ModelCourses/Ordinary Differential Equations

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General Description

  • Sophomore or junior level course
  • Pre-requisite: Calculus


Possible textbooks include, but are not limited to:

  • Fundamentals of Differential Equations and Boundary Value Problems, by Nagle, Saff, and Snider, Addison-Wesley.
  • Elementary Differential Equations and Boundary Value Problems by Boyce and DiPrima, Wiley.

Course Objectives

Upon successful completion of this course, students will be able to:

  • Determine if a given function is a solution to a particular differential equation; apply the theorems for existence and uniqueness of solutions to differential equations appropriately;
  • Distinguish between
    (a) linear and non-linear differential equations;
    (b) ordinary and partial differential equations;
    (c) homogeneous and non-homogeneous differential equations;
  • Solve ordinary differential equations and systems of differential equations using:
    (a) Direct integration
    (b) Separation of variables
    (c) Reduction of order
    (d) Methods of undetermined coefficients and variation of parameters
    (e) Laplace transform methods
  • Determine particular solutions to differential equations with given initial conditions.
  • Analyze real-world problems such as motion of a falling body, compartmental analysis, free and forced vibrations, etc.; use analytic technique to develop a mathematical model, solve the mathematical model and interpret the mathematical results back into the context of the original problem.
  • Apply matrix techniques to solve systems of linear ordinary differential equations with constant coefficients.
  • Find the general solution for a first order, linear, constant coefficient, homogeneous system of differential equations; sketch and interpret phase plane diagrams for systems of differential equations.

Problem Sets

Use of Problem Sets

The problem sets were assembled to allow for personalization by individual faculty. The topics covered are fairly standard in an introductory Differential Equations course, but faculty can rearrange the topics and delete any sections they do not wish to cover, or wish to assess by other means. The names of the problem sets are meant to be descriptive and the learning objectives will help you evaluate if the set should be included or not.

Download the problem sets

A copy of the course can be found at at the MAA website
The course can be downloaded here <insert link>.

To use the files remove the .txt from the end. The .tgz can be added. This file can now be directly uploaded into your own course:

  • go to Filemanager
  • Upload the file
  • etc <provide enough detail to allow for easy installation by anyone>

Description of Problem Sets

Chapter 0 : Introduction

  • 01 : Solutions and Initial Value Problems
    Students will be able to:
    • Determine if a given function is a solution to a particular differential equation
    • Identify elements of a given solution to a differential equation
    • Model with differential equations
  • 02 : Classification of Differential Equations
    Students will be able to distinguish between:
    • linear and non-linear differential equations;
    • ordinary and partial differential equations;
    • homogeneous and non-homogeneous higher order differential equations


Chapter 1 : First-Order Equations Barb

  • 01 : Integrals as Solutions
    Students will be able to:
    • Solve simple first order differential equations by direct integration
    • Solve simple differential equations using their knowledge from Calculus
  • 02 : Separable Equations
    Students will be able to:
    • Identify separable equations;
    • Use separation of variables to find the general solution of separable equations;
    • Find the solution of initial value problems;
    • Find the constant solutions, if any, and appropriately use the initial condition;
    • Solve applications modeled by separable equations.
  • 03 : Linear Integrating Factors
    Students will be able to:
    • Identify first order linear equations;
    • Write a first order linear equation in standard form to be used with integrating factor;
    • Use the method of integrating factor to solve first order linear equations;
    • Solve applications of first order linear equations;
    • Identify the largest domain where the initial value problem first order linear equation has unique solution;
    • Solve applications modeled by first order linear equations.
  • 04 : Slope Fields and Equilibrium Solutions
    Students will be able to:
    • Match given direction fields (slope fields, vector fields) with given first-order differential equations
  • 05 : Exact Equations
    Students will be able to:
    • Identify exact equation by using the exactness test;
    • Apply the method for solving exact equations.
  • 06 : Substitution Techniques and Integrating Factors
    Students will be able to:
    • Use substitution techniques to solve certain types of equations such as Bernoulli and first order homogeneous;
    • Apply the method of integrating factor to transform equations into forms that are easily solvable, such as exact equations;
    • Identify and solve Bernoulli equation;
    • Identify and solve first order homogeneous equations.
  • 07 : Autonomous
    Students will be able to:
    • Match autonomous differential equations with a given phase line graphs;
    • Find bifurcation value(s) for given one-parameter family of autonomous equations.
  • 08 : Existence and Uniqueness Theorem
    Students will be able to:
    • Apply the theorem for existence and uniqueness of solutions to differential equations appropriately;
    • If necessary, re-write the first order equation in a form so the Existence and Uniqueness Theorem can be applied;
    • Determine the largest domain where a given first order differential equation has unique solution;
    • Check the sufficient conditions for a first order linear differential equation to have a unique solution about the initial value.
  • 09 : Euler's Method
    Students will be able to:
    • Estimate solutions to differential equations using Euler’s method;
    • Identify the impact of step size of the accuracy of estimated solutions;
    • Identify if the estimated solution is expected to be an overestimate or underestimate;
    • Estimate solutions using Improved Euler’s method.


Chapter 2 : Higher-Order Equations

  • 01 : Introduction to Linear
    Students will be able to:
    • Recognize higher-order linear equations.
    • Use the principle of superposition to write the general solution of a linear equation, given a basis of solutions.
    • Verify is a set of given solutions is linearly independent.
    • Compute the Wronskian associated with a set of solutions.
    • Derive the characteristic equation corresponding to a linear equation with constant coefficients.
  • 02 : Linear 2nd-Order Constant-Coefficient Homogeneous Equations
    Students will be able to:
    • Solve the auxiliary equation to create the fundamental set of solutions;
    • Recognize the type of general solution based on the roots of the auxiliary equation.
  • 03 : Linear Higher-Order Constant-Coefficient Homogeneous Equations
    Students will be able to:
    • Determine if a given set of functions is a fundamental set of solutions of a homogeneous higher order linear equation;
    • Solve the auxiliary equation to create the fundamental set of solutions;
    • Recognize the type of general solution based on the roots of the auxiliary equation (real, complex, repeated).
  • 04 : Free Mechanical Vibrations
    Students will be able to:
    • Create a differential equation model corresponding to a physical system.
    • Find the general solution of the equation and solve initial value problems.
    • Relate the solution to the physical system.
    • Classify systems as underdamped, overdamped or critically damped.
  • 05 : Nonhomogeneous Undetermined Coefficients
    Students will be able to:
    • Use the principle of superposition to find solutions of the nonhomogeneous equation;
    • Characterize the general solution of a nonhomogeneous equation;
    • Find a particular solution using the method of undertermined coefficients.
    • Solve initial value problems for nonhomogeneous coefficients.
  • 06 : Nonhomogeneous Variation of Parameters
    Students will be able to:
    • Use variation of parameters to find a particular solution of the nonhomogeneous equation.
  • 07 : Forcing Resonance
    Students will be able to:
    • Empty


Chapter 3 : Linear Systems

  • 01 : Intro to Systems
    Students will be able to:
    • understand basic language and concepts of linear algebra as applied to systems of differential equations.
  • 02 : Matrices
    Students will be able to:
    • convert a system of linear differential equations to its matrix representation
    • convert the matrix representation of a system of differential equations to a system
  • 03 : Linear Systems
    Students will be able to:
    • Analyse the stability of the system.
    • generalize ideas applicable to 2D systems to higher dimensions.
  • 04 : Eigenvalue Method
    Students will be able to:
    • solve a linear system using eigenvalues and eigenvectors
    • understand a geometric interpretation of eigenvectors
    • Analyse the stability of the system.
  • 05 : 2D Systems Vector Fields
    Students will be able to:
  • 06 : Second Order Systems Mass Spring Systems
    Students will be able to:
  • 07 : Repeated Eigenvalues
    Students will be able to:
    • solve a linear system using eigenvalues and eigenvectors when the eigenvalues are repeated
    • understand a geometric interpretation of eigenvectors when the eigenvalues are repeated
    • Analyse the stability of the system.
  • 08 : Complex Eigenvalues
    Students will be able to:
    • solve a linear system using eigenvalues and eigenvectors when the eigenvalues are complex
    • understand a geometric interpretation of eigenvectors when the eigenvalues are complex
    • Analyse the stability of the system.
  • 09 : Nonhomogeneous Systems
    Students will be able to:
    • Understand and apply the superposition principle.
    • Analyse the stability of a nonhomogeneous system and its equilbria.


Chapter 4 : Laplace Transforms (Andrew)

    • 01 : Laplace-transforms
      Students will be able to:
      • Determine whether or not a function has a Laplace transformation;
      • Find the Laplace transform of a function by integration;
      • Find the Laplace transform of a function using a table;
      • Identify the domain for the Laplace transform of a given function;
      • Find the inverse Laplace transform of a function using a table.
    • 02 : Shifts-and-IVPs
      Students will be able to:
      • Express piecewise functions using the Heaviside function;
      • Find the Laplace transform of a function which includes the Heaviside function;
      • Find the inverse Laplace transform of a shifted function;
      • Apply Laplace transformations to the solution of non-homogenous IVPs;
      • Apply Laplace transformations to the solution of an IVP with a piecewise non-homogeneous component. (may be moved to a new section dedicated to solving IVPs)
    • 03 : Partial-fractions
      Students will be able to:
      • Apply partial fraction decomposition to a rational function;
      • Find the inverse Laplace transformation of a rational function using partial fraction decomposition.
      • Apply Laplace transformation and partial fraction decomposition techniques in order to solve IVPs.
    • 04 : Periodic-functions
      Students will be able to:
      • Find the Laplace transform of a periodic piecewise function;
      • Construct and solve an IVP from a word-problem requiring a periodic piecewise function.
    • 06 : Convolution
      Students will be able to:
      • Find the convolution of two functions by direct integration;
      • Find the convolution of two functions using the Laplace transform and its inverse;
      • Solve IVPs that include convolutions.
      • Solve integral and integro-differential equations.
    • 07 :Delta-function
      Students will be able to:
      • Evaluate integrals involving the Delta function;
      • Solve IVPs that include the Delta function.

WeBWorK Workshop, Ann Arbor Michigan June 2013