Information

Identity card

Class hours

See the Schedule section for detailed information.

Course Contents

The course aims at describing, from an experimental point of view, the field of Ambient Intelligence (AmI), outlining its multi-disciplinary nature as well as its technology and application areas. Nowadays, the evolution of consumer electronic technologies, wireless networks, sensors, etc. and the ability to represent and process knowledge and data on a large scale allow the conception of environments able to handle, in an optimal way, energy-related variables, comfort, safety, and user interaction. Such scenarios spur a variety of solutions, ranging from smart homes to smart buildings, from smart cities to smart transportation systems.
Special emphasis, on the course, will be devoted to design-related aspects and on the overall hardware-software architecture, besides reviewing the involved technologies. This will enable students to design and realize reusable and interoperable solutions, and to collaboratively build a working prototype of an AmI system, in the laboratory.
The course will be held in English.

Learning Outcomes

Knowledge: technologies involved in the design and realization of smart environments, at various architectural levels (sensors, smart homes and buildings networks, user interfaces). Programming distributed systems based on web APIs. Software design methodologies.

Skills: writing system specifications and high-level design of an Ambient Intelligence system, starting from its functional and behavioral requirements. Realization of real-world intelligent environments. Capability of working in group with modern Internet-based collaboration tools. The Python language for rapid prototyping.

Prerequisites

Knowledge of programming languages, such as C or Java.
General knowledge of computer networks or communication networks.
The course has a strong interdisciplinary nature. The topics are mainly suitable for students enrolled in different degrees in the ICT sector (computer science, electronics, telecommunications), but in the work groups there may be a significant contribution from disciplines oriented to wide AmI application areas: electric, energy, industrial design, mechanics, etc.

Topics

The course aims at tackling, from a system and multidisciplinary approach, the main enabling technologies and the design methodologies involved in the definition of a complex system such as the ones present in AmI.

The course will cover the following topics, including their theoretical, methodological, and practical aspects:

1. Introduction to Ambient Intelligence: definitions and available approaches for smart homes, smart buildings, etc. Overview of application areas (home, building, city, traffic, etc.) and types of applications (monitoring, comfort, anomaly detection, ambient assisted living, control and automation, etc.)
2. Requirements and design methodology for AmI. Design, analysis and specification of requirements and functionalities related to user interacting with AmI settings.
3. Practical programming of AmI systems: the Python language, the Raspberry Pi computer, Web protocols and languages (e.g., HTTP and REST), web-based APIs, and collaboration tools (git, GitHub).

Organization

The course is strongly oriented to laboratory activities. Class lectures are mostly aimed at giving the background needed to develop the group work in the laboratory. Some in-class exercises will focus on hands-on practice and on deepening selected topics.

During laboratory hours (at LADISPE), students will work for programming simple intelligent scenarios and user interfaces with real smart home systems. Hands-on and insights about some topics will be discussed in class.
Additional hours will be devoted to assisted group work in the laboratory.

Materials

The course material is available in the Schedule section and in a dedicated GitHub repository. Lectures will be video-recorded and will be made available on this website and in a YouTube playlist.

Course material encompasses slides, required readings, code exercises and examples (both in class and in lab), as well as additional references and links.