The Quantitative Reasoning Requirement at UMass Boston

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The Quantitative Reasoning Requirement at UMass Boston. Maura Mast, Associate Professor of Mathematics Mark Pawlak, Director, Academic Support Programs University of Massachusetts Boston. Urban mission: to provide a low-cost education to the people of the greater Boston area. - PowerPoint PPT Presentation

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<ul><li><p>The Quantitative Reasoning Requirement at UMass Boston Maura Mast, Associate Professor of Mathematics </p><p> Mark Pawlak, Director, Academic Support ProgramsUniversity of Massachusetts Boston</p></li><li><p>The University of Massachusetts BostonUrban mission: to provide a low-cost education to the people of the greater Boston area.Many students are low-income and the first in their family to attend college.The majority of students are older: mean age is 27; median age is 24.One-third of students are from minority groups.Many transfer students.There are no dorms - it is truly a commuter campus.</p></li><li><p>Why does UMass Boston need a Quantitative Reasoning course?Until a few years ago, students could graduate without taking a course emphasizing quantitative reasoning or mathematics.Those who did take a math course often took Basic Algebra (actually, high school algebra!).Basic Algebra was a traditional, usually terminal, course with an unacceptably high failure rate.Were students really prepared for higher-level courses and the workplace? Feedback indicated they were not.</p></li><li><p>The Math/QR requirement Part of our new general education program. All students must demonstrate competence in mathematics/quantitative reasoning. B.S. students must take Calculus I (a traditional Calculus course) B.A. students have several choices: Test into PreCalculus or Calculus Take College Algebra or Statistics Take a Quantitative Reasoning course</p><p>Each semester, approximately 200 - 250 students choose to take a QR course.</p></li><li><p>How do we define a QR course?Required topics are:descriptive statisticslinear modelsexponential models or probabilityuse of technology (graphing calculators, computers)Students must:engage in critical reading and analysisspeak, listen and write effectivelyuse technology to further learningwork independently and collaborativelyreason logically and quantitatively</p></li><li><p>Math Q114 - Quantitative ReasoningCurrently, Mathematics offers the primary QR courseThis is the lowest-level course Math offersPrerequisite: (outdated) placement testAll sections are taught in a Mac computer labClass size is small - about 20 studentsMany students come out of developmental math courses and are math phobic; have weak skills; hate mathAll topics are motivated using real data, course follows an investigations pedagogyTechnology is used as a tool and as way of seeing patterns.</p></li><li><p>Reading graphs and tables: Population Pyramids Describe 2 similarities and 2 differences between the populations. Be sure to refer to specific elements in the histograms that support your points of comparison. Identify the main feature that distinguishes the populations of these two countries. Answer in complete sentences.</p></li><li><p>Group project: lying with dataStudents work in groups, using UMass student data to argue opposite sides of a given issue.They organize presentations to be made to classEach individual student turns in a summary analyzing one aspect of the data.Peer-grading is used for this exercise.Example: Group 1: You are a student activist trying to convince the Board of Trustees that they have not done enough to increase diversity on campus. Group 2: You are the Affirmative Action Officer arguing that your office has done a good job of increasing the diversity of the student body.</p></li><li><p>Using data sets to teach rate of changeLinear growth is introduced using rate of change. We use lots of examples, some with constant rate of change and most where rate of change is not constant. For example, compare the graph of the federal debt to the rate of change graph. What additional information does the rate of change graph give us?</p></li><li><p>Examples of number senseFrom an article in The Boston Globe: Two people put their son through four years of college at Harvard University by collecting soda cans. Is this possible? What assumptions do you need to make to answer this?Are you 1000 seconds old? A million seconds old? A billion seconds old? How about a trillion seconds old?</p></li><li><p>Exponential Growth and DecayWe introduce the concepts here using different data sets and situations. Students are now quite comfortable using Excel to graph and to find rate of change. The approach is to use Excel to find patterns, and from those patterns construct the exponential function.As with the other topics, we push students to analyze and interpret what they see.</p></li><li><p>Some conclusions from recent assessmentOver 60% of students rated group work as effective (14% said it was very effective)56% reported an improved ability to draw conclusions from data sets, with 31% reporting much improved abilityApproximately 15% of students were already using QR-related skills in their other classes or in their employment.72% of students agreed that they now read articles containing data, charts or graphs more critically.</p></li><li><p>Challenges to teaching the courseIt can be difficult to use the computers in a meaningful way every dayNot all students have computers (especially Macs) or internet access at homeThe computers can be a distraction, both because of their size and because of the easy access to the internetIt has been difficult to recruit, train, and support instructors to teach this type of courseIt is difficult to find tutors with knowledge of the software, knowledge of the math, and ability to do quantitative reasoningThe balance between algebra and QR/QL is challenging</p></li><li><p>Larger challengesIs it better to teach traditional mathematics, or should resources be focused on teaching quantitative reasoning?Is QR just watered-down mathematics?Is it appropriate to call this a Math course?Should we focus more on numeracy and less on the traditional mathematics topics?How can we integrate the QR material and principles into other courses in other departments?</p></li><li><p>Why this is a good courseStudents really learn by doing. It is very hands on and exploration-basedWe use real data that is relevant to the studentsThe students like the applications and they like the idea that they have learned how math is usefulIt gives many students a positive experience of mathematics. They may not like mathematics, but they feel that they dont hate it as much!</p></li><li><p>Some student responses I loved it and feel almost a sense of regret that it wasn't just a little bit longer... Math came alive from the very first class. It became clear to me that without realizing it before, I was engaged in mathematical concepts on a daily basis. I am convinced that the concepts, topics and skills learned in this class will be extremely useful in my future studies and/or career, as well as in my life. Nowadays, when I see a chart of a graph in a book or newspaper I go looking "beyond" the numbers and try to come up with my own interpretation of the data. Before (this course), I hated math. But after taking this course, I feel much more comfortable with difficult math problems. I feel I now have a better understanding of the basics of mathematics. This course dealt with some real life problems, which make it interesting as well as useful. I have most definitely learned things that will be useful to me in the future.</p><p>Students had to take courses in certain distribution areas; by taking a foreign language, they could avoid math.</p><p>The lowest level for-credit math course, and really the only one available to all students, was a basic algebra course. We had no liberal arts math - statistics was the only other general course available. We advertised the algebra course as high school algebra, which it was.</p><p>Of course, it was a very mechanical skill &amp; drill type course with a high failure/drop out rate - pretty standard for that type of course, unfortunatelyWho teaches the course? Its a mix of regular math faculty (very few), part-timers from Math and Philosophy, and faculty from Academic Support programs.This is not an easy course to teach, partially because of the material and partially because of the technology. Teaching in a computer lab is a real challenge. I feel that I have to use the computers every day, to kind of justify them. If I dont, students will use them anyway, to surf the net or do e-mail or work on other projects</p><p>Some students are very very scared of the computer. In a way this is good, because it shifts their focus away from their fears of math toward a fear of something else. Still, it can really slow down the class if you continually have to stop to help one student do some basic cutting and pasting.</p><p>Group work is a real key to making progress in this course. Students can help each other, and they gain confidence by explaining ideas and techniques to others. It also helps the students from feeling isolated, from feeling that they are the only ones who dont understand what is going on.</p><p>Many students have PCs, and they resent using the Mac. A particular problem is that the Macs come with zip drives, not floppy drives, so students cannot easily transfer data to use at home. We do show them how to e-mail attachments, but that is not a perfect solution</p><p>Finally, its hard to get people to help this course be a success. Many math faculty are used to teaching a traditional math course, and are not interested in teaching writing and reasoning and so on (which they view with suspicion as not being math anyway); even if they do agree to teach it, they need to sit in on someone elses section to see how the course is taught and how the technology is used. Similarly, its a challenge to find tutors. We have had the most success with math ed students.This is one of the big issues on college campuses, as faculty members struggle to determine how best to implement a QL requirement. Should all students take a math course, or are they better off taking a QL course? How much mathematics should be in a QL course? Is the mathematics at such a low level that this is not really a college course? By its nature, mathematics builds upward, with the pattern that each subject depends heavily on previously learned knowledge. QL spirals outward, incorporating increasingly larger circles of information and situations as we get deeper into it. </p><p>The course is very much a practice and learn type of course. By the consistent use of data sets to introduce and reinforce material, students really see patterns and have a chance to practice and explore with little effort</p><p>We can use very relevant data - for ex., Census Bureau median income data; data about UMass students and their SAT scores; population growth data; etc.</p><p>By focusing on applications, we give some relevance to the material. Again, that shifts the focus away from the math-only focus and makes it easier for some students to grasp the concepts. Also, students see the concepts concretely - how the rate of change affects growth, for example - and this reinforces the ideas. I have students write an end-of-semester reflection about what they have learned and what progress they have made. One student wrote I dont hate math anymore - to me, that is a success!</p></li></ul>