Nov 25, 2024  
2023-2024 Catalog & Student Handbook 
    
2023-2024 Catalog & Student Handbook Archived Catalog

MATH 2120 - Differential Equations

3 sem hrs cr

This course is a study of ordinary differential equations with applications, numerical solutions, power series, and LaPlace transforms. Prerequisite: MATH 1920  

In rare and unusual circumstances, a course prerequisite can be overridden with the permission of the Department Lead for the discipline.

Formerly/Same As (Formerly MAT 2730)

Transfer (UT) or Non-Transfer Course (UN): UT


Master Course Syllabus
Course Outcomes

The goals of instruction in this course are to…

  • fulfill the math requirement for pre-engineering, physics, and math majors.
  • summarize and review integration techniques from calculus.
  • introduce methods for solving linear differential equations.
  • introduce methods for solving selected higher-order differential equations.
  • use methods of solution of differential equations to solve application problems related to other areas such as physics, chemistry, and biology.
  • provide a course that will require students to apply math knowledge acquired in calculus- and pre-calculus-level courses.

Course Objectives

Through the course, students will have the opportunity to…

  • review integration, including the following techniques:
    • integration involving exponential and trigonometric functions;
    • integration by parts;
    • integration by substitution; and
    • integration by partial fractions.
  • classify differential equations by type, order, and degree.
  • verify that a given equation is a solution to a differential equation.
  • solve initial-value problems.
  • find regions of possible solutions to initial-value problems.
  • understand how differential equations arise in applications.
  • understand how graphs represent solutions of differential equations.
  • solve differential equations using separation of variables.
  • recognize and solve first order linear differential equations using integrating factors.
  • recognize and solve exact differential equations.
  • recognize and solve homogeneous differential equations using the substitutions y=ux and u=vy.
  • solve Bernoulli equations.
  • understand and use Euler’s Method to solve initial-value problems.
  • solve rate of growth/decay, mixture, series circuit and Newton’s Law of Cooling problems using methods of differential equations.
  • solve population logistic and second order chemical reaction problems (optional).
  • understand basic theory of higher order linear equations, including boundary value problems, homogeneous and non-homogeneous equations, and the differential operator.
  • determine whether solutions to differential equations are dependent or independent using Wronskians.
  • construct a second solution from a known solution using reduction of order.
  • solve higher order homogeneous linear differential equations with constant coefficients using auxiliary equations.
  • find the annihilator for polynomial, exponential, and trigonometric functions (optional).
  • solve differential equations using the method of undetermined coefficients (this can be done with either the superposition approach or the annihilator approach).
  • solve differential equations using variation of parameters.