Here at the Raspberry Pi Foundation, we believe that it’s important that our academic research has a practical application. An important area of research we are engaged in is broadening participation in computing education by investigating how the subject can be made more culturally relevant — we have published several studies in this area.
However, we know that busy teachers do not have time to keep abreast of all the latest research. This is where our Pedagogy Quick Reads come in. They show teachers how an area of current research either has been or could be applied in practice.
Our new Pedagogy Quick Reads summarises the central tenets of culturally relevant pedagogy (the theory) and then lays out 10 areas of opportunity as concrete ways for you to put the theory into practice.
Computing remains an area where many groups of people are underrepresented, including those marginalised because of their gender, ethnicity, socio-economic background, additional educational needs, or age. For example, recent stats in the BCS’ Annual Diversity Report 2023 record that in the UK, the proportion of women working in tech was 20% in 2021, and Black women made up only 0.7% of tech specialists. Beyond gender and ethnicity, pupils who have fewer social and economic opportunities ‘don’t see Computing as a subject for somebody like them’, a recent report from Teach First found.
The fact that in the UK, 94% of girls and 79% of boys drop Computing at age 14 should be of particular concern for Computing educators. This last statistic makes it painfully clear that there is much work to be done to broaden the appeal of Computing in schools. One approach to make the subject more inclusive and attractive to young people is to make it more culturally relevant.
As part of our research to help teachers effectively adapt their curriculum materials to make them culturally relevant and engaging for their learners, we’ve identified 10 areas of opportunity — areas where teachers can choose to take actions to bring the latest research on culturally relevant pedagogy into their classrooms, right here, right now.
The Pedagogy Quick Read gives teachers ideas for how they can use the areas of opportunity (AOs) to begin to review their own curriculum, teaching materials, and practices. We recommend picking one area initially, and focusing on that perhaps for a term. This helps you avoid being overwhelmed, and is particularly useful if you are trying to reach a particular group, for example, Year 9 girls, or low-attaining boys, or learners who lack confidence or motivation.
For example, one simple intervention is AO1 ‘Finding out more about our learners’. It’s all too easy for teachers to assume that they know what their students’ interests are. And getting to know your students can be especially tricky at secondary level, when teachers might only see a class once a fortnight or in a carousel.
However, finding out about your learners can be easily achieved in an online survey homework task, set at the beginning of a new academic year or term or unit of work. Using their interests, along with considerations of their backgrounds, families, and identities as inputs in curriculum planning can have tangible benefits: students may begin to feel an increased sense of belonging when they see their interests or identities reflected in the material later used.
The Quick Read presents two practical case studies of how we’ve used the 10 AO to adapt and assess different lesson materials to increase their relevance for learners.
As we’ve shared before, we implemented culturally relevant pedagogy as part of UK primary school teachers’ professional development in a recent research project. The Quick Read provides details of how we supported teachers to use the AOs to adapt teaching material to make it more culturally relevant to learners in their own contexts. Links to the resources used to review 2 units of work, lesson by lesson, to adapt tasks, learning material, and outcomes are included in the Quick Read.
In a different project, we used the AOs to reflect on our adaptation of classroom materials from The Computing Curriculum, which we had designed for schools in England originally. Partnering with Amala Education, we adapted Computing Curriculum materials to create a 100-hour course for young adults at Kakuma refugee camp in Kenya who wanted to develop vocational digital literacy skills.
The diagram below shows our ratings of the importance of applying each AO while adapting materials for this particular context. In this case, the most important areas for making adaptations were to make the context more culturally relevant, and to improve the materials’ accessibility in terms of readability and output formats (text, animation, video, etc.).
You can use this method of reflection as a way to evaluate your progress in addressing different AOs in a unit of work, across the materials for a whole year group, or even for your school’s whole approach. This may be useful for highlighting those areas which have, perhaps, been overlooked.
The ‘Areas of opportunity’ Pedagogy Quick Read aims to help teachers apply research to their practice by summarising current research and giving practical examples of evidence-based teaching interventions and resources they can use.
The set of AOs was developed as part of a wider research project, and each one is itself research-informed. The Quick Read includes references to that research for everyone who wants to know more about culturally relevant pedagogy. This supporting evidence will be useful to teachers who want to address the topic of culturally relevant pedagogy with senior or subject leaders in their school, who often need to know that new initiatives are evidence-based.
Our goal for the Quick Read is to raise awareness of tried and tested pedagogies that increase accessibility and broaden the appeal of Computing education, so that all of our students can develop a sense of belonging and enjoyment of Computing.
Let us know if you have a story to tell about how you have applied one of the areas of opportunity in your classroom.
To date, our research in the field of culturally relevant pedagogy has been generously supported by funders including Cognizant and Google. We are very grateful to our partners for enabling us to learn more about how to make computing education inclusive for all.
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We’re really excited to see that Experience AI Challenge mentors are starting to submit AI projects created by young people. There’s still time for you to get involved in the Challenge: the submission deadline is 24 May 2024.
If you want to find out more about the Challenge, join our live webinar on Wednesday 3 April at 15:30 BST on our YouTube channel.
During the webinar, you’ll have the chance to:
Subscribe to our YouTube channel and press the ‘Notify me’ button to receive a notification when we go live.
The Experience AI Challenge, created by the Raspberry Pi Foundation in collaboration with Google DeepMind, guides young people under the age of 18, and their mentors, through the exciting process of creating their own unique artificial intelligence (AI) project. Participation is completely free.
Central to the Challenge is the concept of project-based learning, a hands-on approach that gets learners working together, thinking critically, and engaging deeply with the materials.
In the Challenge, young people are encouraged to seek out real-world problems and create possible AI-based solutions. By taking part, they become problem solvers, thinkers, and innovators.
And to every young person based in the UK who creates a project for the Challenge, we will provide personalised feedback and a certificate of achievement, in recognition of their hard work and creativity. Any projects considered as outstanding by our experts will be selected as favourites and its creators will be invited to a showcase event in the summer.
You don’t need to be an AI expert to bring this Challenge to life in your classroom or coding club. Whether you’re introducing AI for the first time or looking to deepen your young people’s knowledge, the Challenge’s step-by-step resource pack covers all you and your young people need, from the basics of AI, to training a machine learning model, to creating a project in Scratch.
In the resource pack, you will find:
The pack offers a safety net of scaffolding, support, and troubleshooting advice.
By bringing the Experience AI Challenge to young people, you’re inspiring the next generation of innovators, thinkers, and creators. The Challenge encourages young people to look beyond the code, to the impact of their creations, and to the possibilities of the future.
You can find out more about the Experience AI Challenge, and download the resource pack, from the Experience AI website.
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Big news for young coders and everyone who supports them: project registration is now open for Coolest Projects 2024! Coolest Projects is our global technology showcase for young people aged up to 18. It gives young creators the incredible opportunity to share the cool stuff they’ve made with digital technology with a global audience, and receive certificates and rewards to celebrate their achievements.
The Coolest Projects online showcase is open to young people worldwide. Young creators can register their projects to share them with the world in our online project gallery, and join our exciting livestream event to celebrate what they have made with the global Coolest Projects community.
By taking part in Coolest Projects, young people can join an international community of young makers, represent their country, receive personalised feedback on their projects, and get certificates and more to recognise their achievements.
Here’s how it works:
Taking part in Coolest Projects is simple:
As well as the global online showcase, Coolest Projects in-person events are held for young people locally in certain countries too, and we encourage creators to take part in both the online showcase and their local in-person event.
In 2024, creators can look forward to the following in-person events, run by us and partner organisations around the world:
More events are coming soon, so sign up to the Coolest Projects newsletter to be sure to hear about any in-person events in your country. And if there isn’t an event near you, don’t worry. The online showcase is open to any young person anywhere in the world.
Coolest Projects welcomes all digital tech projects, from beginner to advanced, and there are loads of great resources available to help you support the young people in your community to take part.
We are running a series of online calls and webinars for mentors and young people to share practical tips and help participants develop their ideas and build their creations. Sign up for the sessions here. All sessions will be recorded, so you can watch them back if you can’t join live.
You can also check out the Coolest Projects guidance page for resources to help you support young people throughout their Coolest Projects journey, including a mentor guide and session plans.
To inspire your coders, encourage them to take a look at the 2023 showcase gallery, where they can explore the incredible projects submitted by participants last year.
Our projects site is also a great place for participants to begin — there are hundreds of free step-by-step project guides to help young people create their own projects, whether they’re experienced tech creators or they’re just getting started.
There’s lots more exciting news to come, from the announcement of our VIP judges to details about this year’s swag, so sign up for email updates to be the first to know. And whether your coders have already made something fun, innovative, or amazing that they want to share, or they’re inspired to make something new, Coolest Projects is the place for them. We can’t wait to see what they create!
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You can now access classroom resources created by us for the T Level in Digital Production, Design and Development. T Levels are a type of vocational qualification young people in England can gain after leaving school, and we are pleased to be able to support T Level teachers and students.
With our new resources, we aim to empower more young people to develop their digital skills and confidence while studying, meaning they can access more jobs and opportunities for further study once they finish their T Levels.
We worked collaboratively with the Gatsby Charitable Foundation on this pilot project as part of their Technical Education Networks Programme, the first time that we have created classroom resources for post-16 vocational education.
T Levels are Technical Levels, 2-year courses for 16- to 18-year-old school leavers. Launched in England in September 2020, T Levels cover a range of subjects and have been developed in collaboration with employers, education providers, and other organisations. The aim is for T Levels to specifically prepare young people for entry into skilled employment, an apprenticeship, or related technical study in further or higher education.
For us, this T Level pilot project follows on from work we did in 2022 to learn more about post-16 vocational training and identify gaps where we could make a difference.
Something interesting we found was the relatively low number of school-age young people who started apprenticeships in the UK in 2019/20. For example, a 2021 Worldskills UK report stated that only 18% of apprentices were young people aged 19 and under. 39% were aged 19-24, and the remaining 43% were people aged 25 and over.
To hear from young people about their thoughts directly, we spoke to a group of year 10 students (ages 14 to 15) at Gladesmore School in Tottenham. Two thirds of these students said that digital skills were ‘very important’ to them, and that they would consider applying for a digital apprenticeship or T Level. When we asked them why, one of the key reasons they gave was the opportunity to work and earn money, rather than moving into further study in higher education and paying tuition fees. One student’s answer was for example, “It’s a good way to learn new skills while getting paid, and also gives effective work experience.”
To support teachers in delivering the Digital Production, Design and Development T Level qualification, we created a new set of resources: curriculum materials as well a project brief with examples to support the Occupational Specialism component of the qualification.
The curriculum materials on the topic ‘Digital environments’ cover content related to computer systems including hardware, software, networks, and cloud environments. They are designed for teachers to use in the classroom and consist of a complete unit of work: lesson plans, slide decks, activities, a progression chart, and assessment materials. The materials are designed in line with our computing content framework and pedagogy principles, on which the whole of our Computing Curriculum is based.
The project brief is a real-world scenario related to our work and gives students the opportunity to problem-solve as though they are working in an industry job.
The T Level project brief materials are available for download now, with the T Level classroom materials coming in the next few weeks.
We hope T Level teachers and students find the resources useful and interesting — if you’re using them, please let us know your thoughts and feedback.
Our thanks to the Gatsby Foundation for collaborating with us on this work to empower more young people to fulfil their potential through the power of computing and digital technologies.
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In our series of community stories, we celebrate some of the wonderful things young people and educators around the world are achieving through the power of technology.
In our latest story, we’re heading to Vivek High School in Mohali, India, to meet Sahibjot, a 14-year-old coding enthusiast who has taken his hobby to the next level thanks to mentorship, Code Club, and the exciting opportunity to take part in the Coolest Projects 2023 global online showcase.
When he was younger, Sahibjot loved playing video games. His interest in gaming led him to discover the world of game development, and he was inspired to find out more and try it out himself. He began to learn to code in his spare time, using tutorials to help him develop his skills.
Keen to share the joy he had experienced from gaming, Sahibjot set himself the challenge of creating a game for his cousin. This project cemented his enthusiasm for coding and developing games of his own.
“I always felt that I have played so many games in my life, why not make one and others will enjoy the same experience that I had as a child.
For my cousin, I made a personal game for him, and he played it and he liked it very much, so once he played it, I felt that, yes, this is what I want to do with my life.” – Sahibjot
While continuing to hone his computing skills at home, Sahibjot heard that his school had started a Code Club. After initially feeling nervous about joining, his enthusiasm was bolstered by the club mentor, Rajan, talking about artificial intelligence and other interesting topics during the session, and he soon settled in.
At Code Club, with support and encouragement from Rajan, Sahibjot continued to develop and grow his coding skills. Alongside his technical skills, he also learned about teamwork and working collaboratively. He embraced the opportunity to help his peers, sharing his knowledge with others and becoming a mentor for younger club members.
“Last year, we joined this coding club together and we became friends. He’s a very friendly person. Whenever we need him, he just quickly helps us. He helps us to troubleshoot, find any bugs, or even fix our codes.” – Akshat, fellow Code Club member
The next step for Sahibjot came when Rajan introduced him and his fellow Code Club members to Coolest Projects. Coolest Projects is a celebration of young digital creators and the amazing things they make with technology. It offers participants the opportunity to share their tech creations in a global, online showcase, and local in-person events celebrating young creators are also held in several countries.
Sahibjot was eager to take part and showcase what he had made. He submitted a Python project, a ping-pong game, to the online showcase, and was very excited to then see his creation receive a special shout-out during the Coolest Projects global livestream event. He was delighted to share this achievement with his friends and family, and he felt proud to be representing his school and his country on a global stage.
“I told everyone around me that there was going to be a livestream and I possibly might be featured in that, so that was really exciting. I learned a lot about just not representing my school and myself as an individual, I learned about representing my whole nation.” — Sahibjot
Sahibjot’s passion for computing has helped shape his aspirations and ambitions. Looking to the future, he hopes to use his technology skills to benefit others and make an impact.
“Using code and technology and all of the things like that, I aspire to make effort to do something with the world, like help out people with technology.” — Sahibjot
To find out how you and young creators you know can get involved in Coolest Projects, visit coolestprojects.org. If the young people in your community are just starting out on their computing journey, visit our projects site for free, fun beginner coding projects.
For more information to help you set up a Code Club in your school, visit codeclub.org.
Join us in celebrating Sahibjot’s inspiring journey by sharing his story on X (formerly Twitter), LinkedIn, and Facebook.
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With the rapid advances in digital technologies like artificial intelligence, it’s more important than ever that every young person has the opportunity to learn how computers are being used to change the world and to develop the skills and confidence to get creative with technology.
There’s no better way to develop those abilities (super powers even) than getting hands-on experience of programming, whether that’s coding an animation, designing a game, creating a website, building a robot buggy, or training an AI classification model. That’s what tens of thousands of young people do every day in Code Clubs all over the world.
We were absolutely thrilled to organise a Code Club at Number Ten Downing Street last week, hosted by the UK Prime Minister’s wife Akshata Murty as part of Lessons at 10.
Lessons at 10 is an initiative to bring school children from all over the UK into Number Ten Downing Street, the official residence of the Prime Minister. Every week different schools visit to attend lessons led by education partners covering all kinds of subjects.
We ran a Code Club for 20 Year 7 students (ages 11 to 12) from schools in Coventry and Middlesex. The young people had a great time with the Silly eyes and Ghostbusters projects from our collections of Scratch projects. Both stone-cold classics in my opinion, and a great place to start if you’re new to programming.
You may have spotted in the photos that the young people were programming on Raspberry Pi computers (the incredible Raspberry Pi 400 made in Wales). We also managed to get our hands on some cool new monitors.
Mrs Murty’s father was one of the founders of Infosys, which ranks among the world’s most successful technology companies, founded in India and now operating all over the world. So it is perhaps no surprise that she spoke eloquently to the students about the importance of every young person learning about technology and seeing themselves as digital creators not consumers.
We were lucky enough to be in one of the rather fancy rooms in Number Ten, featuring a portrait by John Constable of his niece Ada Lovelace, the world’s first computer programmer. Mrs Murty reminded us that one of the lessons we learn from Ada Lovelace is that computer programming combines both the logical and artistic aspects of human intelligence. So true.
Since Code Club’s launch in April 2012, it has grown to be the world’s largest movement of free computing clubs and has supported over 2 million young people to get creative with technology.
Code Clubs provide a free, fun, and safe environment for young people from all backgrounds to develop their digital skills. Run by teachers and volunteers, most Code Clubs take place in schools, and there are also lots in libraries and other community venues.
The Raspberry Pi Foundation provides a broad range of projects that young people use to build their confidence and skills with lots of different hardware and software. The ultimate goal is that they are empowered to combine their logical and artistic skills to create something original. Just like Ada Lovelace did all those years ago.
All of our projects are designed to be self-directed, so young people can learn independently or in groups. That means that you don’t need to be a tech expert to set up or run a Code Club. We provide you with all the support that you need to get started.
If you want to find out more about how to set up a Code Club, visit the website here.
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Since November, registration is open for Mission Space Lab, part of the European Astro Pi Challenge 2023/24. The Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation that gives young people up to age 19 the amazing opportunity to write computer programs that run on board the International Space Station (ISS). It is free to take part and young people can participate in two missions: Mission Zero, designed for beginners, and Mission Space Lab, designed for more experienced coders.
This year, Mission Space Lab has a brand-new format. As well as introducing a new activity for teams to work on, we have created new resources to support teams and mentors, and developed a special tool to help teams test their programs.
A big motivator for these changes was to make the activity more accessible and enable more young people to have their code run in space. Listening to feedback from participants and mentors, we are creating the opportunity for even more teams to submit programs that run on the ISS this year, by offering a specific activity and providing more extensive support materials.
For this year’s mission, ESA astronauts have given teams a specific scientific task to solve: to calculate the speed that the ISS is travelling as it orbits the Earth. People working in science often investigate a specific phenomenon or try to solve a particular problem. They have to use their knowledge and skills and the available tools to find ways to answer their research question. For Mission Space Lab, teams will work just like this. They will look at what sensors are available on the Astro Pi computers on board the ISS, develop a solution, and then write a Python program to execute it. To test their program, they will use the new Astro Pi Replay software tool we’ve created, which simulates running their program on board the ISS.
To help teams and mentors take part in Mission Space Lab, we are providing a variety of supporting materials:
We have also run virtual sessions to help mentors and teams familiarise themselves with the new Mission Space Lab activity, and to ask any technical questions they might have. You can watch the recordings of these sessions on YouTube:
Astro Pi Replay is a new simulation tool that we have developed to support Mission Space Lab teams to test their programs. The tool simulates running programs on the Astro Pi computers on board the ISS. It is a Python library available as a plug-in to install in the Thonny IDE where teams write their programs. Thanks to this tool, teams can develop and test their programs on any computer that supports Python, without the need for hardware like the Astro Pi units on board the ISS.
The Astro Pi Replay tool works by replaying a data set captured by a Mission Space Lab team in May 2023. The data set includes readings from the Astro Pi ‘s sensors, and images taken by its visible-light camera like the ones below. Whenever teams run their programs in Thonny with Astro Pi Replay, the tool replays some of this historical data. That means teams can use the historical data to test their programs and calculations.
One of the benefits of using this simulation tool is that it gives teams a taste of what they can expect if their program is run on the ISS. By replaying a sequence of data captured by the Astro Pis in space, teams using sensors will be able to see what kind of data can be collected, and teams using the camera will be able to see some incredible Earth observation images.
If you’re curious about how Astro Pi Replay works, you’ll be pleased to hear we are making it open source soon. That means you’ll be able to look at the source code and find out exactly what the library does and how.
Community members have consistently reported how amazing it is for teams to receive unique Earth observation photos and sensor data from the Astro Pis, and how great the images and data are to inspire young people to participate in their computing classes, clubs, or events. Through the changes we’ve made to Mission Space Lab this year, we want to support as many young people as possible to have the opportunity to engage in space science and capture their own data from the ISS.
If you want a taste of how fantastic Astro Pi is for learners, watch the story of St Joseph’s, a rural Irish school where participating in Astro Pi has inspired the whole community.
Submissions for Mission Space Lab 2023/24 are open until 19 February 2024, so there’s still time to take part! You can find full details and eligibility criteria at astro-pi.org/mission-space-lab.
If you have any questions about the European Astro Pi Challenge, please get in touch at contact@astro-pi.org.
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In the rapidly evolving digital landscape, students are increasingly interacting with AI-powered applications when listening to music, writing assignments, and shopping online. As educators, it’s our responsibility to equip them with the skills to critically evaluate these technologies.
A key aspect of this is understanding ‘explainability’ in AI and machine learning (ML) systems. The explainability of a model is how easy it is to ‘explain’ how a particular output was generated. Imagine having a job application rejected by an AI model, or facial recognition technology failing to recognise you — you would want to know why.
Establishing standards for explainability is crucial. Otherwise we risk creating a world where decisions impacting our lives are made by opaque systems we don’t understand. Learning about explainability is key for students to develop digital literacy, enabling them to navigate the digital world with informed awareness and critical thinking.
AI models can have a significant impact on people’s lives in various ways. For instance, if a model determines a child’s exam results, parents and teachers would want to understand the reasoning behind it.
Artists might want to know if their creative works have been used to train a model and could be at risk of plagiarism. Likewise, coders will want to know if their code is being generated and used by others without their knowledge or consent. If you came across an AI-generated artwork that features a face resembling yours, it’s natural to want to understand how a photo of you was incorporated into the training data.
Explainability is about accountability, transparency, and fairness, which are vital lessons for children as they grow up in an increasingly digital world.
There will also be instances where a model seems to be working for some people but is inaccurate for a certain demographic of users. This happened with Twitter’s (now X’s) face detection model in photos; the model didn’t work as well for people with darker skin tones, who found that it could not detect their faces as effectively as their lighter-skinned friends and family. Explainability allows us not only to understand but also to challenge the outputs of a model if they are found to be unfair.
In essence, explainability is about accountability, transparency, and fairness, which are vital lessons for children as they grow up in an increasingly digital world.
Some models, like decision trees, regression curves, and clustering, have an in-built level of explainability. There is a visual way to represent these models, so we can pretty accurately follow the logic implemented by the model to arrive at a particular output.
By teaching students about AI explainability, we are not only educating them about the workings of these technologies, but also teaching them to expect transparency as they grow to be future consumers or even developers of AI technology.
A decision tree works like a flowchart, and you can follow the conditions used to arrive at a prediction. Regression curves can be shown on a graph to understand why a particular piece of data was treated the way it was, although this wouldn’t give us insight into exactly why the curve was placed at that point. Clustering is a way of collecting similar pieces of data together to create groups (or clusters) with which we can interrogate the model to determine which characteristics were used to create the groupings.
However, the more powerful the model, the less explainable it tends to be. Neural networks, for instance, are notoriously hard to understand — even for their developers. The networks used to generate images or text can contain millions of nodes spread across thousands of layers. Trying to work out what any individual node or layer is doing to the data is extremely difficult.
Regardless of the complexity, it is still vital that developers find a way of providing essential information to anyone looking to use their models in an application or to a consumer who might be negatively impacted by the use of their model.
One suggested strategy to add transparency to these models is using model cards. When you buy an item of food in a supermarket, you can look at the packaging and find all sorts of nutritional information, such as the ingredients, macronutrients, allergens they may contain, and recommended serving sizes. This information is there to help inform consumers about the choices they are making.
Model cards attempt to do the same thing for ML models, providing essential information to developers and users of a model so they can make informed choices about whether or not they want to use it.
Model cards include details such as the developer of the model, the training data used, the accuracy across diverse groups of people, and any limitations the developers uncovered in testing.
Model cards should be accessible to as many people as possible.
A real-world example of a model card is Google’s Face Detection model card. This details the model’s purpose, architecture, performance across various demographics, and any known limitations of their model. This information helps developers who might want to use the model to assess whether it is fit for their purpose.
As the world settles into the new reality of having the amazing power of AI models at our disposal for almost any task, we must teach young people about the importance of transparency and responsibility.
As a society, we need to have hard discussions about where and when we are comfortable implementing models and the consequences they might have for different groups of people. By teaching students about explainability, we are not only educating them about the workings of these technologies, but also teaching them to expect transparency as they grow to be future consumers or even developers of AI technology.
Most importantly, model cards should be accessible to as many people as possible — taking this information and presenting it in a clear and understandable way. Model cards are a great way for you to show your students what information is important for people to know about an AI model and why they might want to know it. Model cards can help students understand the importance of transparency and accountability in AI.
This article also appears in issue 22 of Hello World, which is all about teaching and AI. Download your free PDF copy now.
If you’re an educator, you can use our free Experience AI Lessons to teach your learners the basics of how AI works, whatever your subject area.
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Each year, young people all over the world share and celebrate their amazing tech creations by taking part in Coolest Projects, our digital technology showcase. Our global online showcase and local in-person events give kids a wonderful opportunity to celebrate their creativity with their communities, explore other young creators’ tech projects, and gain inspiration and encouragement for their future projects.
Now, visitors to the Young V&A museum in London can also be inspired by some of the incredible creations showcased at Coolest Projects. The museum has recently reopened after a large reimagining, and some of the inspiring projects by Coolest Projects 2022 participants are now on display in the Design Gallery, ready to spark digital creativity among more young people.
Many Coolest Projects participants showcase projects that they created to make an impact and solve a real-world problem that’s important to them, for example to help members of their local community, or to protect the environment.
One example on display in the Young V&A gallery is EleVoc, by 15-year-old Chinmayi from India. Chinmayi was inspired to create her project after she and her family faced a frightening encounter:
“My family and I are involved in wildlife conservation. One time we were charged by elephants even though we were only passing by in a Jeep. This was my first introduction to human–animal conflict, and I wanted to find a way to solve it!” – Chinmayi
The experience prompted Chinmayi to create EleVoc, an early-warning device designed to reduce human–elephant conflict by detecting and classifying different elephant sounds and alerting nearby villages to the elephants’ proximity and behaviour.
Also exhibited at the Young V&A is the hardware project Gas Leak Detector by Sashrika, aged 11, from the USA. Gas Leak Detector is a device that detects if a fuel tank for a diesel-powered heating system is leaking and notifies householders through an app in a matter of second.
Sashrika knew this invention could really make a difference to people’s lives. She explained, “Typically, diesel gas tanks for heating are in the basement where people don’t visit every day. Leakage may be unnoticed and lead to fire or major repair cost.”
As well as projects designed to solve problems, Coolest Projects also welcomes young people who create things to entertain or have fun.
At the Young V&A, visitors can enjoy the fun, fast-paced game project Runaway Nose, by 10-year-old Harshit from Ireland. Runaway Nose uses facial recognition, and players have to use their nose to interact with the prompts on the screen.
Harshit shared the motivation behind his project:
“I wanted to make a fun game to get you thinking fast and that would get you active, even on a rainy day.” – Harshit
We can confirm Runaway Nose is a lot of fun, and a must-do activity for people of all ages on a visit to the museum.
If you are in London, make sure to head to the Young V&A to see Chinmayi’s, Sashrika’s, and Harshit’s projects, and many more. We love seeing the ingenuity of the global community of young tech creators celebrated, and hope it inspires you and your young people.
With that in mind, we are excited that Coolest Projects will be back in 2024. Registrations for the global Coolest Projects online showcase will be open from 14 February to 22 May 2024, and any young creator up to age 18 anywhere in the world can get involved. We’ll also be holding in-person Coolest Projects events for young people in Ireland and the UK. Head to the Coolest Projects website to find out more.
Coolest Projects is for all young people, no matter their level of coding experience. Kids who are just getting started and would like to take part can check out the free project guides on our projects site. These offer step-by-step guidance to help everyone make a tech project they feel proud of.
To always get the latest news about all things Coolest Projects, from event updates to the fun swag coming for 2024, sign up for the Coolest Projects newsletter.
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We support two networks of coding clubs where young people around the world discover the countless possibilities of creating with digital technologies.
Every year, we send out a survey to volunteers at all the clubs we support. Today we share some highlights from the findings and what we’re planning next.
The simple answer is: to help make clubs even better for everyone involved! Educators and volunteers are doing a remarkable job in helping young people learn about computing and coding, so we want to know more about them, about how they run their clubs, and what impact the club sessions have for young people.
By knowing more about clubs — how frequently club leaders run them, what resources they use, what they would like more of — we can continue to improve the learning experience for educators, volunteers, and young people involved in our clubs.
This year in March we sent out our survey to all Code Clubs and CoderDojos around the world, and we heard back from almost 500. As always, the results were very positive, and they also gave us a lot of useful information on how we can continue to improve our support for clubs all over the world.
Based on the survey, we estimate that at the time, the network of over 4200 Code Clubs and 700 CoderDojos was reaching almost 139,000 young people globally. The global community of clubs has continued to grow since then, with a now even larger network of volunteers supporting ever more young people.
According to the survey, the majority of young people attending clubs are aged between 8 and 13, but clubs host young people as young as 6 and as old as 18. It was great to hear about the participation of girls, and we’d love to see this rise even higher: respondents told us that 42% of their Code Club attendees and 30% of their CoderDojo attendees are female.
Respondents feel that attending club sessions improves young peoples’ interest and engagement in computing and programming, and increases their understanding of the usefulness of computing.
None of these young people would be able to attend clubs without the great work of teams of educators and volunteers. Based on the survey, we estimate that at the time of the survey, there were over 10,300 Code Club leaders and almost 4000 CoderDojo champions around the world. Many survey respondents said that they were motivated to start volunteering after attending a club themselves.
Community is at the heart of clubs and the clubs networks: over 80% of respondents said that belonging to a global community of clubs helps motivates them to volunteer at their own club.
Clubs focus on a wide range of topics and programming languages. Scratch is overwhelmingly popular, with over 95% of respondents telling us that they used Scratch in club sessions in the previous year. Micro:bit projects and Python-based programming were also very popular. Club leaders told us that in future they would like to offer more activities around AI applications, as well as around games and mobile apps.
Club leaders told us that being part of a Code Club or CoderDojo affects young people positively. Respondents feel that attending club sessions improves young peoples’ skills and interest in computing and programming, and increases their understanding of the usefulness of computing. Almost 90% of club leaders also agree that after attending a club, young people are interested in additional experiences of learning about computing and programming.
Attending also positively affects young people’s wider skills and attitudes, with club leaders stating that young people who attend improve their personal confidence, independence in learning, and creative thinking.
Young people who attend improve their personal confidence, independence in learning, and creative thinking.
We were pleased to find out that most Code Club leaders, who run their sessions in schools, think that their clubs increase the visibility of computing within their school. Many also said that the attendees’ parents and guardians value their clubs as opportunities for their children.
We want to keep providing clubs with support to increase their positive impact on young people. Thanks to the survey results, we know to focus our work on providing training opportunities for club volunteers, as well as supporting club leaders to recruit volunteers and advertise their clubs to more young people.
You can read the survey report to dive deeper into our findings.
As we take an impact-focused approach to our work, we are currently partnering with Durham University on an evaluation of Code Clubs in UK schools. The evaluation will provide further insights for how we can best support people around the world to run clubs that provide welcoming spaces where all kids can learn to create with digital technologies.
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The day after the successful meetup with our Global Clubs Partner organisations based in Africa, our team and some of our partners enjoyed participating in the Coolest Projects South Africa 2023 event to meet young tech creators and help out as project judges. Here are some of our impressions.
This is the fourth year of a partner-run, regional version of Coolest Projects — our world-leading showcase for young tech creators — taking place in South Africa, led by David Campey. David is Director of Coder LevelUp, one of our Global Clubs Partners growing and supporting a network of CoderDojos and Code Clubs in the country, and involved in the CoderDojo movement for a whole decade.
There was a buzz of anticipation and excitement at the Cape Town Science Centre as young coders from age 5 to 18 and various backgrounds gathered on this sunny Saturday morning to showcase their coding creations and inventions at Coolest Projects South Africa. From fun games and animations on Scratch, to cool websites created with HTML and CSS, to fantastic Python-based hardware solutions to real-world challenges — every young creator brought along a project they’d created to proudly showcase and celebrate.
While chatting with the creators and discovering what had motivated their projects, we met up with 11-year-old Luhle, who was delighted to take us through the ‘Moon conversation’ animation she had coded in Scratch.
The animation involved a Spanish conversation between two people who journeyed to the moon and back. Luhle had created her animation because of her love for languages and in response to a challenge posed to her class by her teacher: to learn 5 languages. While her mother tongue is isiXhosa, she is confident in English, is learning Afrikaans, has started teaching herself Spanish, and would love to learn Korean.
We also met with 16-year-old Kayden, who showcased a project he’d made to address a real-world challenge. He told us he had always struggled to concentrate in class — a challenge that many young people face — and he wanted to build an alternative solution to the established medications. Using vibration sensors and two microcontrollers, he created a digital device to prompt users when they are no longer paying attention in class. With his friend Carl, he successfully tested the device on a meaningful sample of Grade 1–3 learners (ages 7–9).
Kayden is now developing this low-cost innovative solution to include a heart rate monitor to help to detect when a user loses focus, and he wants this to be a solution that’s widely accessible and affordable for all South African children. One of the judges, our partner Akwabi Paul from Tech Kidz Africa in Kenya, was greatly impressed and motivated by Kayden’s work, and took time to advise Kayden on the next steps to turn his invention into a commercial product.
During the event we also met members of Mrs Hill’s coding club and learnt about Mrs Hill’s experience of nurturing a love and interest for coding and robotics at CBC St Johns Parklands in Cape Town.
Since 2020, Mrs Hills has been providing coding lessons to all school classes — learners aged 6 to 12 years — as well as an after-school coding and robotics club. She approaches her lessons by introducing and demonstrating coding skills and then presenting her learners with a problem to solve collaboratively. In her words, ‘Learners find more interest in learning practically.’
That’s why Coolest Projects is the perfect fit for her and her young people. 4 of her club members took part in Coolest Projects South Africa 2022. This year, she was proud to enter 11 participants, 3 of whom were chosen as judges’ favourites.
After the showcasing and judging, the Coolest Projects South Africa event culminated in a hearty celebration of all that the young tech creators had presented. David Campey’s passion for nurturing coding literacy, digital making skills, and innovative thinking among learners from different walks of life made the whole day a truly enjoyable, inclusive event for the young creators.
It was inspiring, no doubt, for our other African partners who participated as judges and are now keen to host Coolest Projects events back in their home countries.
If you and your young people based anywhere on the globe feel inspired to showcase digital tech creations, you can get involved in our Coolest Projects 2024 online showcase! It’s free and open to any young tech creator up to age 18.
Sign up to the Coolest Projects newsletter to be the first to hear all updates, for example when showcase registration opens on 14 February.
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Today’s blog is written by Dr Alex Hadwen-Bennett, who we worked with to find out primary school learners’ experiences of engaging with culturally relevant Computing lessons. Alex is a Lecturer in Computing Education at King’s College London, where he undertakes research focusing on inclusive computing education and the pedagogy of making.
Despite many efforts to make a career in Computing more accessible, many groups of people are still underrepresented in the field. For instance, a 2022 report revealed that only 22% of people currently working in the IT industry in the UK are women. Additionally, among learners who study Computing at schools in England, Black Caribbean students are currently one of the most underrepresented groups. One approach that has been suggested to address this underrepresentation at school is culturally relevant pedagogy.
For this reason, a particular focus of the Raspberry Pi Foundation’s academic research programme is to support Computing teachers in the use of culturally relevant pedagogy. This pedagogy involves developing learning experiences that deliberately aim to enable all learners to engage with and succeed in Computing, including by bringing their culture and interests into the classroom.
The Foundation’s work in this area started with the development of guidelines for culturally relevant and responsive teaching together with a group of teachers and external researchers. The Foundation’s researchers then explored how a group of Computing teachers employed the guidelines in their own teaching. In a follow-on study funded by Cognizant, the team worked with 13 primary school teachers in England to adapt Computing lessons to make them culturally relevant for their learners. In this process, the teachers adapted a unit on photo editing for Year 4 (ages 8–9), and a unit about vector graphics for Year 5 (ages 9–10). As part of the project, I worked with the Foundation team to analyse and report on data gathered from focus groups of primary learners who had engaged with the adapted units.
For the focus groups, the Foundation team asked teachers from three schools to each choose four learners to take part. All children in the three focus groups had taken part in all the lessons involving the culturally adapted resources. The children were both boys and girls, and came from diverse cultural backgrounds where possible.
The questions for the focus groups were prepared in advance and covered:
“I feel happy that I see myself represented in some way.”
“It was nice to do something that actually represented you in many different ways, like your culture and your background.”
– Statements of learners who participated in the focus groups
When the learners were asked about what they did in their Computing lessons, most of them made references to working with and manipulating graphics; fewer made references to programming and algorithms. This emphasis on graphics is likely related to this being the most recent topic the learners engaged with. The learners were also asked about their reflections on the culturally adapted graphics unit that they had recently completed. Many of them felt that the unit gave them the freedom to incorporate things that related to their interests or culture. The learners’ responses also suggested that they felt represented in the work they completed during the unit. Most of them indicated that their interests were acknowledged, whereas fewer mentioned that they felt their cultural backgrounds were highlighted.
“Anyone can be good at computing if they have the passion to do it.”
– Statement by a learner who participated in a focus group
When considering who does computing, the learners made multiple references to people who keep trying or do not give up. Whereas only a couple of learners said that computer scientists need to be clever or intelligent to do computing. A couple of learners suggested that they believed that anyone can do computing. It is encouraging that the learners seemed to associate being good at computing with effort rather than with ability. However, it is unclear whether this is associated with the learners engaging with the culturally adapted resources.
While this was a small-scale study, the focus groups findings do suggest that engaging with culturally adapted resources can make primary learners feel more represented in their Computing lessons. In particular, engaging with an adapted unit led learners to feel that their interests were recognised as well as, to a lesser extent, their cultural backgrounds. This suggests that primary-aged learners may identify their practical interests as the most important part of their background, and want to share this in class.
Finally, the responses of the learners suggest that they feel that perseverance is a more important quality than intelligence for success in computing and that anyone can do it. While it is not possible to say whether this is directly related to their engagement with a culturally adapted unit, it would be an interesting area for further research.
You can find out more about culturally relevant pedagogy and the Foundation’s research on it, for example by:
The Foundation would like to extend thanks to Cognizant for funding this research, and to the primary computing teachers and learners who participated in the project.
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Underrepresentation in computing is a widely known issue, in industry and in education. To cite some statistics from the UK: a Black British Voices report from August 2023 noted that 95% of respondents believe the UK curriculum neglects black lives and experiences; fewer students from working class backgrounds study GCSE Computer Science; when they leave formal education, fewer female, BAME, and white working class people are employed in the field of computer science (Kemp 2021); only 21% of GCSE Computer Science students, 15% at A level, and 22% at undergraduate level are female (JCQ 2020, Ofqual 2020, UCAS 2020); students with additional needs are also underrepresented.
Such statistics have been the status quo for too long. Many Computing teachers already endeavour to bring about positive change where they can and engage learners by including their interests in the lessons they deliver, so how can we support them to do this more effectively? Extending the reach of computing so that it is accessible to all also means that we need to consider what formal and informal values predominate in the field of computing. What is the ‘hidden’ curriculum in computing that might be excluding some learners? Who is and who isn’t represented?
In a recent research seminar, Katharine Childs from our team outlined a research project we conducted, which included a professional development workshop to increase primary teachers’ awareness of and confidence in culturally relevant pedagogy. In the workshop, teachers considered how to effectively adapt curriculum materials to make them culturally relevant and engaging for the learners in their classrooms. Katharine described the practical steps teachers took to adapt two graphics-related units, and invited seminar participants to apply their learning to a graphics activity themselves.
Culturally relevant pedagogy is a teaching framework which values students’ identities, backgrounds, knowledge, and ways of learning. By drawing on students’ own interests, experiences and cultural knowledge educators can increase the likelihood that the curriculum they deliver is more relevant, engaging and accessible to all.
The idea of culturally relevant pedagogy was first introduced in the US in the 1990s by African-American academic Gloria Ladson-Billings (Ladson-Billings 1995). Its aim was threefold: to raise students’ academic achievement, to develop students’ cultural competence and to promote students’ critical consciousness. The idea of culturally responsive teaching was later advanced by Geneva Gay (2000) and more recently brought into focus in US computer science education by Kimberly Scott and colleagues (2015). The approach has been localised for England by Hayley Leonard and Sue Sentance (2021) in work they undertook here at the Foundation.
Katharine began her presentation by explaining that the professional development workshop in the Primary culturally adapted resources for computing project built on two of our previous research projects to develop guidelines for culturally relevant and responsive computing and understand how teachers used them in practice. This third project ran as a pilot study funded by Cognizant, starting in Autumn 2022 with a one-day, in-person workshop for 13 primary computing teachers.
Katharine then introduced us to the 10 areas of opportunity (AO) our research at the Raspberry Pi Computing Education Research Centre had identified for culturally relevant pedagogy. These 10 areas were used as practical prompts to frame the workshop discussions:
At first glance it is easy to think that you do most of those things already, or to disregard some items as irrelevant to the computing curriculum. What would your own cultural identity (see AO2) have to do with computing, you might wonder. But taking a less complacent perspective might lead you to consider all the different facets that make up your identity and then to think about the same for the students you teach. You may discover that there are many areas which you have left untapped in your lesson planning.
Katharine explained how this is where the professional development workshop showed itself as beneficial for the participants. It gave teachers the opportunity to reflect on how their cultural identity impacted on their teaching practices — as a starting point to learning more about other aspects of the culturally relevant pedagogy approach.
Our researchers were interested in how they could work alongside teachers to adapt two computing units to make them more culturally relevant for teachers’ specific contexts. They used the Computing Curriculum units on Photo Editing (Year 4) and Vector Graphics (Year 5).
Katharine illustrated some of the adaptations teachers and researchers working together had made to the emoji activity above, and which areas of opportunity (AO) had been addressed; this aspect of the research will be reported in later publications.
Although the number of participants in this pilot study was small, the findings show that the professional development workshop significantly increased teachers’ awareness of culturally relevant pedagogy and their confidence in adapting resources to take account of local contexts:
These quantitative shifts in perspective indicate a positive effect of the professional development pilot.
Katharine described that in our qualitative interviews with the participating teachers, they expressed feeling that their understanding of culturally relevant pedagogy had increased and they recognized the many benefits to learners of the approach. They valued the opportunity to discuss their contexts and to adapt materials they currently used with other teachers, because it made it a more ‘authentic’ and practical professional development experience.
The seminar ended with breakout sessions inviting viewers to consider possible adaptations that could be made to the graphics activities which had been the focus of the workshop.
In the breakout sessions, attendees also discussed specific examples of culturally relevant teaching practices that had been successful in their own classrooms, and they considered how schools and computing educational initiatives could support teachers in their efforts to integrate culturally relevant pedagogy into their practice. Some attendees observed that it was not always possible to change schemes of work without a ‘whole-school’ approach, senior leadership team support, and commitment to a research-based professional development programme.
The seminar reminds us that the education system is not culture neutral and that teachers generally transmit the dominant culture (which may be very different from their students’) in their settings (Vrieler et al, 2022). Culturally relevant pedagogy is an attempt to address the inequities and biases that exist, which result in many students feeling marginalised, disenfranchised, or underachieving. It urges us to incorporate learners’ cultures and experiences in our endeavours to create a more inclusive computing curriculum; to adopt an intersectional lens so that all can thrive.
As a pilot study, the workshop was offered to a small cohort of 13, yet the findings show that the intervention significantly increased participants’ awareness of culturally relevant pedagogy and their confidence in adapting resources to take account of local contexts.
Of course there are many ways in which teachers already adapt resources to make them interesting and accessible to their pupils. Further examples of the sort of adaptations you might make using these areas of opportunity include:
Can you see an opportunity for integrating culturally relevant pedagogy in your classroom? We would love to hear about examples of culturally relevant teaching practices that you have found successful. Let us know your thoughts or questions in the comments below.
You can watch Katharine’s seminar here:
You can download her presentation slides on our ‘previous seminars’ page, and you can read her research paper.
To get a practical overview of culturally relevant pedagogy, read our 2-page Quick Read on the topic and download the guidelines we created with a group of teachers and academic specialists.
Tomorrow we’ll be sharing a blog about how the learners who engaged with the culturally adapted units found the experience, and how it affected their views of computing. Follow us on social media to not miss it!
On 12 December we’ll host the last seminar session in our series on primary (K-5) computing. Anaclara Gerosa will share her work on how to design and structure early computing activities that promote and scaffold students’ conceptual understanding. As always, the seminar is free and takes place online at 17:00–18:30 GMT / 12:00–13:30 ET / 9:00–10:30 PT / 18:00–19:30 CET. Sign up and we’ll send you the link to join on the day.
In 2024, our new seminar series will be about teaching and learning programming, with and without AI tools. If you’re signed up to our seminars, you’ll receive the link to join every monthly seminar.
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Big news for young tech creators: Coolest Projects will return in 2024. The world’s leading showcase for young creators of digital tech will be open for registration in the online gallery, and we want young people worldwide to showcase their tech projects.
In 2024, we are hosting the Coolest Projects online showcase and livestream celebration for all young creators around the world, and also in-person events in the UK and Ireland for young creators who live there.
All young tech creators can take part — for free — in the Coolest Projects online showcase:
Coolest Projects is an opportunity for young tech creators to share what they have made with the world. Young people register their tech creations to show them in the Coolest Projects online showcase gallery. Alongside mentors, parents, friends, and family members in their local and global communities, they can explore the gallery and celebrate what they and their peers have made.
If your kids want to learn about creating with technology, check out our free guided coding project paths. These paths are designed to support all young people to learn how to make their own tech projects and develop their coding skills. For example:
Young creators can take a look at the Coolest Projects 2023 online showcase gallery for inspiration if they are not sure what they want to make. You can also watch the story of Zaahra and Eesa, siblings who participated in Coolest Projects 2020.
If you are a young creator in Northern Ireland, the Republic of Ireland, or the UK, then Coolest Projects is also coming to you in person in 2024. Participants will be able to meet other young tech creators, connect to their community, and celebrate each other’s creations. Young people are encouraged to take part in both the Coolest Projects global online showcase and their local in-person event.
Coolest Projects Ireland will take place at DCU St Patrick’s College Campus, Drumcondra in Dublin. It’s open to young creators in Northern Ireland and the Republic of Ireland, and their families and friends are invited to come along to celebrate them and see all the incredible projects on show. Participants can apply for partial bursaries for the costs of attending the event.
Very soon we will announce the date and venue for Coolest Projects UK for all young creators in the UK. Sign up for email updates to be the first to hear about it. We will also share full details of each in-person event on the Coolest Projects website when registration opens.
If there’s not an in-person Coolest Projects event near you, you can still join in the fun: the Coolest Projects online showcase is open to any young creator aged up to 18, from anywhere in the world. We also work with brilliant partner organisations around the world to bring Coolest Projects events to their countries and communities. Sign up to the Coolest Projects newsletter to be the first to know about any in-person event in your country.
Coolest Projects registration opens soon in 2024, and young creators can start thinking of ideas and working on their projects now. Or if young people have already made something they are really proud of, they can showcase that creation once registration is open.
Sign up for email updates to always get the latest news about all things Coolest Projects, from event updates to the fun swag coming for 2024.
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Since launching our free online courses about computing on the edX platform back in August, we’ve been training course facilitators and analysing the needs of educators around the world. We want every course participant to have a great experience learning with us — read on to find out what we’re doing right now and into 2024 to ensure this.
Educators of all kinds are key for supporting children and young people to engage with computing technology and develop digital skills. You might be a professional teacher, or a parent, volunteer, youth worker, librarian… there are so many roles in which people share knowledge with young learners.
That’s why our online courses are designed to support any kind of educator to:
We are constantly improving our online courses based on your feedback, the latest education research, and the insights our team members gain through supporting you on your course learning journeys. Three principles guide these improvements: accessibility, scalability, and sustainability.
Our online courses are used by people who live around the world and bring various knowledge and experiences. Some participants are classroom teachers, others have computing experience from their job and want to volunteer at a kids’ coding club, and some may be parents who want to support their children. It’s important to us that our courses are relevant and accessible to all kinds of adult learners.
We’re currently working to:
When we think about the scalability of our courses, we think about how to best support as many educators around the world as possible. If we can make the jobs of all educators easier, whatever their setting is like, then we are making the right choices.
We’re currently working to:
The educators who take our courses work to achieve amazing things, and this means they are often busy. That they take the time to complete one of our courses to learn new things is a commitment we want to make sure is rewarded. The learning you get from participating in our online courses should continue to benefit you far beyond the time you spend completing it. This is what we mean by sustainability.
We’re currently working to:
Our work to improve the accessibility, scalability, and sustainability of our courses will continue into 2024, and these three principles will likely be part of our online training strategy for the following year too.
If you’d like to support young people in your life to learn about computing and digital technologies, take one of our free courses now and learn something new. We have twenty courses available right now and they are totally free.
We are also looking for adult testers for new course content. So if you’re any kind of educator and would like to test upcoming online course content and share your feedback and experiences, please send us a message with the subject ‘Educator training’.
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In our series of community stories, we celebrate some of the amazing young people and educators who are using their passion for technology to create positive change in the world around them.
In our latest story, we’re sharing the inspiring journey of St Joseph’s Secondary School in Rush, Ireland. Over the past few years, the school community has come together to encourage coding and digital skills, harnessing the European Astro Pi Challenge as an opportunity to kindle students’ enthusiasm for tech and teamwork.
We caught up with some of the educators and students at St Joseph’s, fresh off the success of their participation in another round of Astro Pi, to delve a little deeper into the school’s focus on making opportunities to engage with computing technologies accessible to all.
St Joseph’s Secondary School is in the heart of Rush, a rural town steeped in agricultural heritage. The school houses a diverse student population coming from the local multigenerational farming families as well as families who’ve been drawn to Rush more recently by its beautiful countryside and employment opportunities. St Joseph’s leadership team has responded to the changing demographics and increase of its student population by adapting and growing the school’s curriculum to meet the evolving needs of the young people and help them build a strong community.
One of the school’s most popular initiatives has been teaching coding from first year (ages 12–13). This proactive approach has resonated with many students, including Kamaya, a member of the school’s 2022/23 Astro Pi cohort, who first discovered her passion for space science and computing through the movie Interstellar.
I remember the first time I was like, ‘OK, space is cool’ is when I watched a movie. It was called Interstellar. I [realised] I might want to do something like that in my future. So, when I came to [St Joseph’s] secondary school, I saw coding as a subject and I was like, ‘Mum, I’ve got to do coding.’
Kamaya, student at St Joseph’s
A key person encouraging St Joseph’s students to give coding a try has been Mr Murray, or Danny as he is fondly referred to by students and staff alike. Danny was introduced to the importance of engaging with computing technologies while teaching science at a school in England: he attended a Code Club where he saw kids building projects with Raspberry Pis, and he couldn’t wait to get involved. Growing his knowledge from there, Danny changed subject focus when he moved back to Ireland. He took on the challenge of helping St Joseph’s expand their computer science offering, along with leading on all IT-related issues.
When the school introduced mandatory coding taster sessions for all first-year students, Danny was blown away by the students’ eagerness and wanted to provide further opportunities for them to see what they could achieve with digital technologies.
This is where Astro Pi came in. After hearing about this exciting coding challenge through an acquaintance, Danny introduced it to his computer science class, as well as extending an open invitation to all St Joseph’s students. The uptake was vast, especially once he shared that the young people could become the recipients of some very exciting photos.
You get to see photos of Earth that nobody has ever seen. Imagine just talking to somebody and saying, ‘Oh, there’s a picture of the Amazon. I took that picture when I was 14. From space.’
Danny Murray, computing teacher at St Joseph’s
Danny’s mission is to instil in his students the belief that they can achieve anything. Collaborating on Astro Pi projects has enabled young people at St Joseph’s to team up and uncover their strengths, and has helped foster a strong community.
The students’ sense of community has transcended Danny’s classroom, creating a culture of enthusiasm for digital skills at St Joseph’s. Today, a dedicated team of students is in charge of solving tech-related challenges within the school, as Deputy Principal Darren Byrne explains:
Our own students actually go class to class, repairing tech issues. So, every day there are four or five students going around checking PCs in classrooms. They […] give classes to our first-year students on app usage.
Darren Byrne, Deputy Principal at St Joseph’s
It’s invested in the whole school [now], the idea that students can look after this kind of technology themselves. We’re the ones reaching out for help from the students!
To find out how you can get involved in Astro Pi, visit astro-pi.org for further information, deadlines, and more. If you would like to learn more about the other free resources we have available to help you inspire a coding community in your school, head to www.raspberrypi.org/teach.
Help us celebrate St Joseph’s Secondary School by sharing their story on X (formerly Twitter), LinkedIn, and Facebook.
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Today we’re calling all young people who are excited to explore coding and space science, and the mentors who want to support and inspire them on their journey. Astro Pi Mission Space Lab is officially open again, offering young people all over Europe the amazing chance to have their code for a science experiment run in space on the International Space Station (ISS).
With this year’s Mission Space Lab, astronauts from the European Space Agency are setting young people a task: to write a computer program that runs on the ISS and calculates the speed at which the ISS is orbiting planet Earth. Participation in Mission Space Lab is completely free.
Here’s ESA astronaut candidate Rosemary Coogan to introduce this year’s mission:
Mission Space Lab invites young people up to age 19 to work in teams of 2 to 6 and write a Python program for the Astro Pi computers on board the ISS to collect data and calculate the speed at which the ISS is travelling.
Your role as a mentor is to support teams as they design and create their program — with our free guidance resources to help you and your young creators.
We want as many young people as possible to have the chance to take part in Mission Space Lab, so the way in which teams solve the task set by the ESA astronauts can be different depending on the experience of your team:
The Astro Pis are two Raspberry Pi computers stationed on the ISS, each equipped with a High Quality Camera, a Sense HAT add-on board with a number of sensors, and a Coral machine learning accelerator. Each Astro Pi has a hard casing designed especially for space travel.
There are lots of ways to use sensor data from the Astro Pis to calculate the speed of the ISS, so young people can get creative solving their Mission Space Lab task while learning fascinating facts about physics and the inner workings of the ISS.
All Mission Space Lab participants whose programs run on the ISS will receive a certificate recognising their achievement, and they’ll get the chance to attend a Q&A webinar with an ESA astronaut. Teams also receive back data from the ISS based on their Mission Space Lab programs, for example photos or sensor measurements. That means you’ll have the option to explore and use that data in follow-on activities with your young people.
We are providing lots of supporting materials to help you and your team with Mission Space Lab:
Mission Space Lab is open for submissions from today, 6 November 2023, until 19 February 2024.
Visit the Astro Pi website for full details and eligibility criteria: astro-pi.org/mission-space-lab
The European Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation.
You can keep up with all Astro Pi news by following the Astro Pi X account (formerly Twitter) or signing up to the newsletter at astro-pi.org.
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The UK Bebras Challenge is back and ready to accept entries from schools for its annual event, which runs from 6 to 17 November.
More than 3 million students from 59 countries took part in the Bebras Computational Thinking Challenge in 2022. In the UK alone, over 365,000 students participated. Read on to find out how you can get your school involved.
“This is now an annual event for our Year 5 and 6 students, and one of the things I actually love about it is the results are not always what you might predict. There are children who have a clear aptitude for these puzzles who find this is their opportunity to shine!”
– Claire Rawlinson, Primary Teacher, Lancashire
Bebras is a free, annual challenge that helps schools introduce computational thinking to their students. No programming is involved, and it’s completely free for schools to enter. All Bebras questions are self-marking.
We’re making Bebras accessible by offering age-appropriate challenges for different school levels and a challenge tailored for visually impaired students. Schools can enter students from age 6 to 18 and know they’ll get interesting and challenging (but not too challenging) activities.
Students aged 10 to 18 who do particularly well will get invited to the Oxford University Computing Challenge (OUCC).
We want young people to get excited about computing. Through Bebras, they will learn about computational and logical thinking by answering questions and solving problems.
Bebras questions are based on classic computing problems and are presented in a friendly, age-appropriate way. For example, an algorithm-based puzzle for learners aged 6 to 8 is presented in terms of a hungry tortoise finding an efficient eating path across a lawn; for 16- to 18-year-olds, a difficult problem based on graph theory asks students to sort out quiz teams by linking quizzers who know each other.
“This has been a really positive experience. Thank you. Shared results with Head and Head of Key Stage 3. Really useful for me when assessing Key Stage 4 options.”
– Secondary teacher, North Yorkshire
Here’s a Bebras question for the Castors category (ages 8 to 10) from 2021. You will find the answer at the end of this blog.
A robot picks up litter.
Question: Which kind of litter will the robot pick up last?
The Bebras challenge for UK schools takes place from 6 to 17 November. Register at bebras.uk/admin to get free access to the challenge.
By registering, you also get access to the Bebras back catalogue of questions, from which you can build your own quizzes to use in your school at any time during the year. All the quizzes are self-marking, and you can download your students’ results for your mark book. Schools have reported using these questions for end-of-term activities, lesson starters, and schemes of lessons about computational thinking.
The answer to the example puzzle is:
The image below shows the route the robot takes by following the instructions:
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Throughout this year, space agencies have been embarking on new missions to explore our solar system, and young people can get involved too through the European Astro Pi Challenge 2023/24, which we’re launching today.
In the past few months India’s Chandrayaan-3 mission landed near the Moon’s south pole, NASA’s Parker Solar Probe flew by Venus on its way to the sun, and the SpaceX Crew-7 launched to the International Space Station (ISS), led by ESA astronaut Andreas Mogensen. We’re especially excited about Andreas’ mission because he’s the astronaut who will help to run young people’s Astro Pi programs on board the ISS this year.
As you may know, the European Astro Pi Challenge gives young people the amazing opportunity to conduct scientific experiments in space by writing computer programs for the Astro Pis, special Raspberry Pi computers on board the ISS.
The Astro Pi Challenge is free and offers two missions for young people: Mission Zero is an inspiring activity for introducing kids to text-based programming with Python. Mission Space Lab gives teams of young people the chance to take on a more challenging programming task and stretch their coding and science skills.
Participation in Astro Pi is open to young people up to age 19 in ESA Member States (see the Astro Pi website for eligibility details).
In Astro Pi Mission Zero, young people write a simple Python program to take a reading using a sensor on one of the ISS Astro Pi computers and display a personalised pixel art image for the astronauts on board the ISS. They can take part by themselves or as coding teams.
The theme for Mission Zero 2023/24 is ‘fauna and flora’: young people are invited to program pixel art images or animations of animals, plants, or fungi to display on the Astro Pi computers’ LED pixel screen and remind the astronauts aboard the ISS of Earth’s natural wonders.
By following the guide we provide, kids can complete the Mission Zero coding activity in around one hour, for example during a school lesson or coding club session. No coding experience is needed to take part. Kids can write their code in any web browser on any computer connected to the internet, without special equipment or software.
All young people that meet the eligibility criteria and follow the official Mission Zero guidelines will have their program run in space for up to 30 seconds. They will receive a unique and personalised certificate to show their coding achievement. The certificate will display the exact start and end time of their program’s run, and where the ISS was above Earth in this time period.
Mission Zero 2023/24 opens today and is open until Monday 25 March 2024. It’s very easy to support young people to get involved — find out more on the Astro Pi website:
In this year’s Astro Pi Mission Space Lab, ESA astronauts are inviting teams of young people to solve a scientific task by writing a Python program.
The Mission Space Lab task is to gather data with the Astro Pi computers to calculate the speed at which the ISS is travelling. This new format of the mission will allow many more young people to run their programs in space and get a taste of space science.
Mission Space Lab will open on 6 November. We will share more information about how young people and mentors can participate very soon.
The European Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation.
You can keep up with all Astro Pi news by following the Astro Pi X account (formerly Twitter) or signing up to the newsletter at astro-pi.org.
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In the 2023 Coolest Projects online showcase, 5801 young people from all over the world shared the wonderful, fun, and creative things they had made with technology. But that’s not all we’ve seen of Coolest Projects this year. As well as our worldwide annual online showcase, a number of in-person Coolest Projects events are taking place in countries across the globe in 2023.
Run by us or partner organisations, these exciting events create a space for young people to meet other young tech creators, connect to their community, and celebrate each others’ creations. In-person Coolest Projects events around the world had to pause over the coronavirus pandemic, and we’re delighted to see them return to engage and inspire young people once again.
On 1 July, we were super excited to host Coolest Projects Ireland, our first in-person Coolest Projects event since 2020. 63 young tech creators from Northern Ireland and the Republic of Ireland came together in Dublin for an exciting one-day event where they shared 43 incredible creations, with engineer and STEM communicator Dr Niamh Shaw leading everyone through the day’s celebrations.
One young maker showcasing her project was Charlotte from Kinsale CoderDojo in the Republic of Ireland. Her creative storytelling project ‘Goldicat and the Three Angry Property Owners’ was chosen as a judges’ favourite in the Scratch category.
Charlotte’s story includes different games and three secret endings for the user to discover. She told us: “I know someone who made an animation based off the fairy tale Hansel and Gretel in Scratch. This inspired me to make a game based off a different fairy tale, Goldilocks and the Three Bears.”
Harshit entered the Hardware category with his amazing mini vending machine. Describing his project, he explained, “This is a recreation of a vending machine, but I have added my own twists to it to make it simple to build. You still get the full experience of an actual vending machine, but what makes it special is that it is made fully out of recycled materials.”
Young people at Coolest Projects Ireland were joined and supported by family, friends, and mentors from Code Clubs and CoderDojos. Mentors told us their favourite things about attending a Coolest Projects event in person were “the joy and excitement the participants got from taking part and discussing their project with the judges”, and “the way it was very inclusive to all children and all [were] included on stage for some swag!”
In 2023 we’re partnering with six organisations that are bringing Coolest Projects events for their communities. We’re still looking forward to the exciting Coolest Projects events planned for the rest of the year:
Back in June, more than 30 young creators participated in Coolest Projects Hungary, which was organised in Budapest by the team at EPAM Systems Inc. And April saw our partner CoderDojo Belgium organise Coolest Projects Belgium for 40 young people, who shared 25 projects across different categories from Scratch to Hardware and Advanced Programming.
The CoderDojo Belgium team shared how important the Coolest Projects event is to their community:
“Just like every year, we’ve unlocked the doors to welcome the next generation of tech enthusiasts. And this year, once again, we were absolutely amazed by the projects they brought to the spotlight. From an app predicting stock market evolution, to creatively designed games with unexpected twists, not to mention the incredible robots, and more, their ingenuity knows no bounds.”
CoderDojo Belgium
We’re excited that the Coolest Projects online showcase — open to any young creator anywhere in the world — will return in 2024. And if there isn’t a Coolest Projects in-person event in your country yet, don’t worry. We’re working with more and more partners every year to bring Coolest Projects events to more young people.
To stay up to date with news about the Coolest Projects online showcase, sign up to the newsletter.
And you can celebrate young tech creators with us year round wherever you are by following Coolest Projects on X, Instagram, LinkedIn, or Facebook, where we share inspiring projects from the Coolest Projects online gallery and photos from the in-person events.
We’d like to thank EPAM Systems Inc, Meta, and GoTo for supporting the Coolest Projects Ireland event. If you’re interested in partnering with us for Coolest Projects, please reach out to us via email.
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Celebrate another year of young people’s computer programs in space with us: today we and our collaborators at the European Space Agency can finally announce the winning and highly commended teams in this year’s Astro Pi Mission Space Lab.
In Mission Space Lab, teams of young people work together to create computer programs for scientific experiments to be carried out on the International Space Station. The programs they design and create run on the two Astro Pi computers: space-adapted Raspberry Pis with cameras and a range of sensors.
Teams’ programs were deployed on the ISS during May and ran for up to 3 hours, collecting data for their experiments. Once we’d sent the teams their data, they started analysing it in order to write their Phase 4 reports. To identify patterns and phenomena they were interested in, many teams chose to compare their data with other sources.
We were especially excited to see the results from the experiments this year, particularly given that the upgraded Astro Pi units with their High Quality Cameras were positioned in a new observation window (WORF) on the ISS. This allowed teams to capture high-resolution images with a much wider field of view.
We feel very privileged to see the culmination of the team’s experiments in their final reports. So let’s share a few highlights from this year’s experiments:
Team Aretusa from Sicily explored the effects of climate change by cross-referencing the images they captured with the Astro Pis with historical images from Google Earth. They used Near Infrared photography to capture images, and NDVI (Normalised Difference Vegetation Index) image processing in their analysis. Below you can see that they have compared data of Saudi Arabia from 1987 to 2023, showing increasing levels of vegetation grown in attempts to restore degraded land.
Team Barrande from the Czech Republic trained AI models on images they gathered to identify topographical features of Earth. Their Mission Space Lab program used the Astro Pi computer’s machine learning dongle to train one AI model in real time. Later, the team also used the collected images to train another model back on Earth. Comparing the outputs of the two models, the team could tell how well the models had identified different topographical features. The below selection shows an image the team’s experiment captured on the left, the same image after processing by the AI model trained on the Astro Pi computer in the middle, and the image processed by the AI model trained on Earth.
Team DAHspace from Portugal measured the intensity of the Earth’s magnetic field along the orbit path of the ISS. Using the magnetometer on the Astro Pi, their experiment recorded data allowing the team to track changes of intensity. The team mapped this data to the ISS’s coordinates, showing the difference in the Earth’s magnetic field between the North Pole (points 1 and 2 on the chart below) and the South Pole (points 3 and 4).
We and our collaborators at ESA Education have been busy reviewing all of the reports to assess the scientific merit, use of the Astro Pi hardware, experiment design, and data analysis. The ten winning teams come from schools and coding clubs in 11 countries. We are sending each team some cool space swag to recognise their achievement.
Team | Experiment theme | Based at | Country |
Magnet47 | Life on Earth | O’Neill CVI | Canada |
Aretusa | Life on Earth | Liceo Da Vinci Floridia | Italy |
ASaether | Life on Earth | “Andrei Saguna” National College | Romania |
Barrande | Life on Earth | Gymnázium Joachima Barranda Beroun | Czech Republic |
Escapers | Life in space | Code Club | Canada |
Futura | Life in space | Scuola Svizzera Milano | Italy |
StMarks | Life on Earth | St Mark’s Church of England School | United Kingdom |
DAHspace | Life on Earth | EB 2,3 D. Afonso Henriques | Portugal |
T5Clouds | Life on Earth | Dominican College | Ireland |
PiNuts | Life in space | TEKNISK GYMNASIUM, Skanderborg | Denmark |
You can click on a team name to read the team’s experiment report.
Along with the winning teams, we would like to commend the following teams for their experiments:
Team | Experiment theme | Based at | Country |
Parsec | Life on Earth | Liceo Da Vinci Pascoli Gallarate | Italy |
Celeste | Life on Earth | International School of Florence | Italy |
LionTech | Life on Earth | Colegiul Național ”Mihai Eminescu” | Romania |
OHSpace | Life in Space | Oxford High School | United Kingdom |
Magneto | Life on Earth | The American School of The Hague | Netherlands |
GreenEye | Life on Earth | ROBOTONIO | Greece |
Primus | Life on Earth | Independent coding club | Germany |
You can click on a team name to read the team’s experiment report.
All of the teams whose Mission Space Lab programs ran on the ISS will receive a certificate signed by ESA astronaut Samantha Cristoforetti. The winning and highly commended teams will also be invited to a live video chat with an ESA astronaut in the autumn.
Huge congratulations to every team that participated in Astro Pi Mission Space Lab. We hope you found it fun and inspiring to take part.
A big thank you to everyone who has been involved in the European Astro Pi Challenge this year. An amazing 24,850 young people from 29 countries had their programs run in space this year. We can’t wait to do it all again starting in September.
And it’s not just us saying thanks and well done — here’s a special message from ESA astronaut Matthias Maurer:
On 18 September 2023, we’ll launch the European Astro Pi Challenge for 2023/24. Mission Zero will open in September, and we’ll announce exciting news about Mission Space Lab in September too.
If you know a young person who might be interested in the Astro Pi Challenge, sign up for the newsletter on astro-pi.org and follow the Astro Pi Twitter account for all the latest announcements about how you can support them to take the unique opportunity to write code to run in space.
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Who chooses to study Computing? In England, data from GCSE and A level Computer Science entries in 2019 shows that the answer is complex. Black Caribbean students were one of the most underrepresented groups in the subject, while pupils from other ethnic backgrounds, such as White British, Chinese, and Asian Indian, were well-represented. This picture is reflected in the STEM workforce in England, where Black people are also underrepresented.
That’s why one of our areas of academic research aims to support Computing teachers to use culturally relevant pedagogy to design and deliver equitable learning experiences that enable all learners to enjoy and succeed in Computing and Computer Science at school. Our previous research projects within this area have involved developing guidelines for culturally relevant and responsive teaching, and exploring how a small group of primary and secondary Computing teachers used these guidelines in their teaching.
In our latest research study, funded by Cognizant, we worked with 13 primary school teachers in England on adapting computing lessons to incorporate culturally relevant and responsive principles and practices. Here’s an insight into the workshop we ran with them, and what the teachers and we have taken away from it.
In the group of 13 England-based primary school Computing teachers we worked with for this study:
In November 2022, we held a one-day workshop with the teachers to introduce culturally relevant pedagogy and explore how to adapt two six-week units of computing resources.
The first part of the workshop was a collaborative, discussion-based professional development session exploring what culturally relevant pedagogy is. This type of pedagogy uses equitable teaching practices to:
The rest of the workshop day was spent putting this learning into practice while planning how to adapt two units of computing lessons to make them culturally relevant for the teachers’ particular settings. We used a design-based approach for this part of the workshop, meaning researchers and teachers worked collaboratively as equal stakeholders to decide on plans for how to alter the units.
We worked in four groups, each with three or four teachers and one or two researchers, focusing on one of two units of work from The Computing Curriculum for teaching digital skills: a unit on photo editing for Year 4 (ages 8–9), and a unit about vector graphics for Year 5 (ages 9–10).
In order to plan how the resources in these units of work could be made culturally relevant for the participating teachers’ contexts, the groups used a checklist of ten areas of opportunity. This checklist is a result of one of our previous research projects on culturally relevant pedagogy. Each group used the list to identify a variety of ways in which the units’ learning objectives, activities, learning materials, and slides could be adapted. Teachers noted down their ideas and then discussed them with their group to jointly agree a plan for adapting the unit.
By the end of the day, the groups had designed four really creative plans for:
Before and after the workshop, we asked the teachers to fill in a survey about themselves, their experiences of creating computing resources, and their views about culturally relevant resources. We then compared the two sets of data to see whether anything had changed over the course of the workshop.
After teachers had attended the workshop, they reported a statistically significant increase in their confidence levels to adapt resources to be culturally relevant for both themselves and others.
Teachers explained that the workshop had increased their understanding of culturally relevant pedagogy and of how it could impact on learners. For example, one teacher said:
“The workshop has developed my understanding of how culturally adapted resources can support pupil progress and engagement. It has also highlighted how contextual appropriateness of resources can help children to access resources.” – Participating teacher
Some teachers also highlighted how important it had been to talk to teachers from other schools during the workshop, and how they could put their new knowledge into practice in the classroom:
“The dedicated time and value added from peer discourse helped make this authentic and not just token activities to check a box.” – Participating teacher
“I can’t wait to take some of the work back and apply it to other areas and subjects I teach.” – Participating teacher
After our research team made the adaptations to the units set out in the four plans made during the workshop, the adapted units were delivered by the teachers to more than 500 Year 4 and 5 pupils. We visited some of the teachers’ schools to see the units being taught, and we have interviewed all the teachers about their experience of delivering the adapted materials. This observational and interview data, together with additional survey responses, will be analysed by us, and we’ll share the results over the coming months.
In our next blog post about this work, we will delve into the fascinating realm of parental attitudes to culturally relevant computing, and we’ll explore how embracing diversity in the digital landscape is shaping the future for both children and their families.
We’ve also written about this professional development activity in more detail in a paper to be published at the UKICER conference in September, and we’ll share the paper once it’s available.
Finally, we are grateful to Cognizant for funding this academic research, and to our cohort of primary computing teachers for their enthusiasm, energy, and creativity, and their commitment to this project.
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We love hearing from members of the community and how they use their passion for computing and digital making to inspire others. Our community stories series takes you on a tour of the globe to meet educators and young tech creators from the USA, Iraq, Romania, and more.
For our latest story, we are in the UK with Spencer, a Computer Science teacher at King Edward VI Sheldon Heath Academy (KESH), Birmingham. After 24 years as a science teacher, Spencer decided to turn his personal passion for digital making into a career and transitioned to teaching Computer Science.
From the moment he printed his name on the screen of an Acorn Electron computer at age ten, Spencer was hooked on digital making. He’s remained a member of the digital making community throughout his life, continuing to push himself with his creations and learn new skills whenever possible. Wanting to spread his knowledge and make sure the students at his school had access to computer science, he began running a weekly Code Club in his science lab:
“Code Club was a really nice vehicle for me to get students into programming and digital making, before computer science was an option at the school. So Code Club originally ran in my science lab around the Bunsen burners and all the science equipment, and we do some programming on a Friday afternoon making LEDs flash and a little bit of Minecraft. And from that, the students really got an exciting sense of what programming and digital making could be.”
– Spencer
While running his Code Club, Spencer really embedded himself in the Raspberry Pi community, attending Raspberry Jams, engaging with like-minded people on Twitter, and continuing to rely on our free training to upskill.
When leadership at KESH began to explore introducing Computer Science to the curriculum, Spencer knew he was the right person for the job, and just where to look to make sure he had the right support:
“So when I decided to change from being a science teacher to a computer science teacher, there were loads of course options you could find online, and a lot of them required some really specific prior knowledge and skills. The Foundation’s resources take you from a complete novice, complete beginner — my very first LED flashing on and off — to being able to teach computational thinking and algorithms. So it was a really clear progression from using the Foundation resources that helped take me from a Physics teacher, who could use electricity to light an LED, to a programmer who could teach how to use this in our digital making for our students.”
– Spencer
Thanks to the support from KESH and Spencer’s compelling can-do attitude, he was soon heading up a brand-new Computer Science department. This was met with great enthusiasm from the learners at KESH, with a willing cohort eagerly signing up for the new subject.
“It’s really exciting to see how students have embraced Computer Science as a brand-new subject at school. The take-up for our first year at GCSE was fantastic with 25 students, and this year I’ve really got students asking about, ‘Is there an option for next year, and how can I get on to it?’ Students are almost blown away by the resources now.”
– Spencer
Spencer has a mission to make sure all of KESH’s learners can learn about computing, and making his lessons accessible to all means he’s become a firm favourite amongst the students for his collaborative teaching approach.
“Mr Organ teaches you, and then he just puts you in. If you do need help, you can ask people around you, or him, but he lets you make your own mistakes and learn from there. He will then give you help so you don’t make those mistakes the next time.”
– Muntaha, 16, GCSE Computer Science student, KESH
Spencer’s work is shaped by his awareness that many of the learners at KESH come from under-resourced areas of Birmingham and backgrounds that are underrepresented in computing. He knows that many of them have previously had limited opportunities to use digital tools. This is something he is driven to change.
“I want my young students here, regardless of their background, regardless of their area they’ve been brought up in, to have the same experiences as all other students in the country. And the work I do with Raspberry Pi, and the work I do with Code Club, is a way of opening those doors for our young people.”
– Spencer
As a passionate member of the Raspberry Pi Foundation community, Spencer has been counted on as a friendly face for many years, sharing his enthusiasm on training courses, at Foundation events, and as a part of discussions on Twitter. With the goal to introduce Computer Science at A level shortly, and an ever-growing collection of digital makes housed in his makerspace, Spencer shows no signs of slowing down.
If you are interested in changing your teaching path to focus on Computer Science, take a look at the free resources we have available to support you on your journey.
Help us celebrate Spencer and his dedication to opening doors for his learners by sharing his story on Twitter, LinkedIn, and Facebook.
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After seven successful years on the International Space Station, 250 vertical miles above our planet, the original two Astro Pi computers that we sent to the ISS to help young people run their code in space have been returned to Earth.
From today, one of these Astro Pi computers will be displayed in the Science Museum, London. You can visit it in the new Engineers Gallery, which is dedicated to world-changing engineering innovations and the diverse and fascinating range of people behind them.
The original Astro Pis, nicknamed Izzy and Ed, have played a major part in feeding tens of thousands of young people’s understanding and passion for science, mathematics, engineering, computing, and coding. In their seven years on the International Space Station (ISS), Izzy and Ed had the job of running over 70,000 programs created by young people as part of the annual Astro Pi Challenge.
Nicki Ashworth, 21, took part in the first-ever Astro Pi challenge after hearing about the opportunity at a science fair: “I thought it sounded like an interesting project, and good practice for my programming skills. I was young and had no idea of the extent of the project and how much it would influence my future.”
Like many young people who have participated in the Astro Pi Challenge, Nicki credits the Astro Pi Challenge as an inspiration to learn more about space and programming, and to decide on a career path: “My experience with Astro Pi definitely helped to shape my future choices. I’m currently in my third year of a Mechanical Engineering degree at University of Southampton, specialising in Computational Engineering and Design. I’ve always loved programming, which is why I took part in the Astro Pi competition, but it led to a fascination with space. This encouraged me to look at engineering as a future, and led me to where I am today!”
It all started in 2014, when we started collaborating with organisations including the UK Space Agency and European Space Agency (ESA) to fly two Astro Pi computers to the ISS for educational activities during the six-month Principia mission of British ESA astronaut Tim Peake.
The Astro Pi computers each consist of a Raspberry Pi computer integrated with a digital camera and an add-on board filled with environmental sensors, all enclosed in a protective aluminium flight case.
Commander Tim Peake, Britain’s first visitor to the ISS, accompanied the two first Astro Pi computers on the ISS. He used them to run experiments imagined, designed, and coded by school-age young people across the UK.
We held a competition in UK schools and coding clubs to invite young people to create experiments that could be run on the Astro Pis. Students conceived experiments and coded them in Python; we tested their Python programs and eventually picked seven to run on Izzy and Ed on the ISS.
The students’ experiments ranged from a simple but beautiful program to display the flag of the country over which the ISS was flying at a given time, to a reaction-time test for Tim Peake to measure his changing abilities across the six-month mission. The measurements from all the experiments were downloaded to Earth and analysed by the students.
“I still feel incredibly honoured to have competed in the very first [Astro Pi Challenge],” says Aaron Chamberlain, 18, who was 11 years old when he took part in the first-ever Astro Pi Challenge in 2015. “The experience was incredible and really cemented my enthusiasm for all things computing and coding. Finally looking at the photos the Raspberry Pi had taken of the astronauts floating 400 km above us was a feeling of awe that I will never forget.”
The next year, 2016, we expanded our partnership with ESA Education to be able to open up Astro Pi to young people across ESA Member states. The European Astro Pi Challenge has been going from strength to strength each year since, inspiring young people and adult mentors alike.
In 2021 we decided it was time to retire Izzy and Ed and replace them with upgraded Astro Pi computers with plenty of new and improved hardware, including a Raspberry Pi 4 Model B with 8 GB RAM.
Dave Honess, STEM Didactics Expert at the European Space Agency, was engineering lead at the Foundation for the first Astro Pi Challenge, and the return of the original hardware is a special event and moment of reflection for him: “It was a strange experience to open the box and hold the original Astro Pis again after all that time and distance they have travelled — literally billions of miles. Even though their mission is over, we will continue to learn from them with a tear-down analysis to find out if they have been affected by their time in space. Since Principia, I have watched the European Astro Pi Challenge grow with pride year on year, but I still feel very fortunate to have been there at the beginning.”
Thanks to the upgraded hardware, we are able to continue to grow the Astro Pi Challenge in collaboration with ESA Education. And each year it’s so exciting to see the creative and ingenious programs tens of thousands of young people from across Europe send us; 24,850 young people took part in the Challenge in the 2022/2023 cycle.
But how have Astro Pis Izzy and Ed fared in space over these seven years? Jonathan Bell, Principal Software Engineer at Raspberry Pi Limited, had a chance to find out first-hand: “I was lucky enough to have a look inside the returned Astro Pis. I was looking for the cosmetic effects of the unit being on the ISS for so long. On the inside they still look as pristine as when I assembled them! Barely a speck of dust on the internal boards, nor any signs that the external interface ports were worn from their years of use. A few dings and scrapes on the anodised exterior were all that I could see — and a missing joystick cap (as it turns out, hot-melt glue isn’t a permanent adhesive…). It was great to see that they still worked! It made me feel proud for what the team and the Astro Pi programme has achieved over the years. It’s good to have Izzy and Ed back!”
The new Engineers Gallery in the Science Museum opens today and is free to visit. Astro Pi computer Izzy is among the amazing exhibits. Learn more at sciencemuseum.org.uk/engineers.
To find out more about the Astro Pi Challenge and how to get involved with your kids at home, your school, or your STEM or coding club, visit astro-pi.org.
The next round of the Challenge starts in September — sign up for news to be the first to hear when we launch it.
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In the Columbus module of the International Space Station (ISS), there are two Astro Pi computers called Marie Curie and Nikola Tesla. These computers run the programs young people create as part of the annual European Astro Pi Challenge.
For this year’s Astro Pi Mission Zero, young people sent us over 15000 programs to show the ISS astronauts colourful images and animations of animals and plants on the Astro Pi displays and remind them of home.
Mission Zero is a free beginners’ coding activity. It gives young people the unique opportunity to follow our step-by-step guide to write a simple program in Python that can run in space on the ISS orbiting planet Earth.
The Mission Zero activity this year was to write code to use the Astro Pi’s colour sensor to measure the lighting conditions in the Columbus module, and to then use that measurement to set a colour in an image or animation on the Astro Pi’s 8×8 LED display. We invited young people to design images of fauna and flora to give the astronauts on board the ISS a reminder of the beautiful creatures, plantlife, and landscapes found on planet Earth.
The Mission Zero activity is ideal for learners trying text-based programming for the first time. It covers some key programming concepts, including variables, sequence, and iteration.
This year we received 15551 Mission Zero programs, and after carefully checking them against the entry and safety criteria, we were able to run 15475 programs. They were sent to us by 23605 learners working in teams or independently, and 10207 of this year’s participants were girls.
This year the most Mission Zero programs came from young people in the UK, followed by Spain, France, Italy, and Greece. Lots of different organisations supported young people to take part, including publicly funded primary and secondary schools, as well as educator- and volunteer-led Code Clubs and CoderDojos we support.
We’re celebrating the many different people involved in this year’s mission with a mosaic of the Mission Zero logo made up of lots of the inspiring designs participants sent us. You can explore an interactive version of the image too!
All of the participants whose programs ran on the ISS will be receiving a certificate to recognise their efforts, which will include the time and coordinates of the ISS when their program ran. Programs created by young people from across Europe ran on board the ISS in the final week of May.
If you enjoyed Astro Pi Mission Zero this year, we would be delighted to see you again in the next annual round. If you’re feeling inspired by the images young people have created, we invite you to get involved too. We provide guides and help for all adult mentors who want to support young people to take part, and the step-by-step guide for coding a Mission Zero program in 19 European languages.
The activity of designing an image has been really popular, and we have been super impressed with the creativity of young people’s designs. That’s why we’ll be running Mission Zero in the same format again starting in September.
If you’d like to hear news of the Astro Pi Challenge, please sign up to the newsletter on astro-pi.org:
We are always interested to hear your feedback about Mission Zero, as a mentor or participant. If you would like to share your thoughts with us, please email enquiries@astro-pi.org.
PS Look out for some cool news about the Astro Pi computers, which we’ll announce soon on this blog!
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What do we talk about when we talk about artificial intelligence (AI)? It’s becoming a cliche to point out that, because the term “AI” is used to describe so many different things nowadays, it’s difficult to know straight away what anyone means when they say “AI”. However, it’s true that without a shared understanding of what AI and related terms mean, we can’t talk about them, or educate young people about the field.
So when we started designing materials for the Experience AI learning programme in partnership with leading AI unit Google DeepMind, we decided to create short explanations of key AI and machine learning (ML) terms. The explanations are doubly useful:
As an example, here is our explanation of the term “artificial intelligence” for learners aged 11–14:
Artificial intelligence (AI) is the design and study of systems that appear to mimic intelligent behaviour. Some AI applications are based on rules. More often now, AI applications are built using machine learning that is said to ‘learn’ from examples in the form of data. For example, some AI applications are built to answer questions or help diagnose illnesses. Other AI applications could be built for harmful purposes, such as spreading fake news. AI applications do not think. AI applications are built to carry out tasks in a way that appears to be intelligent.
You can find 32 explanations in the glossary that is part of the Experience AI Lessons. Here’s an insight into how we arrived at the explanations.
In order to ensure the explanations are as precise as possible, we first identified reliable sources. These included among many others:
Vocabulary is an important part of teaching and learning. When we use vocabulary correctly, we can support learners to develop their understanding. If we use it inconsistently, this can lead to alternate conceptions (misconceptions) that can interfere with learners’ understanding. You can read more about this in our Pedagogy Quick Read on alternate conceptions.
Some of our principles for writing explanations of AI terms were that the explanations need to:
We engaged in an iterative process of writing explanations, gathering feedback from our team and our Experience AI project partners at Google DeepMind, and adapting the explanations. Then we went through the feedback and adaptation cycle until we all agreed that the explanations met our principles.
An important part of what emerged as a result, aside from the explanations of AI terms themselves, was a blueprint for how not to talk about AI. One aspect of this is avoiding anthropomorphism, detailed by Ben Garside from our team here.
As part of designing the the Experience AI Lessons, creating the explanations helped us to:
One of the ways education research informed the explanations was that we used semantic waves to structure each term’s explanation in three parts:
Most explanations also contain ‘middle of the wave’ sentences, which add additional abstract content, bridging the ‘bottom of the wave’ concrete example to the ‘top of the wave’ abstract content.
Here’s the “artificial intelligence” explanation broken up into the parts of the semantic wave:
Some of the explanations went through 10 or more iterations before we agreed they were suitable for publication. After months of thinking about, writing, correcting, discussing, and justifying the explanations, it’s tempting to wonder whether I should have just prompted an AI chatbot to generate the explanations for me.
I tested this idea by getting a chatbot to generate an explanation of “artificial intelligence” using the prompt “Explain what artificial intelligence is, using vocabulary suitable for KS3 students, avoiding anthropomorphism”. The result included quite a few inconsistencies with our principles, as well as a couple of technical inaccuracies. Perhaps I could have tweaked the prompt for the chatbot in order to get a better result. However, relying on a chatbot’s output would mean missing out on some of the value of doing the work of writing the explanations in collaboration with my team and our partners.
The visible result of that work is the explanations themselves. The invisible result is the knowledge we all gained, and the coherence we reached as a team, both of which enabled us to create high-quality resources for Experience AI. We wouldn’t have gotten to know what resources we wanted to write without writing the explanations ourselves and improving them over and over. So yes, it was worth our time.
The process of creating and iterating the AI explanations highlights how opaque the field of AI still is, and how little we yet know about how best to teach and learn about it. At the Raspberry Pi Foundation, we now know just a bit more about that and are excited to share the results with teachers and young people.
You can access the Experience AI Lessons and the glossary with all our explanations at experience-ai.org. The glossary of AI explanations is just in its first published version: we will continue to improve it as we find out more about how to best support young people to learn about this field.
Let us know what you think about the explanations and whether they’re useful in your teaching. Onwards with the exciting work of establishing how to successfully engage young people in learning about and creating with AI technologies.
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An absolutely huge congratulations to each and every single young creator who participated in Coolest Projects 2023, our digital technology showcase for young people! 5801 young people from 37 countries took part. This year’s participants made projects that entertained, inspired, and wowed us — creators showcased everything from robotic arms to platformer games.
We celebrated every project and maker in a special livestream event this Tuesday:
Each year, we invite VIP judges to pick their favourite projects. This year they had the difficult job of choosing between 4111 incredible projects young people showcased. Meet the judges and find out which projects were their favourites.
Yewande is a chartered engineer, innovator, and speaker. She has worked on projects in the UK, Africa, the Middle East, and East Asia, and has been named the UK Young Woman Engineer of the Year by the Institution of Engineering & Technology.
See Yewande’s favourites:
Vaishali is an Indian engineer, innovator, and revolutionary educationist. She is the co-founder of Young Tinker Academy and Young Tinker Foundation, started in 2015 to educate the less-privileged students of rural India. Her team at Young Tinker Foundation has impacted the lives of 150,000+ students.
Lella is an award-winning 18-year-old Digital Changemaker and Power of Youth Champion. Since she taught herself to code at age 8, Lella fosters purpose-driven innovation to create global industry opportunities that ensure young people are at the forefront of the ongoing digital transformation.
Lella’s favourite projects are:
Aoife is the Head of Community Development for Meta Data Centres in Europe and Asia. She and her team deliver on Meta’s commitment to playing a positive role and investing in the long-term vitality of Meta Data Centre communities in Ireland, Denmark, Sweden, and Singapore.
See Aoife’s favourite projects:
Broadcom Foundation has partnered with us for Coolest Projects to encourage young people who are solving problems that impact their communities. Broadcom Coding with Commitment™ is a special recognition for a Coolest Projects creator aged 11–14 who has learned basic coding as an essential problem-solving tool in STEM and is “thinking globally while acting locally.”
The Broadcom Coding with Commitment™ recognition goes to Smart Farm, a project by Dang, Chi, and An from Vietnam. They designed Smart Farm to help farmers in their community regulate the temperature of animals, feed them on time, and check them for diseases. The team also built a fish pond model that tests the pH of the water and a vegetable garden model that detects when vegetables are wilting, all with the aim of helping local farmers to care for their livestock and protect their livelihoods. Huge congratulations to the team!
Our judges have chosen their favourite projects — but what about yours? You can explore thousands of incredible projects for 2023 young creators in the Coolest Projects showcase gallery and discover your favourites today.
All young creators who took part will shortly receive their own unique certificate to recognise their amazing achievements. They’ll also be able to log into their Coolest Projects account to find personalised feedback on their projects from our judging team.
Support from our Coolest Projects sponsors means we can make the online showcase and celebration livestream an inspiring experience for the young people taking part. We want to say a big thank you to all of them: Allianz Technologies, Broadcom Foundation, EPAM Systems, Liberty Global, Meta, and Qube Research and Technologies.
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Over 15,000 teams of young people from across Europe had their computer programs run on board the International Space Station (ISS) this month as part of this year’s European Astro Pi Challenge.
Astro Pi is run in collaboration by us and ESA Education, and offers two ways to get involved: Mission Zero and Mission Space Lab.
Mission Zero is the Astro Pi beginners’ activity. To take part, young people spend an hour writing a short Python program for the Astro Pi computers on the International Space Station (ISS). This year we invited them to create an 8×8 pixel image or animation on the theme of fauna and flora, which their program showed on an Astro Pi LED matrix display for 30 seconds.
This year, 23605 young people’s Mission Zero programs ran on the ISS. We need to check all the programs before we can send them to space and that means we got to see all the images and animations that the young people created. Their creativity was absolutely incredible! Here are some inspiring examples:
Mission Space Lab runs over eight months and empowers teams of young people to design real science experiments on the ISS, executed by Python programs they write themselves. Teams choose between two themes: ‘Life in space’ and ‘Life on Earth’.
This year, the Mission Space Lab programs of 1245 young people in 294 teams from 21 countries passed our rigorous judging and testing process. These programs were awarded flight status and sent to the Astro Pis on board the ISS, where they captured data for the teams to analyse back down on Earth.
Mission Space Lab teams this year decided to design experiments such as analysing cloud formations to identify where storms commonly occur, looking at ocean colour as a measure of depth, and analysing freshwater systems and the surrounding areas they supply water to.
Teams will be receiving their experiment data later this week, and will be analysing and interpreting it over the next few weeks. For example, the team analysing freshwater systems want to investigate how these systems may be affected by climate change. What their Mission Space Lab program has recorded while running on the Astro Pis is a unique data set that the team can compare against other scientific data.
For the ‘Life on Earth’ category of Mission Space Lab experiments this year, the Astro Pis were positioned in a different place to previous years: in the Window Observational Research Facility (WORF). Therefore the Astro Pis could take photos with a wider view. Combined with the High Quality Camera of the upgraded Astro Pi computers we sent to the ISS in 2021, this means that the teams got amazing-quality photos of the Earth’s surface.
Once the experiments for ‘Life on Earth’ were complete, the astronauts moved the Astro Pis back to the Columbus module and replaced their SD cards, ready for capturing the data for the ‘Life in Space’ experiments.
Running programs in an environment as unique as the ISS, where all hardware and software is put to the test, brings many complexities and challenges. Everything that happens on the ISS has to be scheduled well in advance, and astronauts have a strict itinerary to follow to keep the ISS running smoothly.
As usual, this year’s experiments met with their fair share of challenges. One initial challenge the Astro Pis had this year was that the Canadarm, a robotic arm on the outside of the ISS, was in operation during some of the ‘Life on Earth’ experiments. Although it’s fascinating to see part of the ISS in-shot, it also slightly obscured some of the photos.
Another challenge was that window shutters were scheduled to close during some of the experiments, which meant we had to switch around the schedule for Mission Space Lab programs to run so that all of the experiments aiming to capture photos could do so.
Well done to all the young people who’ve taken part in the European Astro Pi Challenge this year.
If you’d like to hear about upcoming Astro Pi Challenges, sign up to the newsletter at astro-pi.org.
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Today we share a guest blog from Chris Roffey, who manages the UK Bebras Challenge, a computational thinking challenge we run every year in partnership with the University of Oxford.
Bebras is a free annual challenge that helps schools introduce computational thinking to their learners through online, self-marking tasks. Taking part in Bebras, students solve accessible, interesting problems using their developing computational thinking skills. No programming is involved in taking part. The UK challenge is for school students aged 6 to 18 years old, with a special category for students with severe visual impairments.
While UK schools take part in Bebras throughout two weeks in November, for me the annual cycle starts much earlier. May is the time of the annual Bebras international workshop where the year’s new tasks get decided. In 2022, 60 countries were represented — some online, some in person. For nearly a week, computer scientists and computing teachers met to discuss and work on the new cycle’s task proposals submitted by participating countries a little earlier.
After the workshop, in collaboration with teams from other European countries, the UK Bebras team chose its task sets and then worked to localise, copy-edit, and test them to get them ready for schools participating in Bebras during November. From September, schools across the UK create accounts for their students, with over 360,000 students ultimately taking part in 2022. All in all, more than 3 million students from 59 countries took part in the 2022/2023 Bebras challenge cycle.
In this cycle, the UK Bebras partnership between the Raspberry Pi Foundation and the University of Oxford has been extended to include the Oxford University Computing Challenge (OUCC). This is an invitation-based, online coding challenge for students aged 10 to 18, offered in the UK as well as Australia, Jamaica, and China. We invited the students with the top 10% best results in the UK Bebras challenge to take part in the OUCC — an exciting opportunity for them.
In contrast to Bebras, which doesn’t require participants to do any coding, the OUCC asks students to create code to solve computational thinking problems. This requires students to prepare and challenges them to develop their computational thinking skills further. The two younger age groups, 10- to 14-year-olds, solve problems using the Blockly programming language. The older two age groups can use one of the 11 programming languages that Bebras supports, including all the most common ones taught in UK schools.
Over 20,000 Bebras participants took up the invitation to the first round of the OUCC in the third week of January. Then in March, the top 20 participants from each of the four OUCC age groups took part in the final round. The finalists all did amazingly well. In the first round, many of them had solved all the available tasks correctly, even though the expectation is that participants only try to solve as many as they can within the round’s time limit. In the final round, a few of the finalists managed to repeat this feat with the even more advanced tasks — which is, in modern parlance, literally impossible!
Many of the participants are about to take school exams, so the last stage of the annual cycle — the prize winners’ celebration day— takes place when the exam period has ended. This year we are holding this celebration on Friday 30 June at the Raspberry Pi Foundation’s headquarters in Cambridge. It will be a lovely way to finish the annual Bebras cycle and I am looking forward to it immensely.
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We are excited to share that 294 teams of young people participating in this year’s Astro Pi Mission Space Lab achieved Flight Status: their programs will run on the Astro Pis installed on the International Space Station (ISS) in April.
Mission Space Lab is part of the European Astro Pi Challenge, an ESA Education project run in collaboration with the Raspberry Pi Foundation. It offers young people the amazing opportunity to conduct scientific investigations in space, by writing computer programs that run on Raspberry Pi computers on board the International Space Station.
To take part in Mission Space Lab, young people form teams and choose between two themes for their experiments, investigating either ‘Life in space’ or ‘Life on Earth’. They send us their experiment ideas in Phase 1, and in Phase 2 they write Python programs to execute their experiments on the Astro Pis onboard the ISS. As we sent upgraded Astro Pis to space at the end of 2021, Mission Space Lab teams can now also choose to use a machine learning accelerator during their experiment time.
In total, 771 teams sent us ideas during Phase 1 in September 2022, so achieving Flight Status is a huge accomplishment for the successful teams. We are delighted that 391 teams submitted programs for their experiments. Teams who submitted had their programs checked for errors and their experiments tested, resulting in 294 teams being granted Flight Status. 134 of these teams included some aspects of machine learning in their experiments using the upgraded Astro Pis’ machine learning accelerator.
The 294 teams to whom we were able to award Flight Status this year represent 1245 young people. 34% of team members are female, and the average participant age is 15. The 294 successful teams hail from 21 countries; Italy has the most teams progressing to the next phase (48), closely followed by Spain (37), the UK (34), Greece (25), and the Czech Republic (25).
Teams can use the Astro Pis to investigate life inside ESA’s Columbus module of the ISS, by writing a program to detect things with at least one of the Astro Pi’s sensors. This can include for example the colour and intensity of light in the module, or the temperature and humidity.
81 teams that created ‘Life in space’ experiments have achieved Flight Status this year. Examples of experiments from this year are investigating how the Earth’s magnetic field is felt on the ISS, what environmental conditions the astronauts experience compared to those on Earth directly beneath the ISS as it orbits, or whether the cabin might be suitable for other lifeforms, such as plants or bacteria.
In the ‘Life on Earth’ theme, teams investigate features on the Earth’s surface using the cameras on the Astro Pis, which are positioned to view Earth from a window on the ISS.
This year the Astro Pis will be located in the Window Observational Research Facility (WORF), which is larger than the window the computers were positioned in in previous years. This means that teams running ‘Life on Earth’ experiments can capture better images. 206 teams that created experiments in the ‘Life on Earth’ theme have achieved Flight Status.
Thanks to the upgraded Astro Pi hardware, this is the second year that teams could decide whether to use visible-light or infrared (IR) photography. Teams running experiments using IR photography have chosen to examine topics such as plant health in different regions, the effects of deforestation, and desertification. Teams collecting visible light photography have chosen to design experiments analysing clouds in different regions, changes in ocean colour, the velocity of the ISS, and classification of biomes (e.g. desert, forest, grassland, wetland).
Each of this year’s 391 submissions has been through a number of tests to ensure they follow the challenge rules, meet the ISS security requirements, and can run without errors on the Astro Pis. Once the experiments have started, we can’t rely on astronaut intervention to resolve any issues, so we have to make sure that all of the programs will run without any problems.
This means that the start of the year is a very busy time for us. We run tests on Mission Space Lab teams’ programs on a number of exact replicas of the Astro Pis, including a final test to run every experiment that has passed all tests for the full three-hour experiment duration. The 294 experiments that received Flight Status will take over 5 weeks to run.
97 programs submitted by teams during Phase 2 of Mission Space Lab this year did not pass testing and so could not be awarded Flight Status. We wish we could run every experiment that is submitted, but there is only limited time available for the Astro Pis to be positioned in the ISS window. Therefore, we have to be extremely rigorous in our selection, and many of the 97 teams were not successful because of only small issues in their programs. We recognise how much work every Mission Space Lab team does, and all teams can be very proud of designing and creating an experiment.
Even if you weren’t successful this year, we hope you enjoyed participating and will take part again in next year’s challenge.
Once all of the experiments have run, we will send the teams the data collected during their experiments. Teams will then have time to analyse their data and write a short report to share their findings. Based on these reports, we will select winners of this year’s Mission Space Lab. The winning and highly commended teams will receive a special surprise.
Congratulations to all successful teams! We are really looking forward to seeing your results.
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We are delighted to announce that we’ve launched Experience AI, our new learning programme to help educators to teach, inspire, and engage young people in the subject of artificial intelligence (AI) and machine learning (ML).
Experience AI is a new educational programme that offers cutting-edge secondary school resources on AI and machine learning for teachers and their students. Developed in partnership by the Raspberry Pi Foundation and DeepMind, the programme aims to support teachers in the exciting and fast-moving area of AI, and get young people passionate about the subject.
Artificial intelligence and machine learning applications are already changing many aspects of our lives. From search engines, social media content recommenders, self-driving cars, and facial recognition software, to AI chatbots and image generation, these technologies are increasingly common in our everyday world.
Young people who understand how AI works will be better equipped to engage with the changes AI applications bring to the world, to make informed decisions about using and creating AI applications, and to choose what role AI should play in their futures. They will also gain critical thinking skills and awareness of how they might use AI to come up with new, creative solutions to problems they care about.
The AI applications people are building today are predicted to affect many career paths. In 2020, the World Economic Forum estimated that AI would replace some 85 million jobs by 2025 and create 97 million new ones. Many of these future jobs will require some knowledge of AI and ML, so it’s important that young people develop a strong understanding from an early age.
Something we get asked a lot is: “How do I teach AI and machine learning with my class?”. To answer this question, we have developed a set of free lessons for secondary school students (age 11 to 14) that give you everything you need including lesson plans, slide decks, worksheets, and videos.
The lessons focus on relatable applications of AI and are carefully designed so that teachers in a wide range of subjects can use them. You can find out more about how we used research to shape the lessons and how we aim to avoid misconceptions about AI.
The lessons are also for you if you’re an educator or volunteer outside of a school setting, such as in a coding club.
As part of this exciting first phase, we’re inviting teachers to participate in research to help us further develop the resources. All you need to do is sign up through our website, download the lessons, use them in your classroom, and give us your valuable feedback.
We’ve designed the Experience AI lessons with teacher support in mind, and so that you can deliver them to your learners aged 11 to 14 no matter what your subject area is. Each of the lesson plans includes a section that explains new concepts, and the slide decks feature embedded videos in which DeepMind’s AI researchers describe and bring these concepts to life for your learners.
We will also be offering you a range of new teacher training opportunities later this year, including a free online CPD course — Introduction to AI and Machine Learning — and a series of AI-themed webinars.
We will be inviting schools across the UK to test and improve the Experience AI lessons through feedback. We are really looking forward to working with you to shape the future of AI and machine learning education.
Visit the Experience AI website today to get started.
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In the 1950s, Alan Turing explored the central question of artificial intelligence (AI). He thought that the original question, “Can machines think?”, would not provide useful answers because the terms “machine” and “think” are hard to define. Instead, he proposed changing the question to something more provable: “Can a computer imitate intelligent behaviour well enough to convince someone they are talking to a human?” This is commonly referred to as the Turing test.
It’s been hard to miss the newest generation of AI chatbots that companies have released over the last year. News articles and stories about them seem to be everywhere at the moment. So you may have heard of machine learning (ML) chatbots such as ChatGPT and LaMDA. These chatbots are advanced enough to have caused renewed discussions about the Turing Test and whether the chatbots are sentient.
Without any knowledge of how people create such chatbots, it’s easy to imagine how someone might develop an incorrect mental model around these chatbots being living entities. With some awareness of Sci-Fi stories, you might even start to imagine what they could look like or associate a gender with them.
The reality is that these new chatbots are applications based on a large language model (LLM) — a type of machine learning model that has been trained with huge quantities of text, written by people and taken from places such as books and the internet, e.g. social media posts. An LLM predicts the probable order of combinations of words, a bit like the autocomplete function on a smartphone. Based on these probabilities, it can produce text outputs. LLM chatbots run on servers with huge amounts of computing power that people have built in data centres around the world.
AI applications are often described as “black boxes” or “closed boxes”: they may be relatively easy to use, but it’s not as easy to understand how they work. We believe that it’s fundamentally important to help everyone, especially young people, to understand the potential of AI technologies and to open these closed boxes to understand how they actually work.
As always, we want to demystify digital technology for young people, to empower them to be thoughtful creators of technology and to make informed choices about how they engage with technology — rather than just being passive consumers.
That’s the goal we have in mind as we’re working on lesson resources to help teachers and other educators introduce KS3 students (ages 11 to 14) to AI and ML. We will release these Experience AI lessons very soon.
Our researchers at the Raspberry Pi Computing Education Research Centre have started investigating the topic of AI and ML, including thinking deeply about how AI and ML applications are described to educators and learners.
To support learners to form accurate mental models of AI and ML, we believe it is important to avoid using words that can lead to learners developing misconceptions around machines being human-like in their abilities. That’s why ‘anthropomorphism’ is a term that comes up regularly in our conversations about the Experience AI lessons we are developing.
To anthropomorphise: “to show or treat an animal, god, or object as if it is human in appearance, character, or behaviour”
https://dictionary.cambridge.org/dictionary/english/anthropomorphize
Anthropomorphising AI in teaching materials might lead to learners believing that there is sentience or intention within AI applications. That misconception would distract learners from the fact that it is people who design AI applications and decide how they are used. It also risks reducing learners’ desire to take an active role in understanding AI applications, and in the design of future applications.
Avoiding anthropomorphism helps young people to open the closed box of AI applications. Take the example of a smart speaker. It’s easy to describe a smart speaker’s functionality in anthropomorphic terms such as “it listens” or “it understands”. However, we think it’s more accurate and empowering to explain smart speakers as systems developed by people to process sound and carry out specific tasks. Rather than telling young people that a smart speaker “listens” and “understands”, it’s more accurate to say that the speaker receives input, processes the data, and produces an output. This language helps to distinguish how the device actually works from the illusion of a persona the speaker’s voice might conjure for learners.
Another example is the use of AI in computer vision. ML models can, for example, be trained to identify when there is a dog or a cat in an image. An accurate ML model, on the surface, displays human-like behaviour. However, the model operates very differently to how a human might identify animals in images. Where humans would point to features such as whiskers and ear shapes, ML models process pixels in images to make predictions based on probabilities.
The Experience AI lesson resources we are developing introduce students to AI applications and teach them about the ML models that are used to power them. We have put a lot of work into thinking about the language we use in the lessons and the impact it might have on the emerging mental models of the young people (and their teachers) who will be engaging with our resources.
It’s not easy to avoid anthropomorphism while talking about AI, especially considering the industry standard language in the area: artificial intelligence, machine learning, computer vision, to name but a few examples. At the Foundation, we are still training ourselves not to anthropomorphise AI, and we take a little bit of pleasure in picking each other up on the odd slip-up.
Here are some suggestions to help you describe AI better:
Avoid using | Instead use |
Avoid using phrases such as “AI learns” or “AI/ML does” | Use phrases such as “AI applications are designed to…” or “AI developers build applications that…” |
Avoid words that describe the behaviour of people (e.g. see, look, recognise, create, make) | Use system type words (e.g. detect, input, pattern match, generate, produce) |
Avoid using AI/ML as a countable noun, e.g. “new artificial intelligences emerged in 2022” | Refer to ‘AI/ML’ as a scientific discipline, similarly to how you use the term “biology” |
If we are correct in our approach, then whether or not the young people who engage in Experience AI grow up to become AI developers, we will have helped them to become discerning users of AI technologies and to be more likely to see such products for what they are: data-driven applications and not sentient machines.
If you’d like to get involved with Experience AI and use our lessons with your class, you can start by visiting us at experience-ai.org.
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The European Astro Pi Challenge offers young people the opportunity to write computer programs that run on Raspberry Pi computers on board the International Space Station (ISS). There are two free, annual missions to participate in: Mission Zero and Mission Space Lab.
Sending your computer program to space is amazing already, and to inspire even more young people about this opportunity, we’re sharing some of the fascinating stories European Space Agency astronaut Matthias Maurer told last round’s Mission Space Lab team winners about his experiences on the ISS.
Last round’s winning Mission Space Lab teams were invited to a very special online session with Matthias, and he shared lots of thoughtful and surprising insights from his mission on the International Space Station. Here are three of the questions from the teams and what Matthias had to say:
Lots of the teams wanted to know about the practicalities of life on the ISS. Team Ad Astra from the UK asked “How did you and your crewmates ensure that you got on well together?” Matthias talked about how supporting each member of the team helps everyone work well together:
It was surprising to hear that the astronauts on the ISS have lots of opportunities to communicate with people on Earth. Matthias explained how the astronauts can keep in regular contact with their family while answering the question from Team Atlantes from Spain:
Team NanoKids asked Matthias about the technologies astronauts use on the ISS, and Matthias shared some fascinating glimpses into what tools help the astronauts in their surroundings:
Thank you to all the teams for these great questions. And thank you to Matthias for offering young people a peek into what life is like in space!
We hope Matthias’ stories inspire lots of young people to take part in the European Astro Pi Challenge. Registration for this round of Mission Space Lab is closed, so why not sign up for news about the next round?
But it’s not too late for young people to get involved today and become part of space history. Astro Pi Mission Zero is still open for participation a little while longer — until 17 March.
Mission Zero is a beginner’s coding activity, so it’s really easy to get involved: young people just need a grown-up to register for them, and a computer with a web browser to participate. In Mission Zero, young people up to age 19 in eligible countries have the chance to send their own simple computer program into space to display a colourful image for the astronauts to see on the ISS.
The one-hour Mission Zero activity comes with step-by-step instructions for young people to follow. No special equipment or coding skills are needed, and all eligible young people who follow the guidelines will have their program run in space. Every Mission Zero participants receives a certificate to show the exact time and the location of the ISS during their programs run, so they’ll have something to remember their stellar achievement.
The European Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation.
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Computing combines a very broad mixture of concepts and skills. We work to support any school to teach students about the whole of computing and how to create with digital technologies. A key part of this support is The Computing Curriculum.
The Computing Curriculum is our complete bank of free lesson plans and other resources that offer you everything you need to teach computing lessons to all school-aged learners. It helps you cover the full breadth of computing, including computing systems, programming, creating media, data and information, and societal impacts of digital technology.
The 500 hours of free, downloadable resources within The Computing Curriculum include all the materials you need in your classroom: from lesson plans and slide decks to activity sheets, homework, and assessments. To our knowledge, this is the most comprehensive set of free teaching and learning materials for computing and digital skills in the world.
Our Curriculum’s resources are based on clear progression and content frameworks we’ve designed, and we continuously update them based on the latest research and feedback from practising teachers. Doing this is particularly important for computing education resources, because computing is a young subject where thoughts and understanding about the best teaching approaches are still evolving.
With The Computing Curriculum, we support educators of all levels of experience. Whether you specialise in computing, or you are a newcomer to the subject, the Curriculum will save you time and help you deliver engaging lessons.
In our 2022 survey of teachers who have used The Computing Curriculum resources:
- 91% said the Curriculum was effective or very effective at saving teachers time
- 89% said it was effective or very effective at developing teachers’ subject knowledge
- 81% said it was effective or very effective at engaging students
The resources are organised as themed units, and they support your computing lesson planning, preparation, and delivery because they are comprehensive as well as adaptable. You are free to use the resources as they are, or adjust them to your context, access to hardware, and learners’ needs and experience level.
One aspect of The Computing Curriculum that will facilitate your teaching is the progression framework on which the resources are based. In creating the resources, we have considered the learning objectives throughout each unit and year group, and throughout the entire schooling period. This progression is detailed in curriculum maps and learning graphs, and you’ll be able to use these documents to plan your lessons and to check your learners’ understanding.
You can download and use the resources for the year groups you teach computing right now. And please tell us of your experiences using The Computing Curriculum in your classroom, so that we can make the resources even better for educators around the world.
If you are interested in curriculum resources tailored for your region, please contact us via this form. You can find out how we adapted resources from The Computing Curriculum for learners living in a refugee camp in Kenya if you’d like to learn about our approach to tailoring resources.
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Today we’re sharing an Astro Pi Mission Zero codealong video to help even more young people send their code into space.
In Mission Zero, young people write a simple program and display a colourful image on an Astro Pi computer on board the International Space Station (ISS). When the astronauts on mission on the ISS are working nearby, they can see the images young people have designed.
No coding experience is needed for Mission Zero. It’s a free and inspiring beginners’ coding activity. All young people need is an hour to write the program, a web browser on any computer with internet access, and an adult mentor who can register online to access the Mission Hub (see below).
In the codealong video, Rebecca from our team shows young people how to write their Mission Zero program step by step. We hope that it will open up this amazing coding activity to even more young people. (There’s also the written step-by-step guide to creating your program, available in 20 languages.)
Young people up to age 19 in ESA Member States are invited to take part, individually or as teams (see the eligibility details).
Every participant will receive a piece of space science history to keep: a personalised, printable certificate that shows their Mission Zero program’s exact start and end time, and the position of the ISS while their program ran.
The theme to inspire images for Mission Zero this year is ‘flora and fauna’, to remind the ISS astronauts of their home. The images can show anything from flowers and trees to birds, insects, and other animals. Young people could even create a series of images to show as an animation during the 30 seconds their program will run.
Mission Zero 2022/23 is open until 17 March 2023.
If you’re an adult mentor supporting young people to take part, read the mission guidelines to find out all you need to know. You can also watch this short video showing you exactly how to register to access the Mission Hub and get the code to identify your young people’s programs.
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Young creators, it’s time to share your ideas with the world! Registration for Coolest Projects is now open.
Coolest Projects is an online showcase celebrating all young people who create with digital technology. From today, Monday 6 February, young people can register their projects on the Coolest Projects website. Registered projects will be part of the online showcase gallery, for people all over the world to see.
By entering your digital tech creations into Coolest Projects, you’ll have the chance to get personalised feedback about your project, represent your country in the online showcase, and get fun, limited-edition swag. Your project could even be selected as a favourite by our very special VIP judges.
Coolest Projects is an online celebration of young digital tech creators worldwide, their skills, and their wonderful creative ideas. We welcome all kinds of projects, from big to small, beginner to advanced, and work in progress to completed creation.
Here’s what you need to know:
If you’d like help with your idea or project, take a look at our free, step-by-step Coolest Projects workbook and coding project guides. You can also get inspired by all the creations in the 2022 showcase gallery.
You are also very welcome to register a tech project you’ve already made and want to share with the world this year.
We offer free resources to help mentors and parents support young people through the process of taking part in Coolest Projects, from imagining ideas, to creating projects, to registration.
There are loads more announcements to come, so make sure to subscribe to the Coolest Projects newsletter to be the first to find out about this year’s VIP judges, limited-edition digital swag, and much more.
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In our work, we get to meet so many super inspiring young people who make things with technology. Our series of community stories is one way we share their journeys and enthusiasm for digital making with you.
Today we’re introducing you to Adarsh from California, USA.
We first met Adarsh at the Coolest Projects USA showcase in 2019, when he was 15 years old. Adarsh was chosen as the Coolest Projects judges’ favourite in the showcase’s Hardware category for making a Smart Sprinkler System, which can serve an entire community. He was inspired to create this project by the need he saw in California to manage water during a drought. Using a Raspberry Pi computer, he built a moisture sensor–based sprinkler system that integrates real-time weather forecast data and Twitter feeds to dispense only optimum amounts of water, in compliance with city water regulations. Adarsh says:
“The world around us right now has a lot of different problems that need to be solved and so the way that I get inspired is by looking outwards.”
In 2020, Coolest Projects Global went online with young people across the world sharing their tech projects, and Adarsh created a project for the showcase to solve another real-life problem he had witnessed. When Adarsh had been in middle school, his mother had to be rushed to hospital with a sudden heart problem. The experience of seeing her hooked up to lots of vital sign monitors, with the wires hindering her movement, stayed in his memory. It led Adarsh to create another tech project: the Contactless Vital Signs Monitor. This low-cost device can be used to monitor a person’s skin temperature, heart rate, respiratory rate, blood pressure, and oxygen saturation without needing to be in direct contact with them. Adarsh’s contactless monitor lets patients rest more comfortably and also keeps healthcare staff safer from infections.
Adarsh entered his Contactless Vital Signs Monitor in the Davidson Fellows Scholarship programme, which recognises students who have completed significant projects that have the potential to benefit society.
Adarsh has this message for other young people who think they might like to try creating things with tech:
“None of these projects, to get to the stage where they are today, were without frustration or difficulties. That’s part of the process. You should expect that. Because of all the struggles I had, the fact that I was able to build all of this is so much more rewarding to me.”
A big part of coding and digital making is problem-solving and collaboration. Adarsh told us that he had a really great mentor, Johan, who introduced him to coding and Raspberry Pi hardware, and showed him where Adarsh could ask for help online.
“[The Raspberry Pi community] is such a large and inclusive community. It welcomes young students — even older adults who are first starting to develop their interest in computer science — and we all are developing our own skills, our own projects, and our own passions together, and while doing so, we’re helping each other out.”
Now a freshman at Stanford University, Adarsh is currently doing an epidemiology-related research project about the relationship between COVID-19 mutations and environmental, health, and demographic statistics. He wants to focus either on biomedical engineering or environmental engineering in his studies.
“Really [what I’m studying at university] is going to involve engineering or computer science largely due to the Raspberry Pi and the early influence it has had on my life.”
Thanks for inspiring us, Adarsh, and for letting us share your story with the community!
Help us celebrate Adarsh and inspire other young people to discover coding and digital making as a passion, by sharing his story on Twitter, LinkedIn, Facebook, or Instagram.
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Welcome to 2023. I hope that you had a fantastic 2022 and that you’re looking forward to an even better year ahead. To help get the year off to a great start, I thought it might be fun to share a few of the things that we’ve got planned for 2023.
Whether you’re a teacher, a mentor, or a young person, if it’s computer science, coding, or digital skills that you’re looking for, we’ve got you covered.
Through our collaboration with the European Space Agency, Astro Pi, young people can write computer programs that are guaranteed to run on the Raspberry Pi computers on the International Space Station (terms and conditions apply).
Astro Pi Mission Zero is open to participants until 17 March 2023 and is a perfect introduction to programming in Python for beginners. It takes about an hour to complete and we provide step-by-step guides for teachers, mentors, and young people.
Kids all over the world are already working on their entries to Coolest Projects Global 2023, our international online showcase that will see thousands of young people share their brilliant tech creations with the world. Registration opens on 6 February and it’s super simple to get involved. If you’re looking for inspiration, why not explore the judges’ favourite projects from 2022?
While we all love the Coolest Projects online showcase, I’m also looking forward to attending more in-person Coolest Projects events in 2023. The word on the street is that members of the Raspberry Pi team have been spotted scouting venues in Ireland… Watch this space.
I am sure I wasn’t alone in disappearing down a ChatGPT rabbit hole at the end of last year after OpenAI made their latest AI chatbot available for free. The internet exploded with both incredible examples of what the chatbot can do and furious debates about the limitations and ethics of AI systems.
With the rapid advances being made in AI technology, it’s increasingly important that young people are able to understand how AI is affecting their lives now and the role that it can play in their future. This year we’ll be building on our research into the future of AI and data science education and launching Experience AI in partnership with leading AI company DeepMind. The first wave of resources and learning experiences will be available in March.
With pandemic restrictions now almost completely unwound, we’ve seen a huge resurgence in Code Clubs and CoderDojos meeting all over the world. To build on this momentum, we are delighted to be welcoming Code Club and CoderDojo mentors and educators to a big Clubs Conference in Churchill College in Cambridge on 24 and 25 March.
This will be the first time we’re holding a community get-together since 2019 and a great opportunity to share learning and make new connections.
As part of our global mission to ensure that every young person is able to learn how to create with digital technologies, we have been focused on building partnerships in India, Kenya, and South Africa, and that work will be expanding in 2023.
In India we will significantly scale up our work with established partners Mo School and Pratham Education Foundation, training 2000 more teachers in government schools in Odisha, and running 2200 Code Clubs across four states. We will also be launching new partnerships with community-based organisations in Kenya and South Africa, helping them set up networks of Code Clubs and co-designing learning experiences that help them bring computing education to their communities of young people.
Over the past few years, our research seminar series has covered computing education topics from diversity and inclusion, to AI and data science. This year, we’re focusing on current questions and research in primary computing education for 5- to 11-year-olds.
As ever, we’re providing a platform for some of the world’s leading researchers to share their insights, and convening a community of educators, researchers, and policy makers to engage in the discussion. The first seminar takes place today (Tuesday 10 January) and it’s not too late to sign up.
That’s just a few of the super cool things that we’ve got planned for 2023. I haven’t even mentioned the new online projects we’re developing with our friends at Unity, the fun we’ve got planned with our very own online text editor, or what’s next for our curriculum and professional development offer for computing teachers.
You can sign up to our monthly newsletter to always stay up to date with what we’re working on.
The post What to expect from the Raspberry Pi Foundation in 2023 appeared first on Raspberry Pi.
In the final seminar in our series on cross-disciplinary computing, Dr Tracy Gardner and Rebecca Franks, who work here at the Foundation, described the framework underpinning the Foundation’s non-formal learning pathways. They also shared insights from our recently published literature review about the impact that non-formal computing education has on learners.
Tracy and Rebecca both have extensive experience in teaching computing, and they are passionate about inspiring young learners and broadening access to computing education. In their work here, they create resources and content for learners in coding clubs and young people at home.
UNESCO defines non-formal learning as “institutionalised, intentional, and planned… an addition, alternative, and/or complement to formal education within the process of life-long learning of individuals”. In terms of computing education, this kind of learning happens in after-school programmes or children’s homes as they engage with materials that have been carefully designed by education providers.
At the Raspberry Pi Foundation, we support two global networks of free, volunteer-led coding clubs where regular non-formal learning takes place: Code Club, teacher- and volunteer-led coding clubs for 9- to 13-year-olds taking place in schools in more than160 countries; and CoderDojo, volunteer-led programming clubs for young people aged 7–17 taking place in community venues and offices in 100 countries. Through free learning resources and other support, we enable volunteers to run their club sessions, offering versatile opportunities and creative, inclusive spaces for young people to learn about computing outside of the school curriculum. Volunteers who run Code Clubs or CoderDojos report that participating in the club sessions positively impacts participants’ programming skills and confidence.
Rebecca and Tracy are part of the team here that writes the learning resources young people in Code Clubs and CoderDojos (and beyond) use to learn to code and create technology.
Rebecca started the seminar by describing how the team reviewed existing computing pedagogy research into non-formal learning, as well as large amounts of website visitor data and feedback from volunteers, to establish a new framework for designing and creating coding resources in the form of learning paths.
As Rebecca explained, non-formal learning paths should be designed to bridge the so-called ‘Turing tar-pit’: the gap between what learners want to do, and what they have the knowledge and resources to achieve.
To prevent learners from getting frustrated and ultimately losing interest in computing, learning paths need to:
When Rebecca and Tracy’s team create new learning paths, they first focus on the things that learners want to make. Then they work backwards to bridge the gap between learners’ big ideas and the knowledge and skills needed to create them. To do this, they use the 3…2…1…Make! framework they’ve developed.
Learning paths designed according to the framework are made up of three different types of project in a 3-2-1 structure:
You can learn more about the framework in this blog post and this guide for adults who run sessions with young people based on the learning paths. And you can explore the learning paths yourself too.
Rebecca and Tracy’s team have created several new learning pathways based on the 3…2…1…Make! framework and received much positive feedback on them. They are now looking to develop more tools and libraries to support learners, to increase the accessibility of the paths, and also to conduct research into the impact of the framework.
In the second half of the seminar, Tracy shared what the research literature says about the impact of non-formal learning. She and researchers at the Foundation particularly wanted to find out what the research says about computing education for K–12 in non-formal settings. They systematically reviewed 421 papers, identifying 88 papers from the last seven years that related to empirical research on non-formal computing education for young learners. Based on these 88 papers, they summarised the state of the field in a literature review.
So far, most studies of non-formal computing education have looked at knowledge and skill development in computing, as well as affective factors such as interest and perception. The cognitive impact of non-formal education has been generally positive. The papers Tracy and the research reviewed suggested that regular learning opportunities, such as weekly Code Clubs, were beneficial for learners’ knowledge development, and that active teaching of problem solving skills can lead to learners’ independence.
Non-formal computing education also seems to be beneficial in terms of affective factors (although it is unclear yet whether the benefits remain long-term, since most existing research studies conducted have been short-term ones). For example, out-of-school programmes can lead to more positive perception and increased awareness of computing for learners, and also boost learners’ confidence and self-efficacy if they have had little prior experience of computing. The social aspects of participating in coding clubs should not be underestimated, as learners can develop a sense of belonging and support as they work with their peers and mentors.
The literature review showed that non-formal computing complements formal in-school education in many ways. Not only can Code Clubs and CoderDojos be accessible and equitable spaces for all young people, because the people who run them can tailor learning to the individuals. Coding clubs such as these succeed in making computing fun and engaging by enabling a community to form and allowing learners to make things that are meaningful to them.
Another thing the literature review made obvious is that there are big gaps in the existing understanding of non-formal computing education that need to be researched in more detail. For example, most of the studies the papers in the literature review described took place with female students in middle schools in the US.
That means the existing research tells us little about non-formal learning:
We would also love to see studies that hone in on:
We’re excited to continue collaborating within the Foundation so that our researchers and our team creating non-formal learning content can investigate the impact of the 3…2…1…Make! framework.
This collaboration connects two of our long-term strategic goals: to engage millions of young people in learning about computing and how to create with digital technologies outside of school, and to deepen our understanding of how young people learn about computing and how to create with digital technologies, and to use that knowledge to increase the impact of our work and advance the field of computing education. Based on our research, we will iterate and improve the framework, in order to enable even more young people to realise their full potential through the power of computing and digital technologies.
From January, you can join our new monthly seminar series on primary (K–5) teaching and learning. In this series, we’ll hear insights into how our youngest learners develop their computing knowledge, so whether you’re a volunteer in a coding club, a teacher, a researcher, or simply interested in the topic, we’d love to see you at one of these monthly online sessions.
The first seminar, on Tuesday 10 January at 5pm UK time, will feature researchers and educators Dr Katie Rich and Carla Strickland. They will share findings on how to teach children about variables, one of the most difficult aspects of computing for young learners. Sign up now, and we will send you notifications and joining links for each seminar session.
We look forward to seeing you soon, and to discussing with you how we can apply research results to better support all our learners.
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Young tech creators, get ready: Coolest Projects will be back in 2023, and we want to make this the year of your big idea!
Coolest Projects is the world’s leading online technology showcase for young creators across the world, and we’ll soon be inviting young people to share their creations in the 2023 gallery when project registration opens on 6 February.
For young creators, Coolest Projects is the unique opportunity to share their big ideas with the whole world. All projects in our open online showcase receive personalised feedback from judges, and all creators get some awesome limited-edition swag too. To bring all the participants together, we’ll host a live-streamed celebration event online on 6 June 2023, where we’ll also reveal the favourite projects of our very special VIP judges.
Creators who took part in 2022 told us that the coolest thing about Coolest Projects is that “so many people around the world get to see and appreciate your projects” and that “anyone can have a go”.
Coolest Projects creators make digital tech projects that matter to them and that they want to share with the world. Creators have all different levels of skill — some register their very first coding project, and others have taken part in Coolest Projects for years. We welcome every project from every young person in Coolest Projects. With six project categories from Scratch to hardware, and project topics including environment, health, and fun, creators come up with all kinds of cool ideas.
Take a look at the online showcase gallery to see the projects young makers shared in the most recent showcase, including an app about recycling, a smiley face game, a trash-collecting boat, and a game to help you eat more healthily.
Registration opens on 6 February 2023, and creators can get started on their ideas and make their projects any time.
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This November, teachers across the UK helped 367,023 learners participate in the annual free UK Bebras Challenge of computational thinking.
We support this challenge in the UK, together with Oxford University, and Bebras Challenges run across the world, with more than 3 million learners from schools in 54 countries taking part in 2021. Bebras encourages a love of computational thinking, computer science, and problem solving, especially among learners who haven’t yet realised they have these skills.
Nearly every year since 2013, more UK schools have been participating in Bebras. We think this is because for teachers, registering and entering learners is easy, the online system does all the marking automatically, and teachers receive comprehensive results that can be helpful for assessment.
The computational thinking problems within Bebras are tailored for different age groups, use clear language, and are accessible to colour-blind learners. There is also a challenge for learners with visual impairments. Teachers who run Bebras in their schools seem to love it and regularly tell colleagues about it.
“Our pupils really enjoy [Bebras] and I find it so helpful to teach computational thinking with real-life strategies. We also find the data and information about our pupils’ performance extremely helpful.” — Teacher in London
In the UK Bebras Challenge, the younger learners aged 6 to 10 usually take part in teams and have plenty of time to discuss how to solve the computational thinking problems they are presented with.
Older learners, aged 10 to 18, try to solve as many problems as they can in 40 minutes. The problems they are presented with start off easy and get increasingly difficult. The 10% of participants who solve the most problems are then invited to take part in the Oxford University Computing Challenge (OUCC), an annual programming challenge.
Although the OUCC is only open to some Bebras participants, all of the OUCC problems are archived and teachers registered with Bebras can use them to make auto-marking quizzes for all of their learners at any time of the year. Part of the goal of UK Bebras is to support teachers with free resources, and the UK Bebras online quizzes facility now has computational thinking tasks from the Bebras archive, plus auto-marking Blockly programming problems and text-based programming problems, which can be solved using commonly taught programming languages.
If you want to get a taste of Bebras, check out some of the interactive challenges that require no registration. And if you’d like to register to make quizzes for your learners and find out about next year’s challenge, you can do so at bebras.uk/admin.
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Today we are sharing an evaluation report on another study that’s part of our Gender Balance in Computing research programme. In this study, we investigated the impact of using relevant contexts in classroom programming activities for 12- to 13-year-olds on girls’ and boys’ attitudes towards Computing.
We have been working on Gender Balance in Computing since 2018, together with partner organisations Behavioural Insights Team, Apps for Good, and WISE, to conduct research studies exploring ways to encourage more girls and young women to engage with Computing in school. The research programme has been funded by the Department for Education, and we deliver it as part of the National Centre for Computing Education. The report we share today is about the penultimate study in the programme.
A typical Computing curriculum is built around content: a list of concepts, knowledge, and skills that will be covered during the course. For some learners, that list will be enough to motivate and engage them in Computing. But other learners require more to engage with the subject, such as context about how they can use the computing skills they learn in the real world. Crucially, this difference between learners is often gendered. Research has shown that many boys become absorbed by the content in Computing courses, whereas for many girls the context for using computing skills is more important, and this context needs to relate to a variety of relevant scenarios where computing can solve problems.
In the Relevance study, we worked together with colleagues from Apps for Good to create teaching materials that present Computing in contexts that were relevant to pupils’ own interests. To do this, we drew on a research concept called identification. This states that when learners become interested in a topic because it relates to part of their own identity, that makes the subject more personally meaningful to them, which in turn means that they are more likely to continue studying it. In the materials we created, we drew on learners’ identities based on the communities that they belonged to (see image below). The materials asked them to identify the connections they had to their own communities, and to then use this as the context to design and create a mobile phone app.
“I feel a sense of achievement in Computing when making your ideas a reality makes you proud of your creation, which is rewarding.” (Female learner, Relevance study evaluation report p. 57)
Between January 2022 and April 2022, more than 95 secondary schools were part of our study investigating the effect that learning with these resources might have on the attitudes of Year 8 pupils (aged 12–13) towards Computing. We are very grateful to all the schools, pupils, and teachers who took part in this study.
To enable evaluation of the study as a randomised controlled trial, the schools were randomly divided into two groups: a ‘control’ group that taught standard Computing lessons, and a ‘treatment’ group that delivered the intervention materials we had developed. The impact of the intervention was independently evaluated by the Behavioural Insights Team using data collected from pupils via surveys at the start and end of the intervention. The evaluators also collected data while conducting lesson observations, pupil group discussions, teacher interviews, and teacher surveys to understand how the intervention was delivered.
The girls who took part in the intervention chose an interesting range of contexts for their apps, including:
“I feel like it’s an important subject, and I feel like sea life is at risk right now, and I want to help people realise that.” (Female learner, Relevance study evaluation report p. 60)
“I feel like computing can create apps to do with solving mental health problems, which I think are very important and personally need a lot of improvement on the way we can cope with mental health.” (Female learner, Relevance study evaluation report p. 60)
The start of this blog refers to the core components of a Computing curriculum: concepts, knowledge, and skills. One way of building a curriculum is to list these components and develop a scheme of work which covers them all. However, in a recent computing education paper, researchers present an alternative way: developing curricula around the possible endpoints of learners. For computing, one endpoint could be the economic opportunities of a programming career, but equally, another could be using digital technologies for creative expression. The researchers argue that when learners have the opportunity to use computing as a tool related to personally meaningful contexts, a more diverse group of learners can become engaged in the subject.
Girls who took part in our Relevance study expressed the importance of creativity. “I think last term we had instructions and you follow them, whereas now it’s like your own ideas and your own creativity and whatever you make,” said one female learner (report, p. 56). The series of lessons where learners designed a prototype of their app was particularly popular among girls because this activity included creative expression. Girls who see themselves as creative align their interests with subjects that allow them to express this part of their identity.
Based on learner responses to a ‘yes/no’ question about whether they were likely to choose GCSE Computer Science, the evaluators of the study found no statistically significant differences between the students who were part of the treatment and control groups. However, when learners were asked instead to select from a list which subjects they were likely to choose at GCSE, there was a statistically significant difference in the results: girls from schools in the treatment group were more likely to choose GCSE Computer Science as one of their options than girls in the control group. This finding suggests that it would be beneficial to gender balance in Computing if educators who design Computing curricula consider multiple endpoints for learners and include personally meaningful contexts to create learning experiences that are relevant to diverse groups of learners.
This is the penultimate report to be published about the studies that are part of the Gender Balance in Computing programme. If you would like to stay up-to-date with the programme, you can sign up to our newsletter. Our final report is about a study that explored the role that options booklets and evenings play in students’ subject choice.
The post Using relevant contexts to engage girls in the Computing classroom: Study results appeared first on Raspberry Pi.
We are so excited to share another story from the community! Our series of community stories takes you across the world to hear from young people and educators who are engaging with creating digital technologies in their own personal ways.
In this story we introduce you to Selin, a digital maker from Istanbul, Turkey, who is passionate about robotics and AI. Watch the video to hear how Selin’s childhood pet inspired her to build tech projects that aim to help others live well.
Selin (16) started her digital making journey because she wanted to solve a problem: after her family’s beloved dog Korsan passed away, she wanted to bring him back to life. Selin thought a robotic dog could be the answer, and so she started to design her project on paper. When she found out that learning to code would mean she could actually make a robotic dog, Selin began to teach herself about coding and digital making.
Thanks to her local CoderDojo, which is part of the worldwide CoderDojo network of free, community-based, volunteer-led programming clubs where young people explore digital technology, Selin’s interest in creating tech projects grew and grew. Selin has since built seven robots, and her enthusiasm for building things with digital technology shows no sign of stopping.
One of Selin’s big motivations to explore digital making was having an event to work towards. At her Dojo, Selin found out about Coolest Projects, the global technology showcase for young people. She then set herself the task of making a robot to present at the Coolest Projects event in 2018.
When thinking about ideas for what to make for Coolest Projects, Selin remembered how it felt to lose her dog. She wondered what it must be like when a blind person’s guide dog passes away, as that person loses their friend as well as their support. So Selin decided to make a robotic guide dog called IC4U. She contacted several guide dog organisations to find out how guide dogs are trained and what they need to be able to do so she could replicate their behaviour in her robot. The robot is voice-controlled so that people with impaired sight can interact with it easily.
Selin and her parents travelled to Coolest Projects International in Dublin, thanks to support from the CoderDojo Foundation. Accompanying them was Selin’s project IC4U, which became a judges’ favourite in the Hardware category. Selin enjoyed participating in Coolest Projects so much that she started designing her project for next year’s event straight away:
“When I returned back I immediately started working for next year’s Coolest Projects.”
Selin
Many of Selin’s tech projects share a theme: to help make the world a better place. For example, another robot made by Selin is the BB4All — a school assistant robot to tackle bullying. And last year, while she attended the Stanford AI4ALL summer camp, Selin worked with a group of young people to design a tech project to increase the speed and accuracy of lung cancer diagnoses.
Through her digital making projects, Selin wants to show how people can use robotics and AI technology to support people and their well-being. In 2021, Selin’s commitment to making these projects was recognised when she was awarded the Aspiring Teen Award by Women in Tech.
Listening to Selin, it is inspiring to hear how a person can use technology to express themselves as well as create projects that have the potential to do so much good. Selin acknowledges that sometimes the first steps can be the hardest, especially for girls interested in tech: “I know it’s hard to start at first, but interests are gender-free.”
“Be curious and courageous, and never let setbacks stop you so you can actually accomplish your dream.”
Selin
We have loved seeing all the wonderful projects that Selin has made in the years since she first designed a robot dog on paper. And it’s especially cool to see that Selin has also continued to work on her robot IC4U, the original project that led her to coding, Coolest Projects, and more. Selin’s robot has developed with its maker, and we can’t wait to see what they both go on to do next.
Help us celebrate Selin and inspire other young people to discover coding and digital making as a passion, by sharing her story on Twitter, LinkedIn, and Facebook.
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At the Raspberry Pi Foundation, we engage young people in learning about computing and creating with digital technologies. We do this not only by developing curricula for formal education and introducing tens of thousands of children around the world to coding at home, but also through supporting non-formal learning activities such as Code Club and CoderDojo.
To find out what works in non-formal computing learning, we’ve conducted two research projects recently: a systematic literature review, and a set of two interventions that were applied and evaluated as part of our Gender Balance in Computing programme. In this blog, we outline these two research projects.
When you think of young people learning computing, do you think of schools, classrooms, and curricula? You’d be right that lots of computing education for young people takes place in classrooms as part of national curricula. However, a lot of learning can take place outside of formal schooling. When we talk about non-formal computing education, we mean structured or semi-structured learning environments such as clubs or community groups, often set up by volunteers. These may take place in a school, library, or community venue; but we’ve also heard of some of our communities running non-formal learning activities on buses, in fire stations, or at football grounds — there really is no limit to where learning can happen.
It’s harder to assess the impact and effectiveness of non-formal computing activities than formal computing education: we have to think outside of the traditional measures such as grades and formal exams or assessments. Instead, we estimate outcomes according to measures such as level of participant engagement, attendance, attrition rates, and changes in participants’ attitudes towards computing. We have previously also piloted non-formal assessments such as quizzes and found that these were well-received by adult facilitators and children alike.
Earlier this year, we conducted a systematic literature review into computing education for K–12 learners in non-formal settings. We identified 88 relevant research studies, which we read, compared, and synthesised to provide an overview of what is already known about the effectiveness of non-formal computing activities and to identify opportunities for further research.
Our analysis looked for common themes within existing studies and suggested some benefits that non-formal learning offers, including:
We presented this research at an international computing education conference called ICER 2022, and you can read about it in our open-access paper in the ICER conference proceedings.
One particularly interesting characteristic of non-formal learning is that it tends to attract a broader range of learners than formal computing lessons. For example, a 2019 survey found that about 40% of the young people who attend Code Clubs were female. This is a high percentage compared with the proportion of girls among the learners choosing Computer Science GCSE in England, which is currently around 20%. We believe this points to an opportunity to capitalise on girls’ interest in learning activities outside of the classroom, and we hope to use non-formal activities to encourage more girls to take an interest in formal computer science education.
As part of our Gender Balance in Computing research programme in England, we worked with Apps for Good and the Behavioual Insights Team (BIT) to run two interventions in school-based non-formal settings, for which we adapted non-formal resources and used behavioural science concepts to strengthen the links the resources make between non-formal learning and studying computing more formally. One intervention ran in secondary schools for learners aged 13–14 years old, who used an adapted Apps for Good course, and the other ran in primary school for learners aged 8–11 year olds, who took part in Code Clubs using adapted versions of our projects.
The interventions were evaluated independently by a separate team from BIT, based on data from surveys completed by learners before and after the interventions, and interviews with teachers and learners. This data was analysed by the independent team to explore the impact the interventions had on learners’ attitudes towards computing and intention to study the subject in the future.
Our literature review concluded that future research in this area would benefit from experimenting with a variety of approaches to designing, and measuring the impact of, computing activities in a non-formal setting. For example, this could include comparing the short-term and long-term impact of specific interventions, aiming to cater for different types of participants, and offering different types of learning experiences.
In these two Gender Balance in Computing interventions, there was limited statistical evidence of an improvement in participants’ attitude towards computing or in their stated intention to study computer programming in the future. The independent evaluators recommended that the learning content that was created for the interventions could be adapted further to make the link between non-formal and formal learning even more salient. On the other hand, as is often the case with research, some interesting themes — ones that we weren’t looking for — emerged from the data, including:
In both projects, the findings suggest that it is beneficial for learners to participate in non-formal learning activities that link to real-world situations, and that this could be particularly beneficial for girls to help them see computing as a subject that is relevant to their own interests and goals. Another common theme in both projects is that non-formal learning activities play an important role in showing what a “computer person” looks like and who belongs in computing. This suggests there’s a need for a diverse range of volunteers to run non-formal computing activities, and that we should make sure that non-formal learning resources include representations of a diverse range of learners.
Undertaking these research projects has provided evidence that the work the Foundation does is on the right track and suggested opportunities to use these themes in our future non-formal work and resources.
More information about research projects at the Raspberry Pi Foundation and our newly launched Raspberry Pi Computing Education Research Centre can be found on our research pages and on the Research Centre’s website.
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Inspire young people about coding and space science with Astro Pi Mission Zero. Mission Zero offers young people the chance to write code that will run in space! It opens for participants today.
In Mission Zero, young people write a simple computer program to run on an Astro Pi computer on board the International Space Station (ISS).
Following step-by-step instructions, they write code to take a reading from an Astro Pi sensor and display a colourful image for the ISS astronauts to see as they go about their daily tasks. This is a great, one-hour activity for beginners to programming.
Participation is free and open for young people up to age 19 in ESA Member States (eligibility details). Everything can be done in a web browser, on any computer with internet access. No special hardware or prior coding skills are needed.
Participants will receive a piece of space science history to keep: a personalised certificate they can download, which shows their Mission Zero program’s exact start and end time, and the position of the ISS when their program ran.
All young people’s entries that meet the eligibility criteria and follow the official Mission Zero guidelines will have their program run in space for up to 30 seconds.
Mission Zero 2022/23 is open until 17 March 2023.
If you’ve been involved in Mission Zero before, you will notice lots of things have changed. This year’s Mission Zero participants will be the first to use our brand-new online code editor, a tool that makes it super easy to write their program using the Python language.
Thanks to the new Astro Pi computers that we sent to the ISS in 2021, there’s a brand-new colour and luminosity sensor, which has never been available to Mission Zero programmers before:
Finally, this year we’re challenging coders to create a colourful image to show on the Astro Pi’s LED display, and to use the data from the colour sensor to determine the image’s background colour.
The theme to inspire images for Mission Zero 2022/23 is ‘flora and fauna’. The images participants design can represent any aspect of this theme, such as flowers, trees, animals, or insects. Young people could even choose to program a series of images to show a short animation during the 30 seconds their program will run.
Here are some examples of images created by last year’s Mission Zero participants. What will you create?
The European Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation. Young people can also take part in Astro Pi Mission Space Lab, where they will work to design a real scientific experiment to run on the Astro Pi computers.
You can keep updated with all of the latest Astro Pi news by following the Astro Pi Twitter account or signing up to the newsletter at astro-pi.org.
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The UK Bebras Challenge is back and ready to accept entries from schools for its annual event from 7 to 18 November.
More than 3 million students from 54 countries took part in the Bebras Challenge in 2021. Read on to find out how you can get your school involved.
Bebras a free, annual challenge that helps schools introduce computational thinking to their students. No programming is involved, and it’s completely free for schools to take part. All Bebras questions are self-marking. Schools can enter students from age 6 to 18 and know they’ll get interesting and challenging (but not too challenging) activities.
“This has been a really positive experience. Thank you. Shared results with head and Head of KS3. Really useful for me when assessing KS4 options.” – Secondary teacher, North Yorkshire
We’re making Bebras accessible by offering age-appropriate challenges for different school levels, and a challenge tailored for visually impaired students.
We want young people to get excited about computing. Through Bebras, they will learn about computational and logical thinking by answering questions and solving puzzles.
Bebras questions are based on classic computing problems and presented in friendly, age-appropriate contexts. For example, an algorithm-based puzzle for learners aged 6 to 8 is presented in terms of a hungry tortoise find an efficient eating path across a lawn; for 16- to 18-year-olds, a difficult question based on graph theory asks students to sort out some quiz teams by linking quizzers who know each other.
Here’s a question from the 2021 challenge for the Junior category (ages 10 to 12). You’ll find the correct answer at the bottom of this blog post.
Question: What is the correct order of events for the science fair?
The Bebras challenge for UK schools takes place from 7 to 18 November. Register at bebras.uk/admin to get full access to the challenge.
By registering, you also get access to the back catalogue of questions, from which you can build your own quizzes to use in your school at any time during the year. All the quizzes are self-marking, and you can download your students’ results for your mark book. Schools have reported using the back catalogue of questions for end-of-term activities, lesson starters, and schemes of lessons about computational thinking.
You can also see more of our free resources for Computing and Computer Science teachers, and find out about our newest research project, which you can get involved in if you teach primary Computing.
There are actually two possible answers to the example puzzle:
Option 1 | Option 2 |
Chorus Performance Preparation of Stands Opening Speeches Project Presentations Social Interaction Referee Reviews Awarding Prizes | Preparation of Stands Chorus Performance Opening Speeches Project Presentations Social Interaction Referee Reviews Awarding Prizes |
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The European Astro Pi Challenge is back for another year. This is young people’s chance to write computer programs that run on board the International Space Station.
Young people can take part in two Astro Pi challenges: Mission Zero and Mission Space Lab. Participation is free and open for young people up to age 19 in ESA Member States (see more details about eligibility on the Astro Pi website). Young people can participate in one or both of the challenges.
Their programs will run on the two new upgraded Astro Pi computers, which launched into space in December 2021. The Astro Pis were named after the two inspirational European scientists Nikola Tesla and Marie Skłodowska-Curie by Mission Zero participants. For the 2021/22 European Astro Pi Challenge, these new computers ran over 17,000 programs written by young people from 26 countries.
Here is ESA astronaut Matthias Maurer getting the new Astro Pis ready for young people’s experiments.
In Mission Space Lab, teams of young people work together with a mentor who supports them, as they design a scientific experiment to be run on the Astro Pis in space.
Teams write programs that use an Astro Pi’s sensors and camera to collect data from the International Space Station, which the teams then analyse. This video has more information about the Astro Pi computers and how teams can choose an experiment idea:
Registration for Mission Space Lab is now open, and participation takes place over eight months. Mentors need to register their team and submit the team’s experiment idea by 28 October 2022. For more details on how to register, visit the Mission Space Lab webpages.
For inspiration, you can read the reports written by the winning teams for Mission Space Lab 2021/22. What will your team’s experiment idea be? We can’t wait to hear about it.
Mission Zero is the beginners’ challenge where young people write a simple program and get a taste of space science.
All eligible programs that follow the official guidelines will run in space for up to 30 seconds. The young people who participate receive a certificate they can download which shows their program’s exact start and end time, and the position of the ISS when their program ran — a piece of space science history to keep!
Mission Zero opens on 22 September 2022. Watch this space for more details on launch day.
The European Astro Pi Challenge is an ESA Education project run in collaboration with us here at the Raspberry Pi Foundation.
You can stay up to date with all of the latest Astro Pi news by following the Astro Pi Twitter account or signing up to the newsletter at astro-pi.org
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We are looking for primary schools in England to get involved in our new research study investigating how to adapt Computing resources to make them culturally relevant for pupils. In a project in 2021, we created guidelines that included ideas about how teachers can modify Computing lessons so they are culturally relevant for their learners. In this new project, we will work closely with primary teachers to explore this adaptation process.
This project will help increase the education community’s understanding of ways to widen participation in Computing. The need to do this is demonstrated (as only one example among many) by the fact that in England’s 2017 GCSE Computer Science cohort, Black students were the most underrepresented group. We will investigate how resources adapted to be culturally relevant might influence students’ ideas about computing and contribute to their sense of identity as a “computer person”.
This study is funded by the Cognizant Foundation and we are grateful for their generous support. Since 2018, the Cognizant Foundation has worked to ensure that all individuals have equitable opportunities to thrive in the jobs driving the future. Their work aligns with our mission to enable young people to realise their full potential through the power of computing and digital technologies.
This project about culturally adapted resources will take place between October 2022 and July 2023. It draws from ideas on how to bridge the gap between academic research and classroom teaching, and we are looking for 12 primary teachers to work closely with our researchers and content writers in three phases using a tested co-creation model.
By taking part, you will gain an excellent understanding of culturally relevant pedagogy and develop your knowledge and skills in delivering culturally responsive Computing lessons. We will value your expertise and your insights into what works in your classroom, and we will listen to your ideas.
We will kick off the project with a day-long workshop on 2 November at our head office in Cambridge, which will bring all the participating teachers together. (Funding is available for participating schools to cover supply costs and teachers’ travel costs.) In the workshop, we will first explore what culturally relevant and responsive computing means. Then we will work together to look at a half-term unit of work of Computing lessons and identify how it could be adapted. After the workshop day, we will produce an adapted version of the unit of work based on the teachers’ input and ideas.
In the Spring Term, teachers will deliver the adapted unit of work to their class in the second half of the term. Through a survey before and after the set of lessons, students will be asked about their views of computing. Throughout this time, the research team will be available for online support. We may also visit your school to carry out an observation of one of the lessons.
During this phase, the research team will ask participating teachers about their experiences, and about whether and how they further adapted the lessons. Teachers will likely spend 2 to 3 hours in either April or May sharing their insights and recommendations. After this phase, we will analyse the findings from the study and share the results both with the participating teachers and the wider computing education community.
For this study, we are looking for primary teachers who teach Computing to Year 4 or Year 5 pupils in a school in England.
We will also give preference to schools with culturally diverse catchment areas.
If you are an interested teacher, please apply to take part in this project by the closing date of Monday, 3 October. If you have any questions, email us at research@raspberrypi.org.
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Sobhy Fouda started his Astro Pi journey in 2019 by helping a group of young people participate in Astro Pi Mission Zero, the beginners’ activity of the annual European Astro Pi Challenge. In Mission Zero, participants write a simple computer program that runs on board the International Space Station (ISS).
Seeing the wonder on the faces of the young people on the day when their programs were sent to space motivated Sobhy to take the next step: the year after, he became the mentor of a team of young people who wanted to take part in Astro Pi Mission Space Lab 2020/21. Sobhy supported them for 8 months as they designed and wrote a program to conduct their own scientific experiment on the ISS. The team placed among the 10 winners of Mission Space Lab that year.
Among this winning team was Ismail, who joined Sobhy as a mentor for the next round of Astro Pi Mission Space Lab in 2021/22. We spoke to Sobhy and Ismail about their experiences as mentors, about how being involved in Astro Pi changed their life, and about how when you dream big, you can inspire others to do the same.
“I have always loved space and I had big dreams of becoming a pilot,” said Sobhy. After graduating with a mechatronics engineering degree from the German University in Cairo, he moved to the UK to study aircraft maintenance and aerospace engineering. During this time, Sobhy heard about the Astro Pi Challenge and decided to support some young people in his community to take part in Mission Zero. “It was my first experience with the Astro Pi programme, so it was a great first step for me to teach the team some basic Python skills.”
Sadly, Sobhy was unable to continue down his chosen career path in the UK due to health issues. He said, “It was a very difficult time for me. It was hard to walk away from a dream I had held for so long. I decided to apply for a scholarship within aerospace in Germany, focusing more on writing code, as well as on R&D [research and development].” Sobhy credited his participation as a mentor in Mission Zero as crucial to his success with this next step: “I thoroughly believe that my mentorship of a Mission Zero team helped me to demonstrate my social commitment, which was a significant requirement for the scholarship.”
When Sobhy was awarded the scholarship, he and his wife moved to Berlin, but it was hard for him to find inspiration. This changed when he decided to be an Astro Pi mentor again. “My wife put the word out about it [Astro Pi Mission Space Lab] in my community, and we had a number of young people come forward.”
With help from Sobhy, his Mission Space Lab team started thinking through experiment ideas a couple of months in advance of the challenge start. “Once I had got the kids familiarised with the sensors on the Astro Pi computer and the conditions on the ISS, it was the logical next step to start introducing more Python to learn how to control these sensors and discuss what we could analyse.”
Sobhy’s team successfully submitted an idea for a Mission Space Lab experiment: investigating how the Earth’s magnetic field correlates with its climate, and how this affects near-Earth objects’ behaviour in low-Earth orbit. Next, the team of young people received an Astro Pi hardware kit with which to test the program they wrote in realistic conditions. Sobhy said that “once we received our Astro Pi kit with the sensors, I then used these sensors to make the experiments more relatable to the kids, getting them to measure the humidity in their rooms for example, and I tried to gamify the sessions as much as possible to keep it fun and ignite their imagination.”
One young person on Sobhy’s Mission Space Lab team was Ismail, who was 17 at the time. Ismail explained, “I had some programming experience, as I had worked in Sobhy’s previous teams for Mission Zero, but taking part in Mission Space Lab really helped me to develop these skills in a practical way.”
Ismail was particularly surprised by how much he loved working with the Astro Pi hardware . “I always thought I would follow a career path in programming, however, working with the Raspberry Pi computer and its sensors made me realise that I liked working with the hardware even more than doing programming,” said Ismail. “I ended up changing my choice of degree to mechatronics, so my Mission Space Lab experience really helped me to find the career path I was meant to be on.”
Taking part in Astro Pi Mission Space Lab wasn’t the only thing that shaped Ismail’s path: he credits Sobhy’s mentorship for helping him achieve his goals. “Sobhy was such a good mentor. His passion for the project radiated from him and infected us all! He explained what we needed to tackle, asked questions, and then gave us small activities to put our programming experience into practice in a practical way. It made the programming so much more interesting.”
Sobhy said that when the team was announced among the winners of Mission Space Lab in the 20/21 Astro Pi Challenge, “seeing the team’s reaction was so rewarding. All our hard work paid off, and I was so happy and proud of the team and what they had achieved.” Ismail added, “I still have to pinch myself that we actually won. I’m constantly asking myself if it actually happened, as it was so unbelievable. It was incredible.”
Sobhy has stayed in contact with the young people he mentored in the Astro Pi Challenge and their bond remains strong. Ismail said, “He has really become a friend. He was always so helpful and knowledgeable. I just loved working with him, so when he asked if I wanted to become an assistant Astro Pi mentor, I took the opportunity despite having other commitments.”
Moving on to become a mentor alongside Sobhy in the 2021/22 Astro Pi Challenge was an eye-opening experience for Ismail. “I had to learn a new set of skills,” said Ismail. “In particular, I realised I needed to improve my presentation skills. To start with I was really uncomfortable speaking in front of a group, but now I’m not, and this confidence transferred over to my university studies. That’s been a really great benefit I’ve taken from the experience.”
“[My] Mission Space Lab experience really helped me to find the career path I was meant to be on.”
Ismail, Mission Space Lab participant and mentor
For us it was wonderful to hear about these lasting friendships and connections that have formed among the people participating in Mission Space Lab. Both Sobhy and Ismail felt that while mentoring a Mission Space Lab team can be challenging at times, the rewards are worth it. Watching their team develop and seeing the young people connect made the experience extremely rewarding.
Ismail concluded by saying: “Astro Pi has been one of the best experiences I have had in my life. I have so much to be thankful for, and I owe this to Astro Pi, but even more to my mentor Sobhy. He has encouraged me to have this incredible experience, helped me find my path in life, and guided me every step of the way. I will remember him and be thankful to him for the rest of my life. It’s been life-changing.”
In only a few days, you’ll be able to register as a team mentor for Astro Pi Mission Space Lab 2022/23.
The European Astro Pi Challenge, an ESA education programme in collaboration with us at the Raspberry Pi Foundation, starts again from 12 September. Sign up to the newsletter at astro-pi.org to be the first to hear news about the programme.
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Many technology items are disposed of each year, either because they are broken, are no longer needed, or have been upgraded. Researchers from Germany have identified this as an opportunity to develop a scheme of work for Computing, while at the same time highlighting the importance of sustainability in hardware and software use. They hypothesised that by repairing defective devices, students would come to understand better how these devices work, and therefore meet some of the goals of their curriculum.
The research team visited three schools in Germany to deliver Computing lessons based around the concept of a repair café, where defective items are repaired or restored rather than thrown away. This idea was translated into a series of lessons about using and repairing smartphones. Learners first of all explored the materials used in smartphones and reflected on their personal use of these devices. They then spent time moving around three repair workstations, examining broken smartphones and looking at how they could be repaired or repurposed. Finally, learners reflected on their own ecological footprint and what they had learnt about digital hardware and software.
In the classroom, repair workstations were set up for three different categories of activity: fixing cable breaks, fixing display breaks, and tinkering to upcycle devices. Each workstation had a mentor to support learners in investigating faults themselves by using the question prompt, “Why isn’t this feature or device working?” At the display breaks and cable breaks workstations, a mentor was on hand to provide guidance with further questions about the hardware and software used to make the smartphone work. On the other hand, the tinkering workstation offered a more open-ended approach, asking learners to think about how a smartphone could be upcycled to be used for a different purpose, such as a bicycle computer. It was interesting to note that students visited each of the three workstations equally.
The feedback from the participants showed there had been a positive impact in prompting learners to think about the sustainability of their smartphone use. Working with items that were already broken also gave them confidence to explore how to repair the technology. This is a different type of experience from other Computing lessons, in which devices such as laptops or tablets are provided and are expected to be carefully looked after. The researchers also asked learners to complete a questionnaire two weeks after the lessons, and this showed that 10 of the 67 participants had gone on to repair another smartphone after taking part in the lessons.
The project drew on a theory called duality reconstruction that has been developed by a researcher called Carsten Schulte. This theory argues that in computing education, it is equally important to teach learners about the function of a digital device as about the structure. For example, in the repair café lessons, learners discovered more about the role that smartphones play in society, as well as experimenting with broken smartphones to find out how they work. This brought a socio-technical perspective to the lessons that helped make the interaction between the technology and society more visible.
Using this approach in the Computing classroom may seem counter-intuitive when compared to the approach of splitting the curriculum into topics and teaching each topic sequentially. However, the findings from this project suggest that learners understand better how smartphones work when they also think about how they are manufactured and used. Including societal implications of computing can provide learners with useful contexts about how computing is used in real-world problem-solving, and can also help to increase learners’ motivation for studying the subject.
The final aspect of this research project looked at collaborative problem-solving. The lessons were structured to include time for group work and group discussion, to acknowledge and leverage the range of experiences among learners. At the workstations, learners formed small groups to carry out repairs. The paper doesn’t mention whether these groups were self-selecting or assigned, but the researchers did carry out observations of group behaviours in order to evaluate whether the collaboration was effective. In the findings, the ideal group size for the repair workstation activity was either two or three learners working together. The researchers noticed that in groups of four or more learners, at least one learner would become disinterested and disengaged. Some groups were also observed taking part in work that wasn’t related to the task, and although no further details are given about the nature of this, it is possible that the groups became distracted.
The findings from this project suggest that learners understand better how smartphones work when they also think about how they are manufactured and used.
Further investigation into effective pedagogies to set group size expectations and maintain task focus would be helpful to make sure the lessons met their learning objectives. This research was conducted as a case study in a small number of schools, and the results indicate that this approach may be more widely helpful. Details about the study can be found in the researchers’ paper (in German).
If you’re thinking about setting up a repair café in your school to promote sustainable computing, either as a formal or informal learning activity, here are ideas on where to begin:
This article is from our free computing education magazine Hello World. Every issue is written by educators for educators and packed with resources, ideas, and insights to inspire your learners and your own classroom practice.
For more about computing education in the context of sustainability, climate change, and environmental impact, download issue 19 of Hello World, which focuses on these topics.
You can subscribe to Hello World for free to never miss a digital issue, and if you’re an educator in the UK, a print subscription will get you free print copies in the post.
PS If you’re interested in facilitating productive classroom discussions with your learners about ethical, legal, cultural, and environmental concerns surrounding computer science, take a look at our free online course ‘Impacts of Technology: How To Lead Classroom Discussions’.
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