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| en:safeav:curriculum:introduction [2025/10/30 09:44] – raivo.sell | en:safeav:curriculum:introduction [2025/11/17 08:31] (current) – airi | ||
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| The curriculum follows a modular structure combining theoretical foundations, | The curriculum follows a modular structure combining theoretical foundations, | ||
| - | * SafeAV Handbook – provides the theoretical and methodological background, including system architectures, | + | |
| - | * SafeAV Hands-on Guide – offers practical laboratory and simulation exercises that allow students to perform verification and validation tasks using real and virtual autonomous platforms. | + | |
| + | |||
| + | **Terminology note.** In this document, the SafeAV curriculum is the unified framework that defines the overall programme architecture, | ||
| The SafeAV curriculum architecture defines the overall structure, modular hierarchy, and learning flow that connects theoretical knowledge, simulation-based validation, and experimental practice. It ensures coherence between study levels and provides a clear path from basic understanding to advanced assurance of autonomous vehicle safety. | The SafeAV curriculum architecture defines the overall structure, modular hierarchy, and learning flow that connects theoretical knowledge, simulation-based validation, and experimental practice. It ensures coherence between study levels and provides a clear path from basic understanding to advanced assurance of autonomous vehicle safety. | ||
| - | Modules are organised in pairs: Part 1 (Bachelor) introduces the concepts, while Part 2 (Master) deepens the same topic through practical verification and validation | + | Modules are organised in pairs: Part 1 (Bachelor) introduces the concepts, while Part 2 (Master) deepens the same topic through practical verification and validation methods. This two-level structure enables a stepwise learning progression across study cycles and gives universities the flexibility to adopt the curriculum or parts of it into existing educational programs. |
| Each topic therefore exists in two complementary parts: | Each topic therefore exists in two complementary parts: | ||
| - | * Part 1 (Bachelor level) – introduces the fundamental principles, technologies, | + | |
| - | * Part 2 (Master level) – deepens the focus toward | + | |
| - | For example, in Hardware and Sensing Technologies Part 1, students learn sensor types, signal processing basics, and data acquisition. In Part 2, they perform calibration, | + | For example, in Hardware and Sensing Technologies |
| This two-stage progression ensures continuity between study cycles and supports lifelong learning paths in autonomous vehicle engineering. | This two-stage progression ensures continuity between study cycles and supports lifelong learning paths in autonomous vehicle engineering. | ||
| - | {{ : | + | {{ : |
| The overall curriculum can be described as three integrated layers: | The overall curriculum can be described as three integrated layers: | ||
| - | * Conceptual layer – theoretical foundations and system-level understanding (covered | + | |
| - | * Practical layer – hands-on experiments, | + | |
| - | * Digital layer – self-study materials, MOOC courses, and AI-supported assistants that guide learning and track individual progress | + | |
| These layers are interconnected through shared terminology, | These layers are interconnected through shared terminology, | ||
| + | |||
| ===== Curriculum Composition ===== | ===== Curriculum Composition ===== | ||
| - | The curriculum consists of six interrelated modules that together form a complete 6 ECTS study block but can also be used independently. Each module represents approximately 25–30 hours of student work, combining lectures, laboratory tasks, and self-study. | + | The curriculum consists of six interrelated modules that together form a complete 6 ECTS study block (one for bachelor and one for masters) |
| The modular design allows multiple implementation strategies: | The modular design allows multiple implementation strategies: | ||
| * full six-module SafeAV course (6 ECTS) | * full six-module SafeAV course (6 ECTS) | ||
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| Each module includes theoretical reading, guided experiments, | Each module includes theoretical reading, guided experiments, | ||
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| + | ---- | ||
| ===== Bachelor Level (Part 1) ===== | ===== Bachelor Level (Part 1) ===== | ||
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| Each module combines reading assignments from the SafeAV Handbook with laboratory or simulation tasks from the Hands-on Guide, such as sensor calibration, | Each module combines reading assignments from the SafeAV Handbook with laboratory or simulation tasks from the Hands-on Guide, such as sensor calibration, | ||
| The recommended full scope equals 6 ECTS, yet the modular design allows partial adoption depending on local curricula and student pathways. | The recommended full scope equals 6 ECTS, yet the modular design allows partial adoption depending on local curricula and student pathways. | ||
| + | |||
| + | ---- | ||
| ===== Master Level (Part 2) ===== | ===== Master Level (Part 2) ===== | ||
| - | The Master’s programme deepens the same thematic areas into Part 2 modules that focus on validation, verification, | + | The Master’s programme deepens the same thematic areas into Part 2 modules that focus on validation, verification, |
| - | Modules are directly linked to the advanced chapters of the SafeAV Handbook | + | |
| Modules – Part 2: | Modules – Part 2: | ||
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| Students build validation pipelines from model design to field testing, using digital twins and simulation environments. The progression mirrors the V-model lifecycle introduced in the handbook — from design to verification, | Students build validation pipelines from model design to field testing, using digital twins and simulation environments. The progression mirrors the V-model lifecycle introduced in the handbook — from design to verification, | ||
| + | |||
| + | It is important to note that the distinction between Bachelor (Part 1) and Master (Part 2) levels in this curriculum is conditional rather than absolute. Depending on the structure of the base study programme or the learner’s prior knowledge and competences, | ||
| + | |||
| + | For this reason, the SafeAV Handbook presents most topics in two levels of depth. Students who already have sufficient background or wish to advance further can continue directly to the next sub-sections, | ||
| + | |||
| + | Therefore, the level designation in this curriculum should be interpreted as indicative of content depth—Basic and Advanced rather than as a strict separation between Bachelor and Master academic degrees. | ||
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| ===== Learning Environments and Methods ===== | ===== Learning Environments and Methods ===== | ||
| - | Each module supports flexible learning environments that allow both classroom and remote participation: | + | Most module supports flexible learning environments that allow both classroom and remote participation: |
| * classroom teaching for theoretical foundations | * classroom teaching for theoretical foundations | ||
| - | * local laboratories for experiments with sensors, embedded controllers, | + | * access to the AI-driven hybrid laboratory environment |
| - | * virtual | + | * virtual |
| - | * MOOC-based self-study materials with AI-assisted feedback | + | |
| * hybrid sessions combining on-site instruction with online validation tasks | * hybrid sessions combining on-site instruction with online validation tasks | ||
| - | The SafeAV Hands-on Guide defines equipment lists, | + | The SafeAV Hands-on Guide defines equipment lists, |
| + | |||
| + | Digital tools, Dokuwiki materials, and the MOOC environment allow integration with AI-based assistants that support self-learning, | ||
| + | These learning environments are common across all modules, ensuring coherence, accessibility, | ||
| + | |||
| + | Key features include: | ||
| + | * AI tutoring and feedback – AI assistants answer questions, explain concepts, and provide formative feedback. | ||
| + | * Accessibility and inclusion – automatic transcription, | ||
| + | * Integration with laboratories – seamless connection between online content and hybrid laboratory activities. | ||
| + | * Open-access collaboration – materials and results can be shared, reused, and expanded across institutions. | ||
| + | |||
| + | The MOOC environment also functions as the central tool for monitoring student progress and competence development. It is continuously updated with new content and integrated with AI analysis to track engagement, learning efficiency, and V& | ||
| + | |||
| + | ===== Hybrid Laboratory Environment (AI-driven) ===== | ||
| + | |||
| + | The SafeAV curriculum builds upon the remote and virtual laboratory infrastructure previously developed within earlier Erasmus+ projects (Interstudy, | ||
| + | |||
| + | The hybrid laboratory integrates real test environments, | ||
| + | |||
| + | SafeAV enhances this environment by introducing an AI component that expands the capabilities of the virtual laboratories. AI-based modules enable advanced simulation, automated data analysis, and model validation within digital twin environments. Intelligent assistants help students interpret results, identify anomalies, and generate experiment documentation automatically. | ||
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| + | This AI-driven hybrid environment forms the backbone of the SafeAV practical learning concept. It bridges physical and virtual domains, connects theoretical understanding to verification and validation processes, and provides a unified experimental framework for both Bachelor and Master level studies. | ||
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| + | ===== AI-Based Methods Supporting the Curriculum ===== | ||
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| + | The integration of artificial intelligence (AI) tools into the SafeAV curriculum is a central element for enabling modern, personalized learning experiences. In addition to supporting individualized study paths for typical learners, it also enhances accessibility and provides improved educational opportunities for students with special needs. | ||
| + | |||
| + | AI technologies are implemented at two levels: | ||
| + | * integration within the learning content to illustrate how AI supports autonomous vehicle V&V (e.g., AI in perception, planning, or safety analysis) | ||
| + | * integration as pedagogical tools to assist students and lecturers throughout the learning process | ||
| + | |||
| + | The following AI-based methods are used within the SafeAV ecosystem: | ||
| + | * AI-powered virtual assistants – LLM-based agents embedded in the MOOC and Dokuwiki environment answer course-related questions, explain theoretical concepts, and provide V& | ||
| + | * AI-driven interactive simulations and virtual labs – intelligent digital twins and scenario generators support sensor fusion validation, control-loop testing, and human–machine communication studies. | ||
| + | * Personalized AI tutors – adaptive learning systems analyse student progress and recommend additional materials, exercises, or simulations based on performance. | ||
| + | * AI-supported content summarization – automatic generation of concise summaries of lectures, reports, and laboratory documentation helps students prepare for assessment and supports accessibility. | ||
| + | * Automated peer review and feedback – integrated AI tools assist in assessing reports and coding exercises, providing constructive feedback and reducing lecturer workload. | ||
| + | |||
| + | AI-based tools play a significant role in SafeAV by reducing repetitive communication tasks, offering continuous learning support, and improving the overall organization of study activities. These systems provide students with round-the-clock access to guidance and feedback, allowing instructors to focus on higher-level mentoring and project supervision. | ||
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| + | To ensure trustworthy and responsible use of AI in education, all implementations follow privacy-by-design principles and comply with relevant data protection regulations. Student data are processed transparently and securely, with anonymized interaction records and clear options to opt out of AI-assisted learning when preferred. | ||
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| + | In the long term, the SafeAV approach aims to develop a shared and open AI learning framework that promotes accessibility, | ||
| - | Digital tools, Dokuwiki materials, and the MOOC environment allow integration with AI-based assistants that support self-learning, | ||
| ===== Curriculum Implementation and Adaptation ===== | ===== Curriculum Implementation and Adaptation ===== | ||
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| All materials are licensed under Creative Commons (CC BY-NC), allowing reuse and modification while keeping alignment with European learning standards and ECTS principles. | All materials are licensed under Creative Commons (CC BY-NC), allowing reuse and modification while keeping alignment with European learning standards and ECTS principles. | ||
| This ensures consistency across partner universities while maintaining flexibility for local adaptation and future extension. | This ensures consistency across partner universities while maintaining flexibility for local adaptation and future extension. | ||
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