Abstract
Internet of Things (IoT) has been booming with rapid increase of the various wearable devices, vehicle embedded devices, and so on, and providing the effective mobility management for these IoT devices becomes a challenge due to the different application scenarios as well as the limited energy and bandwidth. Recently, lots of researchers have focused on this topic and proposed several solutions based on the combination of IoT features and traditional mobility management protocols, in which most of these schemes take the IoT devices as mobile networks and adopt the NEtwork MObility (NEMO) and its variants to provide the mobility support. However, these solutions are in face of the heavy signaling cost problem. Since IoT devices are generally combined to realize the complex functions, these devices may have similar movement behaviors. Clearly analyzing these characters and using them in the mobility management will reduce the signaling cost and improve the scalability. Motivated by this, we propose a PMIPv6-based group binding update method. In particular, we describe its group creation procedure, analyze its impact on the mobility management, and derive its reduction ratio in terms of signaling cost. The final results show that the introduction of group binding update can remarkably reduce the signaling cost.
Highlights
According to the statistics analysis, the number of Internet of Things (IoT) devices is expected to reach up to 50 billion by 2020 [1]
When it is applied in IoT scenarios, the mobile router (MR) is generally used as the leader to perform the mobility signaling messages on behalf of all mobile network nodes
In this work we focus on group characteristics of IoT devices while studying the dynamic group management mechanism, and extending the bulk binding update
Summary
According to the statistics analysis, the number of Internet of Things (IoT) devices is expected to reach up to 50 billion by 2020 [1]. IPv6 is believed to be a suitable protocol [3] thanks to its large address space and specific mechanisms to support mobility, such as Mobile IPv6 (MIPv6) [4] and its potential solutions for mobility management. NEMO as a mobility support protocol for mobile network is derived from MIPv6 in which mobile router (MR) is introduced to deliver all the packets for mobile network nodes via the bidirectional tunnel between MR and its Home Agent (HA) [21] When it is applied in IoT scenarios, the MR is generally used as the leader to perform the mobility signaling messages on behalf of all mobile network nodes.
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