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bayestestR

Become a Bayesian master you will

Existing R packages allow users to easily fit a large variety of models and extract and visualize the posterior draws. However, most of these packages only return a limited set of indices (e.g., point-estimates and CIs). bayestestR provides a comprehensive and consistent set of functions to analyze and describe posterior distributions generated by a variety of models objects, including popular modeling packages such as rstanarm, brms or BayesFactor.

You can reference the package and its documentation as follows:

  • Makowski, D., Ben-Shachar, M. S., & Lüdecke, D. (2019). bayestestR: Describing Effects and their Uncertainty, Existence and Significance within the Bayesian Framework. Journal of Open Source Software, 4(40), 1541. 10.21105/joss.01541
  • Makowski, D., Ben-Shachar, M. S., Chen, S. H. A., & Lüdecke, D. (2019). Indices of Effect Existence and Significance in the Bayesian Framework. Frontiers in Psychology 2019;10:2767. 10.3389/fpsyg.2019.02767

Installation

Run the following to install the stable release of bayestestR from CRAN:

install.packages("bayestestR")

Or this one to install the latest development version:

install.packages("remotes")
remotes::install_github("easystats/bayestestR")

Documentation

Click on the buttons above to access the package documentation and the easystats blog, and check-out these vignettes:

Tutorials

Articles

Features

In the Bayesian framework, parameters are estimated in a probabilistic fashion as distributions. These distributions can be summarised and described by reporting 4 types of indices:

describe_posterior() is the master function with which you can compute all of the indices cited below at once.

describe_posterior(
  rnorm(10000),
  centrality = "median",
  test = c("p_direction", "p_significance")
)
## # Description of Posterior Distributions
## 
## Parameter | Median |          89% CI |     pd |    ps
## -----------------------------------------------------
## Posterior |  0.024 | [-1.594, 1.650] | 50.94% | 0.470

describe_posterior() works for many objects, including more complex brmsfit-models. For better readability, the output is separated by model components:

zinb <- read.csv("http://stats.idre.ucla.edu/stat/data/fish.csv")
set.seed(123)
model <- brm(
  bf(
    count ~ child + camper + (1 | persons), 
    zi ~ child + camper + (1 | persons)
  ),
  data = zinb,
  family = zero_inflated_poisson(),
  chains = 1,
  iter = 500
)

describe_posterior(
  model,
  effects = "all",
  component = "all",
  test = c("p_direction", "p_significance"),
  centrality = "all"
)
## # Description of Posterior Distributions
## 
## # Fixed Effects (Conditional Model)
## 
## Parameter | Median |   Mean |    MAP |           89% CI |      pd |    ps |  Rhat |     ESS
## -------------------------------------------------------------------------------------------
## Intercept |  0.962 |  0.963 |  0.964 | [-0.341,  2.293] |  90.00% | 0.884 | 1.011 | 109.680
## child     | -1.159 | -1.156 | -1.155 | [-1.320, -0.995] | 100.00% | 1.000 | 0.996 | 278.161
## camper    |  0.725 |  0.722 |  0.729 | [ 0.568,  0.870] | 100.00% | 1.000 | 0.996 | 271.166
## 
## # Fixed Effects (Zero-Inflated Model)
## 
## Parameter | Median |   Mean |    MAP |           89% CI |      pd |    ps |  Rhat |     ESS
## -------------------------------------------------------------------------------------------
## Intercept | -0.480 | -0.507 | -0.220 | [-1.694,  0.427] |  78.00% | 0.732 | 0.997 | 137.695
## child     |  1.850 |  1.863 |  1.813 | [ 1.371,  2.468] | 100.00% | 1.000 | 0.996 | 302.735
## camper    | -0.883 | -0.860 | -0.988 | [-1.474, -0.225] |  98.40% | 0.964 | 0.996 | 292.499
## 
## # Random Effects (Conditional Model)
## 
## Parameter              | Median |   Mean |    MAP |           89% CI |      pd |    ps |  Rhat |     ESS
## --------------------------------------------------------------------------------------------------------
## persons 1              | -0.990 | -1.013 | -0.841 | [-2.250,  0.384] |  92.00% | 0.904 | 1.007 | 105.679
## persons 2              | -0.005 | -0.035 |  0.026 | [-1.642,  0.950] |  50.00% | 0.452 | 1.013 | 108.942
## persons 3              |  0.693 |  0.662 |  0.686 | [-0.581,  2.078] |  79.60% | 0.776 | 1.010 | 113.791
## persons 4              |  1.574 |  1.560 |  1.561 | [ 0.094,  2.720] |  96.80% | 0.960 | 1.009 | 113.676
## SD persons (Intercept) |  1.422 |  1.584 |  1.067 | [ 0.663,  2.488] | 100.00% | 1.000 | 1.010 | 126.414
## 
## # Random Effects (Zero-Inflated Model)
## 
## Parameter              | Median |   Mean |    MAP |           89% CI |      pd |    ps |  Rhat |     ESS
## --------------------------------------------------------------------------------------------------------
## persons 1              |  1.096 |  1.109 |  1.076 | [-0.064,  2.067] |  94.80% | 0.932 | 0.997 | 166.262
## persons 2              |  0.183 |  0.176 |  0.219 | [-0.826,  1.118] |  63.20% | 0.544 | 0.996 | 153.965
## persons 3              | -0.301 | -0.309 | -0.539 | [-1.442,  0.572] |  64.00% | 0.588 | 0.997 | 153.793
## persons 4              | -1.452 | -1.465 | -1.440 | [-2.438, -0.090] |  98.00% | 0.972 | 1.000 | 189.301
## SD persons (Intercept) |  1.303 |  1.494 |  0.989 | [ 0.614,  2.668] | 100.00% | 1.000 | 0.996 | 129.124

bayestestR also includes many other features useful for your Bayesian analsyes. Here are some more examples:

Point-estimates

library(bayestestR)

posterior <- distribution_gamma(10000, 1.5)  # Generate a skewed distribution
centrality <- point_estimate(posterior)  # Get indices of centrality
centrality
## # Point Estimates
## 
## Median | Mean |  MAP
## --------------------
##   1.18 | 1.50 | 0.51

As for other easystats packages, plot() methods are available from the see package for many functions:

While the median and the mean are available through base R functions, map_estimate() in bayestestR can be used to directly find the Highest Maximum A Posteriori (MAP) estimate of a posterior, i.e., the value associated with the highest probability density (the “peak” of the posterior distribution). In other words, it is an estimation of the mode for continuous parameters.

Uncertainty (CI)

hdi() computes the Highest Density Interval (HDI) of a posterior distribution, i.e., the interval which contains all points within the interval have a higher probability density than points outside the interval. The HDI can be used in the context of Bayesian posterior characterization as Credible Interval (CI).

Unlike equal-tailed intervals (see eti()) that typically exclude 2.5% from each tail of the distribution, the HDI is not equal-tailed and therefore always includes the mode(s) of posterior distributions.

By default, hdi() returns the 89% intervals (ci = 0.89), deemed to be more stable than, for instance, 95% intervals. An effective sample size of at least 10.000 is recommended if 95% intervals should be computed (Kruschke, 2015). Moreover, 89 indicates the arbitrariness of interval limits - its only remarkable property is being the highest prime number that does not exceed the already unstable 95% threshold (McElreath, 2018).

posterior <- distribution_chisquared(10000, 4)

hdi(posterior, ci = .89)
## # Highest Density Interval
## 
## 89% HDI     
## ------------
## [0.18, 7.63]

eti(posterior, ci = .89)
## # Equal-Tailed Interval
## 
## 89% ETI     
## ------------
## [0.75, 9.25]

Existence and Significance Testing

Probability of Direction (pd)

p_direction() computes the Probability of Direction (pd, also known as the Maximum Probability of Effect - MPE). It varies between 50% and 100% (i.e., 0.5 and 1) and can be interpreted as the probability (expressed in percentage) that a parameter (described by its posterior distribution) is strictly positive or negative (whichever is the most probable). It is mathematically defined as the proportion of the posterior distribution that is of the median’s sign. Although differently expressed, this index is fairly similar (i.e., is strongly correlated) to the frequentist p-value.

Relationship with the p-value: In most cases, it seems that the pd corresponds to the frequentist one-sided p-value through the formula p-value = (1-pd/100) and to the two-sided p-value (the most commonly reported) through the formula p-value = 2*(1-pd/100). Thus, a pd of 95%, 97.5% 99.5% and 99.95% corresponds approximately to a two-sided p-value of respectively .1, .05, .01 and .001. See the reporting guidelines.

posterior <- distribution_normal(10000, 0.4, 0.2)
p_direction(posterior)
## pd = 97.73%

ROPE

rope() computes the proportion (in percentage) of the HDI (default to the 89% HDI) of a posterior distribution that lies within a region of practical equivalence.

Statistically, the probability of a posterior distribution of being different from 0 does not make much sense (the probability of it being different from a single point being infinite). Therefore, the idea underlining ROPE is to let the user define an area around the null value enclosing values that are equivalent to the null value for practical purposes Kruschke (2018).

Kruschke suggests that such null value could be set, by default, to the -0.1 to 0.1 range of a standardized parameter (negligible effect size according to Cohen, 1988). This could be generalized: For instance, for linear models, the ROPE could be set as 0 +/- .1 * sd(y). This ROPE range can be automatically computed for models using the rope_range function.

Kruschke suggests using the proportion of the 95% (or 90%, considered more stable) HDI that falls within the ROPE as an index for “null-hypothesis” testing (as understood under the Bayesian framework, see equivalence_test).

posterior <- distribution_normal(10000, 0.4, 0.2)
rope(posterior, range = c(-0.1, 0.1))
## # Proportion of samples inside the ROPE [-0.10, 0.10]:
## 
## inside ROPE
## -----------
## 1.33 %

Bayes Factor

bayesfactor_parameters() computes Bayes factors against the null (either a point or an interval), bases on prior and posterior samples of a single parameter. This Bayes factor indicates the degree by which the mass of the posterior distribution has shifted further away from or closer to the null value(s) (relative to the prior distribution), thus indicating if the null value has become less or more likely given the observed data.

When the null is an interval, the Bayes factor is computed by comparing the prior and posterior odds of the parameter falling within or outside the null; When the null is a point, a Savage-Dickey density ratio is computed, which is also an approximation of a Bayes factor comparing the marginal likelihoods of the model against a model in which the tested parameter has been restricted to the point null (Wagenmakers, Lodewyckx, Kuriyal, & Grasman, 2010).

prior <- distribution_normal(10000, mean = 0, sd = 1)
posterior <- distribution_normal(10000, mean = 1, sd = 0.7)

bayesfactor_parameters(posterior, prior, direction = "two-sided", null = 0)
## # Bayes Factor (Savage-Dickey density ratio)
## 
## BF   
## -----
## 1.946
## 
## * Evidence Against The Null: [0]

The lollipops represent the density of a point-null on the prior distribution (the blue lollipop on the dotted distribution) and on the posterior distribution (the red lollipop on the yellow distribution). The ratio between the two - the Savage-Dickey ratio - indicates the degree by which the mass of the parameter distribution has shifted away from or closer to the null.

For more info, see the Bayes factors vignette.

Utilities

Find ROPE’s appropriate range

rope_range(): This function attempts at automatically finding suitable “default” values for the Region Of Practical Equivalence (ROPE). Kruschke (2018) suggests that such null value could be set, by default, to a range from -0.1 to 0.1 of a standardized parameter (negligible effect size according to Cohen, 1988), which can be generalised for linear models to -0.1 * sd(y), 0.1 * sd(y). For logistic models, the parameters expressed in log odds ratio can be converted to standardized difference through the formula sqrt(3)/pi, resulting in a range of -0.05 to 0.05.

rope_range(model)

Density Estimation

estimate_density(): This function is a wrapper over different methods of density estimation. By default, it uses the base R density with by default uses a different smoothing bandwidth ("SJ") from the legacy default implemented the base R density function ("nrd0"). However, Deng & Wickham suggest that method = "KernSmooth" is the fastest and the most accurate.

Perfect Distributions

distribution(): Generate a sample of size n with near-perfect distributions.

distribution(n = 10)
##  [1] -1.28 -0.88 -0.59 -0.34 -0.11  0.11  0.34  0.59  0.88  1.28

Probability of a Value

density_at(): Compute the density of a given point of a distribution.

density_at(rnorm(1000, 1, 1), 1)
## [1] 0.39

References

Kruschke, J. K. (2015). Doing Bayesian data analysis: A tutorial with R, JAGS, and Stan (2. ed). Amsterdam: Elsevier, Academic Press.

Kruschke, J. K. (2018). Rejecting or accepting parameter values in Bayesian estimation. Advances in Methods and Practices in Psychological Science, 1(2), 270–280. https://doi.org/10.1177/2515245918771304

Kruschke, J. K., & Liddell, T. M. (2018). The Bayesian new statistics: Hypothesis testing, estimation, meta-analysis, and power analysis from a Bayesian perspective. Psychonomic Bulletin & Review, 25(1), 178–206. https://doi.org/10.3758/s13423-016-1221-4

McElreath, R. (2018). Statistical rethinking. https://doi.org/10.1201/9781315372495

Wagenmakers, E.-J., Lodewyckx, T., Kuriyal, H., & Grasman, R. (2010). Bayesian hypothesis testing for psychologists: A tutorial on the SavageDickey method. Cognitive Psychology, 60(3), 158–189. https://doi.org/10.1016/j.cogpsych.2009.12.001

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Version

Install

install.packages('bayestestR')

Monthly Downloads

85,419

Version

0.8.2

License

GPL-3

Last Published

January 26th, 2021

Functions in bayestestR (0.8.2)

bayesfactor_restricted

Bayes Factors (BF) for Order Restricted Models
bayesfactor_parameters

Bayes Factors (BF) for a Single Parameter
bayesfactor_inclusion

Inclusion Bayes Factors for testing predictors across Bayesian models
bayesfactor_models

Bayes Factors (BF) for model comparison
ci

Confidence/Credible/Compatibility Interval (CI)
check_prior

Check if Prior is Informative
as.numeric.map_estimate

Convert to Numeric
bayesfactor

Bayes Factors (BF)
describe_prior

Describe Priors
diagnostic_posterior

Posteriors Sampling Diagnostic
density_at

Density Probability at a Given Value
eti

Equal-Tailed Interval (ETI)
describe_posterior

Describe Posterior Distributions
contr.bayes

Orthonormal Contrast Matrices for Bayesian Estimation
hdi

Highest Density Interval (HDI)
p_significance

Practical Significance (ps)
area_under_curve

Area under the Curve (AUC)
mediation

Summary of Bayesian multivariate-response mediation-models
convert_bayesian_as_frequentist

Convert (refit) a Bayesian model to frequentist
mhdior

Maximum HDI level inside/outside ROPE (MHDIOR)
p_rope

Probability of being in the ROPE
p_map

Bayesian p-value based on the density at the Maximum A Posteriori (MAP)
as.data.frame.density

Coerce to a Data Frame
overlap

Overlap Coefficient
p_direction

Probability of Direction (pd)
distribution

Empirical Distributions
.extract_priors_rstanarm

Extract and Returns the priors formatted for rstanarm
effective_sample

Effective Sample Size (ESS)
.select_nums

select numerics columns
equivalence_test

Test for Practical Equivalence
.prior_new_location

Set a new location for a prior
.flatten_list

Flatten a list
pd_to_p

Convert between Probability of Direction (pd) and p-value.
estimate_density

Density Estimation
weighted_posteriors

Generate posterior distributions weighted across models
unupdate

Un-update Bayesian models to their prior-to-data state
sexit_thresholds

Find Effect Size Thresholds
si

Compute Support Intervals
point_estimate

Point-estimates of posterior distributions
sensitivity_to_prior

Sensitivity to Prior
reshape_ci

Reshape CI between wide/long formats
sexit

Sequential Effect eXistence and sIgnificance Testing (SEXIT)
map_estimate

Maximum A Posteriori probability estimate (MAP)
rope

Region of Practical Equivalence (ROPE)
rope_range

Find Default Equivalence (ROPE) Region Bounds
mcse

Monte-Carlo Standard Error (MCSE)
simulate_correlation

Data Simulation
simulate_prior

Returns Priors of a Model as Empirical Distributions