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1.5: The Pythagorean Theorem for Area and Perimeter

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    4146
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    Find missing sides to calculate the area

    Applications of the Pythagorean Theorem

    Find the Height of an Isosceles Triangle

    One way to use The Pythagorean Theorem is to find the height of an isosceles triangle (see Example 1).

    f-d_6523ee35e4e04bae447231a017020f68965afb15be8ced06c0e615c7+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{1}\)

    Prove the Distance Formula

    Another application of the Pythagorean Theorem is the Distance Formula. We will prove it here.

    f-d_01176afd22daf724ca4681160c93f4f54e3ff2e97e20c48e0d07c2fc+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{2}\)

    Let’s start with point \(A(x_1, y_1)\) and point \(B(x_2, y_2)\). We will call the distance between A and B, d.

    Draw the vertical and horizontal lengths to make a right triangle.

    f-d_01af07305216dce3734e99185913d45cf183cd5a7643dfd748fbdfb2+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{3}\)

    Now that we have a right triangle, we can use the Pythagorean Theorem to find the hypotenuse, d.

    \(\begin{aligned} d^2&=\sqrt{(x_1−x_2)^2+(y_1−y_2)^2} \\ d&=(x_1−x_2)^2+(y_1−y_2)^2 \end{aligned}\)

    Distance Formula: The distance between \(A(x_1,y_1)\) and \(B(x_2,y_2)\) is

    \(d=\sqrt{(x_1−x_2)^2+(y_1−y_2)^2}\).

    Classify a Triangle as Acute, Right, or Obtuse

    We can extend the converse of the Pythagorean Theorem to determine if a triangle is an obtuse or acute triangle.

    Acute Triangles: If the sum of the squares of the two shorter sides in a right triangle is greater than the square of the longest side, then the triangle is acute.

    f-d_c640986581ed5b04fbd2841e5fc5250815c11af7a422dd6547278d60+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{4}\)

    For \(b<c\) and \(a<c\), if \(a^2+b^2>c^2\), then the triangle is acute.

    Obtuse Triangles: If the sum of the squares of the two shorter sides in a right triangle is less than the square of the longest side, then the triangle is obtuse.

    f-d_2d96d7102d3e1fc8ea676d02cbb2b998948c934cd39770637180b134+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{5}\)

    For \(b<c\) and \(a<c\), if \(a^2+b^2<c^2\), then the triangle is obtuse.

    What if you were given an equilateral triangle in which all the sides measured 4 inches? How could you use the Pythagorean Theorem to find the triangle's altitude?

    Example \(\PageIndex{1}\)

    What is the height of the isosceles triangle?

    f-d_6a7985ec07aa746c4c55ac05cce125ba6731048416d39a87d865f6e5+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{6}\)

    Solution

    Draw the altitude from the vertex between the congruent sides, which will bisect the base.

    f-d_02523795ea3c9269a5bde893cae831117c37ec44298b6af5ca273ead+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{7}\)

    \(\begin{aligned} 7^2+h^2 &=9^2 \\ 49+h^2&=81 \\ h^2&=32 \\ h&=\sqrt{32}=\sqrt{16 \cdot 2}=4\sqrt{2}\end{aligned}\)

    Example \(\PageIndex{2}\)

    Find the distance between \((1, 5)\) and \((5, 2)\).

    Solution

    Make \(A(1,5)\) and \(B(5,2)\). Plug into the distance formula.

    \(\begin{aligned} d&=\sqrt{(1−5)^2+(5−2)^2} \\ &=\sqrt{(−4)^2+(3)^2}\\ &=\sqrt{16+9}=\sqrt{25}=5 \end{aligned} \)

    Just like the lengths of the sides of a triangle, distances are always positive.

    Example \(\PageIndex{3}\)

    Graph \(A(−4,1)\), \(B(3,8)\), and \(C(9,6)\). Determine if \(\Delta ABC\) is acute, obtuse, or right.

    f-d_af2851df1c7f3bc70d31ce03f75a30265d3ed31fa9ee85458797f80e+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{8}\)

    Solution

    Use the distance formula to find the length of each side.

    \(\begin{aligned} AB&=\sqrt{(−4−3)^2+(1−8)^2}=\sqrt{49+49}=\sqrt{98} \\ BC&=\sqrt{(3−9)^2+(8−6)^2}=\sqrt{36+4}=\sqrt{40} \\ AC&=\sqrt{(−4−9)^2+(1−6)^2}=\sqrt{169+25}=\sqrt{194}\end{aligned}\)

    Plug these lengths into the Pythagorean Theorem.

    \(\begin{aligned} (\sqrt{98})^2+(\sqrt{40})^2 &? (\sqrt{194})^2 \\ 98+40 &? 194\\ 138 &<194 \end{aligned}\)

    \(\Delta ABC\) is an obtuse triangle.

    For Examples 4 and 5, determine if the triangles are acute, right or obtuse.

    Example \(\PageIndex{4}\)

    Set the longest side to \(c\).

    f-d_a1c45a09a03a3a839b2163a5cdc2c4f57a5af4754a080170353d255c+IMAGE_TINY+IMAGE_TINY.png
    Figure \(\PageIndex{9}\)

    Solution

    \(\begin{aligned} 15^2+14^2 &? 21^2 \\ 225+196 &? 441 \\ 421 &<441\end{aligned}\)

    The triangle is obtuse.

    Example \(\PageIndex{5}\)

    Set the longest side to \(c\).

    A triangle with side lengths 5, 12, 13.

    Solution

    \(5^2+12^2=13^2\) so this triangle is right.

    Review

    Find the height of each isosceles triangle below. Simplify all radicals.


    1. f-d_a6b4fc39d8ed13ca5e9ffaa0ff1f4c0789fe9bf3b0c85f162e3032c7+IMAGE_TINY+IMAGE_TINY.png
      Figure \(\PageIndex{10}\)
    2. f-d_da225560cddce23c4f10c83f29d053dc4f6a285d2836e7d9efacb150+IMAGE_TINY+IMAGE_TINY.png
      Figure \(\PageIndex{11}\)
    3. f-d_f1fd34d23400765319b90470d5885e03fdd7d289001abb48e128e9f1+IMAGE_TINY+IMAGE_TINY.png
      Figure \(\PageIndex{12}\)

    Find the length between each pair of points.

    1. (-1, 6) and (7, 2)
    2. (10, -3) and (-12, -6)
    3. (1, 3) and (-8, 16)
    4. What are the length and width of a 42” HDTV? Round your answer to the nearest tenth.
    5. Standard definition TVs have a length and width ratio of 4:3. What are the length and width of a 42” Standard definition TV? Round your answer to the nearest tenth.

    Determine whether the following triangles are acute, right or obtuse.

    1. 7, 8, 9
    2. 14, 48, 50
    3. 5, 12, 15
    4. 13, 84, 85
    5. 20, 20, 24
    6. 35, 40, 51
    7. 39, 80, 89
    8. 20, 21, 38
    9. 48, 55, 76

    Graph each set of points and determine whether \(\Delta ABC\) is acute, right, or obtuse, using the distance formula.

    1. \(A(3,−5), B(−5,−8), C(−2,7)\)
    2. \(A(5,3),B(2,−7),C(−1,5)\)
    3. \(A(1,6),B(5,2),C(−2,3)\)
    4. \(A(−6,1),B(−4,−5),C(5,−2)\)

    Review (Answers)

    To see the Review answers, open this PDF file and look for section 8.3.

    Resources

    Additional Resources

    Interactive Element

    Video: The Pythagorean Theorem and The Converse of the Pythagorean Theorem


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