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AMR/vignettes/freq.Rmd

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---
title: "How to create frequency tables"
author: "Matthijs S. Berends"
date: '`r format(Sys.Date(), "%d %B %Y")`'
output:
rmarkdown::html_vignette:
toc: true
toc_depth: 3
vignette: >
%\VignetteIndexEntry{How to create frequency tables}
%\VignetteEncoding{UTF-8}
%\VignetteEngine{knitr::rmarkdown}
editor_options:
chunk_output_type: console
---
```{r setup, include = FALSE, results = 'asis'}
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#",
results = 'asis',
fig.width = 7.5,
fig.height = 4.5
)
library(dplyr)
library(AMR)
```
## Introduction
Frequency tables (or frequency distributions) are summaries of the distribution of values in a sample. With the `freq` function, you can create univariate frequency tables. Multiple variables will be pasted into one variable, so it forces a univariate distribution. We take the `septic_patients` dataset (included in this AMR package) as example.
## Frequencies of one variable
To only show and quickly review the content of one variable, you can just select this variable in various ways. Let's say we want to get the frequencies of the `gender` variable of the `septic_patients` dataset:
```{r, echo = TRUE}
septic_patients %>% freq(gender)
```
This immediately shows the class of the variable, its length and availability (i.e. the amount of `NA`), the amount of unique values and (most importantly) that among septic patients men are more prevalent than women.
## Frequencies of more than one variable
Multiple variables will be pasted into one variable to review individual cases, keeping a univariate frequency table.
For illustration, we could add some more variables to the `septic_patients` dataset to learn about bacterial properties:
```{r, echo = TRUE, results = 'hide'}
my_patients <- septic_patients %>% left_join_microorganisms()
```
Now all variables of the `microorganisms` dataset have been joined to the `septic_patients` dataset. The `microorganisms` dataset consists of the following variables:
```{r, echo = TRUE, results = 'markup'}
colnames(microorganisms)
```
If we compare the dimensions between the old and new dataset, we can see that these `r ncol(my_patients) - ncol(septic_patients)` variables were added:
```{r, echo = TRUE, results = 'markup'}
dim(septic_patients)
dim(my_patients)
```
So now the `genus` and `species` variables are available. A frequency table of these combined variables can be created like this:
```{r, echo = TRUE}
my_patients %>%
freq(genus, species, nmax = 15)
```
## Frequencies of numeric values
Frequency tables can be created of any input.
In case of numeric values (like integers, doubles, etc.) additional descriptive statistics will be calculated and shown into the header:
```{r, echo = TRUE}
# # get age distribution of unique patients
septic_patients %>%
distinct(patient_id, .keep_all = TRUE) %>%
freq(age, nmax = 5, header = TRUE)
```
So the following properties are determined, where `NA` values are always ignored:
* **Mean**
* **Standard deviation**
* **Coefficient of variation** (CV), the standard deviation divided by the mean
* **Five numbers of Tukey** (min, Q1, median, Q3, max)
* **Coefficient of quartile variation** (CQV, sometimes called coefficient of dispersion), calculated as (Q3 - Q1) / (Q3 + Q1) using quantile with `type = 6` as quantile algorithm to comply with SPSS standards
* **Outliers** (total count and unique count)
So for example, the above frequency table quickly shows the median age of patients being `r my_patients %>% distinct(patient_id, .keep_all = TRUE) %>% pull(age) %>% median(na.rm = TRUE)`.
## Frequencies of factors
To sort frequencies of factors on factor level instead of item count, use the `sort.count` parameter.
`sort.count` is `TRUE` by default. Compare this default behaviour...
```{r, echo = TRUE}
septic_patients %>%
freq(hospital_id)
```
... with this, where items are now sorted on count:
```{r, echo = TRUE}
septic_patients %>%
freq(hospital_id, sort.count = FALSE)
```
All classes will be printed into the header (default is `FALSE` when using markdown like this document). Variables with the new `rsi` class of this AMR package are actually ordered factors and have three classes (look at `Class` in the header):
```{r, echo = TRUE}
septic_patients %>%
freq(amox, header = TRUE)
```
## Frequencies of dates
Frequencies of dates will show the oldest and newest date in the data, and the amount of days between them:
```{r, echo = TRUE}
septic_patients %>%
freq(date, nmax = 5, header = TRUE)
```
## Assigning a frequency table to an object
A frequency table is actaually a regular `data.frame`, with the exception that it contains an additional class.
```{r, echo = TRUE}
my_df <- septic_patients %>% freq(age)
class(my_df)
```
Because of this additional class, a frequency table prints like the examples above. But the object itself contains the complete table without a row limitation:
```{r, echo = TRUE}
dim(my_df)
```
## Additional parameters
### Parameter `na.rm`
With the `na.rm` parameter (defaults to `TRUE`, but they will always be shown into the header), you can include `NA` values in the frequency table:
```{r, echo = TRUE}
septic_patients %>%
freq(amox, na.rm = FALSE)
```
### Parameter `row.names`
The default frequency tables shows row indices. To remove them, use `row.names = FALSE`:
```{r, echo = TRUE}
septic_patients %>%
freq(hospital_id, row.names = FALSE)
```
### Parameter `markdown`
The `markdown` parameter is `TRUE` at default in non-interactive sessions, like in reports created with R Markdown. This will always print all rows, unless `nmax` is set.
```{r, echo = TRUE}
septic_patients %>%
freq(hospital_id, markdown = TRUE)
```