Protocols for wireless sensor networks
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Sep 14, 2020
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About This Presentation
Wireless Sensor Network (WSN) consists of sensor nodes which interact with each other through physical parameters like sunlight, wind, vibration, humidity etc. Routing protocols provide an optimal data transmission route from sensor nodes to sink node to save energy of nodes. From Base S...
Slide Content
1
Protocols for Wireless
Sensor Networks
By: Debabrata Singh
Dept. of CSIT,ITER
SOA University, Bhubaneswar
Mail: [email protected]
Protocols for Wireless
Sensor Networks
By: Debabrata Singh
Dept. of CSIT,ITER
SOA University, Bhubaneswar
Mail: [email protected]
2
Outline
Introduction
Flat Routing Protocols
Directed Diffusion
SPIN(SensorProtocolfor Information via Negotiation.)
Hierarchical Routing Protocols
LEACH(Low-energy adaptive clustering hierarchy)
PEGASIS(Power Efficient Gathering in Sensor Information
Systems)
TEEN(Threshold-sensitive energy efficient sensor network
(TEEN))
Topic for Discussion
References
Outline
Introduction
Flat Routing Protocols
Directed Diffusion
SPIN(SensorProtocolfor Information via Negotiation.)
Hierarchical Routing Protocols
LEACH(Low-energy adaptive clustering hierarchy)
PEGASIS(Power Efficient Gathering in Sensor Information
Systems)
TEEN(Threshold-sensitive energy efficient sensor network
(TEEN))
Topic for Discussion
References
3
Introduction to WSNs
A sensor network is a computer network of
many, spacially distributed devices using
sensors to monitor conditions at different
locations.
Involve three areas: sensing,
communications, and computation.
Introduction to WSNs
A sensor network is a computer network of
many, spacially distributed devices using
sensors to monitor conditions at different
locations.
Involve three areas: sensing,
communications, and computation.
4
Introduction to WSNs
Sensor nodes scattered in a sensor field
Each nodes has the capabilities to collect data and route data
back to the sink (Base Station).
Protocols and algorithms with self-organization capabilities.
Introduction to WSNs
Sensor nodes scattered in a sensor field
Each nodes has the capabilities to collect data and route data
back to the sink (Base Station).
Protocols and algorithms with self-organization capabilities.
5
Introduction-WSNs Topology
Issues related to topology maintenance and change in
three phases:
Pre-deploymentand deploymentphase:
Sensor nodes can be either thrown in mass or placed one by one in
the sensor field.
Post-deploymentphase:
Topology changes are due to change nodes' position, reachability,
available energy, malfunctioning, and task details.
Re-deployment of additional nodesphase:
Additional sensor nodes can be redeployed at any time to replace
malfunctioning nodes or due to changes in task dynamics.
Introduction-WSNs Topology
Issues related to topology maintenance and change in
three phases:
Pre-deploymentand deploymentphase:
Sensor nodes can be either thrown in mass or placed one by one in
the sensor field.
Post-deploymentphase:
Topology changes are due to change nodes' position, reachability,
available energy, malfunctioning, and task details.
Re-deployment of additional nodesphase:
Additional sensor nodes can be redeployed at any time to replace
malfunctioning nodes or due to changes in task dynamics.
6
Types of Routing Protocol for WSN
Single-hop Networks
The network consists of n nodes, and packets are
transmitted from sources to destinations directly.
Multi-hop Networks
The final destination of a packet might not be reached
directly and the other nodes can be used to route the
packet to the final destination.
Types of Routing Protocol for WSN
Single-hop Networks
The network consists of n nodes, and packets are
transmitted from sources to destinations directly.
Multi-hop Networks
The final destination of a packet might not be reached
directly and the other nodes can be used to route the
packet to the final destination.
7
Flat Routing Protocols
Flat Networks
Every incoming packet is sent out on every
outgoing lineexcept the one it arrived on.
Vast numbers of duplicate packets are
generated.
Routing Protocols: Directed Diffusion, SPIN.
Flat Routing Protocols
Flat Networks
Every incoming packet is sent out on every
outgoing lineexcept the one it arrived on.
Vast numbers of duplicate packets are
generated.
Routing Protocols: Directed Diffusion, SPIN.
8
The Directed Diffusion Protocol
Directed Diffusion consists of several
elements:
Interests
Datamessages
Gradients
Reinforcements
The Directed Diffusion Protocol
Directed Diffusion consists of several
elements:
Interests
Datamessages
Gradients
Reinforcements
9
Directed Diffusion -Interest
Propagation
The sink periodically
broadcasts an interest
messageto each of its
neighbors.
Every node maintains
an interest cache.
Directed Diffusion -Interest
Propagation
The sink periodically
broadcasts an interest
messageto each of its
neighbors.
Every node maintains
an interest cache.
10
Directed Diffusion -Gradient
Establishment
That every pair of
neighboring nodes
establishes a gradient
toward each other.
This technique can
enable fast recovery
from failed pathsor
reinforcement of
empirically better paths.
Directed Diffusion -Gradient
Establishment
That every pair of
neighboring nodes
establishes a gradient
toward each other.
This technique can
enable fast recovery
from failed pathsor
reinforcement of
empirically better paths.
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Directed Diffusion -Data
Propagation
A sensor node that detects a target, it
computes the highest requested event rate
among all its outgoing gradients.
To resend a received data message, a
node needs to examine the matching
interest entry's gradient list.
Directed Diffusion -Data
Propagation
A sensor node that detects a target, it
computes the highest requested event rate
among all its outgoing gradients.
To resend a received data message, a
node needs to examine the matching
interest entry's gradient list.
12
Directed Diffusion -Reinforcement
The node might choose
that neighbor from
whom it first received
the latest event
matching the interest to
reinforce.
It is very reactive to
changes in path quality.
Directed Diffusion -Reinforcement
The node might choose
that neighbor from
whom it first received
the latest event
matching the interest to
reinforce.
It is very reactive to
changes in path quality.
13
The SPIN Protocol
Sensor Protocols for Information via
Negotiation.
Start with a source node sending its data
to all of its neighbors.
The SPIN Protocol
Sensor Protocols for Information via
Negotiation.
Start with a source node sending its data
to all of its neighbors.
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SPIN -Flooding deficiencies
Implosion & Overlap
(a)
(a)
(a)
A
B C
D
(a)
(r, s)(q, r)
A B
C
q s
r
Implosion Problem Overlap Problem
SPIN -Flooding deficiencies
Implosion & Overlap
(a)
(a)
(a)
A
B C
D
(a)
(r, s)(q, r)
A B
C
q s
r
Implosion Problem Overlap Problem
15
SPIN-1 -three types of messages
ADV
When a SPIN node has data to share, it can advertise
an ADV message containing meta-data.
REQ
A SPIN node sends an REQ message when it wishes
to receive some actual data.
DATA
DATA messages contain actual sensor data with a
meta-data header.
SPIN-1 -three types of messages
ADV
When a SPIN node has data to share, it can advertise
an ADV message containing meta-data.
REQ
A SPIN node sends an REQ message when it wishes
to receive some actual data.
DATA
DATA messages contain actual sensor data with a
meta-data header.
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ADVREQ
The SPIN-1 Protocol
Steps
B A
C
D
E
F
DATA
ADV
ADV
ADV
ADVREQ
REQ
DATA
DATA
ADVREQ
The SPIN-1 Protocol
Steps
B A
C
D
E
F
DATA
ADV
ADV
ADV
ADVREQ
REQ
DATA
DATA
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The SPIN-2 Protocol
When energy is plentiful, SPIN-2 nodes
communicate using the same 3-stage
protocol as SPIN-1 nodes.
When a SPIN-2 node observes that its
energy is approaching a low-energy
threshold, it adapts by reducing its
participation in the protocol.
The SPIN-2 Protocol
When energy is plentiful, SPIN-2 nodes
communicate using the same 3-stage
protocol as SPIN-1 nodes.
When a SPIN-2 node observes that its
energy is approaching a low-energy
threshold, it adapts by reducing its
participation in the protocol.
18
Hierarchical Routing Protocols
Hierarchical Networks
The main aim of hierarchical routing is to
efficiently maintain the energy consumptionof
sensor nodes.
Performing data aggregation and fusionin
order to decrease the number of transmitted
messages to the sink.
Routing Protocols: LEACH, PEGASIS, TEEN.
Hierarchical Routing Protocols
Hierarchical Networks
The main aim of hierarchical routing is to
efficiently maintain the energy consumptionof
sensor nodes.
Performing data aggregation and fusionin
order to decrease the number of transmitted
messages to the sink.
Routing Protocols: LEACH, PEGASIS, TEEN.
19
The LEACH Protocol
Low-Energy Adaptive Clustering Hierarchy.
Distributed cluster formation technique
that enables self-organizationof large
numbers of nodes.
The LEACH Protocol
Low-Energy Adaptive Clustering Hierarchy.
Distributed cluster formation technique
that enables self-organizationof large
numbers of nodes.
20
LEACH -Cluster
Algorithms for adapting clusters and rotating cluster
headpositions to evenly distribute the energy load
among all the nodes.
The nodes organize themselves into local clusters, with
one node acting as the cluster head.
The cluster headperforms signal processing functions
on the data, and transmits data to the remote BS.
LEACH -Cluster
Algorithms for adapting clusters and rotating cluster
headpositions to evenly distribute the energy load
among all the nodes.
The nodes organize themselves into local clusters, with
one node acting as the cluster head.
The cluster headperforms signal processing functions
on the data, and transmits data to the remote BS.
21
LEACH -Set-up phase
Cluster Head
Each cluster head node broadcasts an advertisement
message(ADV)let all the other nodes that they have
chosen this role for the current round.
Non-Cluster Head
They transmits a join-request message(Join-REQ)
back to the chosen cluster head.
LEACH -Set-up phase
Cluster Head
Each cluster head node broadcasts an advertisement
message(ADV)let all the other nodes that they have
chosen this role for the current round.
Non-Cluster Head
They transmits a join-request message(Join-REQ)
back to the chosen cluster head.
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LEACH -Set-up phase
The cluster head node sets up a TDMA
scheduleand transmits this schedule to the
nodes in the cluster.
Ensures that there are no collisionsamong data
messages.
Allows the radio components to be turned offat
all times except during their transmit time.
LEACH -Set-up phase
The cluster head node sets up a TDMA
scheduleand transmits this schedule to the
nodes in the cluster.
Ensures that there are no collisionsamong data
messages.
Allows the radio components to be turned offat
all times except during their transmit time.
23
LEACH -Steady-state phase
Broken into frames, where nodes send
their data to the cluster head at most once
per frame during their allocated
transmission slot.
Once the cluster head receives all the data,
it performs data aggregation.
LEACH -Steady-state phase
Broken into frames, where nodes send
their data to the cluster head at most once
per frame during their allocated
transmission slot.
Once the cluster head receives all the data,
it performs data aggregation.
24
LEACH -Time line
Time line showing LEACH operation
NCH
1NCH
2… … …NCH
m-1NCH
m
Slot for NCH
2
Frame
ADVJoin-REQSCH
Set-up phase
LEACH -Time line
Time line showing LEACH operation
NCH
1NCH
2… … …NCH
m-1NCH
m
Slot for NCH
2
Frame
ADVJoin-REQSCH
Set-up phase
25
The PEGASIS Protocol
Power-Efficient GAthering in Sensor
Information Systems.
The key idea in PEGASIS is to form a
chainamong the sensor nodes so that
each node will receive from and
transmit to a close neighbor.
The PEGASIS Protocol
Power-Efficient GAthering in Sensor
Information Systems.
The key idea in PEGASIS is to form a
chainamong the sensor nodes so that
each node will receive from and
transmit to a close neighbor.
26
PEGASIS -Chain
The nodes will be organized to form a
chain, which can either be accomplished
by the sensor nodes themselves using a
greedy algorithmstarting from some node.
When a node dies, the chain is
reconstructedin the same manner to
bypass the dead node.
PEGASIS -Chain
The nodes will be organized to form a
chain, which can either be accomplished
by the sensor nodes themselves using a
greedy algorithmstarting from some node.
When a node dies, the chain is
reconstructedin the same manner to
bypass the dead node.
27
PEGASIS -Leader
The main idea in PEGASIS is for each node to
receive from and transmit to close neighbors
and take turns being the leader for transmission
to the BS.
Nodes take turns transmitting to the BS, and we
will use node number i mod N(N represents the
number of nodes) to transmit to the BS in round i.
PEGASIS -Leader
The main idea in PEGASIS is for each node to
receive from and transmit to close neighbors
and take turns being the leader for transmission
to the BS.
Nodes take turns transmitting to the BS, and we
will use node number i mod N(N represents the
number of nodes) to transmit to the BS in round i.
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PEGASIS -Token
Token passing approach
N0 N1 N2 N3 N4
BS
Token
Data
PEGASIS -Token
Token passing approach
N0 N1 N2 N3 N4
BS
Token
Data
29
The TEEN Protocol
Threshold sensitive Energy Efficient sensor Network
protocol.
Proactive Protocols (LEACH)
The nodes in this network periodicallyswitch on their sensors
and transmitters, sense the environment and transmit the data of
interest.
Reactive Protocols (TEEN)
The nodes react immediately to suddenand drastic changesin
the value of a sensed attribute.
The TEEN Protocol
Threshold sensitive Energy Efficient sensor Network
protocol.
Proactive Protocols (LEACH)
The nodes in this network periodicallyswitch on their sensors
and transmitters, sense the environment and transmit the data of
interest.
Reactive Protocols (TEEN)
The nodes react immediately to suddenand drastic changesin
the value of a sensed attribute.
30
TEEN -Functioning
At every cluster change time, the cluster-head
broadcasts to its members
Hard Threshold (HT)
This is a threshold value for the sensed attribute.
It is the absolute value of the attribute beyond which, the
node sensing this value must switch on its transmitter and
report to its cluster head.
Soft Threshold (ST)
This is a small change in the value of the sensed attribute
which triggers the node to switch on its transmitter and
transmit.
TEEN -Functioning
At every cluster change time, the cluster-head
broadcasts to its members
Hard Threshold (HT)
This is a threshold value for the sensed attribute.
It is the absolute value of the attribute beyond which, the
node sensing this value must switch on its transmitter and
report to its cluster head.
Soft Threshold (ST)
This is a small change in the value of the sensed attribute
which triggers the node to switch on its transmitter and
transmit.
31
TEEN -Hard Threshold
The first time a parameter from the
attribute set reaches its hard threshold
value, the node switches on its transmitter
and sends the sensed data.
The sensed value is storedin an internal
variable in the node, called the sensed
value (SV).
TEEN -Hard Threshold
The first time a parameter from the
attribute set reaches its hard threshold
value, the node switches on its transmitter
and sends the sensed data.
The sensed value is storedin an internal
variable in the node, called the sensed
value (SV).
32
TEEN -Soft Threshold
The nodes will next transmit data in the
current cluster period, only when boththe
following conditions are true:
The current value of the sensed attribute is
greater than the hard threshold.
The current value of the sensed attribute
differs from SV by an amount equal to or
greater than the soft threshold.
TEEN -Soft Threshold
The nodes will next transmit data in the
current cluster period, only when boththe
following conditions are true:
The current value of the sensed attribute is
greater than the hard threshold.
The current value of the sensed attribute
differs from SV by an amount equal to or
greater than the soft threshold.
33
TEEN -Drawback
If the thresholds are not reached, the user
will not get any data from the network at all
and will not come to know even if all the
nodes die.
This scheme practical implementation
would have to ensure that there are no
collisionsin the cluster.
TEEN -Drawback
If the thresholds are not reached, the user
will not get any data from the network at all
and will not come to know even if all the
nodes die.
This scheme practical implementation
would have to ensure that there are no
collisionsin the cluster.
34
References
I.F. Akyildiz, W. Su*, Y. Sankarasubramaniam, and E. Cayirci,
"Wireless sensor networks: a survey".
K. Akkaya, M. Younis,
"A Survey on Routing Protocols for Wireless Sensor Networks".
J.N. Al-Karaki, A.E. Kamal,
"Routing Techniques in Wireless Sensor Networks".
C. Intanagonwiwat, R. Govindan, and D. Estrin,
"Directed Diffusion: A Scalable and Robust Communication Paradigm for Sensor Networks".
W. Heinzelman, J. Kulik, and H. Balakrishnan,
"Adaptive Protocols for Information Dissemination in Wireless Sensor Networks".
W. Heinzelman, A. Chandrakasan, and H. Balakrishnan,
"An Application-Specific Protocol Architecture for Wireless Microsensor Networks".
S. Lindsey and C. Raghavendra,
"PEGASIS: Power-Efficient Gathering in Sensor Information Systems".
A. Manjeshwar and D. Agrawal,
"TEEN: A Routing Protocol for Enhanced Efficiency in Wireless Sensor Networks".
References
I.F. Akyildiz, W. Su*, Y. Sankarasubramaniam, and E. Cayirci,
"Wireless sensor networks: a survey".
K. Akkaya, M. Younis,
"A Survey on Routing Protocols for Wireless Sensor Networks".
J.N. Al-Karaki, A.E. Kamal,
"Routing Techniques in Wireless Sensor Networks".
C. Intanagonwiwat, R. Govindan, and D. Estrin,
"Directed Diffusion: A Scalable and Robust Communication Paradigm for Sensor Networks".
W. Heinzelman, J. Kulik, and H. Balakrishnan,
"Adaptive Protocols for Information Dissemination in Wireless Sensor Networks".
W. Heinzelman, A. Chandrakasan, and H. Balakrishnan,
"An Application-Specific Protocol Architecture for Wireless Microsensor Networks".
S. Lindsey and C. Raghavendra,
"PEGASIS: Power-Efficient Gathering in Sensor Information Systems".
A. Manjeshwar and D. Agrawal,
"TEEN: A Routing Protocol for Enhanced Efficiency in Wireless Sensor Networks".
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