MTE 564 - Quantitative Reasoning

 

Course Instructors:        Dr. Kimberly Childs, childs@math.sfasu.edu

                                                Dr. Jasper Adams, adams@math.sfasu.edu

 

Course Facilitators/Mentors:

                                                Dr. Lesa Beverly, lbeverly@math.uttyl.edu

                                                Ms. Jennie Freeman, jfree@lufkinisd.org

                                                Ms. Mary Ann Williford, mawilliford@hotmail.com

 

Office:                                NM 304, (936) 468-3805

                                                Ms. Linda Boozer, Dept Secretary

boozer@math.sfasu.edu

 

Textbooks:  Van DeWalle, John A. (2001). Elementary and Middle School

Mathematics:  Teaching Developmentally. New York, N.Y.: Addison Wesley Longman.

Long, Calvin T. & DeTemple, Duane W. (2000).  Mathematical

Reasoning for Elementary Teachers.  New York, N.Y.:  Addison Wesley Longman.

Bassarear, Tom (2001).  Mathematics for Elementary Teachers (with

Explorations manual). Boston, MA.:  Houghton Mifflin.

 

Course Description: Elementary concepts of patterns, number theory, and properties of the natural numbers, integers, rational, and real number systems with an emphasis on problem solving and critical thinking.

 

Course Goals and Objectives:  The goal of Quantitative Reasoning is to investigate mathematics content and pedagogy necessary for teaching mathematics in grades 4-8 in such a way as to engage students in mathematical thinking and discourse which allows for construction of concepts, algorithms, and problem solving. Course content, goals, and objectives are consistent with the NCTM Principles and Standards for School Mathematics, the SBEC Standards, and with the Texas Essential Knowledge and Skills.

 

Specific goals and objectives include:

 

• To become a more efficient problem solver
• To learn concepts underlying algorithmic procedures
• To become a better communicator of knowledge and experiences by regularly justifying ideas verbally, concretely, and in writing.
• To develop appropriate language and notation over time
• To learn to value mathematics and to teach mathematics using multiple methods of presentation and assessment.

 

Course Evaluation

 

• Reflective Journal (10%)

 

At the end of each class cycle send an electronic journal entry to your mentor reacting to the class activities and summarizing the readings including :

• The major things you learned
• How the learning relates to SBEC and NCTM Standards, and TEKS
• Questions you have

 

• Assigned Work (30%)

 

This includes maintaining a notebook of all class activities along with your participation in on-line discussions, chat, homework problems, take-home tests/projects, and reading quizzes.

 

• Presentations (10%)

 

• Lesson Sequence (20%)

 

Design a sequence of lesson plans for a grade level and content area you are teaching.  On a cover sheet describe your rationale for selecting the content area and how it relates to course objectives, SBEC and NCTM Standards, and TEKS.

 

• Final Exam (30%)

 

The final exam will be based on course readings, activities and notes you have taken during the semester.  It will measure how well you have met course objectives.

 

Course Syllabus

 

Class:  January 18 - 19

 

·        Exploring Patterns

o       Develop Understanding in Mathematics

o       Introduce Polya’s Problem Solving Process:  Understanding the Problem, Devise a Plan, Carry Out Plan, Look Back

o       Explore Basic Problem Solving Strategies

o       Explore Patterns in Language, Figures, Numbers, and Geometry;  Sequences, including Arithmetic and Geometric

o       Develop A Model for Mathematical Reasoning

o       Describe Patterns using Multiple Formats: Recursive and Closed Form Rules

 

 

Class:  February 8 - 9

 

·        Number Theory/ Mental Math

o       Explore Primes and Composites using Geometry Connections

o       Generate Prime Numbers using the Sieve of Eratosthenes

o       Explore Basic Divisibility Properties of Sums and Products

o       Explore Applications of the Fundamental Theorem of Arithmetic

o       Define the GCD and LCM

o       Explore Algorithms for Finding the GCD and LCM

o       Explore Applications of the GCD and LCM

o       Explore Estimation and Mental Arithmetic Techniques

 

 

Class:  March 1 - 2

 

·        Integers/ Fractions

o       Model Integer Operations Using a Variety of Methods

o       Develop Fraction Models

o       Develop Fraction Number Sense and Equivalent Forms

o       Investigate Extensions of Whole Number Operations and Their Properties: Additive Inverse; Closed, Commutative, Associative, Distributive- Multiplication Over Addition, Identities, Additive Inverse, Multiplication By Zero to Integers and Fractions

o       Explore Absolute Value

o       Explore Connections Between Fractions, Rational Numbers, Decimals, and Percents and Application to Real-world Problems

 

 

Class:  April 5 - 6

 

·        Proportional Thinking

o       Develop Decimal and Percent Number Sense and Connect to Real-world applications

o       Make Appropriate Connections to Probability

o       Develop and Justify Methods for Solving Using Proportions

o       Make Appropriate Connections to Algebra

o       Investigate Practical Uses for Fractions

o       Explore Proportional Thinking as a Habit of Mind