MATHEMATICAL MODEL OF DENGUE TRANSMISSION INVOLVES MOBILITY AND CLIMATE FACTORS USING CLUSTERING METHOD
Dengue is a disease that can be fatal and has been frequently reported to increase dramatically in recent years. Based on reports from the World Health Organization (WHO), dengue is also included in the list of ten diseases that cause the highest mortality in the world. The emergence of outbreaks...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/51324 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Dengue is a disease that can be fatal and has been frequently reported to increase
dramatically in recent years. Based on reports from the World Health Organization
(WHO), dengue is also included in the list of ten diseases that cause the highest
mortality in the world. The emergence of outbreaks every year in many countries
indicates the complexity of dengue prevention and control. It is a big challenge for
researchers and policymakers to understand the spread and establish dengue early
warning systems.
Climatology factors such as rainfall, humidity, and temperature are known as the
primary determinant in the intensity of the dengue incidence. The appropriate
conditions of rainfall, humidity, and temperature can help vectors to multiply
optimally in their ecosystem. This climate information then plays a critical role
in the spread of the dengue virus as the main factor supporting vector dynamics,
which is difficult to predict. On the other hand, increasing population density and
human mobility allow viruses to spread and multiply in non-endemic areas.
This study discusses mathematical models of dengue virus transmission that involve
mobility and climate factors using a clustering method. First, host-vector deterministic
and stochastic models in closed populations are reviewed and validated using
dengue incidence data. However, the autonomous models can only cover the data in
an outbreak period. Therefore, a non-autonomous dengue model was constructed
to cover and analyze the seasonal effects of dengue incidences and their infection
rates. This periodicity is also shown by dengue incidence and climate data that have
been reported for several years by Health Office and Meteorology, Climatology and
Geophysics Agency (BMKG), respectively.
Climate factors are then involved in constructing of the dengue transmission model
using multiple regression models integrated with a clustering method. The climate
variables used in this study are rainfall and humidity. This clustering is used to
distinguish the effects of different climatic conditions on dengue cases. The optimal
barriers are then obtained by using a Particle Swarm Optimization method, which
minimizes the residual. Furthermore, the dengue dynamics model involving climate
factors contained in the infection rate parameter and other parameters in vector
dynamics are constructed to analyze the relationship between host-vector dynamics
and climate.
At the end of this study, a dengue dynamics model was constructed by involving the
mobility and climate factors integrated with a clustering method, which can be used
as dengue prediction. This study can be used as an early effort to prevent dengue
spatially and temporally. The spatial distribution pattern and the spatial correlation
of dengue incidences were investigated at the end of this study. This study is
very beneficial for the relevant health offices and policymakers as consideration for
making optimal and efficient intervention efforts. |
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