Reflecting Surface Assume that when the plane curve C shown in Figure 1.3.21 is revolved | StudySoup
Differential Equations with Boundary-Value Problems | 7th Edition | ISBN: 9780495108368 | Authors: Dennis G. Zill, Michael R. Cullen

Table of Contents

1
INTRODUCTION TO DIFFERENTIAL EQUATIONS
1.1
Definitions and Terminology
1.2
Initial-Value Problems
1.3
Differential Equations as Mathematical Models

2
FIRST-ORDER DIFFERENTIAL EQUATIONS
2.1
Solution Curves Without a Solution
2.2
Separable Variables
2.3
Linear Equations
2.4
Exact Equations
2.5
Solutions by Substitutions
2.6
A Numerical Method

3
MODELING WITH FIRST-ORDER DIFFERENTIAL EQUATIONS
3.1
Linear Models
3.2
Nonlinear Models
3.3
Modeling with Systems of First-Order DEs

4
HIGHER-ORDER DIFFERENTIAL EQUATIONS
4.1
Preliminary TheoryLinear Equations
4.2
Reduction of Order
4.3
Homogeneous Linear Equations with Constant Coefficients
4.4
Undetermined CoefficientsSuperposition Approach
4.5
Undetermined CoefficientsAnnihilator Approach
4.6
Variation of Parameters
4.7
Cauchy-Euler Equation
4.8
Solving Systems of Linear DEs by Elimination
4.9
Nonlinear Differential Equations

5
MODELING WITH HIGHER-ORDER DIFFERENTIAL EQUATIONS
5.1
Linear Models: Initial-Value Problems
5.2
Linear Models: Boundary-Value Problems
5.3
Nonlinear Models

6
SERIES SOLUTIONS OF LINEAR EQUATIONS
6.1
Solutions About Ordinary Points
6.2
Solutions About Singular Points
6.3
Special Functions

7
THE LAPLACE TRANSFORM
7.1
Definition of the Laplace Transform
7.2
Inverse Transforms and Transforms of Derivatives
7.3
Operational Properties I
7.4
Operational Properties II
7.5
The Dirac Delta Function
7.6
Systems of Linear Differential Equations

8
SYSTEMS OF LINEAR FIRST-ORDER DIFFERENTIAL EQUATIONS
8.1
Preliminary TheoryLinear Systems
8.2
Homogeneous Linear Systems
8.3
Nonhomogeneous Linear Systems
8.4
Matrix Exponential

9
NUMERICAL SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS
9.1
Euler Methods and Error Analysis
9.2
Runge-Kutta Methods
9.3
Multistep Methods
9.4
Higher-Order Equations and Systems
9.5
Second-Order Boundary-Value Problems

10
PLANE AUTONOMOUS SYSTEMS
10.1
Autonomous Systems
10.2
Stability of Linear Systems
10.3
Linearization and Local Stability
10.4
Autonomous Systems as Mathematical Models

11
ORTHOGONAL FUNCTIONS AND FOURIER SERIES
11.1
Orthogonal Functions
11.2
Fourier Series
11.3
Fourier Cosine and Sine Series
11.4
Sturm-Liouville Problem
11.5
Bessel and Legendre Series

12
BOUNDARY-VALUE PROBLEMS IN RECTANGULAR COORDINATES
12.1
Separable Partial Differential Equations
12.2
Classical PDEs and Boundary-Value Problems
12.3
Heat Equation
12.4
Wave Equation
12.5
Laplaces Equation
12.6
Nonhomogeneous Boundary-Value Problems
12.7
Orthogonal Series Expansions
12.8
Higher-Dimensional Problems

13
BOUNDARY-VALUE PROBLEMS IN OTHER COORDINATE SYSTEMS
13.1
Polar Coordinates
13.2
Polar and Cylindrical Coordinates
13.3
Spherical Coordinates

14
INTEGRAL TRANSFORMS
14.1
Error Function
14.2
Laplace Transform
14.3
Fourier Integral
14.4
Fourier Transforms

15
NUMERICAL SOLUTIONS OF PARTIAL DIFFERENTIAL EQUATIONS
15.1
Laplaces Equation
15.2
Heat Equation
15.3
Wave Equation

Textbook Solutions for Differential Equations with Boundary-Value Problems

Chapter 1.3 Problem 27

Question

Reflecting Surface Assume that when the plane curve C shown in Figure 1.3.21 is revolved about the x-axis, it generates a surface of revolution with the property that all light rays L parallel to the x-axis striking the surface are reflected to a single point O (the origin). Use the fact that the angle of incidence is equal to the angle of reflection to determine a differential equation that describes the shape of the curve C. Such a curve C is important in applications ranging from construction of telescopes to satellite antennas, automobile headlights, and solar collectors. [Hint: Inspection of the figure shows that we can write 2. Why? Now use an appropriate trigonometric identity.]

Solution

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The first step in solving 1.3 problem number 27 trying to solve the problem we have to refer to the textbook question: Reflecting Surface Assume that when the plane curve C shown in Figure 1.3.21 is revolved about the x-axis, it generates a surface of revolution with the property that all light rays L parallel to the x-axis striking the surface are reflected to a single point O (the origin). Use the fact that the angle of incidence is equal to the angle of reflection to determine a differential equation that describes the shape of the curve C. Such a curve C is important in applications ranging from construction of telescopes to satellite antennas, automobile headlights, and solar collectors. [Hint: Inspection of the figure shows that we can write 2. Why? Now use an appropriate trigonometric identity.]
From the textbook chapter Differential Equations as Mathematical Models you will find a few key concepts needed to solve this.

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Title Differential Equations with Boundary-Value Problems 7 
Author Dennis G. Zill, Michael R. Cullen
ISBN 9780495108368

Reflecting Surface Assume that when the plane curve C shown in Figure 1.3.21 is revolved

Chapter 1.3 textbook questions

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