I really love teaching physics. I like the fact that it is so easily relatable to everyday life. I tell my students that after you study physics, you will never see the world the same. Most of them believe that by the end of the year.
But there is a catch: I teach physics in a small school where there is only one section of the class. We don't have a ton of lab materials, and I have no physics colleagues. In order for a small school like mine to have a physics teacher, they have to hire someone who can also teach other stuff. Enter: Me!
I tend to be more math-focused in my approach to physics. And sadly, I end up putting more energy into my classes that are state-assessed.
I don't think I have done a horrible job teaching physics. I mean, I have had my share of students go on to be successful in physics and engineering careers. One former student landed an internship at Cern physics laboratories in Switzerland.
But I do know that I am a better math teacher than a physics teacher. I also know that I have room for improvement. And it is hard to improve on this island with no colleagues.
Anyway, enough whining already. I do have this thing called the internet. Therefore, there is no excuse for me. The resources are out there, I know it. I must find them.
Next year, I am hoping to make better use of internet resources to kick it up a notch. Elephant List #1. I want more labs, but not just labs for the sake of labs. I want labs that produce "aha" moments for students. I want labs that can be set up with everyday materials. I have laptops, so computer simulations would be okay, too.
This search is long overdue.
If anyone out there has some ideas to help me get started, it would be much appreciated!
Wednesday, April 27, 2011
Sunday, April 24, 2011
Conic Card Follow-Up
Recently, I wrote about my affection for Cindy Johnson's Conic Cards. I thought I would mention, like anything else stolen borrowed, I have added a few things to make it my own.
(This probably won't make any sense unless you have read that post.)
1. Extra time: I have found that following Cindy's outline, I ended up with 5-10 minutes left at the end of my 50 minute class periods. So I would put up an equation for whatever conic(s) they had learned so far and ask students to discuss with their partners to identify the vertex, center, major/minor axis, or whatever. Then I would randomly pick a color and have the students who worked with that color of cards that day answer the question. Since everyone knows they may be called on, they all talk to their partner and make sure they know the answer.
2. Giving directions: I found that it was really hard to give directions while students had cards in their hands. I didn't feel like they were listening because of all the sorting. Then again, I WANT them to be sorting. Instead of fighting it, I wrote out some directions (per Cindy's outline) so that they could go through at their own pace. I stopped them at a few points to write something down, but mostly they were able to figure things out on their own. Here are those sheets:
Parabolas (practice at the end is Cindy's)
Circles (practice at the end is Cindy's)
Ellipses (I combined Day 3 and Day 4 from Cindy's outline)
Sketch Parabolas, Circles, Ellipses
Hyperbolas
3. Green Globs: This is some software our school has purchased, and we like it. For conics, students type an equation to try to match a graph that is given. If they are correct, they advance to the next level. If not, they can see the graph of their incorrect guess so that they can figure out what adjustments to make. Games for linear equations are also included.
(This probably won't make any sense unless you have read that post.)
1. Extra time: I have found that following Cindy's outline, I ended up with 5-10 minutes left at the end of my 50 minute class periods. So I would put up an equation for whatever conic(s) they had learned so far and ask students to discuss with their partners to identify the vertex, center, major/minor axis, or whatever. Then I would randomly pick a color and have the students who worked with that color of cards that day answer the question. Since everyone knows they may be called on, they all talk to their partner and make sure they know the answer.
2. Giving directions: I found that it was really hard to give directions while students had cards in their hands. I didn't feel like they were listening because of all the sorting. Then again, I WANT them to be sorting. Instead of fighting it, I wrote out some directions (per Cindy's outline) so that they could go through at their own pace. I stopped them at a few points to write something down, but mostly they were able to figure things out on their own. Here are those sheets:
Parabolas (practice at the end is Cindy's)
Circles (practice at the end is Cindy's)
Ellipses (I combined Day 3 and Day 4 from Cindy's outline)
Sketch Parabolas, Circles, Ellipses
Hyperbolas
3. Green Globs: This is some software our school has purchased, and we like it. For conics, students type an equation to try to match a graph that is given. If they are correct, they advance to the next level. If not, they can see the graph of their incorrect guess so that they can figure out what adjustments to make. Games for linear equations are also included.
Thursday, April 21, 2011
Thinking about the Flip
Item #2 on my Elephant list: Experiment with flipped/inverted classroom.
Just a few months ago, I read about the idea of the inverted or "flipped" classroom for the first time. Since then, I have noticed that a bunch of people in the blogosphere are talking about it. I am completely intrigued by the idea. Instead of giving direct instruction and sending kids home to practice, you assign a video as homework and do the practice in class.
One thing I love about this idea is that it doesn't feel like it would be that big of a stretch for my teaching style. I have been recording videos of lessons for several years now, using an interwrite pad:
This device allows me to record my voice and handwriting as I teach. I can record an explanation live, and make it available to students who were absent. I have also left videos for a substitute when I was gone for the day. Once, when I had a terrible sore throat and could barely talk, I played a pre-recorded video in class to save myself from the talking. The thought never occurred to me to record a lecture and assign it as homework. But why wouldn't that work? I want to try it.
Here are a few of my concerns:
1. I am not sure how to make the videos accessible to all students.
2. I don't know if I have enough time to record a bunch of videos.
3. I don't know how to make videos anymore. I know I said I've been making videos like this for years, but now that we are in a new school I have a completely new set of audio/visual gadgets to figure out. My interwrite pad has been replaced with a smart slate. It is supposed to be the same, but for me it hasn't been as user-friendly.
4. What if a student shows up to class without having completed the homework?
To help process my thoughts, I had a discussion with my current calculus class about the idea. I was just curious what they would think. In general, they weren't thrilled. The main concern they had was that they want to be able to ask questions if they don't understand something in the lecture. They are also worried about accessibility of the videos, as some of them do homework during their break at work, or riding the bus to and from a sports event. I was sort of surprised. I kind of expected them to be more excited about the idea.
One of my students said "What is the point?". He wasn't being rude, he legitimately wondered what was the advantage of flipping. Good question. My answer was that it takes the part of the lesson that students are most likely to need help with, and puts them in the classroom with teacher and peer support while they are doing that.
But now I am starting to question it myself. Why? I don't want to do something just because it is new and interesting and it seems like it would work. Will it truly enhance learning? I think the key is going to be a combination of quality videos AND how I choose to structure the practice time in class. If all I am going to do is say, "Any questions on the video? Okay, here's your practice", then it probably isn't anymore affective than teaching the traditional way.
I still plan on experimenting with the flip in calculus next year. I can see that it might be a harder sell than I originally thought. . .
Just a few months ago, I read about the idea of the inverted or "flipped" classroom for the first time. Since then, I have noticed that a bunch of people in the blogosphere are talking about it. I am completely intrigued by the idea. Instead of giving direct instruction and sending kids home to practice, you assign a video as homework and do the practice in class.
One thing I love about this idea is that it doesn't feel like it would be that big of a stretch for my teaching style. I have been recording videos of lessons for several years now, using an interwrite pad:
This device allows me to record my voice and handwriting as I teach. I can record an explanation live, and make it available to students who were absent. I have also left videos for a substitute when I was gone for the day. Once, when I had a terrible sore throat and could barely talk, I played a pre-recorded video in class to save myself from the talking. The thought never occurred to me to record a lecture and assign it as homework. But why wouldn't that work? I want to try it.
Here are a few of my concerns:
1. I am not sure how to make the videos accessible to all students.
2. I don't know if I have enough time to record a bunch of videos.
3. I don't know how to make videos anymore. I know I said I've been making videos like this for years, but now that we are in a new school I have a completely new set of audio/visual gadgets to figure out. My interwrite pad has been replaced with a smart slate. It is supposed to be the same, but for me it hasn't been as user-friendly.
4. What if a student shows up to class without having completed the homework?
To help process my thoughts, I had a discussion with my current calculus class about the idea. I was just curious what they would think. In general, they weren't thrilled. The main concern they had was that they want to be able to ask questions if they don't understand something in the lecture. They are also worried about accessibility of the videos, as some of them do homework during their break at work, or riding the bus to and from a sports event. I was sort of surprised. I kind of expected them to be more excited about the idea.
One of my students said "What is the point?". He wasn't being rude, he legitimately wondered what was the advantage of flipping. Good question. My answer was that it takes the part of the lesson that students are most likely to need help with, and puts them in the classroom with teacher and peer support while they are doing that.
But now I am starting to question it myself. Why? I don't want to do something just because it is new and interesting and it seems like it would work. Will it truly enhance learning? I think the key is going to be a combination of quality videos AND how I choose to structure the practice time in class. If all I am going to do is say, "Any questions on the video? Okay, here's your practice", then it probably isn't anymore affective than teaching the traditional way.
I still plan on experimenting with the flip in calculus next year. I can see that it might be a harder sell than I originally thought. . .
Monday, April 18, 2011
Cake Day in Calculus
If you teach calculus, you probably can't look at one of these without seeing a volume of rotation.
Students drew the volume of rotation and found the outer and inner radii. It wasn't too challenging for them, since the cake slice was just a rectangle. This one was my attempt to do the problem with them:
I presented this as a problem to my calc class, after introducing volumes by the disk and shell method. I gave each student a sheet of cm graph paper, and a slice of cake:
To check for accuracy, I filled up the original cake pan with water.
The result: 1700 mL. I calculated 2412.7 mL. I was really hoping for more accurate results. I am not sure what went wrong other than the sides of the pan were a little slanted, and we treated them like they were vertical.
Then, to practice the shell method, we used one of these guys:
Here is one student sketching out the cake.
Students tried to use a parabola to model the shape of the cake, which seemed like a good choice. They knew how to use transformations to flip the parabola and translate it to the right location, but they didn't know how to adjust the width. They ended up choosing a random fraction like 1/2 or 1/3 because they knew a fraction in front of x^2 would make it wider. But the results were no where close to the actual cake volume.
Then again, we were running out of time. It was right before lunch. Everyone was hungry. The room smelled like cake. And everybody wanted to eat cake more than they cared about the exact formula for this parabola, or even if it should have been a parabola.
I like the concept of this activity, but I would like to figure out what adjustments to make to get more accurate results next time. I probably just didn't give my students enough time and/or resources to really figure out the right equation for the cross-section.
In the end, the cake was good. We did some math. And everyone thanked me for having a cake day in calculus. So it wasn't a total disaster.
Wednesday, April 13, 2011
Crazy for Conic Cards!
I just finished another one of my favorite units: Conic Sections! I used to hate them, but now I love them (and so do my students). And it is all thanks to Cindy Johnson for sharing her conic section cards at an NCTM conference a few years ago. Her cards did more than enhance my unit on conics, they completely revolutionized the way that I teach this particular topic! Students learn by identifying patterns, not laboring over tedious formulas. Learning conics has never been so fun and painless.
Here is the basic idea: You have a bunch of decks of cards (hopefully, you have a student aide to copy, laminate, and cut them for you). Each deck contains 20 equation cards (5 for each conic), 20 information cards, and 20 graph cards. They are corresponding so that students can match each equation to its information and graph. There are also four title cards (with the words Parabola, Circle, Ellipse, and Hyperbola) and eight formula/reference cards (with all the a's, b's, h's, and k's explained).
Each card has a letter, number, or symbol in the corner. There is a key for each deck so you can check for correctness at a glance.
At the end of the investigation (which takes 6-8 days), students can identify conics along with their vertices, opening, center, radius, major/minor axes, and asymptotes. And they can sketch them.
I don't go into any more depth than that at the Algebra 2 level. I think advanced students could do the matching more quickly, and you could follow up with some more in-depth study of all the formulas for the formulas. At our school, I leave that to the Precalc teacher.
I have had some contact with Cindy since NCTM, and recently I asked about her policy for sharing the cards. I have no desire to take credit for Cindy's great idea, I just want to help spread it far and wide so that others can benefit the way my students and I have.She said I could share her email, so here it is. You can send her a note to request the Conic Card files. Thanks a million times, Cindy!
Here is the basic idea: You have a bunch of decks of cards (hopefully, you have a student aide to copy, laminate, and cut them for you). Each deck contains 20 equation cards (5 for each conic), 20 information cards, and 20 graph cards. They are corresponding so that students can match each equation to its information and graph. There are also four title cards (with the words Parabola, Circle, Ellipse, and Hyperbola) and eight formula/reference cards (with all the a's, b's, h's, and k's explained).
Each day students learn the characteristics of a new conic. Then they separate, sort, and match the corresponding cards. Each deck is different, so they work with different cards each day. One of my students says to me, "I love this, I wish we could learn all our math with decks of cards".
Each card has a letter, number, or symbol in the corner. There is a key for each deck so you can check for correctness at a glance.
At the end of the investigation (which takes 6-8 days), students can identify conics along with their vertices, opening, center, radius, major/minor axes, and asymptotes. And they can sketch them.
I don't go into any more depth than that at the Algebra 2 level. I think advanced students could do the matching more quickly, and you could follow up with some more in-depth study of all the formulas for the formulas. At our school, I leave that to the Precalc teacher.
I have had some contact with Cindy since NCTM, and recently I asked about her policy for sharing the cards. I have no desire to take credit for Cindy's great idea, I just want to help spread it far and wide so that others can benefit the way my students and I have.
Update August 1, 2014: Cindy's cards are now available on google drive!
Also, I am linking a follow-up post.
Friday, April 8, 2011
A New Elephant
This is the time of the year when I finally feel like I can breathe a little . . . State assessments are over. The results were great, what was I worried about? (Well, there was one oh-so-frustrating exception that I want to blog about, but shouldn't.) And, I have my plans pretty much laid out for the rest of the year.
With all these things squared away, I really start to reflect on how the year has been. I try to focus on some areas to improve for next year, or just some new things that I would like to try. Then I make a long list, and delete some stuff until it feels halfway reasonable. I will get as much of these done as possible before school is out in seven weeks, do some over the summer, and then work on the rest during the next year.
Here is my list, and also possibly the titles of my next ten posts:
Physics:
1. More meaningful lab experiences.
Calculus:
2. Video lectures and experimenting with inverted classroom.
Algebra 2:
3. Look for ways to go more in-depth with fewer topics (like this year with logs)
4. More effective use of ACT practice questions.
5. Look at order of topics (parent functions/transformations first?).
6. Look at how I teach/review factoring.
7. Make sure all topics are aligned to College Readiness/ACT Standards.
8. Look at homework collection/grading procedures.
All:
9. Learn more about Common Core Standards, recently adopted in Kansas.
10. Work on atmosphere of partner cooperation/peer tutoring.
Despite my efforts to edit, the list is still a bit overwhelming.
This calls for the elephant-eating approach:
One. Bite. At. A. Time.
With all these things squared away, I really start to reflect on how the year has been. I try to focus on some areas to improve for next year, or just some new things that I would like to try. Then I make a long list, and delete some stuff until it feels halfway reasonable. I will get as much of these done as possible before school is out in seven weeks, do some over the summer, and then work on the rest during the next year.
Here is my list, and also possibly the titles of my next ten posts:
Physics:
1. More meaningful lab experiences.
Calculus:
2. Video lectures and experimenting with inverted classroom.
Algebra 2:
3. Look for ways to go more in-depth with fewer topics (like this year with logs)
4. More effective use of ACT practice questions.
5. Look at order of topics (parent functions/transformations first?).
6. Look at how I teach/review factoring.
7. Make sure all topics are aligned to College Readiness/ACT Standards.
8. Look at homework collection/grading procedures.
All:
9. Learn more about Common Core Standards, recently adopted in Kansas.
10. Work on atmosphere of partner cooperation/peer tutoring.
Despite my efforts to edit, the list is still a bit overwhelming.
This calls for the elephant-eating approach:
One. Bite. At. A. Time.
Monday, April 4, 2011
Crossing My Fingers, Knocking On Wood
Why, oh why, does this make me so nervous?
In Kansas, we only test students once at the high school level. It is up to schools to decide when they feel students are ready to test. At our school, we test freshmen who are in geometry (our most advanced students), and all the sophomores who haven't already tested.
If a student doesn't reach proficient level, we can remediate and have them test again. We use our math strategies class (junior year) for remediation and retesting.
All scores are banked until a particular class's junior year, then count together for that class. We don't know our complete results for a class until after the retesting takes place. That is happening this week.
Our school has received Standard of Excellence for five years in a row. This involves meeting AYP requirements for a percentage of students reaching the proficient level, but it also means that you must have at least 15% of the class in exemplary level and no more than 15% in academic warning.
We feel pressure to continue to achieve that level of performance.
We feel pressure to continue to achieve that level of performance.
The whole thing turns into an agonizing numbers game:
1. This year's freshman class is 2 students short of the 15% exemplary. We have already tested the most advanced students, so we'll have to pick up a couple more exemplary from next year's sophomores in geometry.
2. This year's sophomore class has just the right number of exemplary students, but what if a bunch of new students enroll and we need another 1 or 2 to reach the 15%?
3. This year's junior class has enough exemplary, but needs 5 more proficient. Those students who did not reach proficient the first try will be retesting this week in their math strategies classes. There are 17 of them, and we're pretty sure there will be more than 5 who make it. So all is probably well for this year, but we'll know for sure by the end of this week.
I hate that we have to do this.
Not the testing. I am okay with that, for the most part. I hate the counting of students and the calculating of percentages, and the worrying that we might be one short of the goal. And the feeling that I am not teaching math as much as I am teaching strategies. And the feeling that you have done all that you can and it might not be enough. I worry too much, I guess.
At this point, I'm just hoping for the best.
1. This year's freshman class is 2 students short of the 15% exemplary. We have already tested the most advanced students, so we'll have to pick up a couple more exemplary from next year's sophomores in geometry.
2. This year's sophomore class has just the right number of exemplary students, but what if a bunch of new students enroll and we need another 1 or 2 to reach the 15%?
3. This year's junior class has enough exemplary, but needs 5 more proficient. Those students who did not reach proficient the first try will be retesting this week in their math strategies classes. There are 17 of them, and we're pretty sure there will be more than 5 who make it. So all is probably well for this year, but we'll know for sure by the end of this week.
I hate that we have to do this.
Not the testing. I am okay with that, for the most part. I hate the counting of students and the calculating of percentages, and the worrying that we might be one short of the goal. And the feeling that I am not teaching math as much as I am teaching strategies. And the feeling that you have done all that you can and it might not be enough. I worry too much, I guess.
At this point, I'm just hoping for the best.