Calculus II (MAT 146) Dr. Day Monday December 4, 2017 Integration Applications Area Between Curves (6.1) Average Value of a Function (6.5) Volumes of Solids (6.2, 6.3) Created by Rotations Created using Cross Sections Arc Length of a Curve (8.1) Probability (8.5) Methods of Integration U-substitution (5.5) Integration by Parts (7.1) Trig Integrals (7.2) Trig Substitution (7.3) Partial-Fraction Decomposition (7.4) Putting it All Together: Strategies! (7.5) Improper Integrals (7.8) Differential Equations What is a differential equation? (9.1) Solving Differential Equations Visual: Slope Fields (9.2) Numerical: Euler’s Method (9.2) Analytical: Separation of Variables (9.3) Applications of Differential Equations Infinite Sequences & Series (Ch 11) What is a sequence? A series? (11.1,11.2) Determining Series Convergence Divergence Test (11.2) Integral Test (11.3) Comparison Tests (11.4) Alternating Series Test (11.5) Ratio Test (11.6) Nth-Root Test (11.6) Power Series Interval & Radius of Convergence New Functions from Old Taylor Series and Maclaurin Series Semester Exam: Tuesday, Dec 12, 7:50 – 10:30 am, WIH 128 Review Session: Sunday, Dec 10, 6:30 – 7:30 pm, STV 308 Monday, December 4, 2017

Power Series: Example If we let cn = 1 for all n, we get a familiar series: This geometric series has common ratio x and we know the series converges for |x| < 1. We also know the sum of this series: Monday, December 4, 2017

Generalized Power Series This is called: a power series in (x – a), or a power series centered at a, or a power series about a. Monday, December 4, 2017

Power Series Convergence For what values of x does each series converge? Determine the Radius of Convergence and theInterval of Convergence for each power series. Monday, December 4, 2017

Geometric Power Series If we let cn = 1 for all n, we get a familiar series: This geometric series has common ratio x and we know the series converges for |x| < 1. We also know the sum of this series: Monday, December 4, 2017

Geometric Power Series Monday, December 4, 2017

Geometric Power Series Monday, December 4, 2017

Geometric Power Series Monday, December 4, 2017

Why Study Sequences and Series in Calc II? Taylor Polynomials applet Infinite Process Yet Finite Outcome . . . How Can That Be? Transition to Proof Re-Expression! Monday, December 4, 2017

Polynomial Approximators Our goal is to generate polynomial functions that can be used to approximate other functions near particular values of x. The polynomial we seek is of the following form: Monday, December 4, 2017

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Polynomial Approximators Goal: Generate polynomial functions to approximate other functions near particular values of x. Create a third-degree polynomial approximator for Monday, December 4, 2017

Create a 3rd-degree polynomial approximator for Monday, December 4, 2017

Beyond Geometric Series Connections: Taylor Series How can we describe the cn so a power series can represent OTHER functions? ANY functions? Now we go way back to the ideas that motivated this chapter’s investigations and connections: Polynomial Approximators! Monday, December 4, 2017

Taylor Series Demo #1 Taylor Series Demo #2 Taylor Series Demo #3 Monday, December 4, 2017

Taylor Series Example: f(x) = ex, centered around a = 0. Look at characteristics of the function in question and connect those to the cn. Example: f(x) = ex, centered around a = 0. Monday, December 4, 2017

Taylor Series Example: f(x) = ex, centered around a = 0. And…how far from a = 0 can we stray and still find this re-expression useful? Monday, December 4, 2017

General Form: Coefficients cn Monday, December 4, 2017

Examples: Determining the cn f(x) = cos(x), centered around a = 0. Monday, December 4, 2017

Examples: Determining the cn f(x) = sin(x), centered around a = 0. Monday, December 4, 2017

Examples: Determining the cn f(x) = ln(1-x), centered around a = 0. Monday, December 4, 2017