Draw the graphs of two functions f and g that are continuous and intersect exactly twice on an interval [a, b]. Explain how to use integration to find the area of the region bounded by the two curves.
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Textbook Solutions for Calculus: Early Transcendentals
Question
Equal area properties for parabolas Consider the parabola \(y=x^{2}\). Let P, Q, and R be points on the parabola with R between P and Q on the curve. Let \(\ell_{P}\), \(\ell_{Q}\), and \(\ell_{R}\) be the lines tangent to the parabola at P, Q, and R, respectively (see figure). Let \(P^{\prime}\) be the intersection point of \(\ell_{Q}\), and \(\ell_{R}\); let \(Q^{\prime}\) be the intersection point of \(\ell_{P}\) and \(\ell_{R}\); and let \(R^{\prime}\) be the intersection point of \(\ell_{P}\) and \(\ell_{Q}\). Prove that Area \(\Delta P Q R=2 \cdot \text{ Area }~\Delta P^{\prime} Q^{\prime} R^{\prime}\) in the following cases. (In fact, the property holds for any three points on any parabola.) (Mathematics Magazine 81, No. 2 (April 2008): 83-95.)
a. \(P\left(-a, a^{2}\right)\), \(Q\left(a, a^{2}\right)\), and R(0, 0), where a is a positive real number
b. \(P\left(-a, a^{2}\right)\), \(Q\left(b, b^{2}\right)\), and R(0, 0), where a and b are positive real numbers
c. \(P\left(-a, a^{2}\right)\), \(Q\left(b, b^{2}\right)\), and R is any point between P and Q on the curve
Solution
The first step in solving 6.2 problem number trying to solve the problem we have to refer to the textbook question: Equal area properties for parabolas Consider the parabola \(y=x^{2}\). Let P, Q, and R be points on the parabola with R between P and Q on the curve. Let \(\ell_{P}\), \(\ell_{Q}\), and \(\ell_{R}\) be the lines tangent to the parabola at P, Q, and R, respectively (see figure). Let \(P^{\prime}\) be the intersection point of \(\ell_{Q}\), and \(\ell_{R}\); let \(Q^{\prime}\) be the intersection point of \(\ell_{P}\) and \(\ell_{R}\); and let \(R^{\prime}\) be the intersection point of \(\ell_{P}\) and \(\ell_{Q}\). Prove that Area \(\Delta P Q R=2 \cdot \text{ Area }~\Delta P^{\prime} Q^{\prime} R^{\prime}\) in the following cases. (In fact, the property holds for any three points on any parabola.) (Mathematics Magazine 81, No. 2 (April 2008): 83-95.)a. \(P\left(-a, a^{2}\right)\), \(Q\left(a, a^{2}\right)\), and R(0, 0), where a is a positive real numberb. \(P\left(-a, a^{2}\right)\), \(Q\left(b, b^{2}\right)\), and R(0, 0), where a and b are positive real numbersc. \(P\left(-a, a^{2}\right)\), \(Q\left(b, b^{2}\right)\), and R is any point between P and Q on the curve
From the textbook chapter Regions Between Curves you will find a few key concepts needed to solve this.
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