AUTONOMOUS ROBOT NAVIGATION SYSTEM WITH COMBINATION OF SLAM, GDM AND ANEMOTAXIS FOR GAS SOURCE LOCALIZATION
Disaster management is hazardous for humans, especially when measuring and sampling disaster data. Remote data measurement and sampling are needed to reduce risks and hazards. One solution that can be done is the use of moving robots to replace the human role in these activities. Research on mob...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/69903 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Disaster management is hazardous for humans, especially when measuring
and sampling disaster data. Remote data measurement and sampling are
needed to reduce risks and hazards. One solution that can be done is the use
of moving robots to replace the human role in these activities. Research on
mobile robots that detect hazardous chemicals (olfactory sensing capabilities),
and hazardous gases, continues to grow. The field of research on robots
engaged in this field is called Mobile Robot Olfaction (MRO). The robot can
provide real-time data on gas concentrations and contaminated environmental
conditions. Localization of gas sources or Gas source localization (GSL) is one
of the studies in MRO. Localization of gas sources means finding the position
of sources around the environment through the distribution of gas carried by
the wind. Research on the GSL problem in an unknown environment is still
very open. This dissertation research aims to find a single gas source using a
single robot and multiple robots in an unknown environment. A robotic
autonomous navigation system for GSL is proposed by combining simultaneous
localization and mapping (SLAM), gas distribution mapping (GDM) and
Anemotaxis. The research developed an evaluation algorithm to determine the
exploratory destination points: Frontier-multi-criteria decision-making
(MCDM) and Anemotaxis-GDM. Both algorithms aim to move the robot
effectively towards the gas source. The robot uses Frontier-MCDM to select
candidate destinations to find gas-contaminated areas. Anemotaxis-GDM is
used for tracking gas sources when robotic gas sensors detect gas
concentrations. Research on tracing gas sources by combining the anemotaxis
and SLAM-GDM (Anemotaxis-GDM) methods has yet to be carried out, so it
is an opportunity to contribute to this dissertation research. Anemotaxis-GDM
ensures that the robot moves in areas with high gas concentrations to estimate
the location of gas sources better. The task allocation method was developed
to support multi-robot collaboration in GSL applications. A combination of the
Frontier-MCDM algorithm and PROMETHEE II-based task allocation is used
to delegate exploration tasks to each robot. This method aims to select target
candidates by involving data from each robot, dividing exploration tasks and
carrying out the coordination process. Several simulations and tests in the
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natural environment were conducted to test and validate all algorithms. The
test results validate the effectiveness of the Frontier-MCDM, Anemotaxis-
GDM and PROMETHEE II-based task allocation algorithms. |
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