INSTRUCTOR: Prof. Goce Trajecvski, Office: Tech L360; Telephone: 847-491-7061; email:  

F. Zhao and L. Guibas, Wireless Sensor Networks: An Information Processing Approach, Morgan Kaufman, 2004.

1. W. Stallings, Wireless Communications and Networks, 2nd Edition, Prentice Hall, 2005.
2. I. Stojmenovic (editor) Handbook of Sensor Networks: Algorithms and Architectures, John Wiley and Sons, 2005.

(Copies will be available under “Reserve” in the Engineering Library).

EECS 343 or EECS 340 (or permission from the instructors).


1. Introduction and Applications

  • Application domains of sensor networks.
  • Enabling technologies: hardware/software platforms.
  • Performance metrics.

2. Communication Model

  • Wireless sensor architecture and protocol stack.
  • Basics of RF communication and the role of MAC.
  • Popular protocols (802.11, 802.15, Bluetooth).

3. Localization and Sensor Node Coverage

  • Global location (GPS-based) and relative location (Beacon-based).
  • Localization methods: anchor-free, anchor-based, range-free, range-based.
  • Coverage and connectivity: properties and quality aspects.

4. Routing


  • Data centric-protocols: gossiping, rumor routing, directed diffusion.
  • Hierarchical protocols: LEACH.
  • .Location-based (Geographical) protocols and energy-aware routing: GPSR, geometric spanners, distributed topology routing (PRADA).

5. Query Processing in Sensor Networks

  • Fundamentals of query approaches: push vs. pull based processing
  • Review of SQL.
  • In-network processing and aggregation: TinyDB and TAG.
  • Statistical approaches to computing aggregates: quantile-digest.
  • Robust aggregation: ODI synopses.

6. Mobility and Tracking

  • Fundamentals of query approaches: push vs. pull based processing
  • QoD/QoS issues in Event-Based Continuous Query Processing.

7. Advanced Topics

  • Security in WSN.
  • In-network storage.
  • Multi-dimensional range queries.
  • Clustering for topology management.

• Programming Projects (40%): The first programming assignment will involve programming in nesC for the purpose of basic tasks being executed on actual Telos motes under TinyOS. The second assignment will require an implementation of routing and/or network aggregation techniques, using a wireless sensor network simulator.
• Midterm (30%):
• Presentation of technical paper(s) and preparing written summaries (20%): Papers from relevant recent conferences and journals addressing contemporary
aspects related to the topics presented in the class/lectures. These presentations will take place in the last two/three weeks of the course.
• Class participation (10%): Students will be expected to read the papers covered in the last two weeks of class and participate in the discussions following the
presentations. They will also have to submit concise write-ups summarizing the pros and cons of the (most, of the) papers presented during the student-presentation-session.

COURSE OBJECTIVES: After completing this course the students should have a thorough understanding of the different issues involved in the information management in wireless sensor networks, and be comfortable with programming motes for actual applications.

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