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DIFFERENTIAL EQUATIONS MATH 2120 |
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Class
Hours: 3.0 |
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Credit
Hours: 3.0 |
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Laboratory
Hours: 0.0 |
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Date
Revised: Fall 08 |
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Catalog
Course Description: |
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A
first course in differential equations emphasizing solution techniques.
Includes first-order equations and applications, theory of linear equations,
basic second-order equations and applications, |
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Entry
Level Standards: |
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Proficiency
in the evaluation and application of both differentiation and integration of
algebraic, trigonometric, exponential, and logarithmic functions is necessary
for entrance to this course. |
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Prerequisites: |
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MATH
1920 |
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Textbook(s)
and Other Reference Materials Basic to the Course: |
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Textbook: Farlow, Stanley J. Differential Equations and Their
Applications. McGraw-Hill, Inc., 1994. Personal Equipment:
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I.
Week/Unit/Topic Basis: |
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Week |
Topic |
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1 |
Definitions and Terminology, Initial-value
Problems, Direction Fields; 1.1-1.3 |
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2 |
Euler’s Method, Phase Portraits, Introduction
to Motion of a Falling Body, Separable
Equations; 1.4, 2.1-2.2 |
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3 |
Linear
Equations, Exact Equations, Substitutions
and Transformations; 2.3, 2.4, 2.6 |
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4 |
Compartmental Analysis; 3.2 |
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5 |
Heating
and Cooling, Newtonian Mechanics; 3.3, 3.4 |
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6 |
Improved
Euler’s Method; 3.6 |
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7 |
Homogeneous
Linear Equations with Constant Coefficients, Auxiliary Equations with Complex
Roots, Method of Undetermined Coefficients; 4.2 – 4.4 |
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8 |
Superposition
and Nonhomogeneous
Equations Variation of Parameters, Reduction
of Order; 4.5 - 4.7 |
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9 |
Interconnected
Fluid Tanks, Elimination Method for Systems; 5.1, 5.2 |
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10 |
Definition
of |
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11 |
Properties
of The Laplace Transform, Inverse |
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12 |
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13 |
Power
Series, Analytic Functions, and the Taylor Series Method, Power Series
Solutions to Linear Differential Equations; 8.1 – 8.3 |
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14 |
Review
for Last Chapter Test and Final Exam |
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15 |
Final
Exam |
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II.
Course Objectives*: |
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A. |
Gain a working knowledge of first- and second-order differential equations and their solutions. VI.2,3,4,5,6 |
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B. |
Apply the concepts of differential equations to suitable mathematical models. VI.2,3,4,5,6 |
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C. |
Scrutinize solution techniques comparatively (graphical, numerical, symbolic, transforms, etc.). VI.2,3,4,5,6 |
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*Roman
numerals after course objectives reference TBR’s
general education goals. |
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III. Instructional Processes*: Students
will: |
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1. |
Employ
graphing calculators and/or computer software as tools for the field of
study. Technological Literacy Outcome |
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2. |
Advance
their skills in analysis, synthesis, symbol manipulation, graphical
conceptualization and technical writing skills using the work and/or projects
assigned. Mathematics Outcome, Numerical Literacy Outcome,
Communication Outcome, Transitional Strategy |
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3. |
Analyze
real life problems such as: using first order differential equations to
construct compartmental analysis, to investigate Newtonian mechanics models
as well as heating and cooling models, and to analyze population
growth. In addition, second order differential equations would be used
to explain mechanical vibration, spring/pendulum, harmonic motion and forced
oscillation models. Mathematics Outcome, Transitional Strategy |
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4. |
Actively
engage in student-led discussions and brainstorming sessions about the
mathematical/physics based models inherent to the course. Active
Learning Strategies, Transitional Strategies |
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5. |
Investigate
and justify the engineering concepts contained in fields of dynamics and
circuit analysis. Mathematics Outcome, Transitional Strategy |
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*Strategies and outcomes listed after instructional
processes reference TBR's goals for strengthening
general education knowledge and skills, connecting coursework to experiences
beyond the classroom, and encouraging students to take active and responsible
roles in the educational process. |
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IV. Expectations for Student Performance*: |
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Upon successful completion of this course, the student
should be able to: |
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1 |
Solve "separable", "exact",
"integrating factor" and "Bernoulli" first order
differential equations symbolically. A |
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2 |
Apply first order differential equations solution
techniques to mathematical models (including: population, heating/cooling,
compartmental analysis, Newtonian mechanics, terminal velocity, and logistic
models). B |
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3 |
Define the numerical solutions (Euler's Method) to first
order differential equations. C |
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4 |
Illustrate familiarity with graphical solutions to first
order differential equations using direction fields. C |
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5 |
Determine the best method (graphically, numerically, or
symbolically) of solving first order differential equations. C |
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6 |
Calculate general and particular solutions to second
order linear homogeneous and nonhomogeneous
equations with constant coefficients (using "auxiliary equations",
"undetermined coefficients" and "variation of parameters"
techniques). A |
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7 |
Apply second order differential equation solution
techniques to mathematical models (including compartmental, mechanical
vibration, spring and pendulum models) B |
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8 |
Analyze the behavior of the second order solutions for
ordinary differential equations. A |
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9 |
Use |
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10 |
Find solutions to systems of differential equations
using |
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Determine series solutions ( |
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*Letters after performance expectations reference the
course objectives listed above. |
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V. Evaluation: |
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A. Testing Procedures: |
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Students are evaluated primarily on the basis of tests,
quizzes, homework, and the comprehensive final exam. A minimum of 4
major tests and the comprehensive is recommended. |
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B. Laboratory Expectations: N/A |
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C. Field Work: N/A |
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D. Other Evaluation Methods: N/A |
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E. Grading Scale: |
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93 -
100 A |
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VI. Policies: |
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A. Attendance Policy: |
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B. Academic Dishonesty: |
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Cheating, including but not limited to unauthorized assistance from material, people, or devices when taking a test, quiz, or examination; writing papers or reports; solving problems; or completing academic assignments. In addition to other possible disciplinary sanctions
that may be imposed as a result of academic misconduct, the instructor has
the authority to assign either (1) an F or zero for the assignment or (2) an
F for the course. |
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C. Accommodations for Disabilities: |
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If you need accommodations because of a disability, if
you have emergency medical information to share, or if you need special
arrangements in case the building must be evacuated, please inform the
instructor immediately. Please see the instructor privately after class or in
his/her office. Students must present a current accommodation plan from a
staff member in Services for Students with Disabilities (SSWD) in order to
receive accommodations in this course. Services for Students with
Disabilities may be contacted by going to Goins 127
or 131 or by phone: 694-6751(Voice/TTY) or 539-7153. |
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D. Make-up work: |
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Instructor discretion about make-up tests and/or
assignments. |
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E. Cell phones: |
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Cell phones are to be either turned off or put on
vibration mode while in class. Instructor discretion as to
penalty. |
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