We are excited to launch Ada Computer Science, the new online learning platform for teachers, students, and anyone interested in learning about computer science.

With the rapid advances being made in AI systems and chatbots built on large language models, such as ChatGPT, it’s more important than ever that all young people understand the fundamentals of computer science. 

Our aim is to enable young people all over the world to learn about computer science through providing access to free, high-quality and engaging resources that can be used by both students and teachers.

A partnership between the Raspberry Pi Foundation and the University of Cambridge, Ada Computer Science offers comprehensive resources covering everything from algorithms and data structures to computational thinking and cybersecurity. It also has nearly 1000 rigorously researched and automatically marked interactive questions to test your understanding. Ada Computer Science is improving all the time, with new content developed in response to user feedback and the latest research. Whatever your interest in computer science, Ada is the place for you.

If you’re teaching or studying a computer science qualification at school, you can use Ada Computer Science for classwork, homework, and revision. Computer science teachers can select questions to set as assignments for their students and have the assignments marked directly. The assignment results help you and your students understand how well they have grasped the key concepts and highlights areas where they would benefit from further tuition. Students can learn with the help of written materials, concept illustrations, and videos, and they can test their knowledge and prepare for exams.

A comprehensive resource for computing education

Ada Computer Science builds on work we’ve done to support the English school system as part of the National Centre for Computing Education, funded by the Department for Education.

The topics on the website map to exam board specifications for England’s Computer Science GCSE and A level, and will map to other curricula in the future.

In addition, we want to make it easy for educators and learners across the globe to use Ada Computer Science. That’s why each topic is aligned to our own comprehensive taxonomy of computing content for education, which is independent of the English curriculum, and organises the content into 11 strands, including programming, computing systems, data and information, artificial intelligence, creating media, and societal impacts of digital technology.

If you are interested in how we can specifically adapt Ada Computer Science for your region, exam specification, or specialist area, please contact us.

Why use Ada Computer Science at school?

Ada Computer Science enables teachers to:

• Plan lessons around high-quality content
• Set self-marking homework questions
• Pinpoint areas to work on with students
• Manage students’ progress in a personal markbook

Students get:

• Free computer science resources, written by specialist teachers
• A huge bank of interactive questions, designed to support learning
• A powerful revision tool for exams
• Access wherever and whenever you want

In addition:

• The topics include real code examples in Python, Java, VB, and C#
• The live code editor features interactive coding tasks in Python
• Quizzes make it quick and easy to set work

Get started with Ada Computer Science today by visiting adacomputerscience.org.

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Source: Raspberry Pi – Launching Ada Computer Science, the new platform for learning about computer science

Today is officially Pi Day. 

While 14 March is an opportunity for our American friends to celebrate the mathematical constant Pi, we are also very happy to make this day a chance to say a massive thank you to everyone who supports the Raspberry Pi Foundation’s work through their generous donations.

More than computers

You may know that the Raspberry Pi story started in Cambridge, UK, in 2008 when a group of engineers-cum-entrepreuers set out to improve computing education by inventing a programmable computer for the price of a textbook.

Fast forward 15 years and there are 50 million Raspberry Pi computers in the world, being used to revolutionise education and industry alike. Removing price as a barrier for anyone to own a powerful, general-purpose computer will always be an important part of our mission to democratise access to computing.

What we also know today is that access to low-cost, high-quality hardware is essential, but it’s not enough. 

If we want all young people to be able to take advantage of the potential offered by technological innovation, then we also need to support teachers to introduce computing in schools, find ways to inspire young people to learn outside of their formal education, and make sure that everything we do is informed by rigorous research.

That’s the focus of our educational mission at the Raspberry Pi Foundation, and we couldn’t do this work without your support. 

What we achieve for young people thanks to your support 

We are fortunate that a large and growing community of people, corporations, trusts, and foundations makes very generous donations to support our educational mission. It’s thanks to you that we are able to achieve what we do for young people and educators: 

• In 2022 alone, over 3.54m people engaged with our free online learning resources for young people, including brand-new pathways of projects for HTML/CSS, Python, and Raspberry Pi Pico. 
• Supported by us, more than 4500 Code Club and CoderDojos are running in 103 countries, and an additional 2891 clubs that were disrupted by the coronavirus pandemic tell us that they are actively planning to start running sessions for young people again soon. 
• We engaged over 30,000 young people in challenges such as Astro Pi and Coolest Projects, enabling them to showcase their skills, think about how to solve problems using technology, and connect with like-minded peers.

• We have supported tens of thousands of computing teachers through our curriculum, resources, and online training. For example, The Computing Curriculum, which we developed as part of the National Centre for Computing Education in England, is now being used by educators all over the world, with 1.7m global downloads in 2022. 
• We completed and published the findings of the world’s largest-ever research programme testing how to improve the gender balance in computing. We are now working on integrating the insights from the programme into our own work and making them accessible and actionable for practitioners.

Trust me when I say this is just a small selection of highlights, all of which are made possible by our amazing supporters. Thank you, and I hope that we made you proud. 

Get involved today

If you haven’t yet made a donation to our Pi Day campaign, it’s not too late to get involved. Your donation will help inspire the next generation of digital technology creators.

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We are working in partnership with Amala Education to pilot a vocational skills course for displaced learners aged 16 to 25 in Kakuma refugee camp, Kenya.

Kakuma camp was set up in Kenya in 1992, following a civil war in neighbouring South Sudan in East Africa. Today, 2 million people are living in the camp, and 61% are 18 and younger.

We’ve designed a 100-hour, 10-week course called Using online digital technologies to create change for the Amala learners in Kakuma camp. The course focused on digital skills including making media and websites, with its content we adapted from our Computing Curriculum. The course pilot was delivered alongside Amala’s High School Diploma programme, which is the first internationally accredited course programme enabling refugee and host community youth to complete their education through flexible study.

Our thanks go to the Ezrah Charitable Trust for generously funding our work in this partnership.

Sharing lessons we are learning

We are learning a lot during this pilot, so we are writing a set of three blogs to share these lessons with you.

Today’s blog is Amala Education‘s perspective on their learners in Kakuma Camp, the purpose of digital skills education, and the course design and facilitation. We will also share our approach to adapting learning resources for the context of the Amala learners and using data to assess the course, and what other support we’ve put in place to ensure this educational project is self-sustaining.

Want to make computing education meaningful? Make it connect to learners’ lived experience

By Polly Akhurst (Co-founder and Co-Executive Director, Amala Education), Louie Barnett (Education Lead, Amala Education) & Ajak Mayen Jok (Programme Coordinator, Amala Education)

Our learners wanted a course that develops not just their digital literacy, but one that aligns with Amala’s agency-based learning model, which gives young people the skills to improve their communities. Many of our learners have limited experience of using digital tools but a huge desire to develop these skills, which they see as essential to improving their lives and the lives of their community members.

So we knew we needed a course that not just builds learners’ technical knowledge and skills but can also enrich their lived experience. 

How would we do it? 

Enter the Raspberry Pi Foundation team. We combined Amala’s agency-based educational approach with the Raspberry Pi Foundation’s experience in pedagogy and teaching about technology and digital literacy to design a course that truly resonates with our learners.

Developing a relevant digital skills course

Before developing the course, the Raspberry Pi Foundation team held focus groups with facilitators and learners in Kakuma camp to understand their needs. This helped them to pitch the 100 hours of course materials at the right level for the learners.

We called the course Using online technologies to create change. It takes the learners on a journey, building their foundation elements of computing and digital literacy. Learners start by finding out how digital devices work using input, process, and output. Then they move on to understanding computer networks. The course includes hands-on activities related to creating media, like filming and reviewing content and creating and choosing sounds to use in a podcast. There is also some light-touch web development with HTML and JavaScript. At the end of the course, learners design and deliver a presentation that reflects the work they’ve completed.

“Before I joined the course, I really didn’t know much about how to operate technology, but through the learning and the process, now I am able to learn something that will be beneficial for me and the people in my community.” — Learner in Kakuma refugee camp

Throughout the course, learners use their newly gained skills and knowledge to make their own project aimed at creating positive change. One example project is this website developed by Shyaka Cedric and other learners, which shares how podcasts and remote learning helped their community stay safe and healthy during the pandemic. Another group of learners used their photography and design skills to develop ID cards to keep Amala students safe within the camp. Having an Amala student ID card protects learners because they can prove their identity to their community and the police.

Facilitators from the camp make the course relatable

One of the great things about this course is that the Amala facilitators who taught the learners look, speak, and sound like them. Amala facilitators are from within the camp, and that they are relatable is great for learners’ self-confidence.

Having the course facilitated by fellow refugees removes the stigmatisation that the learners are vulnerable and sets the precedent that they can do anything if they put their mind to it.

“It gave me power of… getting involved with new things…Any challenge that comes my way I am willing to take after the Raspberry Pi class now…” — Learner in Kakuma refugee camp

While the Raspberry Pi Foundation team worked to make the course content relevant for the learners, our facilitators further localised the content to ensure its relatability for learners. Local contextualisation helps students to understand what they are learning, and to identify with the content — it’s not something out of the blue for them. Localisation is also important because it helps implement one of Amala’s cornerstones: decolonising the African curriculum.

Digital literacy is an urgent need

Because the learners in Kakuma camp lead complex social lives and face high levels of precarity, we decided to make the pilot course optional through our existing Diploma programme. We anticipated a modest enrollment rate, but instead over 100 people within the Amala learner community expressed an interest in this 75-person course. This showed us that the value and urgency of digital literacy in refugee communities is more pertinent than ever.

In a world where a lack of access to technology and digital skills exacerbates existing inequalities, it is critically important for young people who are disadvantaged to access meaningful learning opportunities. As one learner put it:

“I want to study this course because the current world is a digital world and I would like to acquire the skills to boost my computer skills and be able to help myself by getting a job and transforming the community through the digital world.” — Learner in Kakuma refugee camp

So what’s happening next?

We have a blueprint of what works in Kakuma refugee camp, and we are also learning what doesn’t. Bringing these lessons together will help us offer the course to more learners in Kakuma, and adapt the content in other locations, like our site in Amman, Jordan. 

Look out for our follow-up blogs about the support we put in place to enable learners in Kakuma camp to participate in the course, and how we worked to create course content that is suitable for them.

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Source: Raspberry Pi – A vocational digital skills course in Kakuma refugee camp: Connecting to learners’ lives

This year’s International Women’s Day (IWD) focuses on innovation and technology for gender equality. This cause aligns closely with our mission as a charity: to enable young people to realise their full potential through the power of computing and digital technologies. An important part of our mission is to shift the gender balance in computing education.

Gender inequality in the digital and computing sector

As the UN Women’s announcement for IWD 2023 says: “Growing inequalities are becoming increasingly evident in the context of digital skills and access to technologies, with women being left behind as the result of this digital gender divide. The need for inclusive and transformative technology and digital education is therefore crucial for a sustainable future.”

According to the UN, women currently hold only 2 in every 10 science, engineering, and information and communication technology jobs globally. Women are a minority of university-level students in science, technology, engineering, and mathematics (STEM) courses, at only 35%, and in information and communication technology courses, at just 3%. This is especially concerning since the WEF predicts that by 2050, 75% of jobs will relate to STEM.

We see this situation reflected in England: computer science is the secondary school subject with the largest gender gap at A level, with girls accounting for only 15% of students. That’s why over the past three years, we have run a research programme to trial ways to encourage more young women to study Computer Science. The programme, Gender Balance in Computing, has produced useful insights for designing equitable computing education around the world.

Who belongs in computing?

The UN says that “across countries, girls are systematically steered away from science and math careers. Teachers and parents, intentionally or otherwise, perpetuate biases around areas of education and work best ‘suited’ for women and men.” There is strong evidence to suggest that the representation of women and girls in computing can be improved by introducing them to computing role models such as female computing students or women in tech careers.

Presenting role models was central to the Belonging trial in our Gender Balance in Computing programme. One arm of this trial used resources developed by WISE called My Skills My Life to explore the effect of introducing role models into computing lessons for primary school learners. The trial provided opportunities for learners to speak to women who work in technology. It also offered a quiz to help learners identify their strengths and characteristics and to match them with role models who were similar to them, which research shows is more effective for increasing learners’ confidence.

Teachers who used the resources reported learners’ increased understanding of the types and range of technology jobs, and a widening of learners’ career aspirations. 

“Learning about computing makes me feel good because it helps me think more about what I want to be.” — Primary school learner in the Belonging trial

“When [the resources were] showing all of the females in the jobs, nobody went ‘Oh, I didn’t know that a female could do that’, but I think they were amazed by the role of jobs and the fact it was all females doing it.“ — Primary school teacher in the Belonging trial

Learning together to give everyone a voice

When teachers and students enter a computing classroom, they bring with them diverse social identities that affect the dynamics of the classroom. Although these dynamics are often unspoken, they can become apparent in which students answer questions or succeed visibly in activities. Without intervention, a dominant group of confident speakers can emerge, and students who are not in this dominant group may lose confidence in their abilities. When teachers set collaborative learning activities that use defined roles or structured discussions, this gives a wider range of students the opportunity to speak up and participate.

Pair programming is one such activity that has been used in research studies to improve learner attitudes and confidence towards computing. In pair programming, one learner is the ‘driver’.  They control the keyboard and mouse to write the code. The other learner is the ‘navigator’. They read out the instructions and monitor the code for errors. Learners swap roles regularly, so that both can participate equitably. The Pair Programming trial we conducted as part of Gender Balance in Computing explored the use of this teaching approach with students aged 8 to 11. Feedback from the teachers showed that learners found working in structured pairs engaging. 

“Even those who are maybe a little bit more reluctant… those who put their hands up today and said they still prefer to work independently, they are still all engaging quite clearly in that with their pair and doing it really, really well. However much they say they prefer working independently, I think they clearly showed how much they enjoy it, engage with it. And you know they’re achieving with it — so we should be doing this.” – Primary school teacher in the Pair Programming trial

Another collaborative teaching approach is peer instruction. In lessons that use peer instruction, students work in small groups to discuss the answer to carefully constructed multiple choice questions. A whole-class discussion then follows. In the Peer Instruction trial with learners aged 12 to 13 in our Gender Balance in Computing programme, we found that this approach was welcomed by the learners, and that it changed which learners offered answers and ideas. 

“I prefer talking in a group because then you get the other side of other people’s thoughts.” – Secondary school learner (female) in the Peer Instruction trial

“[…] you can have a bit of time to think for yourself then you can bounce ideas off other people.” – Secondary school learner (male) in the Peer Instruction trial

“I was very pleased that a lot of the girls were doing a lot of the talking.” – Secondary school teacher in the Peer Instruction trial

We need to do more, and sooner

Our Gender Balance in Computing research programme showed that no single intervention we trialled significantly increased girls’ engagement in computing or their intention to study it further. Combining several of the approaches we tested may be more impactful. If you’re part of an educational setting where you’d like to adopt multiple approaches at the same time, you can freely access the materials associated with the research programme (see our blog posts about the trails for links).

The research programme also showed that age matters: across Gender Balance in Computing, we observed a big difference in intent to study Computing between primary school and secondary school learners (data from ages 8–11 and 12–13). Fewer secondary school learners reported intent to study the subject further, and while this difference was apparent for both girls and boys, it was more marked for girls.

This finding from England is mirrored by a study the UN Women’s Gender Snapshot 2022 refers to: “A 2020 study of Filipina girls demonstrated that loss of interest in STEM subjects started as early as age 10, when girls began perceiving STEM careers as male-dominated and believing that girls are naturally less adept in STEM subjects. The relative lack of female STEM role models reinforced such perceptions.” That’s why it’s necessary that all primary school learners — no matter what their gender is — have a successful start in the computing classroom, that they encounter role models they can relate to, and that they are supported to engage in computing and creating with technology by their parents, teachers, and communities.

The Foundation’s vision is that every young person develops the knowledge, skills, and confidence to use digital technologies effectively, and to be able to critically evaluate these technologies and confidently engage with technological change. While making changes inside the computing classroom will be beneficial for gender equality, this is just one aspect of building an equitable digital future. We all need to contribute to creating a world where innovation and technology support gender equity.

What do you think is needed?

In all our work, we make sure gender equity is at the forefront, whether that’s in programmes we run for young people, in resources we create for schools, or in partnerships we have, such as with Pratham Education Foundation in India or Team4Tech and Kenya Connect in Wamunyu, Kenya. Computing education is a global challenge, and we are proud to be part of a community that is committed to making it equitable.

This IWD, we invite you to share your thoughts on what equitable computing education means to you, and what you think is needed to achieve it, whether that’s in your school or club, in your local community, or in your country. 

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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:

1. Working together

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:

2. Talking to family

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: 

3. Cutting-edge technology

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!

You can still get involved in this round of Astro Pi Mission Zero

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.

Get coding with Mission Zero today

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.

I want to get involved in Mission Zero

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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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Every young learner needs a successful start to their learning journey in the primary computing classroom. One aspect of this for teachers is to introduce programming to their learners in a structured way. As computing education is introduced in more schools, the need for research-informed strategies and approaches to support beginner programmers is growing. Over recent years, researchers have proposed various strategies to guide teachers and students, such as the block model, PRIMM, and, in the case of this month’s seminar, TIPP&SEE.

We are committed to make computing and creating with digital technologies accessible to all young people, including through our work with educators and researchers. In our current online research seminar series, we focus on computing education for primary-aged children (K–5, ages 5 to 11). In the series’ second seminar, we were delighted to welcome Dr Jean Salac, researcher in the Code & Cognition Lab at the University of Washington.

Jean’s work sits across computing education and human-computer interaction, with an emphasis on justice-focused computing for youth. She talked to the seminar attendees about her work on developing strategies to support primary school students learning to program in Scratch. Specifically, Jean described an approach called TIPP&SEE and how teachers can use it to guide their learners through programming activities.

What is TIPP&SEE?

TIPP&SEE is a metacognitive approach for programming in Scratch. The purpose of metacognitive strategies is to help students become more aware of their own learning processes.

TIPP&SEE scaffolds students as they learn from example Scratch projects: TIPP (Title, Instructions, Purpose, Play) is a scaffold to read and run a Scratch project, while SEE (Sprites, Events, Explore) is a scaffold to examine projects more deeply and begin to adapt them. 

Using, modifying and creating

TIPP&SEE is inspired by the work of Irene Lee and colleagues who proposed a progressive three-stage approach called Use-Modify-Create. Following that approach, learners move from reading pre-existing programs (“not mine”) to adapting and creating their own programs (“mine”) and gradually increase ownership of their learning.

Proponents of scaffolded approaches like Use-Modify-Create argue that engaging learners in cycles of using existing programs (e.g. worked examples) before they move to adapting and creating new programs encourages ownership and agency in learning. TIPP&SEE builds on this model by providing additional scaffolding measures to support learners.

Impact of TIPP&SEE

Jean presented some promising results from her research on the use of TIPP&SEE in classrooms. In one study, fourth-grade learners (age 9 to 10) were randomly assigned to one of two groups: (i) Use-Modify-Create only (the control group) or (ii) Use-Modify-Create with TIPP&SEE. Jean found that, compared to learners in the control group, learners in the TIPP&SEE group:

• Were more thorough, and completed more tasks
• Wrote longer scripts during open-ended tasks
• Used more learned blocks during open-ended tasks

In another study, Jean compared how learners in the TIPP&SEE and control groups performed on several cognitive tests. She found that, in the TIPP&SEE group, students with learning difficulties performed as well as students without learning difficulties. In other words, in the TIPP&SEE group the performance gap was much narrower than in the control group. In our seminar, Jean argued that this indicates the TIPP&SEE scaffolding provides much-needed support to diverse groups of students.

Using TIPP&SEE in the classroom

TIPP&SEE is a multi-step strategy where learners start by looking at the surface elements of a program, and then move on to examining the underlying code. In the TIPP phase, learners first read the title and instructions of a Scratch project, identify its purpose, and then play the project to see what it does.

In the second phase, SEE, learners look inside the Scratch project to click on sprites and predict what each script is doing. They then make changes to the Scratch code and see how the project’s output changes. By changing parameters, learners can observe which part of the output changes as a result and then reason how each block functions. This practice is called deliberate tinkering because it encourages learners to observe changes while executing programs multiple times with different parameters.

You can read more of Jean’s research on TIPP&SEE on her website. There’s also a video on how TIPP&SEE can be used, and free lesson resources based on TIPP&SEE are available in Elementary Computing for ALL and Scratch Encore.

Learning about learning in computing education

Jean’s talk highlighted the need for computing to be inclusive and to give equitable access to all learners. The field of computing education is still in its infancy, though our understanding of how young people learn about computing is growing. We ourselves work to deepen our understanding of how young people learn through computing and digital making experiences.

In our own research, we have been investigating similar teaching approaches for programming, including the use of the PRIMM approach in the UK, so we were very interested to learn about different approaches and country contexts. We are grateful to Dr Jean Salac for sharing her work with researchers and teachers alike. Watch the recording of Jean’s seminar to hear more:

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: Free and comprehensive

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.

Computing lesson plans that save time and engage your learners

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.

Start teaching with The Computing Curriculum

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.

I want to download resources from The Computing Curriculum

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).

Get inspired to code with Mission Zero

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 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 certificate they can download, which 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.

For all educators and parents 

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.

What you need to know about Coolest Projects

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:

• Coolest Projects is all online and completely free
• All digital technology projects are welcome, from very first projects to advanced builds, and they don’t have to be complete
• Young creators up to age 18 from anywhere in the world can take part individually or in teams of up to five friends
• Projects can be registered in one of six categories: Scratch, games, web, mobile apps, hardware, and advanced programming
• Registration is now open and closes on 26 April 2023
• All creators, mentors, volunteers, teachers, parents, and supporters are invited to the special celebration livestream on 6 June 2023

Five steps to taking part in Coolest Projects

1. Imagine your idea for a project
2. Choose your project category
3. Gather a group of friends or work by yourself to make your project
4. Register the project in a few clicks to share it in the showcase gallery
5. Explore the other projects from around the world in the showcase gallery, and join the community at the special celebration livestream

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.

I want to register a project now

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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When we think about a celebration, we also think about how important it is to be intentional about sound. And with this month of February being a celebration of Black history in the USA, we want to help you make some noise to amplify the voices, experiences, and achievements of the Black community.

From the past and present, to those still to come in the future, countless remarkable achievements have been made by Black individuals who have chosen to move to the beat of their own drum. Music and sound can be tools to tell stories, to express ourselves, to promote change, to celebrate, and so much more. So take some time this month to make your own music with your young coders and start dancing.                

Of course, choosing to dance is not the same as choosing to devote your life to the equality and freedom of all people. But it reminds us that you can incite change by choosing to do what is right, even when you feel like you’re the only one moving to the music. It won’t be long before you see change and meet people you resonate with, and a new sound will develop in which everyone can find their rhythm.

So join us this month as we explore the power of code and music to celebrate Black History Month.

Projects to help you find your rhythm

We’ve selected three of our favourite music-related projects to help you bring a joyful atmosphere to your coding sessions this month. All of the projects are in Scratch, a programming language that uses blocks to help young people develop their confidence in computer programming while they experiment with colours and sounds to make their own projects.  

Drum star | Scratch

Find your rhythm with this clicker game where you earn points by playing the drums in different venues. The project is one of our Explore projects and it includes step-by-step instructions to help young creators develop their skills, confidence, and interest in programming. This makes it a great option for beginners who want to get started with Scratch and programming.

Music maker | Scratch

Code to the beat of your own drum — or any instrument you like. Use this project to create your own virtual musical instrument and celebrate a Black musician you admire. For young people who have some experience with Scratch, they may enjoy expressing themselves with this Design project. Our Design projects give young people support to build on their experience to gain more independence coding their own ideas.

Binary hero | Scratch

Can you keep up with the beat? Prove it in this game where you play the notes of a song while they scroll down the screen. You could choose to include a song associated with a moment in Black history that is meaningful to you. This project is a great opportunity for young people to expand their programming knowledge to create lists, while they also test their reaction skills with a fun game.

For young creators who want to create projects that don’t involve music or sound, check out these projects which can help you to:

• Code a book about an inspirational figure in Black history (Scratch)
• Design colourful patterns inspired by Black cultures (Python)
• Create a mood board webpage to share ideas of what Black History Month means to you (HTML/CSS)

Let us know how you’re celebrating Black History Month in your community on Twitter, LinkedIn, Facebook, or Instagram all month long!

Black stories to inspire you to move

• Training teachers and empowering students in Machakos, Kenya

Learn about our partnership with Team4Tech and Kenya Connect, with whom we are empowering educators and students in rural Kenya to use the power of coding and computing to benefit their communities.

• I Belong in Computer Science: Salome Tirado Okeze

Meet Salome, a computer science student from the UK who shares her experiences and advice for young people interested in finding out where computer science can lead them. Salome was one of the first people we interviewed for our ‘I belong’ campaign to celebrate young role models in computer science.

Research to help set the tone  

We believe that creating inclusive and equitable learning environments is essential to supporting all young people to see computer science as an opportunity for them. To help engage young people, especially those who are underrepresented in computer science classrooms, we are carrying out research with teachers to make computing culturally relevant. Our work promoting culturally relevant pedagogy in educational settings in England has been impacted by projects of many US researchers who have already contributed heavily to this area. You can learn about two of these projects in this blog post.

Educators who want to find out how they can use culturally relevant pedagogy with their learners can download our free guidelines today.

We would also like to invite you to our monthly research seminar on 7 February 2023, when we will be joined by Dr Jean Salac who will be sharing their research on Moving from equity to justice in computing instruction for youth. Dr Salac’s session is part of our current series of seminars that centres on primary school (K–5) teaching and learning of computing. The seminars are free and open to everyone interested in computing education. We hope to see you there! 

I want to register for the seminar

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Why are computing systems at the heart of our computing curriculum design? Senior Learning Manager Sway Grantham from the Foundation team explains in her article from the brand-new issue of Hello World, our free magazine for computing educators, out today.

Whether you plan lessons on a Computing topic, develop curriculum content, or even write curriculum policy, you have to make choices. What are you going to include and what is less of a priority? You have to consider time constraints and access to resources, prior learning and maybe even pupil interests. You probably also have to consider the wider curriculum context. Well, here is my first principle to help you: computing systems should be the foundation of your Computing curriculum.

A computing systems epiphany

As a primary teacher, when I first began writing Computing lesson plans for children aged 9 to 10, I started with programming. This was a very visual entry into Computing, and children were excited to create projects that were familiar to them, such as games and animations. However, as my understanding of Computing grew, I realised that something was missing.

My learners could explain what an algorithm is, as well as explaining that a program is ‘a set of instructions that runs on a computer to tell it what to do’. Both of these met the curriculum needs, but I wasn’t convinced that they could link these two concepts together. Could they connect what they were doing on a floor robot to the computing systems around them? Did they understand what a computer was? Well… I asked them to see what they’d say!

According to my class, a computer was:

• A piece of technology
• A keyboard and a screen
• A search engine
• A machine used for work
• A metal brain
• A machine with a keyboard
• An information device
• Electric

This very simple question highlighted a wealth of alternate conceptions about programming and computing systems. The other commonality of my learners’ definitions was that they described the computer’s function, as if, in order to define what a computer is, we just need to know what it does. This view of a definition greatly limits learners’ ability to understand what potential computers have beyond personal use.

My learners had two discrete chunks of knowledge: how to program a floor robot, and that laptops were computers. However, without a bridge to connect them, this learning was disjointed. Learners needed to have a concrete, conceptual understanding of ‘what a computer is’ before they could start to comprehend the more abstract role of a program in that system.

Knowledge of computing systems empowers people to take control of technology and not just consume it.

Beyond the experiences of my young learners, we see examples of a lack of understanding about computing systems all the time in society. Many competent users of software are able to regularly complete the tasks that they need, but if one day something doesn’t work, they do not know how to find a solution. Equally, many people enjoy exploring digital making projects, yet if they want to personalise the project, they don’t know what they can or can’t change to do this. Knowledge of computing systems empowers people to take control of technology and not just consume it.

Planning computing content today

Both of these examples highlight the importance of introducing computing systems as both life skills and as support for developing other areas of computing. More recently, the Raspberry Pi Foundation has been creating 100 hours of curriculum content in partnership with non-profit organisation Amala Education. Through this content we aim to give refugee learners who may never have used technology enough understanding to build a website that encourages social change.

Whilst we know that the material needs to include some foundational knowledge of computing systems, we must first consider the core content that learners must understand to achieve the end goal, such as:

• Webpage creation 
• HTML/CSS/JavaScript
• Project management 
• Project development

These areas of learning are a great place to start as, undeniably, learners aren’t going to be able to build a website without knowing the process of creating a website, the languages used to create web pages, or the project management skills to see a project from start to finish.

This could be the entirety of the content, but instead, I encourage you to think back to those children who could program but didn’t know on what devices programs could run. We need to connect the core content to that foundational content: how is building a website related to computing systems?

Prior knowledge

All learning is built on prior knowledge, even if that prior knowledge has been gained through life experience and not formal education. To build a website, we need to know how to type and use a mouse. We need to know what a website is, why people use websites, and what sort of media is found on them. Beyond that, we need to know how the files that we are creating are being shared with other people. We need to understand that a computer can communicate with another computer and what the process is to make that happen. None of this learning is the core content of building a website, but if you tried to build a website without understanding these things, it would be difficult to do.

All learning is built on prior knowledge, even if that prior knowledge has been gained through life experience and not formal education.

As the learners we support together with Amala Education might have no prior experience of using technology, we needed to ensure that enough foundational computing systems content was built into the learning sequence — things such as:

• Recognising digital devices
• Decomposing computing systems
• Digital painting (mouse skills)
• Combining text and images (desktop publishing)
• Networks and the internet
• Internet searching

By incorporating this content into the learning sequence, we ensure that learners do not just learn a process for creating a website. They understand the impact of the choices they make when building a website, they have the skills to implement their ideas, and they can connect their understanding to solve any unexpected challenges they find along the way. This more holistic approach should support learners’ knowledge transfer and offer them a much broader range of opportunities. 

This more holistic approach should support learners’ knowledge transfer and offer them a much broader range of opportunities.

Whatever your curriculum requires, you will have the core content you need to teach. This could be the requirements of your standardised curriculum, it could be the specific project you’re trying to build, or it could be the aspirations that you have for your students. However, rather than stopping at that part of your learning sequence, take a step back and consider the prior knowledge you’re connecting to. I expect you will find that computing systems is what you need to ensure learners’ new knowledge has a solid foundation.

Read the new Hello World issue today

Computing systems and networks is one of those computer science topics in which misconceptions abound. Hello World issue 20 focuses on how you can support your learners to grasp even the tricky ideas within this topic, giving you practical ideas, activities, and insights from practicing educators. Download your free PDF copy now, and subscribe to never miss an issue.

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In our first seminar of 2023, we were delighted to welcome Dr Katie Rich and Carla Strickland. They spoke to us about teaching the programming construct of variables in Grade 3 and 4 (age 8 to 10).

We are hearing from a diverse range of speakers in our current series of monthly online research seminars focused on primary (K-5) computing education. Many of them work closely with educators to translate research findings into classroom practice to make sure that all our younger learners have positive first experiences of learning computing. An important goal of their research is to impact the development of pedagogy, resources, and professional development to support educators to deliver computing concepts with confidence.

Variables in computing and mathematics

Dr Katie Rich (American Institutes of Research) and Carla Strickland (UChicago STEM Education) are both part of a team that worked on a research project called Everyday Computing, which aims to integrate computational thinking into primary mathematics lessons. A key part of the Everyday Computing project was to develop coherent learning resources across a number of school years. During the seminar, Katie and Carla presented on a study in the project that revolved around teaching variables in Grade 3 and 4 (age 8 to 10) by linking this computing concept to mathematical concepts such as area, perimeter, and fractions.

Variables are used in both mathematics and computing, but in significantly different ways. In mathematics, a variable, often represented by a single letter such as x or y, corresponds to a quantity that stays the same for a given problem. However, in computing, a variable is an identifier used to label data that may change as a computer program is executed. A variable is one of the programming constructs that can be used to generalise programs to make them work for a range of inputs. Katie highlighted that the research team was keen to explore the synergies and tensions that arise when curriculum subjects share terms, as is the case for ‘variable’. 

Defining a learning trajectory

At the start of the project, in order to be able to develop coherent learning resources across school years, the team reviewed research papers related to teaching the programming construct of variables. In the papers, they found a variety of learning goals that related to facts (what learners need to know) and skills (what learners need to be able to do). They grouped these learning goals and arranged the groups into ‘levels of thinking’, which were then mapped onto a learning trajectory to show progression pathways for learning.

Learning materials about variables

Carla then shared three practical examples of learning resources their research team created that integrated the programming construct of variables into a maths curriculum. The three activities, described below, form part of a series of lessons called Action Fractions. You can read more about the series of lessons in this research paper.

Robot Boxes is an unplugged activity that is positioned at the Data User level of thinking. It relates to creating instructions for a fictional robot. Learners have to pay attention to different data the robot needs in order to draw a box, such as the length and width, and also to the value that the robot calculates as area of the box. The lesson uses boxes on paper as concrete representations of variables to which learners can physically add values.

Ambling Animals is set at the ‘Data Storer’ and ‘Variable Interpreter’ levels of thinking. It includes a Scratch project to help students to locate and compare fractions on number lines. During this lesson, find a variable that holds the value of the animal that represents the larger of two fractions.

Adding Fractions draws on facts and skills from the ‘Variable Interpreter’ and ‘Variable Implementer’ levels of thinking and also includes a Scratch project. The Scratch project visualises adding fractions with the same denominator on a number line. The lesson starts to explain why variables are so important in computer programs by demonstrating how using a variable can make code more efficient. 

Takeaways: Cross-curricular teaching, collaborative research

Teaching about the programming construct of variables can be challenging, as it requires young learners to understand abstract ideas. The research Katie and Carla presented shows how integrating these concepts into a mathematics curriculum is one way to highlight tangible uses of variables in everyday problems. The levels of thinking in the learning trajectory provide a structure helping teachers to support learners to develop their understanding and skills; the same levels of thinking could be used to introduce variables in other contexts and curricula.

Many primary teachers use cross-curricular learning to increase children’s engagement and highlight real-world examples. The seminar showed how important it is for teachers to pay attention to terms used across subjects, such as the word ‘variable’, and to explicitly explain a term’s different meanings. Katie and Carla shared a practical example of this when they suggested that computing teachers need to do more to stress the difference between equations such as xy = 45 in maths and assignment statements such as length = 45 in computing.

The Everyday Computing project resources were created by a team of researchers and educators who worked together to translate research findings into curriculum materials. This type of collaboration can be really valuable in driving a research agenda to directly improve learning outcomes for young people in classrooms. 

How can this research influence your classroom practice or other activities as an educator? Let us know your thoughts in the comments. We’ll be continuing to reflect on this question throughout the seminar series.

You can watch Katie’s and Carla’s full presentation here:

Join our seminar series on primary computing education

Our monthly seminar series on primary (K–5) teaching and learning is of interest to a global audience of educators, including those who want to understand the prior learning experiences of older learners.

I want to sign up to join a seminar

We continue on Tuesday 7 February at 17.00 UK time, when we will hear from Dr Jean Salac, University of Washington. Jean will present her work in identifying inequities in elementary computing instruction and in developing a learning strategy, TIPP&SEE, to address these inequities. Sign up now, and we will send you a joining link for the session.

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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.

Meet Adarsh

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.”

Helping each other solve problems

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.”

The future for Adarsh

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, and Facebook.

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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. 

Your code in space 

Through our collaboration with the European Space Agency, theAstro 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. 

Make a cool project and share it with the world 

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. 

Experience AI 

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. 

The big Code Club and CoderDojo meetup

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. 

Building partnerships in India, Kenya, and South Africa 

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. 

Exploring computing education for 5- to 11-year-olds 

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.

And much, much more… 

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.

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Improving gender balance in computing is part of our work to ensure equitable learning opportunities for all young people. Our Gender Balance in Computing (GBIC) research programme has been the largest effort to date to explore ways to encourage more girls and young women to engage with Computing.

Commissioned by the Department for Education in England and led by the Raspberry Pi Foundation as part of our National Centre for Computing Education work, the GBIC programme was a collaborative effort involving the Behavioural Insights Team, Apps for Good, and the WISE Campaign.

Gender Balance in Computing ran from 2019 to 2022 and comprised seven studies relating to five different research areas:

• Teaching Approach:
  • Peer Instruction: Collaborative teaching approach in lower secondary
  • Pair Programming: Working collaboratively in upper primary
  • Storytelling: Connecting computing to storytelling with 6- to 7-year-olds
• Belonging: Supporting learners to feel that they “belong” in computer science
• Non-formal Learning: Establishing the connections between in-school and out-of-school computing
• Relevance: Making computing relatable to everyday life
• Subject Choice: How computer science is presented to young people as a subject choice 

In December we published the last of seven reports describing the results of the programme. In this blog post I summarise our overall findings and reflect on what we’ve learned through doing this research.

Gender balance in computing is not a new problem

I was fascinated to read a paper by Deborah Butler from 2000 which starts by summarising themes from research into gender balance in computing from the 1980s and 1990s, for example that boys may have access to more role models in computing and may receive more encouragement to pursue the subject, and that software may be developed with a bias towards interests traditionally considered to be male. Butler’s paper summarises research from at least two decades ago — have we really made progress?

In England, it’s true that making Computing a mandatory subject from age 5 means we have taken great strides forward; the need for young people to make a choice about studying the subject only arises at age 14. However, statistics for England’s externally assessed high-stakes Computer Science courses taken at ages 14–16 (GCSE) and 16–18 (A level) clearly show that, although there is a small upwards trend in the proportion of female students, particularly for A level, gender balance among the students achieving GCSE/A level qualifications remains an issue:

What did we do in the Gender Balance in Computing programme?

In GBIC, we carried out a range of research studies involving more than 14,500 pupils and 725 teachers in England. Implementation teams came from the Foundation, Apps For Good, the WISE Campaign, and the Behavioural Insights Team (BIT). A separate team at BIT acted as the independent evaluators of all the studies.

In total we conducted the following studies:

• Two feasibility studies: Storytelling; Relevance, which led to a full randomised controlled trial (RCT)
• Five RCTs: Belonging; Peer Instruction; Pair Programming; Relevance, which was preceded by a feasibility study; Non-formal Learning (primary)
• One quasi-experimental study: Non-formal Learning (secondary)
• One exploratory research study: Subject Choice (Subject choice evenings and option booklets)

Each study (apart from the exploratory research study) involved a 12-week intervention in schools. Bespoke materials were developed for all the studies, and teachers received training on how to deliver the intervention they were a part of. For the RCTs, randomisation was done at school level: schools were randomly divided into treatment and control groups. The independent evaluators collected both quantitative and qualitative data to ensure that we gained comprehensive insights from the schools’ experiences of the interventions. The evaluators’ reports and our associated blog posts give full details of each study.

The impact of the pandemic

The research programme ran from 2019 to 2022, and as it was based in schools, we faced a lot of challenges due to the coronavirus pandemic. Many research programmes meant to take place in school were cancelled as soon as schools shut during the pandemic.

Although we were fortunate that GBIC was allowed to continue, we were not allowed to extend the end date of the programme. Thus our studies were compressed into the period after schools reopened and primarily delivered in the academic year 2021/2022. When schools were open again, the implementation of the studies was affected by teacher and pupil absences, and by schools necessarily focusing on making up some of the lost time for learning.

The overall results of Gender Balance in Computing

Quantitatively, none of the RCTs showed a statistically significant impact on the primary outcome measured, which was different in different trials but related to either learners’ attitudes to computer science or their intention to study computer science. Most of the RCTs showed a positive impact that fell just short of statistical significance. The evaluators went to great lengths to control for pandemic-related attrition, and the implementation teams worked hard to support teachers in still delivering the interventions as designed, but attrition and disruptions due to the pandemic may have played a part in the results.

The qualitative research results were more encouraging. Teachers were enthusiastic about the approaches we had chosen in order to address known barriers to gender balance, and the qualitative data indicated that pupils reacted positively to the interventions. One key theme across the Teaching Approach (and other) studies was that girls valued collaboration and teamwork. The data also offered insights that enable us to improve on the interventions.

We designed the studies so they could act as pilots that may be rolled out at a national scale. While we have gained sufficient understanding of what works to be able to run the interventions at a larger scale, two particular learnings shape our view of what a large-scale study should look like:

1. A single intervention may not be enough to have an impact

The GBIC results highlight that there is no quick fix and suggest that we should combine some of the approaches we’ve been trialling to provide a more holistic approach to teaching Computing in an equitable way. We would recommend that schools adopt several of the approaches we’ve tested; the materials associated with each intervention are freely available (see our blog posts for links).

2. Age matters

One of the very interesting overall findings from this research programme was the difference in intent to study Computing between primary school and secondary school learners; fewer secondary school learners reported intent to study the subject further. This difference was observed for both girls and boys, but was more marked for girls, as shown in the graph below. This suggests that we need to double down on supporting children, especially girls, to maintain their interest in Computing as they enter secondary school at age 11. It also points to a need for more longitudinal research to understand more about the transition period from primary to secondary school and how it impacts children’s engagement with computer science and technology in general.

What’s next?

We think that more time (in excess of 12 weeks) is needed to both deliver the interventions and measure their outcome, as the change in learners’ attitudes may be slow to appear, and we’re hoping to engage in more longitudinal research moving forward.

We know that an understanding of computer science can improve young people’s access to highly skilled jobs involving technology and their understanding of societal issues, and we need that to be available to all. However, gender balance relating to computing and technology is a deeply structural issue that has existed for decades throughout the computing education and workplace ecosystem. That’s why we intend to pursue more work around a holistic approach to improving gender balance, aligning with our ongoing research into making computing education culturally relevant.

Stay in touch

We are very keen to continue to build on our research on gender balance in computing. If you’d like to support us in any way, we’d love to hear from you. To explore the research projects we’re currently involved in, check out our research pages and visit the website of the Raspberry Pi Computing Education Research Centre at the University of Cambridge.

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As part of our mission to enable young people to realise their full potential through the power of computing and digital technologies, we work in partnership with organisations around the globe to grow and sustain the Code Club and CoderDojo networks of coding clubs for young people. These organisations are our global clubs partners, and they undertake activities including training educators and volunteers, providing access to equipment, and running clubs and events for young people at a local or national level.

Meeting in the middle

Given that many people at the Raspberry Pi Foundation are based in the UK and Ireland, and that meeting in person has been restricted during the coronavirus pandemic, our work to connect with the global clubs partners network has largely taken place via video calls these last years. We don’t only connect with partners one to one, we also link them to each other so they can share insights, approaches, and resources. Video calls offer a unique opportunity for bringing together partner organisations located all over the world, but they provide a very different experience to building community in person.

With a network of 41 organisations in 35 countries, meeting in person requires careful consideration so we can accommodate as many partners as possible. That’s why we decided to hold several regional meetups in 2022 to make it feasible for all partners to join at least one. In October, a meetup took place in the Netherlands, coinciding with DojoCon Netherlands run by local partners. Our most recent meetup happened in early December, the day before the Coolest Projects Malaysia 2022 event, in Penang on the west coast of Malaysia.

At the December meetup, we welcomed participants from 10 partner organisations across Asia, Oceania, and Africa. This group spent a whole day building connections and sharing their work with each other. Together we covered several areas of interest, including volunteer recruitment, training, and recognition — all crucial topics for organisations that rely on volunteers to support young people. Meet-up participants shared resources, discussed how to sustainably grow networks, and planned for the future. The next day, participants had the chance to visit Coolest Projects Malaysia to find even more inspiration while seeing local young people showcase their own tech creations.

Although it was only one day, the impact of the meetup has been clear. As we had hoped it would, feedback from the partner organisations was very positive and revolved around community and learning, with participants expressing “feeling better connected” and “interconnectedness”, as well as “learning a lot” and “sharing best practices”. One participant even volunteered to host a future meetup, saying “Next year I would like to run this in my country.”

Here at the Foundation, we very much share these sentiments. Ellie Proffitt, Code Club Global Partnerships Manager, said: “It was great to see our partners sharing how they support their clubs with each other and bouncing new ideas around. I think we all left feeling very inspired.”

Looking to the future

After the success of these in-person meetups in 2022, we and our global clubs partners are looking forward to future opportunities to work together. Planning for 2023 is of course well underway, with creative, ambitious projects and new partnerships in the pipeline. We all feel renewed in our commitment to our work and mission, and excited for what’s on the horizon. In the words of Sonja Bienert, Senior Community Manager: “Through this collaboration, we’ve reached a new level of trust that will positively influence our work for a long time to come.”

You can find out more about joining our global clubs partner community on the CoderDojo and Code Club websites, or contact us directly with your questions or ideas about a partnership. 

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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.

How non-formal learning creates opportunities for computing education

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. 

Helping learners make things that matter to them

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:

• Be beginner-friendly
• Include scaffolding
• Support learner’s design skills
• Relate to things that matter to learners

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:

• Three Explore projects to introduce creators to a set of skills and provide step-by-step instructions to help them develop initial confidence
• Two Design projects to allow creators to practise the skills they learned in the previous Explore projects, and to express themselves creatively while they grow in independence
• One Invent project where creators use their skills to meet a project brief for a particular audience

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. 

New literature review of non-formal computing education showcases its positive impact

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.

What existing studies in non-formal computing aren’t telling us

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:

• In other geographic locations
• In other educational settings, such as primary schools or after-school programmes
• For a wider spectrum of learners

We would also love to see studies that hone in on:

• The long-term impact of non-formal learning
• Which specific factors contribute to positive outcomes
• Non-formal learning about aspects of computing beyond programming

3…2…1…research!

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. 

Join our seminar series on primary computing education

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.

I want to sign up to attend

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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Over the past months, we’ve been working with two partner organisations, Team4Tech and Kenya Connect, to support computing education across the rural county of Machakos, Kenya.

Working in rural Kenya

In line with our 2025 strategy, we have started work to improve computing education for young people in Kenya and South Africa. We are especially eager to support communities that experience educational disadvantage. One of our projects in this area is in partnership with Team4Tech and Kenya Connect. Together we have set up the Dr Isaac Minae EdTech Hub in the community Kenya Connect supports in the rural county of Machakos, and we are training teachers so they can equip their learners with coding and physical computing skills.

“Watching teachers and students find joy and excitement in learning has been tremendous! The Raspberry Pi Foundation’s hands-on approach is helping learners make connections through seeing how technology can be used for innovation to solve problems. We are excited to be partnering with Raspberry Pi Foundation and Team4Tech in bringing technology to our rural community.”

– Sharon Runge, Executive Director, Kenya Connect

We are providing the Wamunyu community with the hardware and the skills and knowledge training they need to use digital technology to create solutions to problems they see. The training will make sure that teachers across Machakos can sustain the EdTech Hub and computing education activities independently. This is important because we want the community to be empowered to solve problems that matter to them and for all the local young people to have opportunities that are open to their peers in Nairobi, Kisumu, Mombasa, and other cities in Kenya.

Launching the Dr Isaac Minae EdTech Hub in Wamunyu

In October this year, we travelled to Wamunyu to help Kenya Connect set up and launch the Dr Isaac Minae EdTech Hub, for which we provided hardware including Raspberry Pi 400 computers and physical computing kits with Raspberry Pi Pico microcontrollers, LEDs, buzzers, buttons, motors and more. We also held a teacher training session to start setting up the local educators with the skills and knowledge they need to teach coding and physical computing. In the training, educators brought a range of experiences with using computers. Some were unfamiliar with computer hardware, but at the end of the training session, they all had designed and created physical computing projects using electronic circuits and code. It was hugely inspiring to work with these teachers and see their enthusiasm and commitment to learning.

Through our two-year partnership with Kenya Connect, we aim to reach at least 1000 learners between the ages of 9 to 14 from 62 schools in Machakos county. We will work with at least 150 teachers to build their knowledge, skills, and confidence to teach coding, digital making, and robotics, and to run after-school Code Clubs. We’ll help teachers offer learning experiences based on our established learning paths to their students, and these experiences will include basic coding skills aligned to Kenya’s Competency Based Curriculum (CBC). We are putting particular focus on adapting our learning content so that teachers in Machakos can offer culturally relevant educational activities in their community. 

“Our partnership with the Raspberry Pi Foundation will open up new avenues for teachers to learn coding and physical computing. This is in line with the current Competency Based Curriculum that requires students to start learning coding at an early age. Though coding is entrenched in the curriculum, teachers are ill-prepared and schools lack devices. We are so grateful to the Raspberry Pi Foundation for providing teachers and students access to devices and the Raspberry Pi learning paths.”

– Patrick Munguti, Director of Education and Technology, Kenya Connect

Looking to the future

Next up for our work on this project is to continue supporting Kenya Connect to scale the program in the county.

In all our work in Sub-Saharan Africa, we are committed to strengthening and growing our partnerships with locally led youth and community organisations, the private sector, and the public sector, in line with our mission to open up more opportunities for young people to realise their full potential through the power of computing and digital technologies.

Our work in Sub-Saharan Africa is generously funded by the Ezra Charitable Trust.

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Young tech creators, get ready: Coolest Projects Global will be back in 2023 and we want to make this the year of your big idea!

Coolest Projects Global 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 Global 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.

How does Coolest Projects Global work?

• Coolest Projects Global is completely free, it’s all online, and it’s open to all digital creators up to age 18 from anywhere in the world. Creators can take part independently or in teams of up to five.
• Tech creators of all skill levels are encouraged to participate. Coolest Projects is for young people who are beginners, advanced, or anything in between.
• We love to see works in progress, so projects don’t need to be completed to be registered.

• Projects can be registered in six categories: Scratch, games, web, mobile apps, hardware, and advanced programming.
• Creators can choose topics including community, environment, health, fun, art, education, and identity.
• Judges evaluate projects based on their coolness, complexity, design, usability, and presentation, and give personalised feedback about each project.
• Project registration opens on 6 February and stays open until 26 April.
• The livestream event on 6 June will celebrate all the creators’ projects and reveal the judges’ favourites.

Creators who took part in 2022 told us that the coolest thing about Coolest Projects Global is that “so many people around the world get to see and appreciate your projects” and that “anyone can have a go”.

What makes a coolest project?

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. 

What’s next?

Registration opens on 6 February 2023, and creators can get started on their ideas and make their projects any time.

• Visit the 2022 online gallery of projects if you want to come up with a project idea.
• If you’ve never coded before or want to learn more about creating with technology, try our free guided coding project paths. The ‘Introduction to Scratch path’ is perfect for beginners.
• To always get the very latest news about the upcoming Coolest Projects Global event, including the special swag and the VIP judges, sign up for email updates.

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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.

More and more schools are taking part in the UK Bebras Challenge

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

Age-appropriate computational thinking problems

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.

Year-round free resources for teachers

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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