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https://github.com/stewid/siminf

A framework for data-driven stochastic disease spread simulations
https://github.com/stewid/siminf

cran data-driven epidemiology high-performance-computing markov-chain mathematical-modelling r

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A framework for data-driven stochastic disease spread simulations

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README 

        
```{r, setup, echo = FALSE, message = FALSE}

knitr::opts_chunk$set(

  comment = "#>",

  tidy = FALSE,

  error = FALSE,

  fig.width = 8,

  fig.height = 8,

  fig.path = "man/figures/README-")

```



![](https://raw.githubusercontent.com/stewid/SimInf/main/logo/logo.png)



> A flexible and efficient framework for data-driven stochastic disease spread simulations



[![Build Status](https://github.com/stewid/SimInf/actions/workflows/R-CI.yaml/badge.svg)](https://github.com/stewid/SimInf/actions/workflows/R-CI.yaml)

[![CRAN status](https://www.r-pkg.org/badges/version/SimInf)](https://CRAN.R-project.org/package=SimInf)

[![CRAN RStudio mirror downloads](https://cranlogs.r-pkg.org/badges/last-month/SimInf)](https://CRAN.R-project.org/package=SimInf)

[![Code coverage](https://codecov.io/gh/stewid/SimInf/branch/main/graph/badge.svg)](https://app.codecov.io/gh/stewid/SimInf)



# SimInf



The package provides an efficient and very flexible framework to

conduct data-driven epidemiological modeling in realistic large scale

disease spread simulations. The framework integrates infection

dynamics in subpopulations as continuous-time Markov chains using the

Gillespie stochastic simulation algorithm and incorporates available

data such as births, deaths and movements as scheduled events at

predefined time-points. Using C code for the numerical solvers and

'OpenMP' (if available) to divide work over multiple processors

ensures high performance when simulating a sample outcome. One of our

design goals was to make the package extendable and enable usage of

the numerical solvers from other R extension packages in order to

facilitate complex epidemiological research. The package contains

template models and can be extended with user-defined models.



## Getting started



You can use one of the predefined compartment models in SimInf, for

example, SEIR. But you can also define a custom model 'on the fly'

using the model parser method `mparse`. The method takes a character

vector of transitions in the form of `X -> propensity -> Y` and

automatically generates the C and R code for the model. The left hand

side of the first arrow (`->`) is the initial state, the right hand

side of the last arrow (`->`) is the final state, and the propensity

is written between the two arrows. The flexibility of the `mparse`

approach allows for quick prototyping of new models or features. To

illustrate the `mparse` functionality, let us consider the SIR model

in a closed population i.e., no births or deaths. Let `beta` denote

the transmission rate of spread between a susceptible individual and

an infectious individual and `gamma` the recovery rate from infection

(`gamma` = 1 / average duration of infection). It is also possible to

define variables which can then be used in calculations of

propensities or in calculations of other variables. A variable is

defined by the operator `<-`. Using a variable for the size of the

population, the SIR model can be described as:



```{r, message=FALSE}

library(SimInf)



transitions <- c("S -> beta*S*I/N -> I",

                 "I -> gamma*I -> R",

                 "N <- S+I+R")

compartments <- c("S", "I", "R")

```



The `transitions` and `compartments` variables together with the

constants `beta` and `gamma` can now be used to generate a model with

`mparse`. The model also needs to be initialised with the initial

condition `u0` and `tspan`, a vector of time points where the state of

the system is to be returned. Let us create a model that consists of

1000 replicates of a population, denoted a *node* in SimInf, that each

starts with 99 susceptibles, 5 infected and 0 recovered individuals.



```{r}

n <- 1000

u0 <- data.frame(S = rep(99, n), I = rep(5, n), R = rep(0, n))



model <- mparse(transitions = transitions,

                compartments = compartments,

                gdata = c(beta = 0.16, gamma = 0.077),

                u0 = u0,

                tspan = 1:150)

```



To generate data from the model and then print some basic information

about the outcome, run the following commands:



```{r, echo=FALSE, results="hide"}

## For reproducibility of the example, set the seed and

## the number of threads to use for the simulation.

set.seed(123)

set_num_threads(1)

```



```{r}

result <- run(model)

result

```



There are several functions in SimInf to facilitate analysis and

post-processing of simulated data, for example, `trajectory`,

`prevalence` and `plot`. The default `plot` will display the median

count in each compartment across nodes as a colored line together with

the inter-quartile range using the same color, but with transparency.



```{r mparse-SIR, fig.width = 10, fig.height = 5}

plot(result)

```



Most modeling and simulation studies require custom data analysis once

the simulation data has been generated.  To support this, SimInf

provides the `trajectory` method to obtain a `data.frame` with the

number of individuals in each compartment at the time points specified

in `tspan`. Below is the first 10 lines of the `data.frame` with

simulated data.



```{r, eval=FALSE}

trajectory(result)

```



```

#>    node time  S I R

#> 1     1    1 98 6 0

#> 2     2    1 98 6 0

#> 3     3    1 98 6 0

#> 4     4    1 99 5 0

#> 5     5    1 97 7 0

#> 6     6    1 98 5 1

#> 7     7    1 99 5 0

#> 8     8    1 99 5 0

#> 9     9    1 97 7 0

#> 10   10    1 97 6 1

...

```



Finally, let us use the `prevalence` method to explore the proportion

of infected individuals across all nodes. It takes a model object and

a formula specification, where the left hand side of the formula

specifies the compartments representing cases i.e., have an attribute

or a disease and the right hand side of the formula specifies the

compartments at risk. Below is the first 10 lines of the `data.frame`.



```{r, eval=FALSE}

prevalence(result, I ~ S + I + R)

```



```

#>    time prevalence

#> 1     1 0.05196154

#> 2     2 0.05605769

#> 3     3 0.06059615

#> 4     4 0.06516346

#> 5     5 0.06977885

#> 6     6 0.07390385

#> 7     7 0.07856731

#> 8     8 0.08311538

#> 9     9 0.08794231

#> 10   10 0.09321154

...

```



## Learn more



See the

[vignette](https://CRAN.R-project.org/package=SimInf/vignettes/SimInf.pdf)

to learn more about special features that the SimInf R package

provides, for example, how to:



- use continuous state variables



- use the SimInf framework from another R package



- incorporate available data such as births, deaths and movements as

  scheduled events at predefined time-points.



## Installation



You can install the released version of `SimInf` from

[CRAN](https://CRAN.R-project.org/package=SimInf)



```{r eval = FALSE}

install.packages("SimInf")

```



or use the `remotes` package to install the development version from

[GitHub](https://github.com/stewid/SimInf)



```{r eval = FALSE}

library(remotes)

install_github("stewid/SimInf")

```



We refer to section 3.1 in the

[vignette](https://CRAN.R-project.org/package=SimInf/vignettes/SimInf.pdf)

for detailed installation instructions.



## Authors



In alphabetical order: Pavol Bauer [![ORCID

iD](https://info.orcid.org/wp-content/uploads/2019/11/orcid_16x16.png)](https://orcid.org/0000-0003-4328-7171),

Robin Eriksson [![ORCID

iD](https://info.orcid.org/wp-content/uploads/2019/11/orcid_16x16.png)](https://orcid.org/0000-0002-4291-712X),

Stefan Engblom [![ORCID

iD](https://info.orcid.org/wp-content/uploads/2019/11/orcid_16x16.png)](https://orcid.org/0000-0002-3614-1732),

and Stefan Widgren [![ORCID

iD](https://info.orcid.org/wp-content/uploads/2019/11/orcid_16x16.png)](https://orcid.org/0000-0001-5745-2284)

**(Maintainer)**



Any suggestions, bug reports, forks and pull requests are

appreciated. Get in touch.



## Citation



SimInf is research software. To cite SimInf in publications, please

use:



- Widgren S, Bauer P, Eriksson R, Engblom S (2019) SimInf: An R

  Package for Data-Driven Stochastic Disease Spread Simulations.

  Journal of Statistical Software, 91(12), 1--42. doi:

  [10.18637/jss.v091.i12](https://doi.org/10.18637/jss.v091.i12)



- Bauer P, Engblom S, Widgren S (2016) Fast event-based

  epidemiological simulations on national scales. International

  Journal of High Performance Computing Applications, 30(4),

  438--453. doi: 10.1177/1094342016635723



## Acknowledgments



This software has been made possible by support from the Swedish

Research Council within the UPMARC Linnaeus center of Excellence

(Pavol Bauer, Robin Eriksson, and Stefan Engblom), the Swedish

Research Council Formas (Stefan Engblom and Stefan Widgren), the

Swedish Board of Agriculture (Stefan Widgren), the Swedish strategic

research program eSSENCE (Stefan Widgren), and in the framework of the

Full Force project, supported by funding from the European Union’s

Horizon 2020 Research and Innovation programme under grant agreement

No 773830: One Health European Joint Programme (Stefan Widgren).



## Versioning



The `SimInf` package uses [semantic versioning](https://semver.org/).



## License



The `SimInf` package is licensed under the

[GPLv3](https://github.com/stewid/SimInf/blob/main/LICENSE).