Here is a link to the first of two podcasts on how to learn mathematics (well actually anything). This first episode was recorded while I was working at AMSI with a colleague, Helen Booth, a few years ago and has just been released. The second episode will be recorded soon and will build on the ideas discussed here.
Here is a summary of some of the ideas and resources mentioned:
Routine – create a routine. Learn at the same time of day, in the same place. Find a place where you feel comfortable and make it your own. Have everything you need for learning at hand. It could be in your home, a library or somewhere in school.
Break learning into small chunks – little and often is better (more sticky) than trying to cram a whole topic in a short time.
Mix topics and subjects – sometimes moving on to something else ca help whe you are feeling stuck or overwhelmed by a topic.
Start learning early – spreading learning over time is more effective, in terms of long term memory than cramming.
Be active – reading and highlighting is not revising! Make notes, rephrase notes, use flashcards, do problems/past papers.
Study with others – studying with others is a great way to learn. Whether you work as a group or just work side-by-side. Having others around you creates an atmosphere for learning and improves concentration.
Pomodoro technique
The pomodoro technique is a great way to focus learning/studying. The basic steps are listed below.
The pomodoro technique:
Decide on a small goal (do two problems, make notes on one topic)
Remove all distractions (phone, TV, other people)
Set a timer for 20 – 25 minutes
During that time concentrate on your goal
At the end of the time give yourself a reward (drink, food, walk, phone or TV time)
Repeat the process 2 or 3 more times.
Resources
Learning how to learn – A link to Barbra Oakley’s website and to resources from the book Learning how to learn.
To be explicit or to inquire that is the question!
Here is my take on the latest maths wars. What do I mean? With the revised Australian Curriculum in the news, the war between the proponents of explicit teaching and inquiry learning has been hotting up.
Personally, I do not see this as a dichotomy. Today there was an article in The Age written by Adam Carey. It outlines the two schools of thought and closes with a teacher describing how they ignited students’ interest through inquiry and plugged gaps in knowledge using explicit teaching. This approach seems sensible to me. Below is my response to the article on The Age website.
In a classroom, many different types of pedagogy are used every day. A good teacher will tailor the learning to the students in front of them. They are teaching the same material in different ways. Some explicit teaching is always necessary, and some inquiry/investigation is also needed. For example, being flexible andthinking about numbers and number manipulation in different ways is essential to use numbers in everyday situations and at higher levels. But, in order to approach a new problem, you need to have the inquiry/investigation skills to transfer knowledge and think creatively. There are techniques that I feel are not used often enough in the classroom. These include: using physical objects (manipulatives), encouraging students to visualise and draw diagrams, and to estimate before they calculate.
A curriculum should not be dictating a pedagogy. It should outline content to be learnt but not how it should be taught.
We need to trust and respect our teachers to decide the best way to teach their students.
I have not written a blog for a long time, I apologise. Here is a short post about one of my favourite podcasts.
One of my favourite podcasters is Christina Tondevold of Build Maths Minds.
In her most recent post (12th December 2021) Christina talks about a particular style of problem
The students are asked to write four stories for a given problem. Each story is framed so that there is a different solution.
It took me a while to work out what was going on but as the podcast progressed and possible stories were given, I realised just how clever this problem style is. I began to think about how such problems could be presented to students and how manipulatives could be used.
Students are often reluctant to write in maths in class. Asking them to write stories, making maths more about communication and less about numbers, is a great way to encourage writing. These problems also make students think deeply about the meaning of an answer. Writing these stories will engage and challenge even the ablest students and reveal misconceptions.
Thinking about how I would introduce this to a class I might start with a number talk, asking the students to tell a story, and then ask the students to write them down. The stories, with accompanying illustrations and calculations, would make a great wall display.
The podcast was only part one and I am looking forward to part two to see where this will go.
In this, the last post of the Algebra Tiles series, I will be looking at how you can use the tiles to demonstrate various more advanced ideas, such as difference of two squares and completing the square.
In this, the last post of the Algebra Tiles series, I will be looking at how you can use the tiles to demonstrate various more advanced ideas, such as the difference of two squares and completing the square.
Dividing a quadratic expression by a linear factor
Dividing a quadratic expression by a given linear factor is similar to factorising. Doing this is the same as for factorising, you are building a rectangle, but one of the side lengths is now fixed.
Here are three examples of such divisions in increasing complexity:
Perfect Squares
What is a perfect square? The result of multiplying two identical linear expressions! So we are building squares, not rectangles.
You can use the visual representation to discuss the features of a perfect square and how to recognise one when written out in full:
(x + 3)2 = (x + 3)(x + 3) = x2 + 6x + 9
Difference of Two Squares
By showing students a visual representation and using the tiles to demonstrate the addition of zero-sum pairs, students should be able to see the pattern formed when factorising the difference of two squares.
Completing the Square
What do we mean when we talk about ‘completing the square’?
By attempting to build a square, with the given expression, and showing that we may need to add or remove terms to achieve the square, we can make meaning of the term ‘completing the square’. In the second video, I show how you may need to add in zero-sum pairs to complete the square.
Extending to Two – Variables
I did mention when talking about collecting like-terms, in Part 2 of this series, that you can model expressions that contain two-variables. In this video I show how to do that:
Resources
There is a Padlet to accompany this blog series with links to research, virtual manipulatives and other resources.
This post will explore multiplying algebraic expressions, the area model, and factorising quadratic expressions.
This post will explore multiplying algebraic expressions, the area model, and factorising quadratic expressions.
Multiplying Expressions
Multiplying algebraic expressions by an integer
Here is an example of how to multiply an algebraic expression by an integer. This may seem like quite a trivial example, but students often struggle with the concept of multiplying each part of an expression. In this example, by laying out the expression and then repeating it the given number of times, they can clearly see that each part of the expression is multiplied. This will help set them up for the more complex multiplications to follow.
The Area Model
Before introducing multiplying two linear expressions, it may be useful to revise the area model with students. This model is the base from which they can visualise what is happening when they do the multiplication. Relating an algorithm to a concrete and/or visual representation will deepen the students’ understanding.
Multiplying two linear expressions
Once students have a good grasp of the area model, you can move on to multiplying two linear expressions. The example below shows how you model this by building the area indicated by the factors (the given brackets). I show how you can visually link the concrete, representational and abstract.
Allow the students to decide which method they want to use. Try not to give the impression that using the tiles means they are not as ‘advanced’ as others. Students should feel comfortable to pick up the tiles and use them if they meet a problem where they feel the tiles will help them. In other words, the tiles are a tool, just like a calculator, and students should feel as comfortable reaching for the tiles as they do reaching for the calculator. Similarly, drawing visual representations. Mini-whiteboards are great for these as they allow students to erase ‘mistakes’ and move on.
Factorising Quadratics
Factorising Linear Expressions
Introduce factorising with very simple examples. In the video, I explain that factoring is building a rectangle, with the given pieces, so that there is the same number of each piece in each layer. Doing a few, really simple, examples will help students to get the idea of what factorising is – dividing.
You may want to give students an example where there is more than one way to factorise and then you can discuss which way is ‘better’ and why.
Factorising a quadratic expression
Once students can multiply linear expressions to form quadratic expressions they can begin to explore factorising – the opposite operation.
Starting with simple quadratics that do factorise easily, as in the video below, will familiarise students with the process. I have tried to show how the area model relates to the generally taught algorithm.
In the example in the video, factorising: x2 + 5x + 6 you might explain that you are looking for:
Two numbers that multiply to +6 and that add to +5
Possible factors
multiply
add
1, 6
1 x 6 = 6
1 + 6 = 7
2, 3
2 x 3 = 6
2 + 3 = 5
Meets requirements
By relating the algorithm to the visual model, students can see why they are looking for pairs of factors that meet these requirements.
In this second example, I demonstrate zero-sum pairs’ use when building the area necessary to factorise a quadratic expression.
Factorising a quadratic where the coefficient of x2 is not 1
When we change the coefficient of x2, the algorithm described above becomes a little more involved, and students may begin to struggle with factorising. I show how using Algebra Tiles can make this process easier to see in the two videos below.
In Part 5, the last of this series, I will explore perfect squares, completing the square and extending to two-variables.
Resources
There is a Padlet to accompany this blog series with links to research, virtual manipulatives and other resources.
Exploring solving linear equations using Algebra Tiles
In this post, I will look at how to use Algebra Tiles to solve Linear Equations. There are several ways you can draw diagrams to illustrate this process and also different concrete materials you can use. One of the most common will be using a balance to demonstrate that both sides of an equation must remain the same (in balance) as you manipulate the variables and constants. Using Algebra Tiles, and the zero-sum pair concept can help students understand why we ‘add/subtract the same from both sides’.
Numberless Word Problems
Students have to be comfortable with the notion that the variable an unknown amount. In order to help students I would start with Numberless Word problems (see this link and the Padlet for examples). This allows students to think about the problem before you introduce the numbers.
Here is an example:
Start with a very open scenario:
I have two baskets of apples. Each basket has the same number of apples.
Ask the students what they notice and wonder. There is no problem yet, maybe ask the students what they think the problem might be.
Then add a little more detail to the scenario:
In one of the baskets, the apples are loose. In the other basket, some of the apples are in bags.
What has this added to the problem? what questions might the students have now? What might the problem be?
I now add in some numbers to the scenario:
I have two baskets each with 11 apples. In one basket all the apples are loose. In the other basket, some apples are evenly divided into 3 bags and there are 5 loose apples.
Now you can ask the students how they could write this problem down. Maybe ask them to illustrate it using Algebra Tiles. Here are some possible abstract representations:
3 bags of apples + 5 apples = 11 apples
3b + 5 = 11
There is still no question being asked – ask the students what they think the question is. In this case, the question would probably be:
How many apples are in each of the bags?
Once the problem is set up, you can begin to discuss how to solve the problem.
Solving simple linear equations
In the video below, I show how I would solve the above problem using Algebra Tiles. I have used conventional x rather than b.
I really like to annotate what I am doing as I work. Having a surface where students can easily erase errors will encourage them to ‘give it a go’, to try ideas that they are not confident with.
This also allows them to see where the standard algorithms come from. When they put in tiles to make zero-sum pairs and then annotate that the reasoning behind the algorithm for solving equations becomes more apparent.
In this example, I have introduced negative values.
Make sure you mix it up a little by not having the variables always on the same side of the equals sign!
Linear equations with variables on both sides of the equals sign
In the next few examples, I demonstrate how to use Algebra Tiles to solve linear equations with variables on both sides of the equals sign.
Here is the same equation solved in a different way.
By encouraging students to solve in more than one way, they can begin to discover which methods are more efficient. Allow the students time to explain their methods to the class to discuss which method works ‘best’ and why. A gallery walk is a great way to do this.
One more example of solving a linear equation.
In the above example, the variable has been written after the constant term. Although there are mathematical conventions for writing expressions, students need to work with examples written in unconventional ways. Often in tests, these sorts of questions are put into ‘throw’ the students.
In Part 4 of this series, I will explore multiplying linear expressions and factorising quadratic expressions.
Resources
There is a Padlet to accompany this blog series with links to research, virtual manipulatives and other resources.
In Part 2 of this series, I will demonstrate how Algebra Tiles can be used to build expressions, model addition and subtraction of expressions, and model substitution into algebraic expressions.
In the previous blog post, I looked at how to make Algebra Tiles and use them to model integer operations.
Building an algebraic expression
If you have used Algebra Tiles to model integer operations you can now introduce the x-tile and the x2-tile.
In the video below I show how to build an expression. It is important that the students recognise the different shapes and colours and what they mean. I would take some time on this stage as you want them to be very familiar and comfortable using the tiles.
Using Algebra Tiles to build an expression
Collecting Like-Terms
Once students can build a simple expression you can move on to more complex expressions and looking how they can be simplified by collecting together like-terms. Students often find it difficult to recognise what is meant by a like-term. By using the tiles it is easy to see which terms are similar by their size and shape. I would start with positive values only and then when students are confident with those introduce negative values, which are the same size and shape but a different colour.
Collecting like-terms
Multi-variable expressions
You can use Algebra Tiles to model expressions that have more than one variable. Below are videos of two ways this can be done. The first is using different coloured tile-sets for each variable. This can get a little messy and I would suggest the students write a key for each variable showing which colour is positive and which negative. The beauty of this method is that the students can really identify what a ‘like-term’ is. They can collect the tiles of the same shape and related colours.
The second method uses only one set of tiles as follows:
How to use Algebra Tiles to illustrate multiple variables
Using the square tiles to represent different variables can help the students to appreciate that each variable represents a different value.
Using Algebra Tiles to represent a multi-variable expression
Addition and Subtraction of Expressions
Once students can collect like-terms together you can move on to addition and subtraction of expressions. Below I use the same expressions with each operation and show how the result is different.
Adding expressions
Addition of expressions
Subtracting expressions
Subtracting multivariable expressions
Using the second method of modelling a multivariable expressions I showed above, I will demonstrate how you can use Algebra Tiles to subtract two expressions.
(Spot the mistake!)
Subtraction of multivariable expressions
Substitution
I have found that students often struggle with substitution. They do not understand what it means. Using Algebra Tiles the students can physically exchange the variable tiles for the unit tiles. The x2-tile is replaced by a square with side length of the given value. This allows the students to build a clear visual representation of what they are doing when they substitute the variable with a given value.
Substitution
Other ideas and suggestions
You may find that students will move away from using the tiles quite quickly and start drawing diagrams or using algebraic notation. I would suggest that you encourage them to use the tiles for the first few examples of each new type of question/activity. Students should feel comfortable to use the tiles whenever they feel the need.
I would also allow students access to the tiles during tests as well. Tests and quizzes can cause students increased stress level. Just knowing that they have the manipulative available can reduce their anxiety.
In Part 3 of this series, I will explore solving simple linear equations.
There is a Padlet to accompany this blog series with links to research, virtual manipulatives and other resources.
In this blog, the first of a series, I will show you Algebra Tiles – how to make them and how to introduce them to your students.
This is the first part of a series of blogs on Algebra Tiles. In Part 1 of this blog series, I will be focussing on introducing Algebra Tiles to your students, making your own Algebra Tiles, and using Algebra Tiles to model the four operations with integers.
Although not part of this blog readers should be aware of the Concrete Representation Abstract Model (CRA). In this model, it is suggested that students move through a series of stages when learning a new concept. Students first experience a concept using concrete objects or manipulatives, they then draw diagrams or representations of the concepts and finally move towards the use of abstract symbols. I will be referencing this model throughout this blog series. For more information on this see the Padlet I have made to accompany this blog series.
What are Algebra Tiles?
In this video clip I introduce the three tiles and what they represent.
Why make your own Algebra Tiles?
There are many commercially available Algebra Tiles, but I like to make them with the students. This is for a number of reasons:
The students will then feel that they “own” their tiles.
The process of measuring and cutting can tell you a lot about your students’ skills (or lack thereof)
The students can pick their colours – this is especially important for students with visual impairments
Here is the template I used for making my tiles and here is the template for the baseboard that I use in the videos.
To make the tiles:
Stick two A4 sheets of foam together, this is easiest if one of the sheets has a sticky back.
Then rule the sheet according to the template or use the measurements below:
unit squares were 1.5cm x 1.5 cm
variable rectangles were 1.5cm x 7cm
variable squared squares were 7cm x 7cm
Cut the shapes using a craft knife as scissors will pull the foam.
Keep the tiles in a resealable bag
You might also want to give the students a laminated A3 sheet to work on, so they can annotate and write notes as they use the tiles.
Using the unit tile to model the four operations
In this video clip, I show how the unit tile can be used to model integer addition and the meaning of a zero-sum pair. This concept is key to using Algebra Tiles.
The following clips demonstrate how Algebra Tiles can be used to model the other operations, subtraction, multiplication and division and directed numbers.
Subtraction of directed integersAnother example of subtraction with directed integersUsing the array model for multiplicationUsing the array model and Algebra Tiles for multiplication of directed integersUsing the array model and Algebra Tiles to model division
Points to think about as you watch the video clips:
Using manipulatives in older year levels
It is rare to see manipulatives being used in a high school classroom. It is even rare to see them much beyond Year 3! The impression students have is that using manipulatives is infantile and only for those that are struggling. This is not the case and many (all?) students would benefit from using them, even if only for a short period.
I like to give the students time to familiarise themselves with the manipulative before I explain how we will be using them. I will ask the students to think about how they think the manipulative could be used, what mathematics it might be used with.
I might say to teachers that I “allow the students time to ‘play’ with the manipulative”, but I would be careful with the use of the term ‘play’ with students, as students should not view manipulatives as toys, as this would only reinforce the notion that they are not a serious tool for the exploration of mathematical concepts.
The language one uses
When using the tiles, be aware of the language you use. It is easy to use the same term for multiple concepts.
For instance, the word ‘minus’. Does this mean the operation subtraction or that the integer is a negative? How would you read the following?
Would you say, “plus 2, minus, minus 5”? This can be very confusing for students. By being careful to use the terms positive and negative to indicate the direction of the integer only, and not plus and minus or similar, can help to prevent this confusion. For this example, it would be better to say, “positive two, subtract, negative two”.
Giving the positive integer a direction is important. All integers have a direction. As mathematicians tend to be lazy, we drop the term positive as most numbers we deal with are positive. Students need to understand this point.
Give students plenty of time to use the manipulative
Give the students plenty of time to use the tiles. There will be students that ‘get’ the concepts very quickly and will feel that the tiles are not necessary. I would encourage the students to use the tiles a few times at least. Ask the students to record their thinking by taking photos or drawing pictures/diagrams of what they are doing (the R in the CRA model).
Remember the CRA model does not describe a linear process. Students should feel comfortable in picking up and using the manipulative anytime they feel that would be useful. The manipulatives should, therefore, be readily available and accessible.
Comments
Please use the comment section to let me know if you found this introduction to Algebra Tiles useful and, if you used them with your students, how that went.
In Part 2 of this series, I will show how Algebra Tiles can be used to build algebraic expressions, used to model the addition and subtraction of algebraic expressions, and used to model substitution into algebraic expressions.
I am putting together a series of blog posts demonstrating how to use Algebra Tiles for the new year. As algebra tiles are on my mind, when I saw this Open Middle problem posed in a tweet from Robert Kaplinsky I decided to give it a go using Algebra Tiles.
Algebra Tiles are a great manipulative to use when you introduce algebra to students. They allow the students to explore concepts such as adding and subtracting expressions, factorisation and substitution. There are three different tiles representing the constant, the variable and the variable squared. Each tile is in two colours representing positive and negative values.
The first step was to model what I knew from the given problem. I used a laminated sheet to place the tiles on and wrote what I knew on it.
An Algebra Tile model of the given problem
I arranged the twelve x2-tiles in a rectangle and this gave me my starting point in finding a solution. The arrangement of these tiles was just a random choice.
I noticed that two of the given numbers in the problem limited my choice of the constant in the second factor pair. The -3 in the top factor pair and the -15 in the final expression, restricted my choice of value in the second-factor pair. It had to be +5.
I had 15 negative block that had to be -3 x something – so the something had to +5
I then filled in all the other tiles:
All the tiles laid out in a rectangle
A basic feature of Algebra Tiles is Zero-Sum Pairs. When you have two tiles of the same size and shape, but different colour, they form a zero-sum pair and can be removed. (They cancel each other out)
I formed all the zero-sum pairs of the x-tiles:
The zero-sum pairs
There were three more positive x-tiles than negative x-tiles remaining. as the coefficient of the x-term has to be negative this was not an allowable solution.
My next strategy was to reverse the 3 and the 4 to see if that would leaver me with more negative x-tiles.
The tiles arranged 3 x 4
Again, I could quickly see that there were too many positive x-tiles.
I then started to explore other factors of 12: 6 x 2, 2 x 6
First I arranged the tiles 2 x 6:
Tiles arranged 2 x 6
But there were too many positive x-tiles.
So I switched to 6 x 2:
Tiles arranged 6 x 2
At last! In this arrangement there were more negative x-tiles! I arranged the x-tiles in zero-sum pairs to see how many positive x-tiles were remaining.
Zero-sum pairs from the 6 x 2 arrangement
There were 8 negative x-tiles remaining so my solution was:
(6x + 5) (2x – 3) = 12x2 – 8x – 15
I thought there could be more than one solution to this problem, there normally is in Open Middle problems. So I tried the final factors: 1 x 12 and 12 x 1.
First I tried a 1 x 12 arrangement:
Tiles arranged 1 x 12
This time I ran out of tiles and room! There were too many positive x-tiles so I move on to my last arrangement, 12 x 1:
Tiles arranged 12 x 1
It was easy to see that there were a lot more negative x-tiles in this arrangement. This gave me the solution:
(12x + 5) (x – 3) = 12x2 – 31x – 15
I had found two solutions to the problem.
For many students, the original problem would look inaccessible. Algebra and the notation used is scary and off-putting. By using the Algebra Tiles and building a visual representation of the problem students have a starting point, a route into the problem. Some students may not need to explore all the possibilities with the tiles. Once they have modelled a couple of possibilities many students will start to make predictions and be able to relate what they are seeing to the notation that is used.
Show the students how the arrangement of the tiles relates to the terms they get when they multiply out the brackets – connecting FOIL and the Area Model.
A nice extension of this problem would be to ask students to explore the possibilities if they were not restricted to the -3.
This and many other insights and suggestions for using Algebra Tiles to deepen students’ understanding of algebra concepts will be explored in my series next year.
Below is a link to the Algebra Tiles Learning Sequence I wrote for AMSI. The blog series will be based around this sequence.
This blog post is going to be a little different. The Australian Council for Education Research (ACER) recently published a paper written by Geoff Masters AO called “Time for a paradigm shift in school education”. In my family, I have been teaching for over 20 years, my husband (a school Principal) for even longer and my daughter is in the middle of her Master of Teaching. Hence, this article was the focus of much discussion.
In this article Masters argues that the way the curriculum in schools is currently arranged, with students organised by age into year levels needs to be reassessed and reimagined. He focuses on the mathematics curriculum, as this is the area where there has been the most research on alternative ways of structuring the curriuclum.
In her research on proficiencies in mathematics, Di Siemon and others, found that there were eight identifiable proficiency levels that students move through as they develop their capabilities in maths. Masters suggests that these eight proficiency levels could become the basis of curriculum levels. In this way students could, regardless of their age, work through these proficiencies at their own pace. This has many far-reaching ramifications on schooling, and he addresses these in the article.
Before I add my own thoughts, here is a (very) brief summary of the article. I do suggest you read the original and have linked to the full article above.
Summary of the article:
The results from testing such as PISA show that there is a need for a change in the way we approach teaching and learning as little progress is being made and in some areas students are not reaching the expected levels of achievement.
By arranging the curriculum in year level bands those students that do reach the expected level one year will continue to fall further behind as they start the following year at a disadvantage.
The alternative paradigm that Masters puts forward, is that if the curriculum were to be based on proficiency levels then students would be able to master one level before moving to the next. They would not have to do what everyone else is doing just because they are the same age.
This would necessitate a new way of thinking about how curriculum and assessment are structured. Success would be measured by how a student is moving through the levels and not by whether they have reached an expected level for their age cohort.
Given that this model is so different to the prevailing one it is to be expected that there would be hesitancy and resistance. Masters goes on to list six concerns that he would expect teachers and others to raise on this new way of thinking:
· Concern 1: will this mean abandoning year levels?
· Concern 2: teachers would be unable to manage classrooms in which students are not all working on the same content at the same time.
· Concern 3: some students will be disadvantaged if students are not all taught the same content at the same time.
· Concern 4: a restructured curriculum will result in ‘streaming’ and/or require the development of individual learning plans.
· Concern 5: a restructured curriculum will lower the educational standards
· Concern 6: it will not be possible to do this in some subjects.
In response to these concerns Masters argues that there are valid social reasons for students to be grouped in year levels and that this would not need to change. Teachers are already faced with a wide spectrum of ability and achievement in their classrooms. What would change is the way in which teachers would be differentiating – they would have a different curriculum/set of expectations for students at different levels.
Teaching all students, the same concept, when not all are ready for it is not equitable. Teaching each student at their level would enable the individual student to progress and hence the overall level of achievement for a cohort would also improve.
To introduce this change, Masters suggests that one subject be tackled first – Mathematics. Mathematics is considered to be a sequential subject and there has already been much research on learning trajectories/progressions in this subject. Other subjects could follow as their curricula are researched and designed in a similar manner.
My response
I do not disagree with the premise – that a reimagining of how we design, deliver and assess the curriculum is needed. The system of schooling we have was devised over 100 years ago to suit the needs of the universities and employers at the time. The needs of the modern university and employer, and employee, have changed. There are new subjects that do not fit easily in the subject ‘silos’ most education systems use, such as coding and STEM. The present curriculum is very crowded; the amount of knowledge a student is expected to know at the end of their schooling is far wider than in previous years. Educational systems struggle to accommodate all interests and needs of their stakeholders.
What does worry me though is how these changes will be enacted in the classroom. Today teachers are not just educators; they are also nurses, social workers, negotiators, councillors . . . We need to think about the teachers when big changes are talked about in curriculum design.
Having worked in both the UK and Australia I have experienced several major changes in curriculum design. For such a radical change to be successful all stakeholders, and when talking about education that is everyone, need to be well informed of what the changes are, why they are happening and what students will be doing.
Teachers: Teacher professional development is key. Not just a few PowerPoint sessions and reams of documents to read. To be successful there would need to be generous investment in teacher training and development and teachers will need to be given the time, away from the classroom, they need to plan such a radically different program of study.
Many teachers teach the way they were taught. To shift the way a teacher teaches is not simple. It takes time, in-class mentoring and coaching, and any change needs to demonstrate that it will lead to improved student outcomes very quickly if teachers are to persevere with a new pedagogy.
Teachers work hard and will not be attracted by an idea that seems to involve them working harder. They are already differentiating and trying to deliver the curriculum to students working at many levels in their classrooms. This is difficult, time consuming to plan, and exhausting to deliver. In the system as outlined by Masters, to plan and assess multiple programs, based on different curricula, in the one classroom, looks like it will be harder and more work.
Students: Students are not stupid! However you try to arrange students in differentiated groups, whatever you call them (the red table, blue table . . . the lions, the penguins etc.) they know who is working at a higher level and who at a lower. Having students in the same room working on different programs will make these distinctions more obvious. Students will have to be convinced that doing something different does not mean doing something better/worse. Peer pressure and the need to ‘fit in’ is stronger now than ever before, due to the pervasiveness of social media. Although students may experience more success, as they will be working on material that is accessible to them, that feeling could be cancelled by the feelings of being behind as they see their peers working on different content.
Parents: Parents will need to be convinced that this will be better for their children. And be willing to have the school decide at what level their child is currently at. So often I have heard parents request that their child is put in a different group/stream as they know that the child is capable of more than the school thinks they are. Parents will need to be comfortable that their child is not being offered the same program as others in the classroom. They will need to be educated in a different reporting system and measures of progress/success.
Employers: Depending on how students are assessed at the end of their schooling employers would also need to have these levels of proficiency explained clearly. Their future employees will be coming to them having completed schooling at different levels of proficiency.
I am not against change. The present system is not working for all our students, some change is necessary. In many schools there is already a move towards a more personalised and student led curriculum. Having a curriculum that is less rigid in what is expected to be delivered each year would support this personalisation.
School systems, teachers and students would have to be more flexible than they are now. As students master a proficiency level they would be moving to work with a different group. This may happen quicker for some than for others. Students would have to be willing to move, to work with others.
When I try to imagine what this would like I think that the architecture of the school may need to change too. Rather than groups of 20-30 students in a small room maybe this style of teaching would work better in a larger area with 50+ students and two or three teachers moving around working with small groups. As a student masters a concept they would then move to another group, to work on a different problem or concept. This would require the students to be motivated and self-disciplined. There would have to be a good system in place to track students’ progress and to make sure that no one fell through the cracks. This would relieve some of the burden of planning and assessing as teachers would be working in teams.
All of this sounds, to me, exciting and full of possibility. It needs people of vision who can communicate this vision and to show how it can be successfully executed on mass.
I do not believe that schools in 50 years’ time will look like the schools of the past 100 years. Change is coming. And as with all change it is both exciting and daunting. But, without the investment in stakeholder engagement and teacher professional development such a move could end up being another failed educational experiment that could set back the cause of quality teaching and learning.