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IntroToTextAnalytics_Part5.R
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IntroToTextAnalytics_Part5.R
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#
# Copyright 2017 Data Science Dojo
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
#
# This R source code file corresponds to video 5 of the Data Science
# Dojo YouTube series "Introduction to Text Analytics with R" located
# at the following URL:
# https://www.youtube.com/watch?v=az7yf0IfWPM
#
# Install all required packages.
install.packages(c("ggplot2", "e1071", "caret", "quanteda",
"irlba", "randomForest"))
# Load up the .CSV data and explore in RStudio.
spam.raw <- read.csv("spam.csv", stringsAsFactors = FALSE, fileEncoding = "UTF-16")
View(spam.raw)
# Clean up the data frame and view our handiwork.
spam.raw <- spam.raw[, 1:2]
names(spam.raw) <- c("Label", "Text")
View(spam.raw)
# Check data to see if there are missing values.
length(which(!complete.cases(spam.raw)))
# Convert our class label into a factor.
spam.raw$Label <- as.factor(spam.raw$Label)
# The first step, as always, is to explore the data.
# First, let's take a look at distibution of the class labels (i.e., ham vs. spam).
prop.table(table(spam.raw$Label))
# Next up, let's get a feel for the distribution of text lengths of the SMS
# messages by adding a new feature for the length of each message.
spam.raw$TextLength <- nchar(spam.raw$Text)
summary(spam.raw$TextLength)
# Visualize distribution with ggplot2, adding segmentation for ham/spam.
library(ggplot2)
ggplot(spam.raw, aes(x = TextLength, fill = Label)) +
theme_bw() +
geom_histogram(binwidth = 5) +
labs(y = "Text Count", x = "Length of Text",
title = "Distribution of Text Lengths with Class Labels")
# At a minimum we need to split our data into a training set and a
# test set. In a true project we would want to use a three-way split
# of training, validation, and test.
#
# As we know that our data has non-trivial class imbalance, we'll
# use the mighty caret package to create a randomg train/test split
# that ensures the correct ham/spam class label proportions (i.e.,
# we'll use caret for a random stratified split).
library(caret)
help(package = "caret")
# Use caret to create a 70%/30% stratified split. Set the random
# seed for reproducibility.
set.seed(32984)
indexes <- createDataPartition(spam.raw$Label, times = 1,
p = 0.7, list = FALSE)
train <- spam.raw[indexes,]
test <- spam.raw[-indexes,]
# Verify proportions.
prop.table(table(train$Label))
prop.table(table(test$Label))
# Text analytics requires a lot of data exploration, data pre-processing
# and data wrangling. Let's explore some examples.
# HTML-escaped ampersand character.
train$Text[21]
# HTML-escaped '<' and '>' characters. Also note that Mallika Sherawat
# is an actual person, but we will ignore the implications of this for
# this introductory tutorial.
train$Text[38]
# A URL.
train$Text[357]
# There are many packages in the R ecosystem for performing text
# analytics. One of the newer packages in quanteda. The quanteda
# package has many useful functions for quickly and easily working
# with text data.
library(quanteda)
help(package = "quanteda")
# Tokenize SMS text messages.
train.tokens <- tokens(train$Text, what = "word",
remove_numbers = TRUE, remove_punct = TRUE,
remove_symbols = TRUE, remove_hyphens = TRUE)
# Take a look at a specific SMS message and see how it transforms.
train.tokens[[357]]
# Lower case the tokens.
train.tokens <- tokens_tolower(train.tokens)
train.tokens[[357]]
# Use quanteda's built-in stopword list for English.
# NOTE - You should always inspect stopword lists for applicability to
# your problem/domain.
train.tokens <- tokens_select(train.tokens, stopwords(),
selection = "remove")
train.tokens[[357]]
# Perform stemming on the tokens.
train.tokens <- tokens_wordstem(train.tokens, language = "english")
train.tokens[[357]]
# Create our first bag-of-words model.
train.tokens.dfm <- dfm(train.tokens, tolower = FALSE)
# Transform to a matrix and inspect.
train.tokens.matrix <- as.matrix(train.tokens.dfm)
View(train.tokens.matrix[1:20, 1:100])
dim(train.tokens.matrix)
# Investigate the effects of stemming.
colnames(train.tokens.matrix)[1:50]
# Per best practices, we will leverage cross validation (CV) as
# the basis of our modeling process. Using CV we can create
# estimates of how well our model will do in Production on new,
# unseen data. CV is powerful, but the downside is that it
# requires more processing and therefore more time.
#
# If you are not familiar with CV, consult the following
# Wikipedia article:
#
# https://en.wikipedia.org/wiki/Cross-validation_(statistics)
#
# Setup a the feature data frame with labels.
train.tokens.df <- cbind(Label = train$Label, data.frame(train.tokens.dfm))
# Often, tokenization requires some additional pre-processing
names(train.tokens.df)[c(146, 148, 235, 238)]
# Cleanup column names.
names(train.tokens.df) <- make.names(names(train.tokens.df))
# Use caret to create stratified folds for 10-fold cross validation repeated
# 3 times (i.e., create 30 random stratified samples)
set.seed(48743)
cv.folds <- createMultiFolds(train$Label, k = 10, times = 3)
cv.cntrl <- trainControl(method = "repeatedcv", number = 10,
repeats = 3, index = cv.folds)
# Our data frame is non-trivial in size. As such, CV runs will take
# quite a long time to run. To cut down on total execution time, use
# the doSNOW package to allow for multi-core training in parallel.
#
# WARNING - The following code is configured to run on a workstation-
# or server-class machine (i.e., 12 logical cores). Alter
# code to suit your HW environment.
#
#install.packages("doSNOW")
library(doSNOW)
# Time the code execution
start.time <- Sys.time()
# Create a cluster to work on 10 logical cores.
cl <- makeCluster(10, type = "SOCK")
registerDoSNOW(cl)
# As our data is non-trivial in size at this point, use a single decision
# tree alogrithm as our first model. We will graduate to using more
# powerful algorithms later when we perform feature extraction to shrink
# the size of our data.
rpart.cv.1 <- train(Label ~ ., data = train.tokens.df, method = "rpart",
trControl = cv.cntrl, tuneLength = 7)
# Processing is done, stop cluster.
stopCluster(cl)
# Total time of execution on workstation was approximately 4 minutes.
total.time <- Sys.time() - start.time
total.time
# Check out our results.
rpart.cv.1
# The use of Term Frequency-Inverse Document Frequency (TF-IDF) is a
# powerful technique for enhancing the information/signal contained
# within our document-frequency matrix. Specifically, the mathematics
# behind TF-IDF accomplish the following goals:
# 1 - The TF calculation accounts for the fact that longer
# documents will have higher individual term counts. Applying
# TF normalizes all documents in the corpus to be length
# independent.
# 2 - The IDF calculation accounts for the frequency of term
# appearance in all documents in the corpus. The intuition
# being that a term that appears in every document has no
# predictive power.
# 3 - The multiplication of TF by IDF for each cell in the matrix
# allows for weighting of #1 and #2 for each cell in the matrix.
# Our function for calculating relative term frequency (TF)
term.frequency <- function(row) {
row / sum(row)
}
# Our function for calculating inverse document frequency (IDF)
inverse.doc.freq <- function(col) {
corpus.size <- length(col)
doc.count <- length(which(col > 0))
log10(corpus.size / doc.count)
}
# Our function for calculating TF-IDF.
tf.idf <- function(x, idf) {
x * idf
}
# First step, normalize all documents via TF.
train.tokens.df <- apply(train.tokens.matrix, 1, term.frequency)
dim(train.tokens.df)
View(train.tokens.df[1:20, 1:100])
# Second step, calculate the IDF vector that we will use - both
# for training data and for test data!
train.tokens.idf <- apply(train.tokens.matrix, 2, inverse.doc.freq)
str(train.tokens.idf)
# Lastly, calculate TF-IDF for our training corpus.
train.tokens.tfidf <- apply(train.tokens.df, 2, tf.idf, idf = train.tokens.idf)
dim(train.tokens.tfidf)
View(train.tokens.tfidf[1:25, 1:25])
# Transpose the matrix
train.tokens.tfidf <- t(train.tokens.tfidf)
dim(train.tokens.tfidf)
View(train.tokens.tfidf[1:25, 1:25])
# Check for incopmlete cases.
incomplete.cases <- which(!complete.cases(train.tokens.tfidf))
train$Text[incomplete.cases]
# Fix incomplete cases
train.tokens.tfidf[incomplete.cases,] <- rep(0.0, ncol(train.tokens.tfidf))
dim(train.tokens.tfidf)
sum(which(!complete.cases(train.tokens.tfidf)))
# Make a clean data frame using the same process as before.
train.tokens.tfidf.df <- cbind(Label = train$Label, data.frame(train.tokens.tfidf))
names(train.tokens.tfidf.df) <- make.names(names(train.tokens.tfidf.df))