As a result, after the discipline laerning, the specialist must know:
• the features of development of information and communication system platform based on the concept of the Internet of Things;
• the peculiarities of architectural concepts of information and communication system platform design based on the concept of the Internet of Things: a synthetic approach to RFID, sensor technology in general, wireless telecommunication systems, localization principles of "things", means of ubiquitous computing;
• theoretical and practical approaches to the development and support of information and communication technology solutions, hardware and software systems based on the concept of the Internet of Things;
• skills in the field of creation and programming of high performance and fault tolerant information and communication systems, including in the framework of the concept of the Internet of Things.

prerequisites:
• Informatics (by professions), part 1 (bachelor program);
• Informatics (by professions), part 2 (bachelor program);
• Telecommunications software (bachelor program);
• Technologies of the program platforms development;
• Distributed service systems and cloud technologies;
• Internet of Things and ubiquitous computing.

Introduction to challenge, the methodology of the course work and clarifying optional tasks. The wording of the purpose and requirements to formation of partial problems. Building block diagram and description of the service segment of the network system based on the concept of the Internet of Things. Rationalization for the use of technology, sensor networks, RFID, location of objects. Carrying out the necessary calculations and prototype software development for conventional elements of the system, developed under the concept of Internet of Things using the principles of "ubiquitous computing." Calculation of specialized equipment and network segment system based on the concept of the Internet of Things. The final design of text and graphic parts of the explanatory note to the course work. Presentation of the finished work to the final inspection and defense.

1. Fadel Adib and Dina Katabi, "See Through Walls with Wi-Fi!" , ACM Sigcomm, 2013.
2. Y. Chen, D. Lymberopoulos, J. Liu, and B. Priyantha, “FM-based Indoor Localization”, ACM Mobisys 2012.
3. J. Gummeson, P. Zhang, and D. Ganesan, “Flit: A Bulk Transmission Protocol for RFID-Scale Sensors”, ACM Mobisys 2012.
4. H. Wang, S. Sen, M. Farid, A. Elgohary, M. Youssef, and R.R. Choudhury, “No Need to War-Drive: Unsupervised Indoor Localization”, ACM Mobisys 2012.
5. M. Ra, B. Liu, T. Porta, and R. Govindan, “Medusa: A Programming Framework for Crowd-Sensing Applications”, ACM Mobisys 2012.
6. R. Balan, N. Khoa, and J. Lingxiao, “Real-Time Trip Information Service for a Large Taxi Fleet”, ACM Mobisys 2011.
7. B. Anand, K. Thirugnanam, J. Sebastian, P. Kannan, A. Ananda, M. Chan, and R. Balan, ”Adaptive Display Power Management for Mobile Games”, ACM Mobisys 2011.
8. J. Wang, F. Adib, R. Knepper, D. Katabi, and D. Rus, "RF-Compass: Robot Object Manipulation using RFIDs", ACM Mobicom 2013.
9. S. Nawaz, C. Efstratiou, and C. Mascolo, "ParkSense: A Smartphone Based Sensing System For On-Street Parking", ACM Mobicom 2013.
10. A. Patro, S. Govindan, and S. Banerjee, "Observing home wireless experience through WiFi APs", ACM Mobicom 2013.
11. M. Hoque, M. Siekkinen, and J. K. Nurminen, "Using Crowd-Sourced Viewing Statistics to Save Energy in Wireless Video Streaming", ACM Mobicom 2013.
12. K. Liu, X. Liu, and X. Li, "Guoguo: Enabling Fine-grained Indoor Localization via Smartphone", ACM Mobisys 2013.
13. R. LiKamWa, Y. Liu, N. D. Lane, and L. Zhong, "MoodScope: Building a Mood Sensor from Smartphone Usage Patterns", ACM Mobisys 2013.

Course paper defense (100%).

As a result, after the discipline laerning, the specialist must know:
• the features of informatization system platforms based on the concept of the Internet of Things;
• architectural concepts of information and communication system platform design based on the concept of the Internet of Things: a synthetic approach to RFID, sensor technology in general, wireless telecommunication systems, localization principles of "things", means of ubiquitous computing;
• theoretical and practical approaches to the development and support of information and communication technology solutions, hardware and software systems based on the concept of the Internet of Things;
• skills in the field of creation and programming of high performance and fault tolerant information and communication systems, including in the framework of the concept of the Internet of Things.

prerequisites:
• Informatics (by professions), part 1 (bachelor program);
• Informatics (by professions), part 2 (bachelor program);
• Telecommunications software (bachelor program);
• Technologies of the program platforms development;
• Distributed service systems and cloud technologies.

Introduction to the Internet of Things and ubiquitous computing. Review of current approaches and concepts. Key challenges and problems of the use of the Internet of Things and ubiquitous computing. The future of the Internet of Things. Features of teaching and assessment methods. Radio Frequency Identification Technology (RFID). Potential applications, protocols, software middleware. Security and privacy. Wireless networking platform. Mobile communication systems in IoT. Features of physical and link layer EMVVS ISO / OSI. TCP in the IoT. Efficacy and safety of wireless information and communication platforms. Sensor networks and wireless sensor network system. Basic definitions and basic technology. Difficulties and problems in the use of sensor network systems. The main limitations and problems. Technologies for localization devices in the concept of IoT. Principles and methods of detection. Geolocation systems.

1. Vinod Namboodiri, Lixin Gao, "Energy Aware Tag Anti-Collision Protocols for RFID Systems", Proceedings of IEEE Pervasive Computing (PerCom'07), March 2007.
2. Jihoon Myung, Wonjun Lee, Jaideep Srivastava, and Timothy K. Shih, “Tag-Splitting: Adaptive Collision Arbitration Protocols for RFID Tag Identification”, IEEE Transactions on Parallel and Distributed Systems, Vol. 18, No. 6, June 2007.
3. Jue Wang and Dina Katabi, "Dude, Where’s My Card? RFID Positioning That Works with Multipath and Non-Line of Sight", ACM Sigcomm, 2013.
4. Anshul Rai, Krishna Chintalapudi, Venkata N. Padmanabhan and Rijurekha Sen, “Zee: Zero-Effort Crowdsourcing for Indoor Localization”, ACM Mobicom 2012.
5. Hongbo Liu, Yu Gan, Jie Yang, Simon Sidhom, Yingying Chen and Fan Ye, “Push the Limit of WiFi based Localization for Smartphones”, ACM Mobicom 2012.
6. Tianji Li, Mi Kyung Han, Apurva Bhartia, Lili Qiu, Eric Rozner, Ying Zhang, and Brad Zarikoff, “CRMA: Collision-Resistant Multiple Access”, ACM Mobicom 2011.
7. Xinyu Zhang and Kang G. Shin, “E-MiLi: energy-Minimizing Idle Listening in Wireless Networks”, ACM Mobicom 2011.
8. Souvik Sen, Romit Roy Choudhury, and Srihari Nelakuditi, “No Time to Countdown: Migrating Backoff to the Frequency Domain”, ACM Mobicom 2011.
9. Souvik Sen, Romit Roy Choudhury, and Srihari Nelakuditi, “CSMA/CN: Carrier Sense Multiple Access with Collision Notification”, ACM Mobicom 2010.
10. Brett D. Higgins, Azarias Reda, Timur Alperovich, Jason Flinn, Thomas J. Giuli, Brian D. Noble, and David Watson, “Intentional Networking: Opportunistic Exploitation of Mobile Network Diversity”, ACM Mobicom 2010.
11. Hariharan Rahul, Farinaz Edalat, Dina Katabi, and Charles Sodini, “FARA: Frequency-aware Rate Adaptation and MAC Protocols”, ACM Mobicom 2009.
12. Anirudh Natarajan, Buddhika De Silva, Kok Kiong Yap, and Mehul Motani, “Link Layer Behavior of Body Area Networks at 2.4 GHz”, ACM Mobicom 2009.
13. Jie Liu, Bodhi Priyantha, Ted Hart, Heitor Ramos, Antonio A F Loureiro, and Qiang Wang, “Energy-Efficient GPS Sensing with Cloud Offloading”, ACM Sensys 2012.
14. Rijurekha Sen, Abhinav Maurya, Bhaskaran Raman, Rupesh Mehta, Ramakrishnan Kalyanaraman, Nagamanoj Vankadhara, Swaroop Roy, and Prashima Sharma, “Kyun Queue: A Sensor Network System To Monitor Road Traffic Queues”, ACM Sensys 2012.
15. Timothy W. Hnat, Erin Griffiths, Raymond Dawson, and Kamin Whitehouse, “Doorjamb: Unobtrusive Room-level Tracking of People in Homes using Doorway Sensors”, ACM Sensys 2012.
16. Alireza Vahdatpour, Navid Amini, and Majid Sarrafzadeh, “On-body Device Localization for Health and Medical Monitoring Applications,” IEEE Percom 2011.
17. Seyed Amir Hoseinitabatabaei, Alexander Gluhak, and Rahim Tafazolli, ”uDirect: A Novel Approach for Pervasive Observation of User Direction with Mobile Phones,” IEEE Percom 2011.
18. Haibo Ye, Tao Gu, Xiaorui Zhu, Jingwei Xu, Xianping Tao, Jian Lu, and Ning Jin, “FTrack: Infrastructure-free Floor Localization via Mobile Phone Sensing”, IEEE Percom 2012.
19. Ayan Banerjee and Sandeep Gupta, “Your Mobility can be Injurious to Your Health: Analyzing Pervasive Health Monitoring Systems under Dynamic Context Changes”, IEEE Percom 2012.
20. Sean K. Barker, Aditya Kr. Mishra, David Irwin, Prashant Shenoy, and Jeannie R. Albrecht, “SmartCap: Flattening Peak Electricity Demand in Smart Home”, IEEE Percom 2012.

• written reports on laboratory work, streaming blitz testing, evaluation of individual research tasks (defense) (40%);
• final control (60% verification event, exam), written-oral form (60%)