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Chapter 8: Q-8.2-21E (page 437)

In Exercises 21–24, a, b, and c are noncollinear points in\({\mathbb{R}^{\bf{2}}}\)and p is any other point in\({\mathbb{R}^{\bf{2}}}\). Let\(\Delta {\bf{abc}}\)denote the closed triangular region determined by a, b, and c, and let\(\Delta {\bf{pbc}}\)be the region determined by p, b, and c. For convenience, assume that a, b, and c are arranged so that\(\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\)is positive, where\(\overrightarrow {\bf{a}} \),\(\overrightarrow {\bf{b}} \) and\(\overrightarrow {\bf{c}} \)are the standard homogeneous forms for the points.

21. Show that the area of\(\Delta {\bf{abc}}\)is\(det\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]/2\).

[Hint:Consult Sections 3.2 and 3.3, including the Exercises.]

Short Answer

Expert verified

The area of\(\Delta {\rm{abc}}\)is\(\det \left[ {\begin{array}{*{20}{c}}{\overrightarrow {\rm{a}} }&{\overrightarrow {\rm{b}} }&{\overrightarrow {\rm{c}} }\end{array}} \right]/2\).

Step by step solution

01

State the vertices of the triangle

Let\({\bf{a}} = \left[ {\begin{array}{*{20}{c}}{{a_1}}\\{{a_2}}\end{array}} \right]\),\({\bf{b}} = \left[ {\begin{array}{*{20}{c}}{{b_1}}\\{{b_2}}\end{array}} \right]\), and \({\bf{c}} = \left[ {\begin{array}{*{20}{c}}{{c_1}}\\{{c_2}}\end{array}} \right]\) be the vertices of \(\Delta {\rm{abc}}\).

Then,\(\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\)can be represented as shown below:

\(\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right] = \left[ {\begin{array}{*{20}{c}}{{a_1}}&{{b_1}}&{{c_1}}\\{{a_2}}&{{b_2}}&{{c_2}}\\1&1&1\end{array}} \right]\)

02

Find the area of the triangle 

The area of the triangle can be determined as shown below:

\(\begin{array}{c}{\rm{ar}}\left( {\Delta {\rm{abc}}} \right) = \frac{1}{2}\left[ {\left( {{\rm{a}} \times {\rm{b}}} \right) + \left( {{\rm{b}} \times {\rm{c}}} \right) + \left( {{\rm{c}} \times {\rm{a}}} \right)} \right] \cdot {\bf{k}}\\{\rm{ = }}\frac{1}{2}\left[ {\left| {\begin{array}{*{20}{c}}{\bf{i}}&{\bf{j}}&{\bf{k}}\\{{{\rm{a}}_{\rm{1}}}}&{{{\rm{a}}_{\rm{2}}}}&{\rm{0}}\\{{{\rm{b}}_{\rm{1}}}}&{{{\rm{b}}_{\rm{2}}}}&{\rm{0}}\end{array}} \right| + \left| {\begin{array}{*{20}{c}}{\bf{i}}&{\bf{j}}&{\bf{k}}\\{{{\rm{b}}_{\rm{1}}}}&{{{\rm{b}}_{\rm{2}}}}&{\rm{0}}\\{{{\rm{c}}_{\rm{1}}}}&{{{\rm{c}}_{\rm{2}}}}&{\rm{0}}\end{array}} \right| + \left| {\begin{array}{*{20}{c}}{\bf{i}}&{\bf{j}}&{\bf{k}}\\{{{\rm{c}}_{\rm{1}}}}&{{{\rm{c}}_{\rm{2}}}}&{\rm{0}}\\{{{\rm{a}}_{\rm{1}}}}&{{{\rm{a}}_{\rm{2}}}}&{\rm{0}}\end{array}} \right|} \right] \cdot {\bf{k}}\\{\rm{ = }}\frac{1}{2}\left[ \begin{array}{l}\left( {0 - 0} \right){\bf{i}} - \left( {0 - 0} \right){\bf{j}} + \left( {{a_1}{b_2} - {a_2}{b_1}} \right){\bf{k}}\\ + \left( {0 - 0} \right){\bf{i}} - \left( {0 - 0} \right){\bf{j}} + \left( {{b_1}{c_2} - {b_2}{c_1}} \right){\bf{k}}\\ + \left( {0 - 0} \right){\bf{i}} - \left( {0 - 0} \right){\bf{j}} + \left( {{c_1}{a_2} - {a_1}{c_2}} \right){\bf{k}}\end{array} \right] \cdot {\bf{k}}\\{\rm{ = }}\frac{1}{2}\left[ {\left( {{a_1}{b_2} - {a_2}{b_1}} \right){\bf{k}} + \left( {{b_1}{c_2} - {b_2}{c_1}} \right){\bf{k}} + \left( {{c_1}{a_2} - {a_1}{c_2}} \right){\bf{k}}} \right] \cdot {\bf{k}}\end{array}\)

Simplify further as shown below:

\(\begin{array}{c}{\rm{ar}}\left( {\Delta {\rm{abc}}} \right) = \frac{1}{2}\left[ {\left( {{a_1}{b_2} - {a_2}{b_1}} \right){\bf{k}} + \left( {{b_1}{c_2} - {b_2}{c_1}} \right){\bf{k}} + \left( {{c_1}{a_2} - {a_1}{c_2}} \right){\bf{k}}} \right] \cdot {\bf{k}}\\ = \frac{1}{2}\left[ {\left( {{a_1}{b_2} - {a_2}{b_1}} \right) + \left( {{b_1}{c_2} - {b_2}{c_1}} \right) + \left( {{c_1}{a_2} - {a_1}{c_2}} \right)} \right] \cdot {\bf{k}} \cdot {\bf{k}}\\ = \frac{1}{2}\left[ {\left( {{a_1}{b_2} - {a_2}{b_1}} \right) + \left( {{b_1}{c_2} - {b_2}{c_1}} \right) + \left( {{c_1}{a_2} - {a_1}{c_2}} \right)} \right]\\ = \frac{1}{2}\det \left[ {\begin{array}{*{20}{c}}{{a_1}}&{{b_1}}&{{c_1}}\\{{a_2}}&{{b_2}}&{{c_2}}\\1&1&1\end{array}} \right]\end{array}\)

Here, \(\det \left[ {\begin{array}{*{20}{c}}{{a_1}}&{{b_1}}&{{c_1}}\\{{a_2}}&{{b_2}}&{{c_2}}\\1&1&1\end{array}} \right] = \left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\).

Thus, \({\rm{ar}}\left( {\Delta {\rm{abc}}} \right) = \frac{1}{2}\det \left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\).

Hence, it is proved that the area of \(\Delta {\rm{abc}}\) is \(\det \left[ {\begin{array}{*{20}{c}}{\overrightarrow {\rm{a}} }&{\overrightarrow {\rm{b}} }&{\overrightarrow {\rm{c}} }\end{array}} \right]/2\).

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Most popular questions from this chapter

In Exercises 21–24, a, b, and c are noncollinear points in\({\mathbb{R}^{\bf{2}}}\)and p is any other point in\({\mathbb{R}^{\bf{2}}}\). Let\(\Delta {\bf{abc}}\)denote the closed triangular region determined by a, b, and c, and let\(\Delta {\bf{pbc}}\)be the region determined by p, b, and c. For convenience, assume that a, b, and c are arranged so that\(\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\)is positive, where\(\overrightarrow {\bf{a}} \),\(\overrightarrow {\bf{b}} \)and\(\overrightarrow {\bf{c}} \)are the standard homogeneous forms for the points.

23. Let p be any point in the interior of\(\Delta {\bf{abc}}\), with barycentric coordinates\(\left( {r,s,t} \right)\), so that

\(\left[ {\begin{array}{*{20}{c}}{\overrightarrow {\bf{a}} }&{\overrightarrow {\bf{b}} }&{\overrightarrow {\bf{c}} }\end{array}} \right]\left[ {\begin{array}{*{20}{c}}r\\s\\t\end{array}} \right] = \widetilde {\bf{p}}\)

Use Exercise 21 and a fact about determinants (Chapter 3) to show that

\(r = \left( {area of \Delta pbc} \right)/\left( {area of \Delta abc} \right)\)

\(s = \left( {area of \Delta apc} \right)/\left( {area of \Delta abc} \right)\)

\(t = \left( {area of \Delta abp} \right)/\left( {area of \Delta abc} \right)\)

Question: 19. Let \(S\) be an affine subset of \({\mathbb{R}^n}\) , suppose \(f:{\mathbb{R}^n} \to {\mathbb{R}^m}\)is a linear transformation, and let \(f\left( S \right)\) denote the set of images \(\left\{ {f\left( {\rm{x}} \right):{\rm{x}} \in S} \right\}\). Prove that \(f\left( S \right)\)is an affine subset of \({\mathbb{R}^m}\).

Question: 17. Choose a set \(S\) of three points such that aff \(S\) is the plane in \({\mathbb{R}^3}\) whose equation is \({x_3} = 5\). Justify your work.

Suppose that\(\left\{ {{p_1},{p_2},{p_3}} \right\}\)is an affinely independent set in\({\mathbb{R}^{\bf{n}}}\)and q is an arbitrary point in\({\mathbb{R}^{\bf{n}}}\). Show that the translated set\(\left\{ {{p_1} + q,{p_2} + q,{p_3} + {\bf{q}}} \right\}\)is also affinely independent.

Question:In Exercises 21 and 22, mark each statement True or False. Justify each answer.

21. a. A linear transformation from\(\mathbb{R}\)to\({\mathbb{R}^n}\)is called a linear functional.

b. If\(f\)is a linear functional defined on\({\mathbb{R}^n}\), then there exists a real number\(k\)such that\(f\left( x \right) = kx\)for all\(x\)in\({\mathbb{R}^n}\).

c. If a hyper plane strictly separates sets\(A\)and\(B\), then\(A \cap B = \emptyset \)

d. If\(A\)and\(B\)are closed convex sets and\(A \cap B = \emptyset \), then there exists a hyper plane that strictly separate\(A\)and\(B\).
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