Optimized scheme for efficient and scalable key management in IEEE 802.16e-based networks
The computer industry has defined the IEEE 802.16 family of standards that will enable mobile devices to access a broadband network as an alternative to digital subscriber line (DSL) technology. Based on this standard, WiMAX which stands for worldwide interoperability for microwave access, was...
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| Main Author: | |
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| Format: | Thesis |
| Language: | English |
| Published: |
2015
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| Online Access: | http://psasir.upm.edu.my/id/eprint/67716/1/FK%202015%20126%20IR.pdf http://psasir.upm.edu.my/id/eprint/67716/ |
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| Institution: | Universiti Putra Malaysia |
| Language: | English |
| Summary: | The computer industry has defined the IEEE 802.16 family of standards that will
enable mobile devices to access a broadband network as an alternative to digital
subscriber line (DSL) technology. Based on this standard, WiMAX which stands
for worldwide interoperability for microwave access, was introduced by an
industry consortium called WiMAX Forum, to offer a broadband wireless access
to a plethora of mobile devices such as lap top, smart phones, and potentially any
other network of devices. Subsequently, Mobile WiMAX was developed based on
IEEE802.16e to support mobility where mobile devices can then roam from one
coverage area to the next and remain connected.
As the mobile devices join and leave a network, security measures must be taken
to ensure the safety of the network against unauthorized usage by encryption and
key management. IEEE 802.16e uses multicast and broadcast service (MBS) as an
efficient mechanism to distribute the same data concurrently to multiple mobile
stations (MSs) through one Base Station. To generate, update and distribute the
keys for secure communication over IEEE 802.16e, the MBS applies Multicast
and Broadcast Rekeying Algorithm (MBRA) as a basic key management
algorithm. The main performance parameters of group key management schemes
are typically communications, computation and storage cost as well as scalability
and energy efficiency.
This thesis focuses on improving group key management performance in IEEE
802.16e. In general, there is a trade-off among the communications, computation
and storage costs of key management scheme. The aim is to enhance the group
key management performance by providing a good trade-off among the
communications, computation and storage costs. In addition, the proposed scheme
should guarantee network scalability and consumes less energy upon rekeying
process.First, a new key management scheme called Scalable and Efficient Key
Management Protocol (SEKMP) is proposed. It is built on two tree data structures
that organize the MSs into subgroups which enable it to manage the group keys
effectively. One of the trees is a binary tree data structure and the other is a B-tree
data structure. The aim of SEKMP is to seek a balance between various
performance parameters.
Next, an enhanced version of the proposed Scalable and Efficient Key
Management Protocol called extended SEKMP (E-SEKMP) is developed based
on SEKMP. E-SEKMP works by arranging the MSs into three main groupings
based on their duration of stay in the cell, which in turn depends on the speeds of
the respective MSs.
Simulation results show that SEKMP achieves a better balance among the
performance parameters compared against the other schemes, while E-SEKMP
shows reduced communications costs and energy consumptions. In terms of
communications costs, the proposed scheme shows 77.41% improvement in
comparison to MBRA, and an average of 47.87% improvement over ELAPSE in
all modes, while in energy consumptions, the proposed scheme consumes less
energy with an average of 38.27% improvement over that of ELAPSE. In terms of
scalability, the proposed scheme shows 94.18% improvement compared to
MBRA and 61.15% compared to ELAPSE. |
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