Enhancing network access for highly mobile nodes
With the proliferation of mobile devices, the demand for mobile computing has called for better mobile network access technology. In particular, network access for highly mobile nodes such as vehicles is envisioned to have great significance to future transportation systems and help to fost...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2014
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| Online Access: | http://hdl.handle.net/10356/55436 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | With the proliferation of mobile devices, the demand for mobile computing has
called for better mobile network access technology. In particular, network
access for highly mobile nodes such as vehicles is envisioned to have great
significance to future transportation systems and help to foster many
attractive applications from disseminating safety information among vehicles to
downloading of multimedia infotainment content from the fixed network
infrastructure. Mobile nodes can form Mobile Ad hoc Networks (MANETs) on demand
and communicate among themselves without infrastructure support. On the other
hand, they can also exchange information with the surrounding network
infrastructure while moving. However, the high node mobility causes frequent
topology changes among mobile nodes and brief contacts between mobile nodes and
roadside infrastructure. This poses great challenges to communication within
the MANET and the data exchange between mobile nodes and roadside
infrastructure in highly mobile networks such as vehicular networks.
The author first focuses on mitigating the impact of high node mobility on the
routing in highly dynamic mobile ad hoc networks. Existing literatures propose
to use mobility based clustering schemes to form stable communication structure
among mobile nodes by exploiting group mobility. To understand the degree of
group mobility in common mobility models, particularly Manhattan mobility model
which represents urban vehicle movements, the author first proposes a group
mobility metric based on the underlying network topology to measure the degree
of group mobility for various mobility models. The author observes that in some
mobility models, including Manhattan model, no significant group mobility is
demonstrated. This suggests mobility based clustering can be ineffective in
these models.
To find an alternative solution for scenarios in which significant group
mobility is absent, the author continues to investigate the effectiveness of
deploying mobile relays with stable uplinks. The simulation results show that
the mobile relays can significantly improve network connectivity. The author
compare the effectiveness of deploying mobile relays against adding more user
nodes. The simulation results from both Manhattan and Random Waypoint mobility
models suggest that mobile relays are much more effective than adding more user
nodes. It is also observed that the path duration is usually brief in highly
mobile networks even with mobile relays. This suggests that the clustering and
routing algorithms should incur minimum delay to maximally utilize the
established paths.
Based on the above observation, the author proposes a new cluster based routing
protocol FASTR which utilizes mobile relays as backbones to mitigate the impact
of node mobility for dense networks with high node mobility and low group
mobility. The proposed scheme eliminates the delay caused by cluster head
election and enables nodes to start communication immediately after joining a
cluster. Through simulation and analysis, the protocol is shown to possess good
scalability, incur lower control overhead and achieve higher packet delivery
ratio than existing routing protocol. The control overhead of FASTR is shown to
be independent of node mobility and consumes less network resources.
On the other hand, mobile Internet access through roadside Access Points (APs)
has emerged as an alternative to cellular networks due to its high
bandwidth and low cost. However, due to the limited range and sparse deployment
of roadside APs, several issues could arise when vehicles roam between APs.
Besides the brief contact between mobile nodes and roadside infrastructure
caused by high node mobility, other issues include intermittent network
connectivity and changes in IP address. To address these issues, the author
proposes a mobile network access protocol (mNAP) for highly mobile nodes. mNAP
introduces a Terminal Local Proxy (TLP) to shield application connections from
connectivity disruptions and change of IP address such that the application
connections can be preserved across network disruption when roaming between
different APs. By enabling cooperative relaying, mNAP exploits opportunistic
contacts for additional data transfer. Through simulation, mNAP is shown to be
able to exploit both direct and indirect contact opportunities and delivers
more than existing scheme.
In addition, when vehicles roam across several APs with overlapping coverage,
it is important to provide fast and transparent mobility management for the
vehicles. To this end, the author proposes a network based local mobility
management scheme COAP for 802.11 wireless mesh networks. COAP makes use of
802.11s to forward traffic to the correct location after mobile nodes have
roamed to a different AP. Furthermore, COAP proposes a cooperative DHCP
service to ensure mobile node always obtain the same IP address within the
mesh network. It has several advantages compared to existing schemes. COAP
does not require modification on the mobile node and the mobility management
is entirely handled by the network. In addition, unlike existing Proxy
Mobile IPv6 (PMIPv6) protocol, COAP allows network based mobility across
different operator domains. In summary, COAP facilitates easy deployment
and helps to enable transparent roaming between roadside APs for mobile
nodes. |
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