FFTrees 2.0.0 FFTrees

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The R package FFTrees creates, visualizes and evaluates fast-and-frugal decision trees (FFTs) for solving binary classification tasks, using the algorithms and methods described in Phillips, Neth, Woike & Gaissmaier (2017, doi 10.1017/S1930297500006239 | html | PDF).

What are fast-and-frugal trees (FFTs)?

Fast-and-frugal trees (FFTs) are simple and transparent decision algorithms for solving binary classification problems. The key feature making FFTs faster and more frugal than other decision trees is that every node allows making a decision. When predicting novel cases, the performance of FFTs competes with more complex algorithms and machine learning techniques, such as logistic regression (LR), support-vector machines (SVM), and random forests (RF). Apart from being faster and requiring less information, FFTs tend to be robust against overfitting, and are easy to interpret, use, and communicate.


The latest release of FFTrees is available from CRAN at https://CRAN.R-project.org/package=FFTrees:


The current development version can be installed from its GitHub repository at https://github.com/ndphillips/FFTrees:

# install.packages("devtools")
devtools::install_github("ndphillips/FFTrees", build_vignettes = TRUE)

Getting started

As an example, let’s create a FFT predicting patients’ heart disease status (Healthy vs. Disease) based on the heartdisease dataset included in FFTrees:

library(FFTrees)  # load package

Using data

The heartdisease data provides medical information for 303 patients that were examined for heart disease. The full data contains a binary criterion variable describing the true state of each patient and were split into two subsets: A heart.train set for fitting decision trees, and heart.test set for a testing these trees. Here are the first rows and columns of both subsets of the heartdisease data:

diagnosis age sex cp trestbps chol fbs restecg thalach exang oldpeak slope ca thal
FALSE 44 0 np 108 141 0 normal 175 0 0.6 flat 0 normal
FALSE 51 0 np 140 308 0 hypertrophy 142 0 1.5 up 1 normal
FALSE 52 1 np 138 223 0 normal 169 0 0.0 up 1 normal
TRUE 48 1 aa 110 229 0 normal 168 0 1.0 down 0 rd
FALSE 59 1 aa 140 221 0 normal 164 1 0.0 up 0 normal
FALSE 58 1 np 105 240 0 hypertrophy 154 1 0.6 flat 0 rd

Table 1: Beginning of the heart.train subset (using the data of 150 patients for fitting/training FFTs).

diagnosis age sex cp trestbps chol fbs restecg thalach exang oldpeak slope ca thal
FALSE 51 0 np 120 295 0 hypertrophy 157 0 0.6 up 0 normal
TRUE 45 1 ta 110 264 0 normal 132 0 1.2 flat 0 rd
TRUE 53 1 a 123 282 0 normal 95 1 2.0 flat 2 rd
TRUE 45 1 a 142 309 0 hypertrophy 147 1 0.0 flat 3 rd
FALSE 66 1 a 120 302 0 hypertrophy 151 0 0.4 flat 0 normal
TRUE 48 1 a 130 256 1 hypertrophy 150 1 0.0 up 2 rd

Table 2: Beginning of the heart.test subset (used to predict diagnosis for 153 new patients).

Our challenge is to predict each patient’s diagnosis — a column of logical values indicating the true state of each patient (i.e., TRUE or FALSE, based on the patient suffering or not suffering from heart disease) — from the values of potential predictors.

Questions answered by FFTs

To solve binary classification problems by FFTs, we must answer two key questions:

Once we have created some FFTs, additional questions include:

The FFTrees package answers these questions by creating FFTs and allowing to evaluate, visualize, and compare them to alternative algorithms.

Creating fast-and-frugal trees (FFTs)

We use the main FFTrees() function to create FFTs for the heart.train data and evaluate their predictive performance on the heart.test data:

# Create an FFTrees object from the heartdisease data:
heart_fft <- FFTrees(formula = diagnosis ~.,
                     data = heart.train,
                     data.test = heart.test, 
                     decision.labels = c("Healthy", "Disease"))

Evaluating FFTrees() analyzes the training data, creates several FFTs, and applies them to the test data. The results are stored in an object heart_fft, which can be printed, plotted and summarized (with options for selecting specific data or trees).

# Plot the best tree applied to the test data: 
     data = "test",
     main = "Heart Disease")
An FFT predicting heart disease for test data.

Figure 1: A fast-and-frugal tree (FFT) predicting heart disease for test data and its performance characteristics.

# Compare predictive performance across algorithms: 
#> # A tibble: 5 × 18
#>   algorithm     n    hi    fa    mi    cr  sens  spec    far   ppv   npv   acc
#>   <chr>     <int> <int> <int> <int> <int> <dbl> <dbl>  <dbl> <dbl> <dbl> <dbl>
#> 1 fftrees     153    64    19     9    61 0.877 0.762 0.238  0.771 0.871 0.817
#> 2 lr          153    55    13    18    67 0.753 0.838 0.162  0.809 0.788 0.797
#> 3 cart        153    50    19    23    61 0.685 0.762 0.238  0.725 0.726 0.725
#> 4 rf          153    59     8    14    72 0.808 0.9   0.1    0.881 0.837 0.856
#> 5 svm         153    55     7    18    73 0.753 0.912 0.0875 0.887 0.802 0.837
#> # ℹ 6 more variables: bacc <dbl>, wacc <dbl>, dprime <dbl>, cost_dec <dbl>,
#> #   cost_cue <dbl>, cost <dbl>

Building FFTs from verbal descriptions

FFTs are so simple that we even can create them ‘from words’ and then apply them to data.
For example, let’s create a tree with the following three nodes and evaluate its performance on the heart.test data:

  1. If sex = 1, predict Disease.
  2. If age < 45, predict Healthy.
  3. If thal = {fd, normal}, predict Healthy,
    otherwise, predict Disease.

These conditions can directly be supplied to the my.tree argument of FFTrees():

# Create custom FFT 'in words' and apply it to test data:

# 1. Create my own FFT (from verbal description):
my_fft <- FFTrees(formula = diagnosis ~., 
                  data = heart.train,
                  data.test = heart.test, 
                  decision.labels = c("Healthy", "Disease"),
                  my.tree = "If sex = 1, predict Disease.
                             If age < 45, predict Healthy.
                             If thal = {fd, normal}, predict Healthy,  
                             Otherwise, predict Disease.")

# 2. Plot and evaluate my custom FFT (for test data):
     data = "test",
     main = "My custom FFT")
An FFT created from a verbal description.

Figure 2: An FFT predicting heart disease created from a verbal description.

The performance measures (in the bottom panel of Figure 2) show that this particular tree is somewhat biased: It has nearly perfect sensitivity (i.e., is good at identifying cases of Disease) but suffers from low specificity (i.e., performs poorly in identifying Healthy cases). Expressed in terms of its errors, my_fft incurs few misses at the expense of many false alarms. Although the accuracy of our custom tree still exceeds the data’s baseline by a fair amount, the FFTs in heart_fft (created above) strike a better balance.

Overall, what counts as the “best” tree for a particular problem depends on many factors (e.g., the goal of fitting vs. predicting data and the trade-offs between maximizing accuracy vs. incorporating the costs of cues or errors). To explore this range of options, the FFTrees package enables us to design and evaluate a range of FFTs.


We had fun creating the FFTrees package and hope you like it too! As a comprehensive, yet accessible introduction to FFTs, we recommend our article in the journal Judgment and Decision Making (2017), entitled FFTrees: A toolbox to create, visualize,and evaluate fast-and-frugal decision trees (available in html | PDF ).

Citation (in APA format):

We encourage you to read the article to learn more about the history of FFTs and how the FFTrees package creates, visualizes, and evaluates them. When using FFTrees in your own work, please cite us and share your experiences (e.g., on GitHub) so we can continue developing the package.

By 2023, over 100 scientific publications have used or cited FFTrees (see Google Scholar for the full list).
Examples include:

[File README.Rmd last updated on 2023-06-03.]