The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
This R package provides a user-friendly application for epiworldR, a wrapper of the C++ library epiworld. It provides a general framework for modeling disease transmission using agent-based models. Some of the main features include:
You can find more examples on the package’s website: https://uofuepibio.github.io/epiworldRShiny/
You can install the development version of epiworldRShiny from GitHub with:
::install_github("UofUEpiBio/epiworldRShiny") devtools
Or from CRAN
install.packages("epiworldRShiny")
To run this ShinyApp, you need to type the following:
::run_app() epiworldRShiny
This first example demonstrates how to run the Shiny app, run a simulation, and observe results. Notice the sidebar contains many disease and model parameters that can be altered. Changing these parameters will affect the spread of the infectious disease in the simulated population. After running the simulation, a plot of the distribution of states over time, a plot of the disease’s reproductive number, a model summary, and a table of counts over time are displayed.
This example features: - SEIR network model for COVID-19
The day of peak infections occurs on day 12, maxing at about 18,000
infections.
- The disease spreads rapidly at the simulation’s beginning, drastically
decreasing over the first ten days.
- Model summary
- State counts table
This example features the implementation of the vaccine and school closure interventions to curb disease spread. All model output can be interpreted using the same logic from example #1.
Key features: - SEIRD network model for COVID-19
- Vaccine prevalence = 70%
- School closure prevalence = 50%
- Day of school closure implementation = 7
- Significantly decreased number of infections and deaths.
- The majority of the population recovered or was susceptible by day
30.
The last example features the SEIR equity model. This model is unique because it accounts for demographic diversity in a population, such as race, gender, and age. This allows for comparing disease spread among different demographics, unlike the previous two examples.
Key features: - SEIR equity model for COVID-19 - 30% hispanic population, 70% non-hispanic - 52% female population - 30% of population younger than 20 years old - 30% of population between 20 and 60 years old - 40% of population older than 60.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.