SPATIAL SIMULATION OF SEIR EPIDEMIC MODEL USING CELLULAR AUTOMATA
Severe acute respiratory syndrome (SARS) is one of diseases that quickly spread through populations and has relatively long infection period. It has been shown that almost fifty percent of susceptible individuals that have been in contact with the infected individuals are also found to be infecte...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/37369 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Severe acute respiratory syndrome (SARS) is one of diseases that quickly spread
through populations and has relatively long infection period. It has been shown that
almost fifty percent of susceptible individuals that have been in contact with the
infected individuals are also found to be infected by SARS. At the same time, the
relatively long infection period will cause the speed of the spread increases each
day. Therefore, good analysis of SARS becomes an important matter for making
the best decision.
According to WHO, mathematics model is one of useful tools in analyzing a spreading
disease and making the best decision for it. There are many mathematics models
built using a system of ordinary differential equations and its improvements.
The combination between SEIR epidemic model and cellular automata (CA) called
SEIR-CA model is used in this research to analyze the spread of SARS in Hong
Kong at 2003. This phenomenon is chosen because of its properties are suitable
with the assumption given in the model, that is, it has incubation period, it spreads
through both direct and indirect contact between individuals, and has not been affected
by other parameters such as precautions like vaccination.
The combination of SEIR epidemic model and CA enables the disease to spread
from one to another region through indirect contacts that are given by transition
mechanism in CA’s neighborhood system. An improvement to the parameter of
neighborhood’s impact of the previously established SEIR-CA model is proposed
in this research. The simulation results of the improved SEIR-CA model show
that the model is well established for both population with uniformly distributed
individuals and randomly distributed individuals.
The improved SEIR-CA model is then tested with the parameters obtained from thedisease spread data in Hong Kong, 2003, on the population with the distribution of
the individuals is randomly generated. The simulation result shows that the graph
has similar trend with the real data. On the other hands, the graph of the simulation
results more looks like the expanded version of the real data.
In addition to the test of the model on the spread of SARS in Hong Kong, 2003,
several control mechanisms in the form of vaccination are also proposed in this
research. The vaccine is given in a constant ratio for each day with several vaccination
period. The simulation results show that the longer the vaccination period gives
greater impact to the reduction of the number of infected individuals. Furthermore,
the faster the decision of vaccination is taken can prevent the disease to spread to
other regions. |
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