Families of Curves #3

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I have now printed out my Families of Curves projects at school, and hung them up. I still have to look through the actual booklets that students turned in and give feedback, but the actual way that these look — once hung — is pretty awesome.

I used just some tags I had lying around (I love buying random useless stuff from Staples and hoarding it at my desk at school) and dissection pins. I photocopied their artwork on cardstock.

Being honest, I hung them because I wanted the kids to think “Hey, Mr. Shah liked these enough to take the time to do this.” Implicitly. I wanted the kids to know I was proud of their creations (and to let them know that they should be proud of them too.) No kid in my class has said “Hey, that’s awesome.” So I don’t know if I accomplished that goal. But I have heard a zillion other people say how much they have liked seeing them there. A number of other teachers have randomly come up to me unsolicited to tell me how cool they think they are. And the head of the Upper School gave them a shout out in the Upper School meeting. And just recently, yesterday at the subway, I ran into a student who graduated a couple years ago. And she was at our school because her brother goes here, and she said she was looking at them thinking “how cool! Mr. Shah!”

Another great moment with these was having two of my kids go to a neighboring school which holds a math art seminar, and watch these kids talk with other students about their work. It was clear how invested these two kids were. Watching them articulate their process just made my heart melt.

[Here is Families of Curves #1, and Families of Curves #2]

polar!

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After my last unit, which didn’t go as well as I’d have liked, I have been teaching a unit on polar. Where one space (rectangular) transmogrifies into another space (polar).

polardrawing

I’ve been content with what the kids have done this unit. Again, they did all the discovery.

  • How to change a point in rectangular coordinates to polar
  • How to change a point in polar to rectangular
  • How to graph a polar point — and find a bunch of different ways to represent that point in polar coordinates (showing that polar coordinates are not unique, unlike rectangular coordinates)
  • How to convert from a rectangular equation to the polar equation
  • How to convert from a polar equation to a rectangular equation
  • How to graph simple polar equations by hand
  • How to conceptually understand what the polar graphs will look like, and why
  • How to graph complex numbers on the complex plane
  • How to represent complex numbers in polar form (“cis”)
  • How to multiply and divide complex numbers using polar form
  • How to take find roots of unity (haven’t taught yet… throwing it in tomorrow…)

This unit, I’ve been more conscientious about collecting their work almost each night, so I could see their problems. One big thing was that I identified that rectangular points in the 2nd and 3rd quadrants provided difficulty when converting to polar (because of the inverse tangent function, which only yields angles in the 1st and 4th quadrant). Because of that, I was able to target that and bring that up in class, and incorporate more points there.

I think I made some solid — but very basic — materials for polar. I’m going to share them below, and explain each one of them…  [In Word format, in case you want to use/modify them, they are here: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10]

1. Introduction to a new spaceThis is my introduction to polar. I introduce the idea of isotropy (without using the word) and say that we need things to anchor us so we can refer to them. One way — the way we’ve always done it — is using how for north/south we’ve gone from the origin, and how far east/west we’ve gone from the origin. Our regular rectangular coordinates. But… BUT there is another way. I have them play a few rounds of polar battleship on Geogebra to get a sense of it, without telling them anything. Then, without any direct instruction, students move on to actually convert from rectangular coordinates to polar. I do a little direct instruction about how to plot polar coordinates, when r is negative and when \theta is negative. And then they do some plotting, and then convert from polar coordinates to rectangular coordinates. Most importantly, they figure out how to do these conversions on their own. 

2. Graphing in PolarThe warm up refreshes kids on the equation for a circle, but it also importantly has them graph a horizontal and a vertical line. When we talk about the warm up, I really emphasize that for the equation x=-2, what does that mean about the y coordinate? (“It can be ANYTHING! There is no restriction placed on y!”) The reason this is so important is that when they graph r=2, I hope they say “well r is stuck at 2, but the angle can be anything” (and similarly, for \theta=\pi/4, “I suppose \theta is stuck at \pi/4, but r can be anything.”). The rest is pretty much saying: okay, we’ve got our conversions for individual points… can we use them to convert whole equations? (Yes.)

3. Understanding Polar GraphsNow, after all of this, we’re finally going to graph our first not-so-simple polar equation by hand. We do the very basic first one together, and then they’re off to the races! I wasn’t sure how much I truly cared about them graphing by hand, but it’s clear to me now that doing a few of these by hand really brings to life what graphing in polar truly means. Especially when you get negative r values.

4. Polar Graphing Exploration: This was a day and a half of conceptual lifting, done by the students. There is the most amazing polar applet created by David Little. More than anything else, this one applet has truly let me understand how polar graphs are created. It’s simple, and amazing. I didn’t want to teach my kids about the different names for the different graphs, and to identify what the graph will look like based on the equation. Instead, I wanted them to be able to understand why some graphs have a dent, why some look like a  loop with a loop-de-loop inside of it, why some are spirals, and why some are flowers.

So I had them use the applet — and the packet — to explore. And I have to say: they were really making solid connections, and having good conversations, as they were going through it. If you use it, the one thing you want to tell the kids is to “not touch a” and “after you finish analyzing one graph, change b back to b=0.1$”. Honestly, this was the most “risky” of my classes because instead of staying traditional, I said “here, learn it.”

5. Shape of a Polar Graph: After they finished their exploration, I wanted to see what they took away from it, so I gave this out. I collected it and read through them. Some kids fared better on it than others. I didn’t have time to mark them up and give lots of individual feedback, so instead I created a solution packet and I gave it to them — letting them compare, ask questions, etc.

6. Polar Practice: After the last assessment, because I wasn’t totally confident on my kids’s ability to do the basic types of problems, I whipped this set of problems up, which I gave to them, collected, and harshly marked up. This was the best feedback for me, because I got to see what kids were confident about, and what they struggled with.

7. Complex Numbers, the Complex Plane, and Polar Coordinates: I start bringing complex numbers into the mix. I first have them spend a few minutes trying to multiply and divide complex numbers, but it starts getting tedious and annoying (it’s supposed to). We talk about what a complex plane looks like, how I can graph complex numbers on them, and how complex numbers not only have a rectangular (a+bi) form, but also a polar form (involving r and \theta). They don’t seem to have any trouble getting that.

Then: BAM! I immediately have them do a problem, look for a pattern, and make a conjecture. The theorem we’re going for says that if you have two complex numbers written in polar form, if you multiply these numbers, you simply have to multiply the r values and add the \theta values. BAM. Awesome. So they see this. We talk about whether it’s a proof or not (it’s not). We talk about another example to evidence it, and then I let them loose on complex multiplication and division problems.

8. Basic Practice Problems for Complex Numbers: These are the practice problems I gave for students to work on. I also taught them how to use their calculators to input, store, and multiply/divide complex numbers.

9. Advanced Practice with Complex NumbersThis is a short sheet that has kids prove DeMoivre’s theorem.

10. Complex Roots:  I wanted to teach roots of unity, but I don’t have a lot of time, so I made this sheet up — and we’re going to walk through it together. (Tomorrow.) We almost never do that. But it’s our last class before the test, and I think it’s just so cool that I have to show it to them.

Reflecting back, I feel kinda bad that I didn’t design this sheet backwards. Start by having students draw a perfect, regular pentagon on the coordinate plane (letting one point be (1,0) and the center at (0.0)). Then have them find the coordinate of the vertices of the pentagon. Then talking through the vertices to conclude they all are roots of unity (if we consider the plane a complex plane). But eh, I didn’t.

Bloodbath

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So today I had this experience where this precalculus test I gave was a bit of a bloodbath. Not for everyone, but for more than usual. In a way where I cringe, cry out to the high heavens, and scream:

WHYYYYYYYYYYYYYYYYYYYYYY?

The reason is because I felt pretty proud of the way I have been introducing the material. You see, in precalculus this year, the kids are coming up with everything on their own. I don’t give them anything.* And thus far they’ve been doing well with this. And during this unit, even though I didn’t quite have the same amount of time to create everything to my best ability (I relied a lot on the textbook for this stuff), I felt pretty confident about my kids’s understanding.

So I have to wonder: Where did I go wrong as a teacher? What was different about this unit than the others?

First off, this unit was some pretty heavy stuff. We were deriving and applying the trig formulas, and then we were solving more complicated trig equations (they had done basic trig equations previously). All in all, we took a total of 8 days to do this. I should also note that this is an advanced class, and they have been doing a lot of collaborative work this year.

FYI: these were the trig formulas we derived and applied… this is the “trig formula family tree” I made for them.

And for this unit, I led class in a pretty routine way. Each day I had a packet for the kids to work on. They would work on the warm ups with their groups (which were designed to activate prior things they knew but forgot, and have kids make some connections on their own). After 5-10 minutes, we would all talk through the warmup problems together.

Then I would let each group work on their own. I would walk around and facilitate, nudge, question, and answer questions. On some packets, I would have special places where I told kids to “draw in a heart, and call me over when you get to the heart.” (But to be honest, overall, I think I was throwing myself into the groups less than I usually do this unit, as I’ve been trying to let go.)

Then class would end. Most groups were where they should have been… close to done with the packet, and ready to start working on the book problems. These book problems varied in difficulty from the routine “can you do something simple?” to the “okay, apply this in a moderately deep way.” For this unit, I did assign more nightly work than I normally assign, because I knew that to get good at this stuff involves a lot of practice. (I don’t think that is true for everything in math, btdubs.)

Then at the start of the next class, I would have one set of my handwritten solutions per each table (that way, three kids have to share, and thus talk!). I would give kids 5-10 minutes to compare their answers, talk with their groups to figure out things they were doing wrong, and then we would come together as a class and I would field questions that groups couldn’t answer. Then we started a new packet, and the process continued like that for most days. [We did have a bit where we did a paper folding activity, which was pretty cool.]

To see what these packets look like, I combined all of them here so you can scroll through them. I highlighted some of the problems/questions which I thought were good at getting at something hard/interesting/conceptual:

As you can see, these aren’t really great. Not bad either, though. [1]

So where did things go wrong?

When I look through the tests, here are some things I noticed as a trend:

  • Kids struggled with some of the basic “apply the formula” questions
  • Kids had trouble figuring out which sign to use when using the half angle formulas (e.g. \cos(\beta/2)=\pm\sqrt{\frac{\cos\beta+1}{2}}) [2]
  • Kids really nailed the conceptual explanation part of “how many solutions does this trig equation (e.g. \cos(24\theta)=-1) have on the interval $\latex 0\leq\theta<2\pi$?” question
  • Kids struggled with remembering that when you take the square root of both sides, you get two solutions (so \sin^2(\theta)=1/2 is really two equations to solve)
  • Kids did a pretty good job of deriving the trig formulas
  • Even though kids did a pretty good job on the “how many solutions does this trig equation have?” they didn’t find all the solutions to the basic trig equations given.

As far as I can tell, here were the contributing factors (in no particular order):

(a) Lots and lots of sickness. I still have 5 kids who haven’t taken it (out of 19).

(b) I thought I was getting formative feedback when I gave regular little mini non-graded “do you remember the trig formulas we’ve derived” at the start of some classes…

popquiz

And honestly, I felt proud that I have been making a conscious effort to collect this formative feedback. But now I see it wasn’t the right formative feedback.

(c) I usually get a good amount of formative feedback in Precalculus. Mainly I do it by collecting of the nightly work, marking it up, and handing it back. Thus I usually know what students are understanding and what they are not, and they also know what they understand and what they don’t. However, because I was swamped, I didn’t really do that. Maybe once in eight days? So each day, kids got to compare their own work to my solutions, which I thought would at least give THEM feedback… But I never got to see what kinds of mistakes they were making, or where they were getting tripped up, not in detail and not in a big-picture way. So I didn’t build these things into the lessons… which is important because…

(d) This material is hard. Harder than some of the previous units/ideas. That’s because this unit required conceptual understanding, juggling a lot of memorized formulas, a bunch of intuition (as to how to start solving the trig equations), and a lot of “fact” information (like where in the unit circle is \sin(\theta)=-1/2?). It’s just pulling a lot of stuff together.

(e) I should have spent more time reminding them of the trig equations they had previously solved. I assumed that they remembered all of that stuff we did weeks ago and could apply it. I jumped in too fast.

(f) The test was a bit too long. The kicker is, I thought it was too long, so I cut some stuff out. I was trying to be conscious of that. Well, the road to hell…

So there we are. Surprisingly, typing this out has made me feel a lot better. I feel like I now have a better grasp on why something I thought was going pretty well was actually not going as well as I thought. I also have some concrete ideas on what to do next year. The main takeaways for me are: go slower, bring in more visual understanding for trig equations, don’t mess around with the harder stuff, get a lot of formative feedback on the basic types of problems, and make the assessment shorter than my intuition tells me.

*Okay, to be fair, I have given them two things — one which we proved later, the other which I never proved. (The former was the sum of angles formula for sine and cosine, the latter was Heron’s formula.)

[1] It was a stressful time when I was doing this unit, and so I just didn’t have time to come up with anything better. But still, I think they get at good stuff. Even if there needs to be A LOT MORE GRAPHING next year. We did a lot of graphing when we did basic trig equations. We should have done graphing here too.

[2] The kicker is that I said in class that figuring out the correct sign is the most important thing about applying that formula. Multiple times. But me saying it until I’m blue in the face the same as them totally understanding it. Next year I need to build in some warm up questions like: if \alpha=200^o, what quadrant is \alpha/2 in? Draw a picture. If \beta is in the fourth quadrant, explain in words and with pictures why \beta/2 is in the second quadrant..

Have you given a presentation about the mathtwitterblogosphere?

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I think this year, one of the biggest things that have happened to the mathteacherblogosphere (or whatever variant of that word you use) is that we’ve broken out of our own little community. We are no longer just a few of us talking with each other. There are a ton more of us, tons of blogs, tons of people twittering.

And more and more people are joining us, because they’re seeing what good things we have to offer.

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And now and then, on twitter, I’ll see that someone or another is giving a talk on this community, and what it has to offer. I’d love to create a list of presentations or talks that people have given about our little world. Partly, this is my archivist nature, trying to record all of this good stuff in one place. But mainly, because as more and more of us are building talks/presentations, it might be nice to have other talks and presentations to refer to.

Now I’m not talking only about hour long talks to huge groups of teachers. I mean anything — whether it’s a five minute talk to your department, to a 15 minute spiel to your school, to a three hour workshop you’ve crafted.

So if any of you have given talks, and have blogged about them, could you throw your links below? And if you could include any digital files you used (powerpoint, keynote, PDFs), an outline of how you actually lead it (if it was more than just you talking, but had participants actually do things), and anything else that might be useful… that would rock.

And if you have given a talk and haven’t blogged about it, BLOG ABOUT IT! Or if you don’t have a blog, because you mainly twitter, you can write a guest post on my blog if you want!

I hope to compile them as a list on this blog, or maybe include them on a special page on the mathtwitterblogosphere site.

Full confession: I haven’t really given talks or anything. I’m not really a teacher leader or anything and it feels weird to give talks when I feel like I’m not an expert teacher or a leader or whatever. So I’ve only done one talk to new teachers last summer [post here]. Here is a 7 minute presentation I gave at a summer math conference/workshop (PCMI) which I think went really well [post here].

Related Rates, Yet Another Redux

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I posted in 2008 how I didn’t actually find related rates all that interesting/important in calculus. The problems that I could find were contrived, and I didn’t quite get the “bigger picture.” In 2011, I posted again about something I found from a conference that used Logger Pro, was pretty interesting, and helped me get at something less formulaic.

I still don’t know how I feel about related rates. I’m torn. Part of me wants to totally eliminate them from the curriculum (which means I can also possibly eliminate implicit differentiation, because right now I see one of the main purposes of implicit differentiation is to prime students for related rates). Part of me feels there is something conceptually deeper that I can get at with related rates, and I’m missing it.

I still don’t have a good approach, but this year, I am starting with the premise that students need to leave with one essential truth:

Often times, as we change one thing, it affects a number of other things. However, the way that the other things are affected can vary greatly. 

Right now, to me, that’s the heart of related rates. (To be honest, it took some conversation with my co-teacher before we were able to stumble upon this essential understanding.)

In order to get at this, we are starting our related rates unit with these two worksheets. A nice bonus is that it gets students to think about the shape of a graph, which is what we’ll be embarking on next.

The TD;DR for the idea behind the worksheets: Students study a circle which has it’s radius increase by 1 cm each second, and see how that changes the area and circumference. Then students study a circle which has it’s area increase by 10 cm^2 each second, and see how that changes the radius and circumference. The big idea is that even though one thing is changing, that one thing affects a number of different things, and it changes them in different ways.

[.docx] [.docx]

(A special thanks to Bowman for making the rocket and camera problem dynamic on Geogebra.)

It’s not like this is a deep investigation or they come out knowing anything super special. But the main takeaway that I want them to get from it becomes pretty apparent. And what’s really powerful (for me, as a teacher trying to illustrate this essential understanding) is seeing the graphs of how the various thing change.

***

IMAG2906

I had students finish the first packet one night. Before we started going over it, or talking about it, I started today’s class asking for a volunteer to blow up balloons. (We got a second volunteer to tie the balloons.) While he practiced breathing even breaths, I tied and taped an empty balloon to the whiteboard.

Then I asked our esteemed volunteer to use one breath to blow up the first balloon. Taped it up. Again, for two breaths. Taped. Et cetera until we got a total of six balloons taped.

Then I asked what things are measurable in the balloons.

Bam. List.

(We should have listed more. Color. What it’s made of. Thickness of rubber.]

Then I asked what we did to the balloon.

Added volume. A constant volume (ish) in each balloon.

Which of the other things changed as a result?

How did they change?

This five minute start to class reinforced the main idea (hopefully). We changed one thing. It changed a bunch of other things. But just because one thing changed in one particular way doesn’t mean that everything changed in that same way. For example, just because the volume increased at a constant rate doesn’t mean the radius changed at a constant rate.

***

 This is about all I got for now. I’m going to teach the rest of the topic the way I always do. It’s not up to my personal standards, but I still am struggling to get it there. I suppose to do that, I’ll have to see a more nuanced bigger picture with related rates, or find something that approaches what’s happening more visually, dynamically, or conceptually.

PS. The more I mull it over, the more I think that geogebra has to be central to my approach next year… teaching students to make sliders to change one parameter, and having them develop something that dynamically illustrates how a number of other things change. And then analyzing how those things change graphically and algebraically.

(A simple example: Have a rectangle where the diagonal changes length… what gets affected? The sides, the angle between the diagonal and the sides of the rectangle, the area, the perimeter, etc. How do each of these things get affected as the diagonal changes?)

Quick Questions on Proving Trig Identities

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I’m sure that this question has been asked in a million high school math offices, so apologies for the rudimentary nature of the question.

I’m teaching Precalculus for the first time. And I’m about to teach proving trig identities, like:

\frac{\sin(x)}{\sin(x)-\cos(x)}=\frac{1}{1-\cot(x)}

I understand that the standard ways to prove trig identities is:

(a) pick one side of the equation, and keep morphing it until it matches the second side of the equation

(b) individually modify both side of the equations independently until they equal the same thing.

I always learned that what you cannot do is start mixing both sides of the equations. So, for the equation above, you can’t cross multiply to get:

\sin(x)(1-\cot(x))=1(\sin(x)-\cos(x))

and keep on simplifying both sides to show they are the same and the equality is true.

 

The reasons I’ve heard this is not allowed:

1. Because I said so.

2. You can only cross multiply if you know the equality is true. But that’s precisely what you’re trying to prove. You are assuming the statement is true to prove the statement is true.

However, both explanations are unsatisfying to me. The first one is for obvious reasons. My objection with the second one is that it seems to always work for these problems. Although I know it is logically unsound, I can’t quite pinpoint why with a concrete example to demonstrate it.. 

My questions are the following:

What do you do to explain to your kids why you can only work the sides of the equality independently? Does it convince them?

Does anyone have a good example involving trigonometric identities that illustrates that bad things happen when you don’t solve the sides independently, but start mixing them together? Like proving something that isn’t true actually is true… or proving something true that actually isn’t true?

Thanks for any help. I feel a little foolish, like I’m missing something obvious. Like I should know this. But hey, if I knew everything, I wouldn’t need all y’all.

 

 

Guest Post: Conics Project

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This is a guest post from my friend Liz Wolf.

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“The conics section comes at a tough time in our curriculum.  It’s a few weeks after Spring Break, and kids are always antsy in class and have major spring fever.  I wanted a way to make conics less abstract and show the kids how often they come up in every day life.  I came up with a project that not only got them outside, but also got them looking at things in a different way.  The photo of the water droplet on the swing set was my favorite.  The students really embraced this and I was impressed with how well they embraced GeoGebra having never used it before.”

***

Below are some examples of final products from her class, and the instruction sheet she used.

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Update: Liz sent me her Geogebra instruction sheet!

Swampped

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This is one of those days where the one good thing was hard to find. I had to reprimand one class for not doing their work at home, I am having to deal with juggling because a ton of students have been out, I’m dealing with a lot of this and that, and I have a HUGE amount on my plate for this weekend. Like: impossibly large amount of stuff to do. So my anxiety is through the roof. And, yes, I have that tickle in the back of my throat which could mean something or it could mean nothing.

But that’s precisely why we need this blog. So I’m going to post some of the small good things that happened. None of them were GOOD (like, enough to undo my stress) but they were positive.

(1) Another multivariable calculus student turned in her aweeeeesome 3D function which is aweeesome possum…Image

 

(2) Some kids were really excited about showing me some of the stuff they did for their roller coasters in their calculus projects (which were due today).

(3) I took over a colleagues precalculus class while she took my multivariable calc kids (and one of her classes) to the Museum of Mathematics… and her kids were working on the same project mine are (the family of curves project). Her kids were soooo into it and were coming up with some stunning, beyond stunning in fact, pieces of artwork.

(4) A former kid who served for all my years on the SFJC came back to visit and we caught up after school. It was nice to hear what exciting things he has planned in the next five months!

That’s about it. When I’m overwhelmed and overextended, and when a lot of kids have their own things I’m dealing with, I can’t appreciate these small moments. So I am glad I took the time to force myself to think of these small moments, in a sea of mediocre ones.

Families of Curves #2

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So today I started the Family of Curves project in Precalculus. Students are going to be given three in class days to work on this, and about a week or two of out-of-class to finish it on their own.

I started class showing around 4 or 5 minutes of this Vi Hart video with no introduction:

Then I showed a whole bunch of pictures… of tessellations, Escher prints, one of the things they were going to be creating on geogebra [but without telling them it was not a famous artist], and a few beautiful prints and the website for Geometry Daily.

Then I had them take out their laptops, and just get started working on Geogebra. The packet below takes them through the sequence command, and then shows them how the sequence command can create a family of curves…

Here’s the instructions getting kids started on Geogebra and what’s expected of them…

[.docx]

Note: My kids are getting more and more fluent with Geogebra… We have been using it on-and-off all year at various times.

They were silently working the entire class. I put on some music, and they started talking a bit. But since it’s an individual project, I suppose I can’t expect a lot of talking. Some kids have been asking me “how do you make circles?” and one student asked me how to fill in circles…

It took them pretty much the whole day today to do the geogebra introductory stuffs, so they didn’t all get to play around with their own functions. I expect tomorrow will be pretty awesome to watch them tinker and explore, and get cool things.

I don’t know if they are “into” this yet. I’ll see if I get any anecdotal evidence tomorrow.

One Good Thing

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A short post:

For those of you who don’t know, Rachel Kernodle (@rdkpicklehttp://sonatamathematique.wordpress.com/) has started a group blog called “one good thing.” She wrote about it here, and you can visit the blog here.

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The idea is that even in the most frustratingly upsetting days as teachers, there is at least one good thing that happens — as long as you keep your eyes open to it. We may feel we suck, we may get all arrrrgh at students, a lot of random stress can take over and fill us with anxiety… and we get our blinders on, and lose sight of the bigger picture. Looking for one good thing each day helps us see the bigger picture when our vision narrows. And it also helps us archive the little moments, which are oh so important!

Right now there are about 7 authors posting regularly. This is one of the many projects that math teachers have going on (others are here)! I know Rachel wants to invite others who want to contribute regularly or semi-regularly to join in (it’s not an exclusive club!) — so she said you can throw your email in the comments here in the next couple days and she’ll add you as an author to the blog. Or you can tweet her to get added or find out more information. That simple!

What’s nice is this blog will soon be populated with a million little stories from a bunch of (math) teachers all around the world. A beautiful pastiche of why we teach, with concrete, on-the-ground examples.

(My entries on the “one good thing” blog are archived here.)