Self-Organizing Wireless Networks Training
|Commitment||2 days, 7-8 hours a day.|
|How To Pass||Pass all graded assignments to complete the course.|
|User Ratings||Average User Rating 4.8 See what learners said|
|Delivery Options||Instructor-Led Onsite, Online, and Classroom Live|
Self-Organizing Wireless Networks Training Course – Hands-on
Self-Organizing Wireless Networks Training Course – Customize it
- We can adapt this training course to your group’s background and work requirements at little to no added cost.
- If you are familiar with some aspects of this training course, we can omit or shorten their discussion.
- We can adjust the emphasis placed on the various topics or build the training around the mix of technologies of interest to you (including technologies other than those included in this outline).
- If your background is nontechnical, we can exclude the more technical topics, include the topics that may be of special interest to you (e.g., as a manager or policy-maker), and present the training course in manner understandable to lay audiences.
Self-Organizing Wireless Networks Training Course – Audience/Target Group
The target audience for this training course:
Self-Organizing Wireless Networks Training Course – Objectives:
Upon completing this training course, learners will be able to meet these objectives:
- Why can be accomplished using ad hoc mote networks?
- What are “motes”?
- What missions are achievable with mote fields?
- What are the limitations and strengths associated with mote fields?
- How does one deploy motes, effectively?
- Which sensor technologies are suited for low-power mote applications?
- How do systems get integrated into “useable” systems and architectures?
- How do I size mote fields?
- How do I localize motes?
- What exfiltration routes exist to get data out and commands in?
- How do I program motes? And how would I reprogram motes?
- What programming can I employ? (What middleware resources available to me?)
- How to command and control unattended sensors? What are the emerging architectures to accomplish such (e.g., PULSEnet)?
Self-Organizing Wireless Networks Training – Course Content
Mote Definitions. What is a mote? Fundamental building blocks that comprise a mote core. Subsystem designs and implementations. Review of ad hoc network reviewed.
Mote Design. Mote design goals and objectives. Descriptions and examples of mote subsystems. Mote sensor systems descriptions and examples. Passive sensors, RF (ultrawideband, UWB) sensors, active-optical sensors, olfactory-based sensors.
Mote RF Design. RF propagation at ground level. RF designs. RF reliability.
Mote Programming. Review of network management systems (NMS), employing low-power media Access Communications (LPMAC). Middleware functionality. Mote constraints. Distributed sensor, signal, and data processing.
Mote Field Architecture. Self-organizing capability. Mote field logistics. Mote field initialization. Localization techniques. Relay definition and requirements. Interfaces to backhaul data communications, interfaces: Cellular, SATCOM, LP-SEIWG-005A, UHF, other.
Mission Analysis. Mission definition and needs. Mission planning. Interaction between mote fields and sophisticated sensors. Mote/sensor selection. Distribution of motes. Deployment mechanisms. Relay statistics. Exfiltration capabilities.
Situational Awareness. Situational displays employed. Sensor injection design rules and examples. Display capabilities and examples, including: C2PC. COT. Falcon View. PULSEnet.
Self-Organizing Wireless Networks Training – Design of systems. Area persistent surveillance. MOUT application.