Lesson Plan and Full Lesson 6: Use two’s complement to represent positive and negative 8-bit binary integers. • Convert a positive binary or denary integer to a two’s complement 8-bit integer and vice versa • Convert a negative binary or denary integer to a two’s complement 8-bit integer and vice versa

IB DP Artificial intelligence (AI) tools – common questions and concerns The simple answer is that Artificial Intelligence (AI) are software tools—with ChatGPT being one example— that can respond to a request (or prompt) with an answer that creates a humanlike conversational dialogue. So, for example, if an AI tool is asked “What started World War 2?”, then it would provide several, detailed paragraphs—just as if you had asked a human that question. AI tools such as ChatGPT are different to search engines which direct you to webpages that could answer your question. Dramatic improvements in AI tools have taken place over the last few months and many people have been surprised at the quality of what they can produce. Though others see it as superficial and there are many questions around its limitations, accuracy and bias.

IB DP Academic integrity policy Academic integrity is a guiding principle in education and a choice to act in a responsible way whereby others can have trust in us as individuals. It is the foundation for ethical decision-making and behaviour in the production of legitimate, authentic and honest scholarly work. Academic integrity goes beyond a definition and a well-structured school policy; it should also be part of an “ethical culture” of any educational institution, be that a primary school or a university. It is an obligation that must be embraced and fostered by the entire school community, so students continue their future life, whether in higher education or in the workplace, in strict adherence to this principle. Fostering an academic integrity culture, and a personal positive attitude towards it, requires the design of a school strategy that combines policies and good academic practice, while understanding the fundamental dimension it has in the authentic construction of meaning and learning in all IB programmes. The guiding principle of academic integrity can be seen as built up from a number of simpler concepts in education, that can start early during the Primary Years Programme (PYP), be reinforced during the Middle Years Programme (MYP) and cemented later through the Diploma Programme (DP) and Career-related Programme (CP). Expectations should be clearly communicated and modelled at an age-appropriate level so that all IB students understand: • their responsibility for producing authentic and genuine individual and group work • how to correctly attribute sources, acknowledging the work and ideas of others • the responsible use of information technology and social media • how to observe and adhere to ethical and honest practice during examinations. Educators supporting IB students in their learning should understand their own central role in developing the approaches to learning and reinforce the principle of academic integrity through all teaching, learning and assessment practices

**IB DP Diploma Programme updates 2024-2027 ** Welcome to the Diploma Programme updates, the new name for Coordinator’s notes. The name change has been introduced as a result of feedback from stakeholders and to reflect the fact that this regular publication contains important information for the whole IB community. This more compact publication features content that is brand new or especially relevant for the forthcoming assessment session. The decision to remove older content was made as a result of discussions with stakeholders. All previous editions of the Diploma Programme (DP) Coordinator’s notes and Programme updates are available on the Programme Resource Centre at DP resources > Implementation > Information for coordinators > Diploma Programme updates. Please send any feedback on the new look to support@ibo.org. In addition to contacting schools directly, the International Baccalaureate (IB) will post updates regarding upcoming assessment sessions or curriculum amendments on the IB website, ibo.org. Schools and educators are reminded that official IB information is published through the Programme Resource Centre. Resources shared through social media and other channels are unofficial. For general IB news and information—for example, research news and professional development (PD) opportunities—please refer to the monthly newsletter IB Global News. Coordinators will automatically receive newsletters via email using the email address they have entered into the IB information system (IBIS)

Project Overview: KS3 STEAM Project - Water Rocketry 2024 This comprehensive STEAM project engages Year 8 students in the exciting world of water rocketry. Students will design, build, and test a water rocket with the goal of achieving the highest possible altitude. The project integrates principles from mathematics, physics, and chemistry, providing a hands-on, interdisciplinary learning experience. Key Activities: Research: Investigate a space launch complex and create a detailed report and model. Experimentation: Conduct experiments to understand the variables affecting rocket performance. Design and Build: Apply research and experimental data to construct and test a high-performing water rocket. Presentation: Present findings, processes, and final designs to peers, teachers, and parents. Learning Outcomes: Develop critical thinking and problem-solving skills. Apply scientific principles to real-world scenarios. Enhance teamwork and communication abilities. This project not only fosters a deep understanding of STEAM subjects but also inspires creativity and innovation among students. Perfect for engaging young minds and making learning fun!

Tracing Table Question and Answer Questions 14 with full details Section B – Year May 2019

Computer Science_Year 7/8/9/10/11 _Exam with Answer_1.1 Number systems Computer Science_Year 7/8/9/10/11 _Exam with Answer_1.1 Number systems Data representation 1.1 Number systems Candidates should be able to: 1 Understand how and why computers use binary to represent all forms of data 2 (a) Understand the denary, binary and hexadecimal number systems (b) Convert between (i) positive denary and positive binary (ii) positive denary and positive hexadecimal (iii) positive hexadecimal and positive binary 3 Understand how and why hexadecimal is used as a beneficial method of data representation 4 (a) Add two positive 8-bit binary integers (b) Understand the concept of overflow and why it occurs in binary addition Notes and guidance • Any form of data needs to be converted to binary to be processed by a computer • Data is processed using logic gates and stored in registers • Denary is a base 10 system • Binary is a base 2 system • Hexadecimal is a base 16 system

Introduction to the AI Curriculum from Year 7 to Year 13 Artificial Intelligence (AI) is revolutionizing industries, economies, and societies at an unprecedented pace. Understanding AI’s principles and applications is becoming essential for the next generation of innovators, leaders, and informed citizens. Our AI curriculum, spanning from Year 7 to Year 13, is meticulously designed to equip students with foundational knowledge, practical skills, and ethical awareness in AI. By integrating AI education into school curricula, we aim to foster critical thinking, creativity, and problem-solving abilities among students. Why Choose Our AI Curriculum? 1. Future-Ready Education: Prepare your students for a future dominated by AI. This curriculum ensures they are not just passive consumers of technology but active innovators and ethical decision-makers. 2. Comprehensive Learning Journey: Our curriculum is structured to provide a progressive learning experience, starting with basic concepts in Year 7 and advancing to specialized AI topics and applications by Year 13. Each year builds on the previous one, ensuring a deep and thorough understanding of AI. 3. Practical, Hands-On Experience: Students engage in practical projects and collaborative learning from the outset. They will not only learn theoretical concepts but also apply their knowledge in meaningful, real-world contexts. 4. Ethical AI Development: We emphasize the importance of ethics in AI development throughout the curriculum. Students will explore the ethical implications of AI technologies and learn to develop AI responsibly. 5. Expert-Led Instruction: Our curriculum is developed by leading AI educators and industry experts, ensuring that the content is cutting-edge and relevant. Teachers will receive comprehensive training and support to deliver this curriculum effectively.

Implementing AI in Education: Enhancing Learning and Administrative Efficiency Artificial Intelligence (AI) has revolutionized the EdTech industry, transforming the way education is delivered and experienced. This transformation is driven by AI’s ability to analyses vast amounts of data and tailor learning experiences to individual needs. Here, we explore how AI impacts EdTech through personalized learning, intelligent tutoring systems, automated grading and feedback, predictive analytics, and enhanced administrative efficiency. We also address the challenges and future prospects of AI in education. Note: This research was conducted using AI; however, the main idea and structure were developed by Mr. Noureddine Tadjerout. Utilizing AI can expedite research and analysis, but the core ideas and research are human-driven. AI is a tool to assist and enhance the research process, not replace human creativity and insight. Table of Contents Introduction • Overview of AI in Education • Importance and Impact of AI Main Responsibilities of an AI Implementation Specialist • Needs Assessment • Solution Design and Selection • Deployment and Integration • Training and Support • Performance Monitoring Real System Implementation in a School • Personalized Learning • Example: Mathematics (Primary and Secondary Levels) • Implementation Details • Intelligent Tutoring Systems • Example: Science (Primary and Secondary Levels) • Implementation Details • Automated Grading and Feedback • Example: English (Secondary Level) • Implementation Details • Predictive Analytics • Example: General Academic Performance (Primary and Secondary Levels) • Implementation Details • Enhanced Administrative Efficiency • Example: Administrative Tasks • Implementation Details AI Applications and Tools for Specific Subjects • Science • Physics • English • Mathematics • ICT/Computer Science • History • Geography • Chemistry • STEAM • Spanish/French Challenges and Considerations • Algorithmic Biases • Data Privacy • Digital Divide Future Prospects • Advancements in AI Technologies • Potential for Bridging Educational Gaps • Promoting Lifelong Learning Conclusion References Note • Acknowledgment of AI and Human Collaboration in Research

Pseudocode Guide for Teachers Cambridge International AS & A Level Computer Science 9618 The following information sets out how pseudocode will appear within the examined components and is provided to allow you to give learners familiarity before the exam.

IGCSE Revision_the three basic constructs of sequence_selection and iteration

IGCSE Revision Network hardware and Programming concepts ((e) Understand and use the concept of string handling) and Algorithm design and problem-solving (validation and verification check)

Term 3_Y12_IBDP_End of Year Exam_Questions with Answers__2024

Computer Science Class Feedback Form for Your Students

IB DP Year 12/ 13_ Test 3_ Paper 1_Topic 3_Networks_ Questions and Answers for SL/HL

Online or Face to Face lesson presentation for Computer Science Teachers position: include IGCSE lesson plan and lesson presentation

IGCSE Revision Pseudocode ( FOR_WHILE_REPEAT_ LOOP with Questions and Answers

IB DP Year 12/ 13_ Test 2_ Paper 1_Topic 2_Computer organization_ Questions and Answers for SL/HL

IB DP Year 12/ 13_ Test 1_ Paper1_Topic 1_System fundamentals Section 1.1 and 1.2 Questions and Answers for SL and HL

Introduction : Introduction to Landscape Modeling Welcome to our project on landscape modeling! Today, we will explore how to create a realistic landscape model using both digital tools like Tinkercad and physical materials. Our goal is to recreate a mountain scene with a bridge and river, similar to the image shown. We’ll start by sketching our ideas, then move on to digital modeling in Tinkercad, and finally, build a physical model. This process will help us understand the principles of landscape design and the practical aspects of constructing a model. Marking Rubric for Project 4 : Landscape