the figure:
$hspace2cm$
From similarity of triangles $Delta ADE$ and $Delta BCD$ (corresponding angles are equal):
$$fracxy=fracy-z2x Rightarrow 2x^2=y^2-zy (1)$$
From the right $Delta BCD$:
$$z^2+y^2=(2x)^2 (2)$$
Now substitute $(1)$ to $(2)$:
$$z^2+y^2=2(y^2-zy) Rightarrow \
(y-z)^2=2z^2 Rightarrow \
y-z=zsqrt2 Rightarrow \
fracy-zz=fracysqrt2y,$$
which is consistent with the angle bisector theorem.
$endgroup$
Refer to the figure:
$hspace2cm$
From similarity of triangles $Delta ADE$ and $Delta BCD$ (corresponding angles are equal):
$$fracxy=fracy-z2x Rightarrow 2x^2=y^2-zy (1)$$
From the right $Delta BCD$:
$$z^2+y^2=(2x)^2 (2)$$
Now substitute $(1)$ to $(2)$:
$$z^2+y^2=2(y^2-zy) Rightarrow \
(y-z)^2=2z^2 Rightarrow \
y-z=zsqrt2 Rightarrow \
fracy-zz=fracysqrt2y,$$
which is consistent with the angle bisector theorem.
answered 1 hour ago
farruhotafarruhota
22.3k2942
22.3k2942
add a comment |
add a comment |
$begingroup$
Let $M$ be the midpoint of $BD$ and $G$, $F$ be projections of $M$, $E$ onto $AC$ respectively.
First notice that $angle GMD = angle DAE = 90^circ -angle ADE$.
Now $triangle MGD$ and $triangle AFE$ are congruent as they are right triangle having equal hypothenuse ($MD=AE$) and a pair of equal angles. So $$FA = MG = BC/2 = AC/2.$$
Thus $F$ is the midpoint of $AC$ and $AE = EC$. Since $E$ lies on the circumcircle of $triangle ABC$, it follows that $E$ is the midpoint of arc $AC$. Hence, $BE$ is the angle bisector of $angle ABC$.
$endgroup$
add a comment |
$begingroup$
Let $M$ be the midpoint of $BD$ and $G$, $F$ be projections of $M$, $E$ onto $AC$ respectively.
First notice that $angle GMD = angle DAE = 90^circ -angle ADE$.
Now $triangle MGD$ and $triangle AFE$ are congruent as they are right triangle having equal hypothenuse ($MD=AE$) and a pair of equal angles. So $$FA = MG = BC/2 = AC/2.$$
Thus $F$ is the midpoint of $AC$ and $AE = EC$. Since $E$ lies on the circumcircle of $triangle ABC$, it follows that $E$ is the midpoint of arc $AC$. Hence, $BE$ is the angle bisector of $angle ABC$.
$endgroup$
add a comment |
$begingroup$
Let $M$ be the midpoint of $BD$ and $G$, $F$ be projections of $M$, $E$ onto $AC$ respectively.
First notice that $angle GMD = angle DAE = 90^circ -angle ADE$.
Now $triangle MGD$ and $triangle AFE$ are congruent as they are right triangle having equal hypothenuse ($MD=AE$) and a pair of equal angles. So $$FA = MG = BC/2 = AC/2.$$
Thus $F$ is the midpoint of $AC$ and $AE = EC$. Since $E$ lies on the circumcircle of $triangle ABC$, it follows that $E$ is the midpoint of arc $AC$. Hence, $BE$ is the angle bisector of $angle ABC$.
$endgroup$
Let $M$ be the midpoint of $BD$ and $G$, $F$ be projections of $M$, $E$ onto $AC$ respectively.
First notice that $angle GMD = angle DAE = 90^circ -angle ADE$.
Now $triangle MGD$ and $triangle AFE$ are congruent as they are right triangle having equal hypothenuse ($MD=AE$) and a pair of equal angles. So $$FA = MG = BC/2 = AC/2.$$
Thus $F$ is the midpoint of $AC$ and $AE = EC$. Since $E$ lies on the circumcircle of $triangle ABC$, it follows that $E$ is the midpoint of arc $AC$. Hence, $BE$ is the angle bisector of $angle ABC$.
answered 1 hour ago
Quang HoangQuang Hoang
13.3k1233
13.3k1233
add a comment |
add a comment |
$begingroup$
A simple geometric solution:
Extend BC and AE to intersect at F. Triangles AFC and BDC are similar. The side CB of triangle BDC is equal to side AC of triangle AFC, this results in that other sides of AFC and BDC are equal including AF and BD and we have $AE=frac 12DB=frac 12AF$. But AE is also perpendicular to BE, that means BE is the height of ABE and triangle ABF is isosceles and its height BE bisects the angle$ <ABC$.
$endgroup$
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
add a comment |
$begingroup$
A simple geometric solution:
Extend BC and AE to intersect at F. Triangles AFC and BDC are similar. The side CB of triangle BDC is equal to side AC of triangle AFC, this results in that other sides of AFC and BDC are equal including AF and BD and we have $AE=frac 12DB=frac 12AF$. But AE is also perpendicular to BE, that means BE is the height of ABE and triangle ABF is isosceles and its height BE bisects the angle$ <ABC$.
$endgroup$
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
add a comment |
$begingroup$
A simple geometric solution:
Extend BC and AE to intersect at F. Triangles AFC and BDC are similar. The side CB of triangle BDC is equal to side AC of triangle AFC, this results in that other sides of AFC and BDC are equal including AF and BD and we have $AE=frac 12DB=frac 12AF$. But AE is also perpendicular to BE, that means BE is the height of ABE and triangle ABF is isosceles and its height BE bisects the angle$ <ABC$.
$endgroup$
A simple geometric solution:
Extend BC and AE to intersect at F. Triangles AFC and BDC are similar. The side CB of triangle BDC is equal to side AC of triangle AFC, this results in that other sides of AFC and BDC are equal including AF and BD and we have $AE=frac 12DB=frac 12AF$. But AE is also perpendicular to BE, that means BE is the height of ABE and triangle ABF is isosceles and its height BE bisects the angle$ <ABC$.
answered 30 mins ago
siroussirous
1,7581514
1,7581514
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
add a comment |
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
$begingroup$
+1. Thinking out of box.
$endgroup$
– farruhota
15 mins ago
add a comment |
Pushpa Kumari is a new contributor. Be nice, and check out our Code of Conduct.
Pushpa Kumari is a new contributor. Be nice, and check out our Code of Conduct.
Pushpa Kumari is a new contributor. Be nice, and check out our Code of Conduct.
Pushpa Kumari is a new contributor. Be nice, and check out our Code of Conduct.
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$begingroup$
Start by drawing a diagram and showing all the given information.
$endgroup$
– 1123581321
2 hours ago
$begingroup$
@PushpaKumari just provide a link to your image, someone will be willing to edit it.
$endgroup$
– Quang Hoang
2 hours ago
$begingroup$
To prove that the two triangles are similar, show that they both have right angles (this is given) and use the fact that angles EDA and BDC are vertically opposite.
$endgroup$
– 1123581321
2 hours ago