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Introduction to the Mathematical Sciences

Explore the origin, features, and content of a unique math course covering algebra, statistics, and computer science, designed for seamless transition between high school and college. Discover how students benefit from practical application, reduced homework, and collaborative learning.

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Introduction to the Mathematical Sciences

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  1. Introduction to the Mathematical Sciences Glen Richgels Bemidji State University grichgels@bemidjistate.edu http://faculty.bemidjistate.edu/grichgels/ Amber Severson Anoka Ramsey Community College Cambridge Campus Amber.severson@anokaramsey.edu

  2. Origin of the course • Transition between HS and college mathematics • Researched 24 departments at Bemidji State University • Collaboration of 6 members of the mathematics and computer science department at BSU • Course content 1/3 algebra, 1/3 statistics, 1/3 computer science – use of excel as the computational device not a calculator

  3. Features of the course • 3 days per week for 2 hours per day – 6 hours of face to face contact per week – 90 instructional hours in the semester • Student access to computer, and calculator if they have one, at all times • Reduced homework because of the type of students that choose this class: not great math ability, busy, other choices other than math at night for homework, chooses non-traditional math sequence

  4. Features of the course • Introduce a little work and a little practice; not lecture for an hour, work for an hour • Multiple representations • Problem solving / contextual settings based • Student presentations expected

  5. Course ContentAlgebra Topics • Functions • Represented by formula, table, graph, words • Graphical and Tabular Analysis • Tables and trends • Graphs • Solving linear equations • Solving nonlinear equations • Optimization • Linear Functions • The geometry of lines • Linear Functions • Modeling data with linear functions • Linear regression • System of equations • Rates of Change • Velocity • Rates of change of other functions

  6. Course ContentStatistics Topics • Collecting and displaying data • Types of data • Creating data files in spread sheets • Displaying data in tabular format • Bar charts, histograms, pie charts, box plots, scatter plots • Populations and samples • Measures of central tendency • Sample mean, median, and mode • Measures of dispersion • Sample range, standard deviation, and inter quartile range • Shapes of distributions • Skewness, symmetry, and modality • Correlation and association • Introduction to linear regression

  7. Course Content Computer Science Topics • Syntax and Semantics • Understanding Processes • Describing processes used to solve specific problem • Generalizing processes to solve general problem • Converting processes into computer solutions • The notion of a “variable” in computing • Variable names, references, and values • Formulas and expressions • Operations, evaluation order, results, and errors • Making decisions • Logical and rational operators and their values • Conditional syntax • Conditional semantics • Using functions • Function syntax and semantics.

  8. Educational Partners • Partners: • Bagley High School • Bemidji High School • Cass Lake-Bena High School • Clearbrook-Gonvick High School • Fairmont High School • Floodwood High School • Grand Rapids High School • Thief River Falls High School • Win-E-Mac High School • Northwest Technical College • Northland Community and Technical College • White Earth Tribal and Community College • Red Lake Nation College • Red Lake Head Start instructors and pre-service instructorsl

  9. Findings • Approximately 40% of high school teachers surveyed believed that statistics will be a part of their student’ careers • Over 80% of high school students believe that statistics will be a part of their careers • A study of BSU graduates over a 5 year period of time found that ~12% needed calculus to graduate while ~77% needed at least one statistics class to graduate • The average cooperating teacher had no statistical intuitions prior to teaching this course • The average student, high school or post secondary, had no statistical intuitions prior to taking this course

  10. Findings • This course can’t fix attendance problems. • This course can’t fix students who do not try. • This course can help low achieving students • This course can help high achieving students

  11. Findings • With a few minor exceptions, all partners found statistically significant gains in student learning in algebra, statistics, cs – use of excel • Some 2-year institutions have found it to be a better pre-requisite than college algebra • Many HS are using this with their students who are not in the top 50% of their graduating class

  12. Findings • Some HS have supplemented this course to help with the remediation of HS seniors – and it has worked • Some HS have found that special needs students can succeed in the class • Some HS have found that student attitude toward math changes to positive • Some post-secondary students take more math because of this course

  13. Implementation • Initially we worked on grant funds with limited locations on a weekly basis • We found that a three week Stats class prepared teachers to teach the course with few problems • We are working with locations at a distance with weekly to monthly correspondence • We are willing to try many implementation models

  14. Pedagogy in I2MS • Teachers can be convinced that teaching the way students learn, rather than the way math was taught in traditional textbooks and curricula, works better. This may sound obvious to the reader, but is not the way mathematics is taught at most institutions.

  15. Teachers need good instruction modeled for them and need long-term support in their professional development to see sustained gains in their student achievement. • Contextual learning gives relevance to topics. There is a reason for learning math and teachers need to be able to convey this to their students in a meaningful way, not just give it “lip-service.”

  16. Group work helps all students. The best students do not lose ground interacting with lower achieving students and the lower achieving students make bigger gains than if they worked in isolation. • Students have completely learned a concept when they are able to present the concept to their peers in their own words. That is why Drs. Webb and Richgels stress student presentations, both individually and in groups, in their classroom pedagogy.

  17. Practicing skills, exploring concepts, and presenting what students have learned during a class-period instead of at the end of the period keeps students engaged all hour. Many teachers have students do homework or worksheets most of a class period which results in low student engagement and boredom.

  18. A critical pedagogical change most teachers need to enact is to assign fewer, richer, more valuable homework problems. Fewer homework problems resulting in greater learning seems counterintuitive to most parents and teachers. But, student interest and success increases and this results in greater learning.

  19. Students need to be made aware of the fact that most problems have multiple solution paths. Too many teachers present one solution path and students come to believe it is the only correct (or “most correct”) solution path. Students need to gain confidence in finding solutions to problems that make sense to them and are based on their particular skill sets. This topic of multiple solution paths should not be ignored because teachers say: “there is not enough time to present multiple solution paths because we won’t get through all the material.” This is not true. Multiple representations of problems is a must. This helps students see connections between the concrete and the abstract and helps them formulate models, pictures, and representations to help them solve problems.

  20. The use of dynamic software tools helps students see what happens instantaneously when changes are made. Programs such as Microsoft Excel, Geometers Sketchpad, Fathom, and Tinkerplots are examples of such programs. They are also better suited for learning than the conventional graphing calculator most mathematics teachers still cling to. Drs. Webb and Richgels advocate for using technology in the classroom that enhances student learning, not for using technology with which teachers are comfortable.

  21. Access to the internet re-enforces the fact that math is real, useful, and contemporary. It also helps develop independent student learning, gives students tools and skills for researching problems, and student confidence in that they can solve problems on their own. Drs. Webb and Richgels strongly advocate for curricula that makes use of the internet.

  22. Students are more important than course content. There is a need to develop a relationship with the students that demonstrates to them that the teacher is there to help them learn difficult material, and not just present it and abandon them

  23. Skills are important. Drs Webb and Richgels have learned that a teacher cannot fix bad foundational skills while practicing new or extending skills. Students can fix their foundational skills if the basics are reviewed briefly (day to day) in a short period of time. These skills need to be approached as long term development and maintenance skills. This is not how traditional texts deal with skills. A child can be taught how to dribble a basketball at one time. But proficiency develops with daily practice over time.

  24. Primary Contacts • Glen Richgels • grichgels@bemidjistate.edu • 1-218-755-2824 • http://faculty.bemidjistate.edu/grichgels/ • Derek Webb • dwebb@bemidjistate.edu • 1-218-755-2846 • http://faculty.bemidjistate.edu/dwebb/

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