This is to avoidgetting duplicated

This is to avoid
getting duplicated messages. Also, when the power
level of the sensor node is low, the sensor node
broadcasts to its neighbors that it is low in power
and cannot participate in routing messages. The
remaining power is reserved for sensing. The mobility
management plane detects and registers the
movement of sensor nodes, so a route back to the
user is always maintained, and the sensor nodes
can keep track of who are their neighbor sensor
nodes. By knowing who are the neighbor sensor
nodes, the sensor nodes can balance their power
and task usage. The task management plane balances
and schedules the sensing tasks given to a
specific region. Not all sensor nodes in that region
are required to perform the sensing task at the
same time. As a result, some sensor nodes perform
the task more than the others depending on their
power level. These management planes are needed,
so that sensor nodes can work together in a power
efficient way, route data in a mobile sensor network,
and share resources between sensor nodes.
Without them, each sensor node will just work
individually. From the whole sensor network
standpoint, it is more efficient if sensor nodes can
collaborate with each other, so the lifetime of the
sensor networks can be prolonged. Before we discuss
the need for the protocol layers and management
planes in sensor networks, we map three
existing work [42,69,77] to the protocol stack as
shown in Fig. 3.
The so-called WINS is developed in [69], where
a distributed network and Internet access is provided
to the sensor nodes, controls, and processors.
Since the sensor nodes are in large number,
the WINS networks take advantage of this short
distance between sensor nodes to provide multi
hop communication and minimize power consumption.
The way in which data is routed back to
the user in the WINS networks follows the architecture
specified in Fig. 2. The sensor node, i.e., a
WINS node, detects the environmental data, and
the data is routed hop by hop through the WINS
nodes until it reaches the sink, i.e., a WINS gateway.
So the WINS nodes are sensor nodes A, B, C,
Fig. 3. The sensor networks protocol stack.
Fig. 2. Sensor nodes scattered in a sensor field.
I.F. Akyildiz et al. / Computer Networks 38 (2002) 393–422 405
D, and E according to the architecture in Fig. 2.
The WINS gateway communicates with the user
through conventional network services, such as the
Internet. The protocol stack of a WINS network
consists of the application layer, network layer,
MAC layer, and physical layer. Also, it is explicitly
pointed out in [69] that a low-power protocol suite
that addresses the constraints of the sensor networks
should be developed.