Every teacher has their own brand of first week of school activities. Some teachers start with a blank and empty classroom, then construct the space collaboratively with students. Other teachers spend the time playing fun ice breakers and learning names, while still others hop straight into the curriculum. I fall on another spot on that spectrum.
My favorite way to start the school year is to use the classroom routines and protocols that I want students to be able to use later in the year as the structure for getting to know each other. This means learning Turn’n’Talk as a means of short interviews, or practicing turning in writing assignments after writing Introduce-Your-Classmate narratives.
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All posts by Emily Eissenberg
Welcome back to school — we missed you!
As you prepare for the first few weeks of school, you might be ready for a little reminder about how Cubelets work. You may also have a new colleague who was never introduced to Cubelets at all. Don’t worry, we have resources for you to use or pass along – no need to reinvent the wheel. I recommend taking a few minutes to explore the Hub.
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Depending on which combination of Cubelets you own, you may have different questions about how to store and manage your Cubelets. Our Education Packs, for instance, arrive in plastic tubs that each contain multiple groups’ worth of Cubelets.
Some schools ordered many Cubelets TWELVEs (replaced by the Curiosity Set in 2019), which arrive in one cardboard box per student group, but the cardboard box requires Cubelets to be stacked on top of each other, so it’s hard to quickly scan to see if the Cubelets have all been returned to their proper places.
So let’s talk about how you might manage the storage of your Cubelets.
Cubelets Containers: Plastic “Education Tubs”
First and foremost, many schools and teachers come back asking for our Cubelets Containers (the same plastic tubs that all Education Packs ship in). To make quick-scan accountability easier, they’ll print out a Packing Reference Guide and tape it to the inside cover of each Cubelets Container: Continue reading
Cubelets are useful in a variety of learning environments from open-play stations to whole-group guided release. But this balance between unstructured play (important!) and guided instruction (also important!) is a pendulum whose best practices are still not firmly agreed-upon by education researchers, so many teachers like to create their own middle ground. This often involves a workshop model of sorts, which we’ve talked about in previous #CubeletsChat posts. Today, I want to go more in-depth about using the Activity Cards we created, if Workshop Model describes your classroom.
Each Activity Card is double-sided. On the front, we always have an image or icon to help students quickly identify what type of task they are being asked to do. We also have a title for the card and a super-brief description to make sure students have everything they need to understand the challenge. On the back, we have three different types of information. One is a complexity rating using both stars and our labeling. For Cubelets we label our levels as: Novice, Apprentice, Artisan, and Master. We also have set-up clues and helpful hints. If students are struggling to complete their activity from the front side alone, encourage them to read through our clues on the back to help them get over their hurdles.
Our Cubelets Activity Cards include several different types of challenges that push students into unique types of thinking.
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Computational Thinking is a term that’s being thrown around left, right, and center these days. By now, we all have a pretty good understanding of what computational thinking means (if not, check out our blog post about it here!), but for all the definitions of computational thinking, how do we know if students are demonstrating growth in their computational thinking?
As with all growth measurements, having students take a pre- and post-assessment is the best way to get growth data, especially if it’s supported by formatives along the way. So, what if we started with a bigger-picture approach?
We could measure students at the beginning of the year, in the middle of the year, and at the end of the school year. That way we would get an idea of how students’ computational thinking overall changes during this time in our classrooms.
So, what does computational thinking look like? How is it different from, say, number sense or even being proficient in a specific programming language like Blockly?
Researchers have been trying to isolate computational thinking in assessments for years, and their hard work is starting to pay off. From rubrics, to programming analysis, to multiple choice tests, the options are growing and constantly being tested for greater accuracy and reliability.
Here is an example of a computational thinking behavioral rubric developed for the Livingstone Academy in East London. It is clear this resource is designed for teachers by teachers. These teachers focus primarily on the supporting behavioral aptitudes. Things like: confidence in understanding complex problems, persistence in working with difficult problems, iteratively developing solutions, and communicating throughout the process with peers.
Behavioral aptitudes are often a great launchpad for teachers seeking to gather data about a new skill or process. After all, if students are struggling with any of these behavioral categories, it will be incredibly hard for them to demonstrate the thinking they are capable of.
Regardless of the age of your students, you may consider learning more about the Bebras assessment which provides great examples of non-coding-based questions that were developed in conjunction with the University of Oxford. They have printable cards (.pdf) for primary students (grades 1-5) as well as an app for middle school and high school students. Here are some sample challenges from previous years for different age groups in the UK.
So, how can you assess students’ growth in computational thinking using Cubelets? Try giving related challenges to students at the beginning and the end of the year. First, build a steering robot (or a lighthouse if you are working with younger students). At the end of the year, build a maze-solving robot (or an energy-efficient lighthouse for our primary learners). While these end-of-year challenges may be repeats from an earlier lesson, their value is in how students approach the challenge and which intermediate robots they try before they are successful.
Ask students to explain their solution as well as how they got to that answer. Listen for language specific to each of the four main subskills of computational thinking:
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- Decomposition:“First, I thought about the different things my robot would need to do. For instance….”
- Pattern Recognition:“Then I thought about other robots, examples in nature, examples outside the classroom that this reminded me of. For example…”
- Abstraction:“At first, I tried really hard to work on_____. But then I realized that was sending me down the wrong path and it wasn’t as important as I originally thought it was. So I decided to focus on ____ instead.”
- Algorithmic Solutions:“Finally, I landed on this robot. You’ll notice it meets the design challenge because it does ______ and _______. Let me tell you how it works: [gives an explanation of the robot that includes both cause-and-effect and sequential language tags].”
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Cubelets are at their most effective when all students are engaged and continuing to build their skill sets. However, as with any tool, some students will pick it up quickly, and others may need extra help. When teaching with Cubelets, it’s helpful to use the following rules of thumb about interventions and extensions for your robot challenges.
Interventions
First and foremost, to help students who struggle with designing effective robots, start by limiting the number of Cubelets they have access to at the beginning of the design challenge. If students only have n+1 Cubelet (one more Cubelet than they need to successfully build their challenge), they will be better able to focus on the challenge at hand. Continue reading
It’s finally summer! Students are playing, relaxing, and experiencing many new things, but your Cubelets don’t need to be gathering dust in a closet all summer. Many people are looking for highly engaging tools that secretly prevent the dreaded “summer slide”. Have you considered loaning them to a summer camp or a few of your school families for the summer?
Cubelets work really well inside *Theme Weeks* that are often part of summer camp curriculums. Here are a few ideas that might help you pinpoint where Cubelets fit within your summer plans:
Animal Behaviors
Do you have an animal-themed week at camp this year? Are you taking a field trip to the zoo or reading about lots of very exotic animals? Cubelets are great models of natural animal behaviors. Try making robots that act like predators or prey. Or you can invent Cubelets animals that find different kinds of food in an artificial environment. Continue reading
Using Cubelets Blockly, you can code every single Cubelet within your robot construction. But what does this mean? And how does it compare with coding in other contexts?
User Interface
Cubelets Blockly functions very similarly to other visual programming languages like Blockly or Scratch by using a drag and drop functionality of function blocks that hook together like puzzle pieces. Cubelets Blockly has a few of its own blocks, however, that you won’t find anywhere else. That’s because Cubelets are such a unique robot-building experience. Check out Episode 9.1 of our Create with Cubelets series to learn more! Continue reading
The Cubelets App has two main functions: Remote Control and Personality Swap. We’ve already introduced you to the Personality Swaps, but have you begun to use Remote Control in your classroom? There’s a hidden feature I want to highlight for you because it’s not the first application people think of when they see a title like Remote Control: gathering data about our robot constructions.
(Before you continue, it’s a good idea to make sure you understand how data travels through Cubelets by either reading this blog post or taking the Cubelets 102 (free) online workshop.)
As you already know, you can easily gather information about how data is traveling through a Cubelets robot construction using the Bar Graph Cubelet. The Bar Graph is also a screen-free way to gather data about your Cubelets constructions. It simplifies the numbers into a 1-10 scale, as opposed to numbers between 1-255, so it makes data flow conversations available for students who are still emergent mathematicians.
However, there is one thing Remote Control can do that Bar Graph Cubelets cannot: collect information about every Cubelet in a robot construction at the same time. By screenshotting the data in Remote Control, students can very quickly gather static data to analyze later.
As students build more complex creations, especially by adding multiple SENSE Cubelets, it’s more important that they check their assumptions about how the data is flowing through their robot constructions. In general, the five main states of a two-SENSE robot are:
- two sensors at 255,
- two sensors at 0,
- two sensors at ~127 (about halfway),
- one sensor at 255 while the other sensor is at 0,
- and vice versa.
By now, you’ve probably heard all about Computational Thinking. You’ve already defined it and shown how it relates to your content. But of course, Computational Thinking applies to many subjects and tools, including Cubelets.
Here at Modular Robotics, we define computational thinking as being a problem-solving process that helps break down complex problems into smaller parts, so you can develop a model to solve the problem, evaluate the results, and recreate the solution over and over! (If you’d like to learn more about our definition, check out our page devoted entirely to Computational Thinking.)
Computational Thinking is commonly divided into four subskills:
- Decomposition
- Pattern Recognition
- Abstraction
- Algorithmic Solutions