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MBESS (version 4.1.0)

The MBESS R Package

Description

Implements methods that useful in designing research and analyzing data, with particular emphasis on methods that are developed for or used within the behavioral, educational, and social sciences (broadly defined). That being said, many of the methods implemented within MBESS are applicable to a wide variety of disciplines. MBESS has a suite of functions for a variety of related topics, such as effect sizes, confidence intervals for effect sizes (including standardized effect sizes and noncentral effect sizes), sample size planning (from the accuracy in parameter estimation [AIPE], power analytic, equivalence, and minimum-risk point estimation perspectives), mediation analysis, various properties of distributions, and a variety of utility functions. MBESS (pronounced 'em-bes') was originally an acronym for 'Methods for the Behavioral, Educational, and Social Sciences,' but at this point MBESS contains methods applicable and used in a wide variety of fields and is an orphan acronym, in the sense that what was an acronym is now literally its name. MBESS has greatly benefited from others, see for a detailed list of those that have contributed and other details.

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Version

Install

install.packages('MBESS')

Monthly Downloads

9,054

Version

4.1.0

License

GPL-2 | GPL-3

Maintainer

Ken Kelley

Last Published

September 23rd, 2016

Functions in MBESS (4.1.0)

One-factor confirmatory factor analysis model

Confidence Interval for a Reliability Coefficient

Confidence interval for a regression coefficient

Confidence interval for a contrast in a fixed effects ANOVA

Confidence interval for the population squared multiple correlation coefficient

Confidence Interval for a Regression Coefficient

Confidence Interval for the Proportion of Variance Accounted for (in the dependent variable by knowing the levels of the factor)

Confidence interval for the multiple correlation coefficient

Sample size planning for the standardized mean different from the accuracy in parameter estimation approach

ancova.random.data

Generate random data for an ANCOVA model

conf.limits.nc.chisq

Confidence limits for noncentral chi square parameters

Confidence limits for the standardized mean difference.

Confidence Interval for a Standardized Regression Coefficient

Confidence interval for the population root mean square error of approximation

Confidence Interval for a Standardized Contrast in a Fixed Effects ANOVA

Confidence Interval for the Square Root of the Signal-To-Noise Ratio

Confidence Interval for the Standardized Mean

conf.limits.ncf

Confidence limits for noncentral F parameters

Confidence Interval for the Signal-To-Noise Ratio

Confidence limits for the standardized mean difference using the control group standard deviation as the divisor.

Function to calculate the regular (which is also biased) estimate of the coefficient of variation or the unbiased estimate of the coefficient of variation.

Complete Data Set of Holzinger and Swineford's (1939) Study

Expected value of the squared multiple correlation coefficient

conf.limits.nct

Confidence limits for a noncentrality parameter from a t-distribution

Correlation Matrix to Covariance Matrix Conversion

The Gardner learning data, which was used by L.R. Tucker

Plotting Conditional Regression Lines with Interactions in Two Dimensions

F.and.R2.Noncentral.Conversion

Conversion functions from noncentral noncentral values to their corresponding and vice versa, for those related to the F-test and R Square.

Regression Surface Containing Interaction

covmat.from.cfm

Covariance matrix from confirmatory (single) factor model.

Unbiased estimate of the population standard deviation

mediation.effect.bar.plot

Bar plots of mediation effects

power.equivalence.md

Power of Two One-Sided Tests Procedure (TOST) for Equivalence

power.equivalence.md.plot

Plot power of Two One-Sided Tests Procedure (TOST) for Equivalence

Cohen et. al. (2003)'s professor salary data set

Standardized mean difference using the control group as the basis of standardization

mediation.effect.plot

Visualizing mediation effects

Sigma.2.SigmaStar

Construct a covariance matrix with specified error of approximation

Effect sizes and confidence intervals in a mediation model

Sample size necessary for the accuracy in parameter estimation approach for an unstandardized regression coefficient of interest

Sample size planning for polynomial change models in longitudinal study

Sample size planning for an ANOVA contrast from the Accuracy in Parameter Estimation (AIPE) perspective

ss.aipe.R2.sensitivity

Sensitivity analysis for sample size planning with the goal of Accuracy in Parameter Estimation (i.e., a narrow observed confidence interval)

Standardized mean difference

ss.aipe.c.ancova

Sample size planning for a contrast in randomized ANCOVA from the Accuracy in Parameter Estimation (AIPE) perspective

ss.aipe.rc.sensitivity

Sensitivity analysis for sample size planing from the Accuracy in Parameter Estimation Perspective for the unstandardized regression coefficient

Sample Size Planning for Accuracy in Parameter Estimation for the multiple correlation coefficient.

ss.aipe.cv.sensitivity

Sensitivity analysis for sample size planning given the Accuracy in Parameter Estimation approach for the coefficient of variation.

Sample size planning for the coefficient of variation given the goal of Accuracy in Parameter Estimation approach to sample size planning

ss.aipe.sem.path.sensitiv

a priori Monte Carlo simulation for sample size planning for SEM targeted effects

Sample size planning for Accuracy in Parameter Estimation (AIPE) of the standardized mean

ss.aipe.reg.coef

Sample size necessary for the accuracy in parameter estimation approach for a regression coefficient of interest

ss.aipe.sc.ancova

Sample size planning from the AIPE perspective for standardized ANCOVA contrasts

ss.aipe.reg.coef.sensitivity

Sensitivity analysis for sample size planning from the Accuracy in Parameter Estimation Perspective for the (standardized and unstandardized) regression coefficient

ss.aipe.sem.path

Sample size planning for SEM targeted effects

Transform Fischer's Z into the scale of a correlation coefficient

sample size for a targeted regression coefficient

Variance of squared multiple correlation coefficient

ss.power.reg.coef

sample size for a targeted regression coefficient

Sample size planning for power for polynomial change models

Function to plan sample size so that the test of the squared multiple correlation coefficient is sufficiently powerful.

theta.2.Sigma.theta

Compute the model-implied covariance matrix of an SEM model

Sample size planning for the standardized mean difference from the Accuracy in Parameter Estimation (AIPE) perspective

Transform a correlation coefficient (r) into the scale of Fischer's Z

ss.aipe.smd.sensitivity

Sensitivity analysis for sample size given the Accuracy in Parameter Estimation approach for the standardized mean difference.

ss.aipe.src.sensitivity

Sensitivity analysis for sample size planing from the Accuracy in Parameter Estimation Perspective for the standardized regression coefficient

sample size necessary for the accuracy in parameter estimation approach for a standardized regression coefficient of interest

Find target sample sizes for the accuracy in standardized conditions means estimation in CRD

t.and.smd.conversion

Conversion functions for noncentral t-distribution

Visualize individual trajectories

ss.aipe.reliability

Sample Size Planning for Accuracy in Parameter Estimation for Reliability Coefficients.

Sample size planning for RMSEA in SEM

Find target sample sizes for the accuracy in unstandardized conditions means estimation in CRD

Sample size planning for structural equation modeling from the power analysis perspective

Visualize individual trajectories with fitted curve and quality of fit

verify.ss.aipe.R2

Internal MBESS function for verifying the sample size in ss.aipe.R2