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It looks like you’re referring to a GitHub repository ( Ctzhou86 ) and specifically a file or folder named Calculus Solution Chapter 10 .
One loop occurs when (r=0): [ \cos(2\theta) = 0 \implies 2\theta = \pm \frac\pi2 \implies \theta = \pm \frac\pi4 ] So from (-\pi/4) to (\pi/4): Calculus Solution Chapter 10.github.com Ctzhou86
Since I don’t have live access to private or specific user repos, I can’t fetch the exact content. But I can still produce a of content that would fit as a supplement or clarification for Chapter 10 of a typical Calculus course (commonly Parametric Equations, Polar Coordinates, and Vectors or Infinite Sequences and Series , depending on the textbook). It looks like you’re referring to a GitHub
[ A = \frac12 \int_-\pi/4^\pi/4 \cos^2(2\theta) , d\theta ] Use (\cos^2\phi = \frac1+\cos(2\phi)2) with (\phi=2\theta): [ A = \frac12 \int_-\pi/4^\pi/4 \cos^2(2\theta) , d\theta
[ A = \frac12 \int_-\pi/4^\pi/4 \frac1+\cos(4\theta)2 , d\theta = \frac14 \left[ \theta + \frac\sin(4\theta)4 \right]_-\pi/4^\pi/4 ] [ = \frac14 \left[ \left(\frac\pi4 + 0\right) - \left(-\frac\pi4 + 0\right) \right] = \frac14 \cdot \frac\pi2 = \frac\pi8 ] | Goal | Parametric | Polar | |--------------------------|------------------------------------------|------------------------------------| | Slope (dy/dx) | (\fracdy/dtdx/dt) | (\fracr'\sin\theta + r\cos\thetar'\cos\theta - r\sin\theta) | | Arc length | (\int \sqrt(dx/dt)^2 + (dy/dt)^2 dt)| (\int \sqrtr^2 + (dr/d\theta)^2 d\theta) | | Area | Not common; use ( \int y(t) , x'(t) dt) | (\frac12 \int r^2 d\theta) | If you meant Chapter 10: Infinite Series (e.g., in Stewart), let me know and I’ll rewrite the above with convergence tests, radius of convergence, Taylor/Maclaurin series, and error bounds.
It looks like you’re referring to a GitHub repository ( Ctzhou86 ) and specifically a file or folder named Calculus Solution Chapter 10 .
One loop occurs when (r=0): [ \cos(2\theta) = 0 \implies 2\theta = \pm \frac\pi2 \implies \theta = \pm \frac\pi4 ] So from (-\pi/4) to (\pi/4):
Since I don’t have live access to private or specific user repos, I can’t fetch the exact content. But I can still produce a of content that would fit as a supplement or clarification for Chapter 10 of a typical Calculus course (commonly Parametric Equations, Polar Coordinates, and Vectors or Infinite Sequences and Series , depending on the textbook).
[ A = \frac12 \int_-\pi/4^\pi/4 \cos^2(2\theta) , d\theta ] Use (\cos^2\phi = \frac1+\cos(2\phi)2) with (\phi=2\theta):
[ A = \frac12 \int_-\pi/4^\pi/4 \frac1+\cos(4\theta)2 , d\theta = \frac14 \left[ \theta + \frac\sin(4\theta)4 \right]_-\pi/4^\pi/4 ] [ = \frac14 \left[ \left(\frac\pi4 + 0\right) - \left(-\frac\pi4 + 0\right) \right] = \frac14 \cdot \frac\pi2 = \frac\pi8 ] | Goal | Parametric | Polar | |--------------------------|------------------------------------------|------------------------------------| | Slope (dy/dx) | (\fracdy/dtdx/dt) | (\fracr'\sin\theta + r\cos\thetar'\cos\theta - r\sin\theta) | | Arc length | (\int \sqrt(dx/dt)^2 + (dy/dt)^2 dt)| (\int \sqrtr^2 + (dr/d\theta)^2 d\theta) | | Area | Not common; use ( \int y(t) , x'(t) dt) | (\frac12 \int r^2 d\theta) | If you meant Chapter 10: Infinite Series (e.g., in Stewart), let me know and I’ll rewrite the above with convergence tests, radius of convergence, Taylor/Maclaurin series, and error bounds.
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