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One of the vertices of an equilateral triangle is on the vertex of a square and two other vertices are on the not adjacent sides of the same square. Find the side of the triangle if the side of the square is 10 ft.

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danielmaduroh

Answer:

The side of the triangle is either 38.63ft or 10.35ft

Step-by-step explanation:

This problem can be translated as an image as shown in the Figure below. We know that:

  • The side of the square is 10 ft.
  • One of the vertices of an equilateral triangle is on the vertex of a square.
  • Two other vertices are on the not adjacent sides of the same square.

Let's call:

Since the given triangle is equilateral, each side measures the same length. So:

x: The side of the equilateral triangle (Triangle 1)

y: A side of another triangle called Triangle 2.

That length is the hypotenuse of other triangle called Triangle 2. Therefore, by Pythagorean theorem:

[tex]\mathbf{(1)} \ x^2=100+y^2[/tex]

We have another triangle, called Triangle 3, and given that the side of the square is 10ft, then it is true that:

[tex]y+(10-y)=10[/tex]

Therefore, for Triangle 3, we have that by Pythagorean theorem:

[tex](10-y)^2+(10-y)^2=x^2 \\ \\ 2(10-y)^2=x^2 \\ \\ \\ \mathbf{(2)} \ x^2=2(10-y)^2[/tex]

Matching equations (1) and (2):

[tex]2(10-y)^2=100+y^2 \\ \\ 2(100-20y+y^2)=100+y^2 \\ \\ 200-40y+2y^2=100+y^2 \\ \\ (2y^2-y^2)-40y+(200-100)=0 \\ \\ y^2-40y+100=0[/tex]

Using quadratic formula:

[tex]y_{1,2}=\frac{-b \pm \sqrt{b^2-4ac}}{2a} \\ \\ y_{1,2}=\frac{-(-40) \pm \sqrt{(-40)^2-4(1)(100)}}{2(1)} \\ \\ \\ y_{1}=37.32 \\ \\ y_{2}=2.68[/tex]

Finding x from (1):

[tex]x^2=100+y^2 \\ \\ x_{1}=\sqrt{100+37.32^2} \\ \\ x_{1}=38.63ft \\ \\ \\ x_{2}=\sqrt{100+2.68^2} \\ \\ x_{2}=10.35ft[/tex]

Finally, the side of the triangle is either 38.63ft or 10.35ft

Ver imagen danielmaduroh
profantoniofonte

Answer:

[tex]10\sqrt{6} -10\sqrt{2} \approx 10.35 ft[/tex]

Step-by-step explanation:

1) Check the first picture, to visualize what the question has told. An equilateral triangle DLM inscribed in a square ABCD. A triangle like that has three 60º angles.

2) Looking to DCL and DBE we have two right triangles. The next natural step, is doing Pythagorean theorem.

[tex]\triangle DCO \:a^{2}=10^{2}+x^{2}\Rightarrow a=\sqrt{100+x^{2}}\\\triangle DBE \:a^{2}=10^{2}+y^{2}\Rightarrow a=\sqrt{100+y^{2}}[/tex]

Since this is an equilateral triangle, all three sides have the same size, we can set them as equal:

[tex]\sqrt{100+y^{2}}=\sqrt{100+x^{2}}\\\left ( \sqrt{100+y^{2}} \right )^{2}=\left ( \sqrt{100+x^{2}} \right)^{2}100+y^{2}=100+x^{2}\\y^{2}=x^{2}\\y=x[/tex]

3} This allows to replace x for y. We also have, since there is symmetry. We can check that's on the left, a right isosceles triangle (ALE) whose hypotenuse is [tex]a\sqrt{2}[/tex]. Hence, the hypotenuse would be [tex]\sqrt{2}(10-x)[/tex]

. Again starting from the fact this is an equilateral triangle

[tex]\sqrt{2}(10-x)=\sqrt{100-x^2}\\\left ( \sqrt{2}(10-x) \right )^{2}=\left ( \sqrt{100+x^{2}} \right)^{2}\\2(100-20x+x^{2})=100+x^{2}\\200-40x+2x^{2}=100+x^{2}\Rightarrow x^{2}-40x+100[/tex]

[tex]Completing \:the \: square\\ x^{2}-40x+100 -100 =0-100\\x^{2}-40x=-100\\\\ Adding \:the \:half \:of \:the \:absolute \:value \:of\: b, and \:square \:it\\x^{2}-40x +20^{2}= 20^{2}-100\\x^{2}-40x +400= 400-100\\ Rewrite\\(x-20)^2=300\\(x-20)=\sqrt{300}\:\rightarrow x-20=10\sqrt{3}\\\rightarrow x_{1}=20+10\sqrt{3} \approx37.32, x_{2}=20-10\sqrt{3}\approx 2.67[/tex]

4) One and only one value must fit. So let's try plugging the minor one.

[tex]\sqrt{2}(10- (20-10\sqrt{3})=10\sqrt{6}-10\sqrt{2}\approx 10.35 \:ft[/tex]

[tex]\sqrt{2}(10- (20+10\sqrt{3})=-10\sqrt{6}-10\sqrt{2}\approx -38.64 \:ft[/tex]

If one vertex of the triangle is on the square, it can't be an outlying value as the absolute value of 38.64.  Furthermore the greatest value for a line segment of this square would be the value of the diagonal, in this case[tex]10\sqrt{2}\approx 14.14[/tex]

So, it is 10.35

Ver imagen profantoniofonte
Ver imagen profantoniofonte
Ver imagen profantoniofonte

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