Illustrated by Pop Sutthiya Lertyongphati
It was a cold October morning in North Wales. I was a fresh, Newly Qualified Teacher at Denbigh High School.
Young and inexperienced with rose-tinted goggles: I was mindful of my responsibilities as a new Science teacher. Expectations were high.
When the Deputy Head of the school suddenly asked to observe one of my Year 9 Physics lessons I knew I had to perform well. As a thriving school with a great reputation, Denbigh definitely set the bar high.
My Year 9 kids were typical 13 and 14-year-olds. Some days they were great and some days they’d just had enough. Keeping them on-task was a challenge for an unskilled teacher like me.
Frantically thinking of ideas for this major lesson observation that was coming up, I thought about how to keep the kids interested whilst maintaining challenge at the same time. I was going to be teaching a lesson about series and parallel circuits, but I’d made the mistake of not ordering circuitry and equipment from my Science technician. A class practical was simply out of the question at such short notice, and the circuitry was booked by a number of other teachers that day anyway. I could only order enough equipment for a class demo.
What on Earth was I going to do?
Simulations and online learning was out of the question – this was 2006 and kids didn’t have the right mobile devices and they didn’t carry laptops. Online resources were also limited.
I felt uneasy about taking the kids to the computer lab, even though it was available. My Deputy Head wanted to see me teach, not watch the kids work on computers for 40 minutes (or so I assumed).
In a moment of despair and perplexity I was suddenly given a flash of inspiration: what if I could turn the lab into a giant circuit? The kids could become ‘model electrons’ and could walk around the classroom holding up little signs, pretending to be flowing around a circuit. I could even hold up a sign saying ‘cell’, and a few kids could be model ‘switches’ and ‘bulbs’. Hell, it might just work!
The day comes
I frantically printed a class set of A4 signs – just simple sheets which said ‘electron’, ‘switch’ and ‘bulb’ in big letters.
‘This crazy idea might save my day after all’, I thought!
The kids came in and sat down. Back then I hadn’t mastered the art of giving students something quick to do as soon as they enter the door (see my three A’s in my book). I got right into this activity as a starter (which turned into a semi-main body of the lesson).
I lined all the kids up and gave them each a sign. Most of them would pretend to be electrons and a few would be switches and bulbs (‘switch on’, ‘switch off’, ‘bulb on’ and ‘bulb off’ signs were given to these pupils).
The desks were arranged in rows, so I started with a series circuit. I explained the route the kids had to take and they started walking, holding up their signs. They smiled and giggled along the way. When the ‘electrons’ passed the ‘bulb’ it ‘lit up’, and when the ‘switch off’ student held up his sign, the ‘electrons’ stopped moving and the ‘bulb off’ sign was held up, proudly.
To my astonishment, the kids absolutely loved it. More importantly: they understood the concepts of the lesson brilliantly. They completed a short worksheet after the ‘circuit walk’ (which they all could answer with ease) and then I gave my short circuit demo with actual wires and bulbs and switches.
My deputy head was very impressed. She praised my creativity and said that the ‘circuit walk’ was very effective.
Not bad for a freshy who prepared in rush!
That day I became a hardcore Spatial Learning fan. Fast forward to today and all of my students will tell you that I use spatial learning in almost every lesson I teach. It’s effectiveness speaks for itself.
But what is Spatial Learning?
There are many definitions and interpretations of spatial learning on the web and in various books. Some of this pedagogical mumbo-jumbo can be really confusing, but I believe I’ve nailed it down to one sentence:
Spatial Learning is when students use bodily movements to express themselves, solve problems and model situations.
Spatial Learning has both general and specific applications. I’ll now go through some great examples that illustrate the power of this excellent teaching tool.
Here’s a quick video I made about Spatial Learning:
A human graph and true or false?
Do you want to know the opinions of your students on a subject matter? Maybe you’re taking a survey (e.g. which day is the best for canteen food). Maybe you have a list of multiple choice questions and you want a fun way to get the kids through them.
A human graph might be the right tool for you!
What if you just want to quickly check your students’ conceptual understandings (e.g. as a plenary)? You could ask some true/false questions and get the kids to raise their hands, or you could use a way cooler (and more fun) method!
Choose one wall to be the ‘True’ wall and one to be the ‘False’ wall. Once you’ve asked the question, get the kids to walk to the correct wall. It’s that simple! Just make sure that the kids walk back to the middle of the classroom before each question.
This great illustration from Pop shows you the steps to take for each of these activities:
Do your kids need to express numerical answers sometimes? Maybe they need to work out a percentage or a fraction, or translate numbers from one language into another. Maybe they need to express something in Binary Code. Well it’s time to put pen and paper down and get your kids moving!
Turn your students into ‘human numbers’ by following Pop’s beautifully illustrated instructions:
For double and triple-digit numbers you can put students into groups for added fun!
The vast majority of the Spatial Learning I do involves modelling a situation, concept or solution. Like the example I gave earlier about the electrons travelling around the circuit, the students actually become the things that you’re teaching about.
I find that almost everything I teach can be modelled spatially in one form or another.
I’ll provide some examples to show just how easy it is, with just a little creativity, to turn any monotonous textbook paragraph into a living, breathing, exciting and stimulating task.
Modelling example one: Diffusion
Textbook definition: Diffusion is the passive movement of liquid or gas particles from a region of high particle concentration to a region of low particle concentration. The speed of diffusion of any given particle is dependent on its molecular mass. This means that a particle of ammonia, for example, will diffuse faster than a particle of hydrogen chloride as ammonia is the lighter of the two particles.
Modelling activity: As you can see, the textbook definition is rather hard to swallow. So, to jazz things up a little, you can turn the students into ammonia and hydrogen chloride particles and tell them to diffuse! In this activity, the students simply walk across the classroom at different speeds, depending on which molecule they are. Quick, easy to do and a nice break from writing, reading and listening to a lecture. More importantly: it’s really useful as a tool to help kids understand this concept.
See this illustration I drew below (my art work is dire compared to Pop’s, so I hope it’s understandable!):
Modelling example two: A Typical Home Network
In an attempt to show you just how pliable spatial learning is, I’ve designed a task for a subject area I don’t specialise in: ICT
Concept: A typical home network may be wired, wireless or a combination of both. Hardware components process and convey the data message from from part of the network to another.
Spatial learning task: For this task you need moving and stationary students. The stationary students stand at predetermined positions in the classroom (you can put signs on desks or on walls to help). These students represent the hardware. The rest of the students are the ‘data message’, and they move from one component to another. I hope the illustration below helps you to see just how easy this is to implement and how much fun it can be. Students should shout out the name of the hardware component they reach at each stage as they walk around the room.
Can you think think of ways to use modelling in your subject area?
My debut book is filled with great spatial learning and active engagement tips. After the enormous success of that book I’ve decided to work on a new book that will be released mid-2018 which goes into even greater depth and breadth about the range of classroom management tactics available to teachers. Also, if you’re looking for a great book to build up spatial learning skills in small children, then I strongly recommend Julie Dillemuth’s Lucy in the City:
Also, a great manual for designing great spatial-learning activities is Dr. Thomas Armstrong’s Multiple Intelligences in the Classroom (highly recommended):