CUZZ ED.

Wednesday, October 9, 2013

Conference Presentation on Collaboration, Technology, and Education

For any who are interested, I am presenting at a conference in Vancouver on Friday. My talk is Thursday morning at 10:30am. I am planning to video the presentation and upload it to YouTube, but for those who are viewing the presentation and want a copy of it, I have uploaded it here as well.

Wednesday, September 11, 2013

First Week of Classes

The first week and a bit is over. How has it gone? Not badly! Here are a few updates class-wise. First, Science 8 is going well. The class is great and very easy to work with. Coursework wise, I have changed a few things, but for the most part I am keeping the timing the same (it seems to work). However, I have made sure that I repeat a lot of the concepts every day; making sure that they understand the main ideas of the course. I am at this point doing it verbally, but I will also do some more worksheet and test questions in class. Tomorrow will be Microscope work and then (my favorite) CELL CITY on Friday (a cell representation on a plate made with candy!). They can eat only the part of the cell that they can name and explain its purpose. Last year, most got all of it - this year they are having to memorize the cell parts beforehand and then blindly create the cell (no textbook) on Friday - I will mark what they know. Should be fun! The question I have is how well the students will be able to do on the city (will this assignment and the short review we have done in class be enough to know the parts of the cell and what they do?). I already know that they did this in Grade 7, so I am hoping this is review-ish for them.

One thing I will take out next year is the ICKTHOSS assignment in the Science 8 textbook. I like the idea (gets students to think outside the box a bit and solve problems) but I don't think it fits with the plan (or the objectives), which tells me that, with respect to the UBD concept, it is not a needed assignment. This is a good thing because I have a lot to cover and taking out this assignment would be good. Here is my only concern: I use that assignment to teach about working in a group as well, so I will have to find another assignment that I can use to teach about how to work in a group.

I will post some pictures and a more complete lessons plan for that assignment next posting, for those interested.

Finally, on a curriculum note, I found a worksheet in the student workbook (of which I do not use on class in its entirety) that was very interesting - very basic, but interesting with respect to what it suggested was important. Here is the assignment: it was a basic drawing of a microscope with some blanks beside the parts. The assignment was to label the parts of the microscope. However, simply knowing the names of the parts of a microscope is somewhat useless. Instead, I would rather they didn't know the names of the parts, but what the parts did. Thus, I took the blank picture and changed the assignment: write down what it does and, if you remember, what it's called. To help them, I gave them a microscope to use to see what the parts did. This I think was a better assignment and fit more with what the students needed to know about the microscope.

Monday, September 2, 2013

Getting Ready for 2013!

This year will, I believe, be very exciting! I have two to three points to focus on:

New course (Electronics Level 2 for Grades 10-12)
Second Shot at Science 8 (focus on UDB)
Extra-curricular educational development (personal writings, study, and journey)

New Course

One of the most interesting things I have on my plate is the new Electronics course. I began electronics Level 1 a few years back and I have found it very successful. However, we have recently moved it to the grade 8 and 9 level, and for the students the content became way too hard. Therefore, the first thing I am doing is working towards lowering the scope of knowledge the level 1 group will work towards learning. This is especially true for the math focus, where the math involved in the Electronics course was over their heads (they did not learn any of the algebraic manipulation needed until grade 9 math, so they found it very difficult to see it used in this course). As well, more focus will be placed on repetition of concepts and smaller lab work where measuring and mastering of basic electronic knowledge will be the focus. I have also lowered the projects to two of them (though I will try to get a third one in before the end of the year - perhaps another smaller project...).

Level 2 will focus on the math, complex circuitry, robotics, and alternative power (solar, wind, etc.). I am super excited about it, especially since I have some new toys to play with (Parallax SMART boards, numerous chips, etc.). Should be good!

Science 8

For this second time around, I think I will focus on refining the projects and making sure that I repeat much of the information, working towards having the students master the concepts. However, I want to still be careful that they don't focus on memorizing terms, but actually showing that they understand the main larger concepts. To this end, I will work towards finding ways to assess their knowledge of the main ideas of the units in numerous other ways beyond the large projects only. Perhaps smaller experiments that will ask students to answer the "why" without me discussing with them first what that might be and then doing the experiments to "show" it in action? I will keep posting on how this goes and what I implement.

Personal

I have recently finished working on publishing the findings from my thesis in an online journal. I am hoping to get the OK on it soon and will post the link to that here. As well, I am planning to keep up on my reading and learning in some way, working on continuing to do some reading on topics, and perhaps even continue to do some research in some way (if at all possible), under the supervision of someone if I need to.

Saturday, August 3, 2013

Understanding By Design and Science 8

Below is the text from my Science 8 implementation of the Understanding By Design concept. I am not sure that I did it in the way that I would be taught to do by the UBD guys, but it did make a difference, especially when it came to assessment, something that I will post next time. For now, if any teachers are thinking about implementing UBD into their classes, here is what happened to me!

Hint for reading: start reading at the bottom (the topmost post is the last post).

Past half way and...

Well, here are a few things I have found:

1) The test for unit one was not at the 70% level overall, so it didn't do what I thought it would. However, mark-wise for the term, many students have brought their mark up overall, especially those who have struggled in the past in courses. Yes, some are incomplete, but they are incomplete in other classes as well, so I think there are other issues there. Those who do well in other classes have still done well here, but doing more project based assessment seems to have brought up the ones who hover at around the 50% mark up a bit, thus closing the gap a bit.
2) I do find that the vocabulary for this course (as portrayed in the book and on tests) is difficult, however. In fact, many of the questions from the textbook question bank are vocab based and not knowledge based. If I take those types of questions out of tests, the students seem to do better (and they still know the concepts!).
3) I am doing a bit of a mix of UDB and other stuff now - so I have a project at the end of each unit that is a summative evaluation, along with a paper or verbal test of some kind. I wonder if this is true UDB? I think it is, and I admit the students have enjoyed the projects and I think have learned a lot from doing them. I wonder, however, if UDB is really just project-based learning when it actually is implemented into the classroom?
Anyway, if I do teach this course again, I will definitely continue using this concept - it is working for this class and for me as a teacher.

February 20

2.5 Weeks in and...

All is good! I am planning to do a bit of a summative evaluation in the next few weeks outside of the animal building project; however, I will do it without giving the students a chance to study (WHAT!!!!); yup, a pop test Unit Exam! I am curious to know how much they have learned simply from doing the projects and assignments themselves. I will feel very good if the average mark is at around 70% - this will constitute a success in this.
Benefits of UDB: Well, to be honest, it has been a lot of fun and it has been very easy to come up with daily activities for the most part so far. I love that I look at the objectives only and create around them more than follow the textbook. This has given me freedom to do cool things that I think the students enjoy. The students have also been involved and I have not had a lot of classroom issues with the 8's - surprising, but true!
Problems: If anything, the biggest issue has been myself knowing the stuff and filling in the class time correctly. Also, since all lessons are new (never done them before), there have been two that I know of that could have worked better (planning was off a bit). For example, one day to come up with a skit and portray them was way too quick - should have planned skits on one day and done them the next. Also, I am not doing a lot of summative tests yet (early), but my plan is to not do too many anyway (not short quizzes etc.). However, I think I need more than one.
So far, it has been a lot of fun and I have felt very energized - I am scared and actually excited about teaching the class all at the same time! The stretch has been great for me and I think this makes a difference to the quality of the teaching.

February 06

Three days and how is it going you ask? Well...

I think this are going excellently! The best part of this whole thing has been telling the students the second day of class what their final project for the unit will be (how backwards!). This has done something for us as a class, however: it has focused everything we do on learning the stuff needed to complete the task (which is to create an animal). The funniest part to this whole thing is that everything they need to know is actually everything in the first unit of the textbook - but the students brainstormed the topics themselves. This has given them ownership of the course. I think this helps the students a lot.

Personally, I feel quite happy about the whole thing right now; though I am tired after a class. My teaching style seems to fit nicely with this approach - lots of discussion time and brainstorming, hands on work, coming at things differently, looking up the answers, etc. Yes, it is a little messier than it could be (it's not like we do page 10, and then questions on the next page, and then...), but the learning has been fun, inviting, and students seem to be into the course material.

Of course, the biggest problem is my own knowledge of the material: I am not a science teacher by trade so there are things I do not know. My strategy for this, however, fits with the UBD concept: I am not to be the wealth of information, but a supporter, a coach, standing beside them as they learn.

Here's a great example of this that happened today: the students were given a hands-on observational project where they had to observe what happened inside of two cups of warm sugary water: one had yeast in it and the other had sand. They had to write down what happened every 20 seconds. The observation worked great and the students understood the concept. However, I personally did not know enough about yeast to conclusively say if it was alive or not - my thought was that it didn't really reproduce. However, some quick Google search showed me that I was in fact wrong. So how do I turn such a thing around? Well, I tasked a student to look it up and give a quick blurb about it tomorrow in class, as well as getting a Biology 11 student to come in and explain it to us.

So, I was wrong. I know that we as teachers like to think that this is OK, because it shows us as not being perfect, but I would go beyond this: in today's day and age, we should not be perfect because we know everything - thus when we don't get something right it just proves we are not perfect. Instead, we should be co-workers with the student, guiding and leading them onto their own knowledge. This is the stance I will take with them tomorrow: we can all learn and we should all be lifelong learners. Also, there is always so much to learn! If I can get students to think this way, it will make this class even better - the students will begin to ask what they want to know and go find out; I will guide and direct them and (what a concept) learn as well!

January 25

Next Stage: A Look at Daily Activities

So, I have tried experiments, tested a few larger projects, and I have been studying and reading the textbook. I feel like I am ready enough with the big things to begin teaching. In the past years, this would be all the planning I do and I would then go at it with the textbook under my arm ready to tackle the day to day assignments, which would consist of:
1) reading of chapter, 2) note taking, 3) textbook questions, 4) quizzes, 5) larger tests, 6) some bigger group assignments, 7) larger reports of some kind.
However, as I look at the UBD concept further, I realize that I might not be doing the course any service at all, and that doing my assessment based on this classic model of marking students is quite narrow. For example, five out of the seven things I do are based around reading would have done revolve around the textbook itself (1,2,3,4,5), while 7 is simply a report of some kind (so research) that I would have them write. 6 would probably be a textbook assignment done in a group.
The UBD concept says this about assessment and tasks: assessment should varied, using authentic tasks and projects, academic exam questions, prompts, and problems, quizzes and tests, informal checks for understanding, and student self-assessment. However, the tasks need to be effective and engaging. I love the quote "The art of holding interest lies in raising questions and delaying answers".
OK, so I will take a look at my first two units and see if I have planned So, I started off well, but I want the students to create their own experiments right off the bat. this will teach them that procedures are important to science. This will put off the second unit a bit, but I think getting the students to build experiments right off the bat is important and will be done throughout the course, so I plan to start there. I think I should have some starters for them, however: perhaps some questions that they can start off with.
I have downloaded a booklet called "SmarteScience" (www.smarterscience.org) and it deals specifically with this concept of having students do their own eexperiments. I like the idea a lot and perhaps I will start the year off with it (why not - another new thing: go big or go home eh?).
I printed off a few things to look at. I love how they begin to get students to look at inferrences and observations and the difference between them. this might get students started on creating experiments.

January 22

Building a 3d Cell is a good one!

I like this assignment, and I have seen it done so many times. Its on page 35 of the textbook and they can build it in a box. Looks good and definitely teaches them the parts of the cell. It is not necessarily UBD, but it will work as another hands-on approach.
I realized as well that I have to also teach them how to work in groups, or collaboratively, so I have incorporated that into one of the early lessons. this will be something I have to review often in class.
OK, I am working through assignments for the first few weeks now. I think I am ready.
Oh, yeah, the exploding person thing is harder than it looks! It won't work with Alka-Seltzer and chip containers: the top is not sealed enough. I am going to try it with pill bottle (or film canister) and water and Alka-Seltzer this week and see if that blows nicely. Another option that Steve gave me (he is so helpful in this) is a balloon overtop of a water bottle filled with Vinegar and Baking soda. The gas will blow up the balloon and no water is thrown around the room. I like that too - cleaner - but is it as much fun :)?

January 21

Uh Oh, Waves are not easy to work with...

So, I have been trying to work on the "converting waves into energy" lab and it is not easy to do, mostly because the fish tank I have is too small: the waves bounce back and the propeller I created in the water will not move. So the classic spinning turbines will not work. Looking online, designs like Salter's Ducks are used in real life, but these are hard to create on a small scale.
If I did it from a running water source, it would be very easy (like a river dam concept), but that would not show any knowledge at all. OK, so this looks like it will be some kind of report. On pages 468 and 469 of the textbook are two things, either a research investigation or a project. I think that this, along with the WIKI unit, should be good as the ending result for the water unit. I see many little experiments in the book, so supplementing these large projects with smaller experiments should work out well.
OK, time to clean up the classroom!

January 18

Boat done-ish!

I hope I am alright with this, but I did the clay boat thing (did a little research on the best way to float a clay boat) and I did it -minus the straws, but oh well! So, the best layout is a flat bottomed boat and you have to make sure that the sides are straight up and not cracked at all so water does not go through it into the boat).

One thing I found out was that clay becomes very messy when it's wet, so I will have to make sure that I have lots of paper towel and rags to clean off with. Other than that, it works great! So, all I need for this is washers and straws and away I go!
Next one: let's stay on the water topic and see about getting energy from waves! First, I will need to figure out how to change movement into energy. to do that, I need magnets and copper wire (which I have a lot of). Let's try that first - i think Blake had some stuff to do that with, so I will check there...
(5 min. later...)
Yes, he had something that will work perfectly! It has two magnets on the end of a spinning axis. Using my multimeter, I can very quickly measure the electrical output form the spinning of the magnets. OK, now onto creating a turbine of some sort. the other thing to think about is whether or not I should use a step-up transformer to up the electrical output? For now, I won't but I will think about it. OK, next step is to see how I will create waves in the aquarium (is it too small to make waves in?, how will I set up a turbine in it so that it doesn't move?) I need some plastic on a stick!

January 09

A change in Tasks

the fog light assignment is actually just an experiment (in the book page 234). It looks real easy to do so I am putting the call out for cellophane to do it. It will work great with the experiment forms I already have.
thus, the only assignment for the Visible light unit is the eyeball. Also, I love the idea of cutting a cow eye, but it sounds like that was already done in grade 7 by PJ (though I will ask him about that). If he hasn't, then that would be perfect!
At this stage, I am going to move on to Float Your Boat project. Here's the write-up for that one:

Boat Creation

Goal: Students will design a boat given a set amount of material that maximizes buoyancy and safety.

Role: The students will assume the role of a boat/ship designer.

Audience: The audience is a rich teacher who has commissioned a safe and strong yacht to show off all the money he is earning.

Situation: The teacher has sent a package of information to a wide variety of boat/ship builders with the intent of creating a safe and strong yacht. Given the same amount of materials, (100 g of clay and three straws) the boat builders are to create a boat that at a minimum will float on water. Better designs will be capable of holding more materials, in the form of washers. The more washers the boat can hold while still floating, the better the design.

Product/Performance: The end product will be a boat design that will be tested against the other designs. The winning design will float and hold the most weight. In addition, each boat building team will submit a written report of the process of creating the boat and the considerations undertaken to create the boat. Both the boat’s ability to float and hold weight and the written report will be evaluated.

I am going to get clay and straws right now to play with this! Love it!

January 09

The eyeball was easy and fun!

Well that was not a problem at all! I created a tube version of an eyeball in around 1 hour total time. I decided to record it with my laptop video camera and I will upload it on to my YouTube site so students can see it anytime they want to (I will just post a link on the Moodle site for them to see).
Materials I used were very minimal (the lens that I will give them, saran wrap, paper, masking tape, some construction paper, scissors, glue, and a paper tube (like the one that Christmas paper comes in).
the only thing I want to do with it to finish it off is put it into a round ball of some kind so that it looks like an eyeball. Other than that, it works great! I can move the lens a little off so that you can see how the change in the shape or length of the eyeball will affect vision.
Today, I was thinking of tackling the fog lights or one of the water ones. I will go see what supplies I have to tackle each one and go from there. as well, I will try to get a table up in room N101 and something that can have water in it (like a big fish tank). I will need that for the water unit.

January 08

Lessons and Classroom Setup

So now that I have the core ideas, I think I should begin my part in the learning process and do the following:

1) Try out the experiments myself! : One of the worst things is to give a student an assignment that you yourself have not tried. I believe this: heck, I have lived this! So, that is my job for this week. I have already tried the building of the eye thing (or at least 50% of it) and I am confident that I could do that one without an issue. I will try to do them all in the next while and make sure that they are doable.

2) Set up the classroom. I have begun to put up posters that deal with what we will be covering in class, as well as putting up forms that students will use to do their own experiments. This comes from a website called "Smarter Science" and it was recommended to me by Dr. Carol Rees at TRU. She taught Science for many years at the High School level and said that this is a great resource (www.smarterscience.org). I have decided to implement their ideas a bit - it fits in with my vision for Science. In essence, it gets students to think through creating, trying, and recording experiments that they themselves design. I am not sure exactly how I am going to implement it yet (students have to do 1-2 in the year perhaps? Will I have a bank of some ideas? Will they have to present?), but I know I love the idea.

Fear: I am a bit fearful of how students will find the materials needed for the experiments. I think that I would love to have some of the materials at the school, but encourage students to use whatever they want from home.

The ones that worry me the most are the eye, fog lights (so the visible science part), the elevator (for Physical Science part) and the water one (I will need water, waves, and the students will need materials to make their models).

I guess I will tackle one at a time and see what happens. Today, the eyeball! As well, I should read and be familiar with the information in the textbook and the teacher manual about the knowledge I will need (yes, stay ahead of the students).

December 10

Assessment Evidence

Review:
So in my limited knowledge, this is what it seems like we do:
1) Create the Big Idea and Core Tasks to go along with it (Equivalence ["Students will understand that..." - these have lasting value, can be transferred to other classes, require "uncoverage" of knowledge] and being able to solve real-life problems that requires in-depth knowledge of the unit)
2) Create "Essential Questions" that will point students to the Big Idea. This is where my Christian worldview can come into play as well, I think.
OK, so here is the final list of what I think will work for each unit for Science 8. To help with the concept of the "Core Tasks", here is another way to define it: "The most important complex performances, in realistic contexts, in each field." So basically, this is a task that is complex enough that, without knowledge of the unit the student will not be able to complete correctly. It is a different way of assessing the knowledge of the student: if they can do this, they know the main concepts of the unit.

Process of Science

Big Idea: Students will understand that there are procedures that must be followed if they are to understand how something works
Essential Question: How important is a plan in learning about something - can't we just explore and figure it out as we go?

Task: students have been hired to find out what best works to get rid of ticks in pets. Students need to come up with a step by step process that takes into account what is needed, how to measure success and failure, and what issues will have to be addressed.

Living Things

Big Idea: Though life is a mystery in itself (created from God) we can learn about it since every living thing on Earth is similar in its makeup

Essential Question

Task: Create a New Animal! What would your animal look like and act like and why? It needs to incorporate everything that any living creature needs to survive on this world.

Visible Light

Big Ideas: Light is one small component of the larger light spectrum; each of the areas on the light spectrum has a purpose for us.
Essential Question: How can we manipulate light to better our lives?
Task:
The students are being hired by the Optomotrist Association of Canada to create a model of an eye that works! They will use glass, paper to put the image on, etc. The model should be able to show how defects (changing the focal point etc..) will affect someone's vision.
or
Creating Fog lights (pg. 254 in textbook) - Your company makes automobile lights and supplies them to a major auto firm. You must design the best possible fog light using mirror placement, material used, and color to use.

Physical Sciences

Big Idea: Everything is matter in different forms; we can manipulate matter using force to do what we need it to do.
Essential Question: How can I use the world around me to better my life?

Task: Float your Boat (create a boat out of materials given - which one works best and why?) and Elevator (create an elevator or rock picker using Pneumatic or Hydraulic designs

Water

Big Idea: Water is important to life's survival
Essential Question: If the Earth is mostly water, why did God make us to live on land?
Task: Wrestling Energy from Waves (page 469 in textbook). Students are being asked to change wave energy into electricity. Students will work in groups to create a model that will actually work in a tank of water (electricity can actually be measured!).

Interestingly, at the end of each chapter in our Science textbooks are what they call "Research Investigations" that work for this (Water example is one). Ok, these are all good in my opinion. Anyone think otherwise?
OK, the first two stages of the planning process are done:
Stage one was the big ideas and essential questions are set out, stage two was the core assessment tasks, focusing on evidence of mastery of the bit ideas, and that mastery of key performances requires understanding of the big ideas.
On To Stage Three: The Learning Plan!

December 03

Step 2: Assessment Evidence

Well, here is where I need to come up with performance tasks that will show me that the students can apply what they have learned and demonstrate their understanding. I'll do this per unit so far.

Process of Science

Big Idea: Students will understand that there are procedures that must be followed if they are to understand how something works

Task: students have been hired to find out what best works to get rid of ticks in pets. Students need to come up with a step by step process that takes into account what is needed, how to measure success and failure, and what issues will have to be addressed.

Living Things

Big Idea: Though life is a mystery in itself (created from God) we can learn about it since every living thing on Earth is similar in its makeup

Task: Create a New Animal! What would your animal look like and act like and why? It needs to incorporate everything that any living creature needs to survive on this world.

Visible Light

Big Ideas: Light is one small component of the larger light spectrum; each of the areas on the light spectrum has a purpose for us.

Task:

Physical Sciences

Big Idea: Everything is matter in different forms; we can manipulate matter using force to do what we need it to do.

Task: Float your Boat (create a boat out of materials given - which one works best and why?) and Elevator (create an elevator or rock picker using Pneumatic or Hydraulic designs

Water

Big Idea: Water is important to life's survival

Task:

As you can see, I don't have any for visible light or water as of yet. However, I like the other three so far. As well, I have found some online resources that I think I will use to help. Will tackle this later in the week. Once I am happy with these first evidence bits, I can continue to look closer into other forms of evidence that might fulfill my big ideas.

December 03

Step 1: What the heck are the "Big Ideas" in Science 8?

OK, so snag #1 - our IRP objectives are not "big idea" oriented, but seem more content based. Thus, I have to look at the units themselves and come up with the "Big Ideas" for them. Here's what I have done:
1) I have taken the PLO's for each section and created big ideas for each of the five units.
I like these. They seem to make sense to me and seem to be big, transferrable, and are not content based.

December 03

The beginnings

First, let me share a little about UBD (Understanding By Design). The concept behind UBD is to help teachers (like us) to create lesson plans that does not revolve around a specific resource, but that instead revolves around the objectives to be taught. This opens up the classroom teacher to use whatever resource they find and want to use, as long as it fulfills the objective to be taught.

Here is the WIKIpedia page on it: http://en.wikipedia.org/wiki/Understanding_by_Design
In essence, you start "backwards" by looking only at the objectives and what we want students to know or be able to do. This part is easy because it is prescribed in our IRP's as the PLO's. The second part is simply looking at the PLO's only and deciding on the evidence that will fulfill that objective. This is the stage I am at right now. Only after that will I then begin to create assignments that lead to fulfilling the objectives.
The "bible" of this the book by Wiggins and McTighe called "Understanding by Design". I have a shorter PDF file of the highlights that was done by Wiggins as a workshop and I am using that to start with.
The course I am implementing this in is Science 8. The reason is that I am both curious to see if it will effect the class' engagement and learning into the concepts as well as what it will be like to do this as a teacher. So far, I am excited but I still have a long way to go.

Saturday, July 6, 2013

Implications of UTAUT and High School Students

Last post, I had mentioned that I used a TAM instrument (specifically something called the Unified Theory of Acceptance and Use of Technology model (UTAUT) with high school students to measure their acceptance of a technology, namely a WIKI page. My findings were interesting (see above); I do also want to mention that I have done the same research this year again (without a publication hanging over it - just some simple in-class research done by the classroom teacher - and so far, my findings are replicating themselves (this is very exciting!). What I have found this year is that it is the ease-of-use that is driving the actual usage of the technology, not the usefulness. Also, there is again a gender bias (girls used the WIKI a bit more than boys).

So, what does this suggest and how do I use this information in a classroom? Well, firstly using a WIKI should not be a one shot deal, as experience with it will definitely change their usage (true, in this study the people who were more apprehensive actually used it more, but it was not clear if that was gender or GPA as it was the girls who were more apprehensive, used the WIKI more, and had the higher GPA overall); this should put the students at ease a bit more. Also, because of the difference in confidence levels for each gender, “This may indicate that different forms of intervention are necessary to encourage the interests of male and females with respect to IT” (Forssen et. al., 2011, p. 55). Secondly, group work is an issue with high school students that needs to be addressed; they need to be taught how to work in groups and it needs to be practiced. In my study, fear of group work came out loud and clear in the focus group discussions after the WIKI unit was implemented, with many students mentioning how worried they were about working with other people that they had not worked with before. It is possible that nervousness about group work could be playing a role in how effectively students will use a WIKI for collaborative work. Strategies for this might include keeping groupings of students together for more than one project, thus allowing students to get used to the partners they have in the groups. As well, previous research suggests that having students assessed both individually and as a group can decrease “any resentment among members that can be created when an individual or small number of people completes a large amount of the work” (Vaca, Lapp, & Fisher, 2011, 273); assessment should therefore include these two views, something that the inherent user tracking system in a WIKI easily allows for.

My next blog post will deal with something that I implemented last year during my Science 8 class, called Understanding By Design. To be honest, this was one of the most exciting things I have done in my educational experience and allowed me to change my assessment strategies to better fit students needs. Stay tuned!

On a different but connected note...
Tomorrow I will be talking about this study at Thompson Rivers University during their Language, Culture and Community Research Symposium. The website for this event is www.tru.ca/lcc and the Twitter hashtag is #lcctru for those who are interested. As well, one of the projects I have for this summer is to get my thesis converted into a journal paper for publication, which I will be doing with my supervisor Dr. Carol Rees. I will give you more information on this as I go.

Friday, June 28, 2013

Masters Thesis!

The Thesis
One of the concepts that is often missed when looking at incorporation of technology into education deals with how to measure its impact. Students might say "I like it," but that might not mean anything with respect to actual usage. One of the main ways that technology acceptance is measured is by using something like the Technology Acceptance Model (TAM) postulated by Davis (1989). From the research I have done, this (or one of it's newer iterations) is one of the most popular measuring tools used in researching technology acceptance. However, it has historically been used with adults or, at the very least, college and university students.

So what did I do? I made a version of it (changing only wording) that could be used at the high school level. My findings were very interesting, and I will share a quick overview of it here. The original TAMs found that there were at least four different factors that influence technology usage: perceived usefulness (this is the most important), perceived ease of use, social influence, and facilitating conditions. In essence, then, if someone thinks that a technology is useful, will be easy to use, feel that other people think it will be a good idea, and feel that there will be support, then people will tend to want to use the technology in question. Makes sense.

In my study, I used the same instrument, but there were two differences. 1) the technology I used was a WIKI page, something that I knew no student had every created; 2) WIKI pages allowed me to look at actual usage, not simply a questionnaire that dealt with a users intent to use. My findings were as follows: 1) I found that, with high school level students, the only factor that significantly influenced their actual WIKI usage was perceived ease of use; 2) boys felt more comfortable with the technology in question but 3) girls used the WIKI way more than boys (so gender played a role).

This finding suggests that the ease of use is the most important factor, something I feel is a change in attitude towards technology acceptance - technology must be easy now (IPOD or Facebook-like) and more intuitive perhaps. How does this play out in education? That will be the discussion of my next blog posting! Stay tuned!

Tuesday, June 18, 2013

The Beginning...

Background

Well, I thought I should start this blog by answering the question of why I am now blogging. The best way to answer this is to give a little background about me: I have recently graduated from Thompson Rivers University with my Masters in Education (B. Ed., B.A. (English Major), TCOM Technician, and Comptia A+ Certification are my other credentials). These things all add up to what I am now doing, which is teaching at a high school and acting as the school computer specialist (Network Administrator).

My focus has become quite specific: yes, I teach numerous subjects (it seems that, when you are in as a teacher at a high school, whatever they need you to teach is what you will be assigned to do regardless of personal knowledge or specialty), but I also have a passion to successfully incorporate technology into my courses. This is not done for the sole purpose of sprinkling it on top of my curriculum like icing sugar, but instead I want it to be the tool that students use correctly to fulfill objectives; and not only because it’s there, but because it is the best thing to use to fulfill that specific objective.

Thus this blog: my travels into the incorporation of technology into my classes (the good, the bad, the incomprehensibly ugly).

What I Teach

I teach at an Independent school in a city in the interior of BC. My clientele are mostly lower to middle class family students, predominantly white. In fact, I have discussed with colleagues at the school that our school, though private, does not get the “crème of the crop” students like many larger private schools at the coast (St. George’s comes to mind), but instead is a fairly standard representation of any public school with students coming from all areas of the city. Our school is not a University prep school, nor is it a school for gifted, exceptionally bright, problematic, learning disabled, or troubled students – it boasts nothing but a standard student body whose family choose our school for various reasons, the largest by far being that they are looking for something different than they have or believe they will find in public schools in the area. In fact, I might argue that, because our numbers are small, there are times where the classroom dynamic is quite skewed one way or the other (a few very bright students or a few challenged students in a small class, can change the overall feel of the class on a whole quite easily).

The courses I teach have nothing to do with my specialty anymore (English and Computers), but I teach a trades class (Electronics 8 and 9), musical classes, and now Science 8. However, I have taught Yearbook, ITECH 11 and 12, and English 8, 9, and 10, in previous years.

What this Blog Will Do for You

I will be using this blog mostly as my own educational diary of sorts. Glean what you will or what you can from it. I do hope to deal with realistic educational ideas, thoughts, and concepts that I have actually tried. Who knows? It may be useful one day... to someone. As well, as a lover of language and writing itself, I hope that keeping a blog will help me to hone my writing itself. Comments, thoughts, and ideas will always be welcome!

Here we go.