IMPROVEMENT OF TOPOLOGY CONTROL PERFORMANCE WITH NODE RANK AND REINFORCEMENT LEARNING METHOD ON CDMA WIRELESS SENSOR NETWORK
A high-capacity and energy-efficient wireless sensor network will be needed to accommodate the exponential traffic increase in the 5th and 6th generation (5G / 6G) communication systems or the internet of things (IoT) generation. Currently, wireless sensor networks apply the low energy adaptive c...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/53233 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | A high-capacity and energy-efficient wireless sensor network will be needed to
accommodate the exponential traffic increase in the 5th and 6th generation (5G /
6G) communication systems or the internet of things (IoT) generation. Currently,
wireless sensor networks apply the low energy adaptive clustering hierarchy
(LEACH) algorithm, where the cluster head (CH) selection is randomized. As a
result, the distance between member nodes to CH can be far apart so that the sensor
will transmit power with high power, which will further cause interference and
waste energy. The LEACH algorithm also uses a static power control so that the
received signal to interference and noise ratio (SINR) signals in the CH can be
decreased if the interference increases. The LEACH algorithm needs to be
improved to increase network capacity and save energy.
This dissertation develops a new algorithm by re-selecting CH, using the node rank
method and reinforcement learning power control. With the node rank method, the
method selects CH from the sensor with the most significant rank contributing from
the largest number of neighboring nodes and high residual energy to balance
energy consumption. The sensor determines neighboring nodes from nodes that
have received signal strength indicator (RSSI) values above the current CH's
average RSSI value. With the proposed method, the distance of member nodes to
CH will shorten. The decreased distance will reduce the sensor's transmit power.
Interference is also further suppressed by transmission power control techniques
using a dual policy multi-agent reinforcement learning algorithm using SINR as a
control parameter. The use of the reinforcement learning (RL) method will enable
the sensor to track SINR fluctuations due to interference changes so that the
transmit power of the sensor will be adjusted according to the minimum
requirement.
Testing the proposed node rank and reinforcement learning is carried out by
computer simulation using a randomly wireless sensor network model with uniform
distribution. Wireless network propagation channels use the free space path loss
model (for short-range representation) and the two-ray ground channel model (for
longer distance representation). The simulation shows that the proposed node rank
algorithm performance is better than the conventional LEACH. The indicator
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improvements are a network lifetime growth by 8%, first node death (FND) growth
by 9%, half node death (HND) growth by 14%, and delivered packets by 11%. The
performance improvement is due to the formation of a closer distance between the
node and the CH. The simulation also shows that the proposed power control is
better than static power control used by conventional LEACH. The improvements
consist of an increase in the network lifetime by 129%, FND by 52%, HND by 35%,
and delivered packets by 162%. It can be explained that with the SINR fluctuation
tracking capability, the sensor transmit power will meet the minimum requirement.
In addition to suppressing interference, low (minimum) transmit power will also
save energy consumption simultaneously. Controlling the transmit power using
SINR as a control parameter gives better results than the signal strength (RSSI)
because SINR involves the level of interference in controlling the sensor's transmit
power. |
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