2009-04-27

[Tccc] Call for Chapter Proposals:ZigBee Network Protocols and Applications

(Please accept our apologies for multiple postings of this Call for Papers)

******** Call for Chapter Proposals ********

You are invited to propose papers for a BOOK on:

*ZigBee Network Protocols and Applications*

(To be published by Auerbach Publications, CRC Press, Taylor & Francis
Group)

*SCOPE*

ZigBee is a new standard for near-field wireless communications. It was
developed by the ZigBee Alliance, which is a global ecosystem of over 200
major OEMs creating wireless solutions for home, commercial and industrial
applications, focusing on standardizing and enabling interoperability of
products. ZigBee can provide a cost-effective and energy-efficient means for
short-range networking and it is a promising candidate for
energy-constrained applications, such as wireless sensor networks. Moreover,
it is the only global wireless communication standard for the development of
easily deployed, low-power consumption products. Several multi-billion
dollar OEMs, as well as major suppliers, support the ZigBee Alliance.
Compared with other wireless communication technology, such as Bluetooth,
WiFi and UWB, ZigBee is more reliable, cheaper, and importantly more
energy-conservative.

The protocol stack of ZigBee is compact and its size is only 4-32 KB, which
can be compatible with 8-bits micro-processors. An integrated protocol stack
of ZigBee consists of four top-down layers: application layer, network
layer, MAC layer and PHY layer. The PHY and MAC layers adopt the standard of
IEEE802.15.4, which makes the solutions independent of RF IC vendors due to
the 2.4GHz standardized radio by IEEE 802.15.4. Therefore, ZigBee is more
cost-effective for designing short-range wireless communication
applications. Based on the PHY and MAC layers, the specifications of ZigBee
introduce reliable and secure network topologies, including mesh, star and
cluster-tree topology. The upper layers, however, can be specified by the
OEMs for specific design requirements. For example, the design of routing
protocols for WSNs always needs to be energy-efficient. In addition, we also
can exploit adaptive cross-layer design for performance optimization.

Usually, the applications based on ZigBee are generally low-power, flexible
and easily deployable. Hence, some issues in the design of ZigBee networks
should be considered, including power management, security, quality of
service, reliability and dependability, topology control, routing protocol,
MAC protocol and so on. Typically, the efficient power management is much
important. In addition, due to the vulnerability of wireless channel,
security control mechanism needs to be incorporated into the design of
ZigBee networks. Although people more likely realize specific designs
through high-layer protocol adaptation, the MAC layer can be also adjusted
or improved accodingly.

ZigBee networks has the following requirements and features: low power
assumption, low cost, low packet throughput, lots of network nodes, low
request on quality of service, security control, complicated topology, high
reliability. Therefore, it has been becoming widely used in many
applications, e.g., medical industry, home networking, location and
position, industrial automation, intelligent monitoring and control,
telecommunication, wireless sensor networks and etc. Many OEMs are currently
available to provide different solutions and tools for developing various
ZigBee-based applications.

*TOPICS*

Prospective subject areas and specific topics for this publication include,
but are not limited to, the following

*Part 1: Background*

Near-Field Communications (NFC) and Low-Power Communications

Brief Introduction ZigBee, Bluetooth, WiFi, UWB, and Wireless USB

* *

*Part 2: ZigBee Standards and Protocols*

ZigBee Architecture (ZigBee and IEEE 802.15.4)

ZigBee Physical Techniques

ZigBee MAC Protocols

ZigBee Network Protocols

ZigBee Application Protocols

Performance Analysis of ZigBee Networks

*Part 3: Other Issues and Improvements of ZigBee*

Power Management in ZigBee Networks

Security Issues in ZigBee Networks

Quality of Service in ZigBee Networks

Reliability and Dependability of ZigBee Networks

Topology Control in ZigBee Networks

Advanced MAC Protocols for ZigBee Networks

Advanced/Mesh Routing Protocols for ZigBee Networks

Transport Protocols for ZigBee Networks

*Part 4: ZigBee Applications and Testbeds*

ZigBee Applications in Medical Fields

ZigBee in Home Networking

ZigBee-based Location and Positioning

ZigBee in Industrial Automation

ZigBee in Intelligent monitoring and Control

ZigBee in Telecommunications

ZigBee in Wireless Sensor Networks

ZigBee Product Development Tools and Examples

Voice Communications over ZigBee

*Part 5: ZigBee versus Other Standards/Protocols*

ZigBee and 6LoWPAN

ZigBee and Z-Wave

ZigBee and Wireless Hart

ZigBee and RFID

ZigBee and ISA100

*IMPORTANT DATES*

Proposal submission: Apr. 30, 2009

Notification of proposal acceptance: Jun 8, 2009

Full chapter submission: Sept. 7, 2009

Review report received: Nov 1, 2009

Final version submission: Jan 11, 2010

*SUBMISSION GUIDELINES*

Potential prestigious authors in the fields of interest will be selectively
invited to submit a 1-2 pages proposal describing the topic of their
chapters. The proposal should include the chapter outline, the number of
pages of the final manuscript and authors' detail contact information.

Please send inquiries or submit material electronically (Rich Text files) to
editors at

Dr. Chonggang Wang

NEC Labs of America, USA

Email: cgwang@ieee.org

Dr. Tao Jiang

Huazhong University of Science and Technology, Wuhan, P. R. China

Email: Tao.Jiang@ieee.org <yanzhang@ieee.org>

Dr. Qian Zhang

Hong Kong University of Science and Technology, Hongkong, P. R. China

Email: qianzh@cs.ust.edu

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