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SentimentAnalysis performs a sentiment analysis of textual contents in R. This implementation utilizes various existing dictionaries, such as QDAP, Harvard IV or Loughran-McDonald. Furthermore, it can also create customized dictionaries. The latter uses LASSO regularization as a statistical approach to select relevant terms based on an exogenous response variable.
The most important functions in SentimentAnalysis are:
Compute sentiment scores from contents stored in different
formats with analyzeSentiment()
.
If desired, convert the continuous scores to either binary
sentiment classes (negative or positive) or tertiary directions
(negative, neutral or positive). This conversion can be done with
convertToBinary()
or convertToDirection()
respectively.
Compare the calculated sentiment socres with a baseline (i.e. a
gold standard). Here, compareToResponse()
performs a
statistical evaluation, while plotSentimentResponse()
enables a visual comparison.
Generate customized dictionaries with the help of
generateDictionary()
as part of an advanced analysis.
However, this prerequisites a response variable (i.e. the
baseline).
To see examples of these functions in use, check out the help pages, the demos and the vignette.
This section shows the basic functionality of how to perform a sentiment analysis. First, install the package from CRAN. Then load the corresponding package SentimentAnalysis.
# install.packages("SentimentAnalysis")
library(SentimentAnalysis)
This simple example shows how to perform a sentiment analysis of a single string. The result is a two-level factor with levels “positive” and “negative.”
# Analyze a single string to obtain a binary response (positive / negative)
<- analyzeSentiment("Yeah, this was a great soccer game of the German team!")
sentiment convertToBinaryResponse(sentiment)$SentimentGI
#> [1] positive
#> Levels: negative positive
The following demonstrates some of the functionality provided by SentimentAnalysis. It also shows its visualization and evaluation capabilities.
# Create a vector of strings
<- c("Wow, I really like the new light sabers!",
documents "That book was excellent.",
"R is a fantastic language.",
"The service in this restaurant was miserable.",
"This is neither positive or negative.",
"The waiter forget about my a dessert -- what a poor service!")
# Analyze sentiment
<- analyzeSentiment(documents)
sentiment
# Extract dictionary-based sentiment according to the QDAP dictionary
$SentimentQDAP
sentiment#> [1] 0.3333333 0.5000000 0.5000000 -0.3333333 0.0000000 -0.4000000
# View sentiment direction (i.e. positive, neutral and negative)
convertToDirection(sentiment$SentimentQDAP)
#> [1] positive positive positive negative neutral negative
#> Levels: negative neutral positive
<- c(+1, +1, +1, -1, 0, -1)
response
compareToResponse(sentiment, response)
#> Warning in cor(sentiment, response): the standard deviation is zero
#> Warning in cor(x, y): the standard deviation is zero
#> Warning in cor(x, y): the standard deviation is zero
#> Warning in cor(sentiment, response): the standard deviation is zero
#> WordCount SentimentGI NegativityGI PositivityGI
#> cor -0.18569534 0.990011498 -9.974890e-01 0.942954167
#> cor.t.statistic -0.37796447 14.044046450 -2.816913e+01 5.664705543
#> cor.p.value 0.72465864 0.000149157 9.449687e-06 0.004788521
#> lm.t.value -0.37796447 14.044046450 -2.816913e+01 5.664705543
#> r.squared 0.03448276 0.980122766 9.949843e-01 0.889162562
#> RMSE 3.82970843 0.450102869 1.186654e+00 0.713624032
#> MAE 3.33333333 0.400000000 1.100000e+00 0.666666667
#> Accuracy 0.66666667 1.000000000 6.666667e-01 0.666666667
#> Precision NaN 1.000000000 NaN NaN
#> Sensitivity 0.00000000 1.000000000 0.000000e+00 0.000000000
#> Specificity 1.00000000 1.000000000 1.000000e+00 1.000000000
#> F1 NaN 1.000000000 NaN NaN
#> BalancedAccuracy 0.50000000 1.000000000 5.000000e-01 0.500000000
#> avg.sentiment.pos.response 3.25000000 0.333333333 8.333333e-02 0.416666667
#> avg.sentiment.neg.response 4.00000000 -0.633333333 6.333333e-01 0.000000000
#> SentimentHE NegativityHE PositivityHE SentimentLM
#> cor 0.4152274 -0.083045480 0.3315938 0.7370455
#> cor.t.statistic 0.9128709 -0.166666667 0.7029595 2.1811142
#> cor.p.value 0.4129544 0.875718144 0.5208394 0.0946266
#> lm.t.value 0.9128709 -0.166666667 0.7029595 2.1811142
#> r.squared 0.1724138 0.006896552 0.1099545 0.5432361
#> RMSE 0.8416254 0.922958207 0.8525561 0.7234178
#> MAE 0.7500000 0.888888889 0.8055556 0.6333333
#> Accuracy 0.6666667 0.666666667 0.6666667 0.8333333
#> Precision NaN NaN NaN 1.0000000
#> Sensitivity 0.0000000 0.000000000 0.0000000 0.5000000
#> Specificity 1.0000000 1.000000000 1.0000000 1.0000000
#> F1 NaN NaN NaN 0.6666667
#> BalancedAccuracy 0.5000000 0.500000000 0.5000000 0.7500000
#> avg.sentiment.pos.response 0.1250000 0.083333333 0.2083333 0.2500000
#> avg.sentiment.neg.response 0.0000000 0.000000000 0.0000000 -0.1000000
#> NegativityLM PositivityLM RatioUncertaintyLM
#> cor -0.40804713 0.6305283 NA
#> cor.t.statistic -0.89389841 1.6247248 NA
#> cor.p.value 0.42189973 0.1795458 NA
#> lm.t.value -0.89389841 1.6247248 NA
#> r.squared 0.16650246 0.3975659 NA
#> RMSE 0.96186547 0.7757911 0.9128709
#> MAE 0.92222222 0.7222222 0.8333333
#> Accuracy 0.66666667 0.6666667 0.6666667
#> Precision NaN NaN NaN
#> Sensitivity 0.00000000 0.0000000 0.0000000
#> Specificity 1.00000000 1.0000000 1.0000000
#> F1 NaN NaN NaN
#> BalancedAccuracy 0.50000000 0.5000000 0.5000000
#> avg.sentiment.pos.response 0.08333333 0.3333333 0.0000000
#> avg.sentiment.neg.response 0.10000000 0.0000000 0.0000000
#> SentimentQDAP NegativityQDAP PositivityQDAP
#> cor 0.9865356369 -0.944339551 0.942954167
#> cor.t.statistic 12.0642877257 -5.741148345 5.664705543
#> cor.p.value 0.0002707131 0.004560908 0.004788521
#> lm.t.value 12.0642877257 -5.741148345 5.664705543
#> r.squared 0.9732525629 0.891777188 0.889162562
#> RMSE 0.5398902495 1.068401367 0.713624032
#> MAE 0.4888888889 1.011111111 0.666666667
#> Accuracy 1.0000000000 0.666666667 0.666666667
#> Precision 1.0000000000 NaN NaN
#> Sensitivity 1.0000000000 0.000000000 0.000000000
#> Specificity 1.0000000000 1.000000000 1.000000000
#> F1 1.0000000000 NaN NaN
#> BalancedAccuracy 1.0000000000 0.500000000 0.500000000
#> avg.sentiment.pos.response 0.3333333333 0.083333333 0.416666667
#> avg.sentiment.neg.response -0.3666666667 0.366666667 0.000000000
# Optional visualization: plotSentimentResponse(sentiment$SentimentQDAP, response)
Research in finance and social sciences nowadays utilizes content analysis to understand human decisions in the face of textual materials. While content analysis has received great traction lately, the available tools are not yet living up to the needs of researchers. This package implements a novel approach named “**dictionary generation” to study tone, sentiment and reception of textual materials.
The approach utilizes LASSO regularization to extract words from documents that statistically feature a positive and negative polarity. This immediately reveals manifold implications for practitioners, finance research and social sciences: researchers can use R to extract text components that are relevant for readers and test their hypothesis based on these.
SentimentAnalysis is released under the MIT License
Copyright (c) 2023 Stefan Feuerriegel & Nicolas Pröllochs
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.