BIG DATA SENSING, COMPRESSION AND COMMUNICATION

Academic Year 2020/2021 - 2° Year
Teaching Staff: Laura Galluccio
Credit Value: 6
Scientific field: ING-INF/03 - Telecomunicazioni
Taught classes: 40 hours
Term / Semester:

Learning Objectives

ING-INF/03 - 6 CFU - 40 hours

 

Coherence of the course with reference to the Master Degree in “Data Science for Management”

Data is growing and has grown very fast in the last years.”Big Data” analytics is challenging today because of the unprecedented large data volumes. In this course, we will describe the structure of data generated in big data sensing applications, by distinguishing the type and structure of data. Then we will discuss SoA methodologies which can be used to compress this data based on its intrinsic features; finally, communication protocols for remotely delivering this data will be described and detailed. In this way students will be provided with communication engineering competences allowing them to actively communicate with experts in various fields by providing focused and competent data analysis for every application, such as in scientific, technological or business fields. Students will also be able to exploit the competences gained for design processes of collection, compression and communication of heterogeneous big data.

This course will be of interest for students attending all paths for the following reasons:

  • For “Business and economics data scientists”, this course will allow to complement their business competences being able also to communicate with technical experts in the field.
  • For students in “Data driven applications for the IoT” and “Data for sciences”, this is a fundamental course to well understand the intrinsic nature of IoT big data.

 

 

Learning Objectives

The course aims to provide students with some basics of information generation, encoding, compression and communication for big data scenarios.

 

Dublin Descriptors

  1. Knowledge and understanding (Conoscenza e capacità di comprensione) - The course aims to provide students with knowledge and understanding of techniques and algorithms for acquisition and processing of data (e.g. sensor generated data, images, audio files) collected in smart environments such as in environmental monitoring, e-health, smart cities and/or vehicular scenarios. Then students will understand and study techniques for data compression both at the sources and, in a distributed way, in the network. Finally technologies and architectures for the transmission of big data will be studied.
  2. Applying knowledge and understanding (Capacità di applicare conoscenza e comprensione) - After attending this course, students will be able to manipulate, process and reconstruct different types of data acquired from a smart environment, design compression algorithms suitable to perform data compression both at the data sources or into the network, choose and exploit the most appropriate set of technologies for data transmission in big data scenarios. Finally students will be able to solve specific big data design problems in realistic scenarios.
  3. Making judgements (Autonomia di giudizio) - Upon completion of the course the students will gain independent and critical understanding skills as well as ability to discuss design aspects in real big data scenarios, commenting also on the design choices. Finally, at the end of the course, the students will be able to prosecute independently their study of other engineering-related disciplines with the ability to appropriately use big data design considerations in the appropriate context.
  4. Communication skills (Abilità comunicative) - Students attending this course will learn to communicate and discuss/describe relevant Big Data application scenarios. Also they will be able to critically discuss and illustrate the most relevant design aspects to be taken into account upon focusing on generation, elaboration and communication of huge amounts of heterogeneous data like those generated in IoT networks.

Course Structure

The course consists of lectures and laboratory activity. The theorethical lectures are taught by the teacher while laboratory activities, consisting of exercises, will be carried out in collaboration by the teacher and by the students who are invited to solve, with the support of the teacher, exemplary problems. In addition, other lectures will be devoted to the illustration of software tools, e.g. Mathworks Matlab, useful for the solution of specific problems.

Should teaching be carried out in mixed mode or remotely, it may be necessary to introduce changes with respect to previous statements, in line with the programme planned and outlined in the syllabus.


Required Prerequisites

Basics of maths (integrals, derivatives, matrixes, vectors, functions, scientific/exponential notation), basics of communication systems (not strictly required).


Attendance of Lessons

Attending classes is not mandatory but strongly recommended.

The final exam will consist of a colloquium with the teacher on the topics dealt during the course. Learning assessment may also be carried out on line, should the conditions require it.


Detailed Course Content

Introduction (approx 3 hours): Introduction to Internet of Things-Introduction to big data-Definition of big data-Types of big data-operations on big data-Examples of big data.

Part 1 (approx 12 hours). Big data sensing: Types of data - Audio sources - Basics of acoustics - Human earing fundamentals - Basics of digital audio - Digital encoding - Sampling Theory - Different audio file formats - Compressed audio - Video sources - Basics of video encoding - Different video file formats - Multimedia transmission - Fundamentals - Jitter and synchronization - Multimedia file formats - Data sources - Data file formats - Examples of different mechanisms for data generation.

Part 2 (approx 10 hours). Big data compression: Source coding - Compressive sensing - Channel coding - Examples of compression techniques applied to different types of data.

Part 3 (approx 15 hours). Big data communication: Technologies for the IoT - Bluetooth LE-RFID - 6LowPAN - IEEE 802.15.4 - WiFi - ZigBee - LoRa - SigFox - Examples of communication between nodes exploiting some of the technologies discussed above.


Textbook Information

The following texts are suggested readings. During the course, the teacher can also suggest further readings (e.g. scientific papers and articles) on specific topics.

-A. Rezzani. Big Data Analytics: Il manuale del data scientist, Apogeo Maggioli Editore

-V. Lombardo, A. Valle. Audio e multimedia, 4th edition, Apogeo Maggioli Editore.

-Z. Han, H. Li, W. Yin. Compressive sensing for wireless networks. Cambridge University Press.

-F. Wu. Advances in visual data compression and communication: Meeting the Requirements of New Applications, CRC Press.

 



Course Planning

 SubjectsText References
1 Introduction to Internet of ThingsRezzani. Big Data Analytics: Il manuale del data scientist, Apogeo Maggioli Editore, Chapter 1  
2Introduction to big data-Definition of big data-Types of big data-operations on big data-Examples of big data.Teacher's slides; Chi Yang, Deepak Puthal, Saraju P. Mohanty, and Elias Kougianos. Big Sensing Data Curation in Cloud Data Center for Next Generation IoT and WSN, www.smohanty.org 
3Introduction to big data-Definition of big data-Types of big data-operations on big data-Examples of big data.Jie Lin, Wei Yu, Nan Zhang, Xinyu Yang, Hanlin Zhang, and Wei Zhao. A Survey on Internet of Things: Architecture, Enabling Technologies, Security and Privacy, and Applications. IEEE INTERNET OF THINGS JOURNAL, VOL. 4, NO. 5, OCTOBER 2017. 
4Introduction to big data-Definition of big data-Types of big data-operations on big data-Examples of big data.M. Sha. Big data and the Internet of Things in N. Japkowicz and J. Stefanowski; Big Data Analysis: New Algorithms for a New Society, Springer; J. Gao. Big data Sensing and service: A Tutorial. 2015 IEEE First International Conference on Big Data Computing 
5Big data sensing: Types of data-Audio sources - Basics of acoustics- Human earing fundamentals- Basics of digital audio- - Digital encoding-Sampling Theory-Different audio file formats-Compressed audio V. Lombardo, A. Valle. Audio e multimedia, 4th edition, Apogeo Maggioli Editore, Chapters 1, 2, 3, 4, 6, 8; Teacher's slides; D. Solomon. Data Compression, 4th edition, Springer, Chapters 1, 2, 3 ; D. Solomon. Data Compression, 4th edition, Springer 
6-Video sources - Basics of video encoding-Different video file formats-Multimedia transmission-Fundamentals-Jitter and synchronization-Multimedia file formats-Data sources-Data file formats-Examples of different mechanisms for data generation.Z. Li and M. Drew. Fundamentals of Multimedia, Pearson Chapters 3, 4, 5, 8, 9, 10 
7Big data compression: Source coding- Compressive sensing-Channel coding. Examples of compression techniques applied to different types of data.Z. Han, H. Li, W. Yin. Compressive sensing for wireless networks. Cambridge University Press Chapters 3, 4, 5, 6; Teacher's slides 
8Big data communication: Technologies for the IoT: Bluetooth LES. M. Darroudi, C. Gomez. Bluetooth Low Energy Mesh Networks: A Survey. MDPI Sensors, 2017.  
9Big data communication: Technologies for the IoT: RFIDDheeraj K. Klair ; Kwan-Wu Chin ; Raad Raad. A Survey and Tutorial of RFID Anti-Collision Protocols. IEEE Comm. Surveys and Tutorial, Vol. 12, 2010. 
10Big data communication: Technologies for the IoT: 6LowPANZ. Shelby and C. Bormann. 6LoWPAN: The wireless embedded Internet. Wiley. ; C. Yibo et al. 6LoWPAN Stacks: A Survey. Proc. Of 2011 7th International Conference on Wireless Communications, Networking and Mobile Computing 
11Big data communication: Technologies for the IoT: IEEE802.15.4 and ZigBeeHarrison Kurunathan , Ricardo Severino, Anis Koubaa, and Eduardo Tovar. IEEE 802.15.4e in a Nutshell: Survey and Performance Evaluation. IEEE Comm. Survey and Tutorial, Vol. 20, 2018; Paolo Baronti, Prashant Pillai, Vince W.C. Chook, Stefano Chessa, Alb 
12Big data communication: Technologies for the IoT: LPWANU. Raza, P. Kulkarni and M. Sooriyabandara, Low Power Wide Area Networks: An Overview, IEEE CommunicaXon Surveys and Tutorials, 19(2), pp. 855-874, 2017  
13Big data communication: Technologies for the IoT: LoRa and SigFox• Sigfox Technical Overview, May 2017; Teacher's slides; M. Lavric, V. Popa. Internet of Things and LoRa™ Low-Power Wide-Area Networks: A survey. proc. of 2017 International Symposium on Signals, Circuits and Systems (ISSCS) 2017. 

Learning Assessment

Learning Assessment Procedures

The final exam will consist of a colloquium with the teacher on the topics dealt during the course. Learning assessment may also be carried out on line, should the conditions require it.


Examples of frequently asked questions and / or exercises

See material available on Studium