Sunday, June 30, 2013

The Curse of Rote Teaching [PEMDAS & its Siblings]

An excellent question was raised in the Global Math Department bulletin board that I decided to elaborate upon in here.

Rote teaching of certain mathematical rules and the lack of understanding of their underlying concepts lead to difficulties that students will continue to struggle with even at higher level courses such Precalculus, College Algebra, and even Calculus. These difficulties manifest themselves in what I have called MBs in an earlier post

In this post, I will address an MB related to PEMDAS. So, what to make of a student's treatment of let's say 4-6(3x+1) the same way as -2(3x+1)? And, generally how do we disrupt the misconception inertia that PEMDAS and its siblings of rote-taught mathematical rules engender within our students?

1) Geometry, Geometry, & Geometry: I am a firm believer that Geometry should be used as extensively as possible to enable our students grasp algebraic concepts better and at a deeper level for geometric, graphical, and pictorial representations offer visual clues and cues that facilitate students' understanding of abstract concepts of Algebra and other mathematical fields. So, have the students predict the nature of the graphs associated with the above two expressions and then have them execute the actual graphing processes either by hand or with a graphing technology tool (to add potential "What if?" investigations afterwards.) 



Once the above tasks are completed, one must ask the students to interpret the outcomes, reflect upon them, and tie them to other math concepts (such as translation, scaling, and meaning of slopes to mention a few) to complete the learning cycle. What other geometric tools have you used to aid your students' understanding of mathematical concepts?

2) Carefully crafted assessment items can also aid our students in confronting their misconceptions and try to sort out the difficulties therein until they get a strong handle on the underlying concepts. Following is such an assessment item.


*** Start of Assessment Item ***


PEMDAS refers to the concept of order of operations. Four students argued about how PEMDAS should be carried out when evaluating mathematical expressions. To find the answer to "1 – 10 ÷ 5 ∙ 2 + 44 = x, what is x?" the students used the four different steps shown below. Which of the four solutions steps do you agree with and why? Make sure you state how the student of your choice must have interpreted PEMDAS based on his/her solution steps.

Student 1 Solution: 1 – 10 ÷ 5 ∙ 2 + 44 = 45 – 10 ÷ 5 ∙ 2 = 35 ÷ 5 ∙ 2 = 7 ∙ 2 = 14
Student 2 Solution: 1 – 10 ÷ 5 ∙ 2 + 44 = -9 ÷ 10 + 44 = -0.9 + 44 = 43.1
Student 3 Solution: 1 – 10 ÷ 5 ∙ 2 + 44 = 1 – 2 ∙ 2 + 44 = 1 – 4 + 44 = 41
Student 4 Solution: 1 – 10 ÷ 5 ∙ 2 + 44 = 1 – 10 ÷ 10 + 44 = 1 – 1 + 44 = 44


*** End of Assessment Item ***



With such assessment items both the student as well as the instructor would have a better idea as to what to address conceptually speaking based on the problem-solver's answer choice. In the comments area, please, provide your own assessment examples of how you address specific students' misconceptions.


3) One day one of my children came home ecstatic that he learned the four geographical directions (NESW) through a chant. Unfortunately, the whole chant hinged on knowing where the first direction is supposed to be to proceed with the rest. So, when I asked him about a specific direction, he was at loss for he was not sure what direction he should point for the first direction in the chant. So, it was time for us to go through a brief on the field (both during day light and night time) conceptual encounter with the Astronomy of orienting oneself in space and toss the cute chant in the bin of seeming handy but useless methods of sponging in information.

Share your own anecdotes of such missed opportunities in learning because of "cute" rote teaching approaches. Thank you


Sunday, June 16, 2013

What is math?

"What is math?" is an essential question a la Grant Wiggins for it is an open ended question that does not have a single answer, it definitely is ageless, it elicits different answers from different people, and it encourages deep thinking, and it may even arouse passions especially in our country where math and Physix tend to charge the air during conversations.

It is imperative that our students address this question to establish the kind of frame of mind that we ask of them and assist them to approach math more as we and math experts/practitioners approach the subject.

So, I start each semester (year) with a Critical Thinking Activity (CTA) that asks this very question and guides the students through a sequence of math problems that I adopted from RonRitchhart's PZC*2009: Views on Understanding (pg. 79). The key parts of the activity are listed below.  

*** Start of Sample Items from the CTA  ***


1) What is math? What does it mean to you?

2) List the 7 mathematical words/phrases that come to your mind when doing math.

...

13) Now that you have completed this activity, complete these last two tasks:

a) What do you think math is? 


b) List 7 mathematical words/phrases that the above activity suggests to your mind.



*** End of Sample Items from the CTA ***

The new background that I adopted for this blog is a picture of my old blackboard (click here to view the full image) with my students' lists of mathematical phrases pre/activity (item 2 above) and post/activity (item 13b above).

The list on the right side of the board clearly demonstrates that students' perception of what math is all about has evolved and all one hopes is that they would carry this new frame of mind for the remainder of the semester (year).

Share what you do in the first few days of classes to guide your students toward a renewed look at what math is. Thank you

Wednesday, June 12, 2013

Hip hip hooray for the Global Math Department!

I am both proud and honored to have joined the Global Math Department community yesterday. In addition, I spent a cool hour attending my first web conference with this cool group. The topic was Interactive Notebooks (IN) and it was facilitated by a panel consisting of @rawrdimus (Jonathan Claydon) @jacehan (James Cleveland) @mgolding (Megan Hayes-Golding). 

Kudos to the panel members and to the rest of the members who attended, I enjoyed the session and took good practices involving IN from it. Implementation time!  

What impressed me the most about yesterdays experience is the fact that this group of dedicated teachers who have to deal with 150 students on average each year manage to go out of their way to not only make math as accessible and as fun as possible for their students but also squeeze enough precious time of their respective busy schedules to share their excellent teaching ideas with their peers. Wow! I am humbled, tickled, and above all grateful that there are such high caliber math teachers in our country. 


Whoever complains about education in our country suffering from decadence and decline should look no further than what these dedicated teachers at Global Math Department and others like them (see Cool Sites on the side bar for a sample) practice with our students to realize that we are on the right track as a nation (math-wise at least). Just encourage a lot of cross pollination between such colleagues and any aspiring teachers or teachers who just need a bit of a nudge to rejuvenate their teaching/learning practices.




Tuesday, June 11, 2013

Nadji's Personalized Conceptual Problems (PCP) [How to make assessment personalized, inventive, & concept-driven?]

Generally, there seems to be a tendency in our mathematical curricula to encourage the inertial, linear, and algorithmic-heavy approach to learning and assessment. It is imperative that, as educators, we break the cycle of these mind-numbing approaches and disturb them with various pedagogical tools that offer students the chance to let their resistive, non-linear, creative selves shine through. 
One such method (aka PCP, read on) would be to insist that students every now and then invent their own mathematical functions, expressions, equations, or real-life application (word) problems that address specific concepts on one hand and allow the students to demonstrate their true conceptual grasp of those concepts on the other hand.
I conceived and started using the Personalized Conceptual Problem (PCP) idea to address some of the shortcomings of routine-laden problems that students typically encounter in most textbooks. These PCPs are personalized and tailored to each student's individual conceptualization of the concepts at hand, open-ended, and still do not sacrifice any procedural or algorithmic processes that are equally important in our students' progress in their mastery of mathematics. Following are two examples of such PCPs that deal with algebra topics.


PCP 1: Invent your own absolute-value equation that uses one of your initials as its variable (unknown) and would have no solutions at all. Show the detailed process of solving your equation for the given variable, graph the solution on a number line, and share how you conceived your equation in the first place. (EC: How about inventing your own inequality that has no solutions at all?)

PCP 2: Write your own math application problem (word problem) whose solution process must eventually involve the use of the equation 7x + 13 = 41, solving it, showing the detailed solution process, and providing the real life meaning of each of the equation's constants.


In the comments area, share your thoughts about the PCP assessment approach, your variation on it, and sample problems of your own. Thank you