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Opinion Mining in GATE Horacio Saggion & Adam Funk

Opinion Mining in GATE Horacio Saggion & Adam Funk. Opinion Mining. Is interested in the opinion a particular piece of discourse expresses Opinions are subjective statements reflecting people’s sentiments or perceptions on entities or events

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Opinion Mining in GATE Horacio Saggion & Adam Funk

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  1. Opinion Mining in GATE Horacio Saggion & Adam Funk

  2. Opinion Mining • Is interested in the opinion a particular piece of discourse expresses • Opinions are subjective statements reflecting people’s sentiments or perceptions on entities or events • There are various problems associated to opinion mining • Identify if a piece of text is opinionated or not (factual news vs. Editorial) • Identify the entity expressing the opinion • Identify the polarity and degree of the opinion (in favour vs. against) • Identify the theme of the opinion (opinion about what?)

  3. Extract Factual Data with Information Extraction from Company Web Site Extract Opinions using Opinion Mining from Web Fora

  4. Application • Combine information extraction from company Web site with OM findings • Given a review find company web pages and extract factual information from it including products and services • Associate the opinion to the found information • Use information extraction to identify positive/negative phrases and the “object” of the opinion • Positive: correctly packed bulb, a totally free service, a very efficient management… • Negative: the same disappointing experience, unscrupulous double glazing sales, do not buy a sofa from DFS Poole or DFS anywhere, the utter inefficiency…

  5. Opinions on the Web sentiment opinion

  6. positive opinions negative opinions negative opinion, but less evident

  7. OM as text classification • Because we have access to documents which have already an associated class, we see OM as a classification problem – we consider our data “opinionated” • We are interested in: • differentiate between positive opinion vs negative opinion • “customer service is diabolical” • “I have always been impressed with this company” • recognising fine grained evaluative texts (1-star to 5-star classification) • “one of the easiest companies to order with” (5-stars) • “STAY AWAY FROM THIS SUPPLIER!!!” (1-star) • We use a supervised learning approach (Support Vector Machines) that uses linguistic features; the system decides which features are most valuable for classification • We use precision, recall, and F-score to assess classification accuracy

  8. Corpus • We have a customisable crawling process to collect all texts from Web fora • 92 texts from a Web Consumer forum • Each text contains a review about a particular company/service/product and a thumbs up/down – texts are short (one/two paragraphs) • 67% negative and 33% positive • 600 texts from another Web forum containing reviews on companies or products • Each text is short and it is associated with a 1 to 5 stars review • * ~ 8%; ** ~ 2; *** ~ 3%; **** ~ 20%; ***** ~ 67% • Each document is analysed to separate the commentary/review from the rest of the document and associate a class to each review • After this, the documents are processed with GATE processing resources: • tokenisation; sentence identification; parts of speech tagging; morphological analysis; named entity recognition, and sentence parsing

  9. SVMs for OM • Support Vector Machines (SVM) are very good algorithms used for classification and have been also used in information extraction • Learning in SVM is treated as a binary classification problem and a multiclass problem is transformed in a set of n binary classification problems • Given a set of training examples, each is represented as a vector in a space of features and SVM tries to find an hyper plane which separates positive from negative instances • Given a new instance SVM will identify in which side of the hyper plane the new instance lies and produce the classification accordingly • The distance from the hyper plane to the positive and negative instances is the margin and we use SVM with uneven margins available in GATE • In order to use them, we need to specify how instances are represented and decide on a number of parameters usually adjusted experimentally over training data

  10. Bag-of-words binary-classification • We decided to start investigating a very simple approach – word-based or bag of words approach (usually works very well in text classification) • the original word • the root or lemma of the word (for “running” we use “run”) • the parts of speech category of the word (determinant, noun, verb, etc.) • the orthography of the word (all uppercase, lowercase, etc.) • Each sentence/text is represented as a vector of features and values • we carried out different combinations of features (different n-grams) • 10-fold cross validation experiments were run over the corpus with binary classifications (up/down) • the combination of root and orthography (unigram) provides the best classifier • around 80% F-score • use of higher n-grams decreases performance of the classifier • use of more features not necessarily improves performance • a uninformed classifier would have a 67% accuracy

  11. Bag-of-words fine-grained classification • Same learning system used to produce the 5 stars classification over the fine-grained dataset • Same feature combinations were studied: • 74% overall classification accuracy using word root only • other combinations degrade performance • 1* classification accuracy = 80%; 5* classification accuracy = 75% • 2* = 2%; 3*=3%; 4*=19% • 2*, 3*, 4* difficult to classify because or either share vocabulary with extreme cases or are vague

  12. Relevant features according to the SVM models • word-based binary classification • thumbs-down: !, not, that, will, … • thumbs-up: excellent, good, www, com, site, … • word-based fine-grained classification • 1*: worst, not, cancelled, avoid,… • 2*: shirt, ball, waited,…. • 3*: another, didn’t, improve, fine, wrong, … • 4*: ok, test, wasn’t, but, however,… • 5*: very, excellent, future, experience, always, great,…

  13. Sentiment-based Classifier • Engineered features based on “linguistic” and sentiment information associated to words • Linguistic features • word-based features are restricted to adjective and adverbs and their bigram combinations • “good”, “bad”, “rather”, “quite”, “not”, etc. • Sentiment information • WordNet lexical database where words appear with their senses and synonyms • chair = the furniture • chair, professorship = the position • chair, president, chairman, … = the officer • chair, electric chair, … = execution instrument • SentiWordNet adds sentiment information to WordNet and has been used in opinion mining and sentiment analysis

  14. Sentiment-based classifier • SentiWordNet (cont.) • each word has three numerical scores (between 0 and 1): obj, pos, neg (obj+neg+pos=1)

  15. Sentiment-base classifier • Features deduced from SentiWordNet • word analysis: • countP(w) : the word positivity score (#(pos(w)>neg(w))) • countN(w) : the word negativity score (#(pos(w)<neg(w))) • countF(w): the number of entries of w in SentiWordNet • sentence analysis • sentiP: number of positive words in sentence • a word is positive if countP(w)>½countF(w) • sentiN: number of negative words in sentence • a word is negative if countN(w)>½countF(w) • senti: pos (sentiP > sentiN), neg (sentiN > sentiP), neutral (sentence feature) • text analysis: • count_pos: number of pos sentences in text • count_neg: number of neg sentences in text • count_neutral: number of neutral sentences in text

  16. Sentiment-based Classifier • Each text is represented as a vector of features and values • combining the linguistic features (adjectives, adverbs, and their combinations) and the senti, count_pos, count_neg, count_neutral features • 10-fold cross validation experiments were run over the corpus with binary classifications (up/down) • overall F-score 76% • 10-fold cross validation over the fine-grained corpus • overall F-score 72% • 1*=58%, 2*=24%, 3*=20%, 4*=19%, 5*=83% (better job in less extreme categories)

  17. Relevant features according to the SVM models • sentiment-based binary classification • thumbs-down: 8 neutral , never, 1 neutral, negative sentiment (senti feature), very late • thumbs-up: 1 negative , 0 negative , good, original, 0 neutral, fast • sentiment-based fine-grained classification • 1*: still not, cancelled, incorrect,… • 2*: 9 neutral, disappointing, fine, down, … • 3*: likely, expensive, wrong, not able,…. • 4*: competitive, positive, ok, … • 5*: happily, always, 0 negative, so simple, very positive, …

  18. Use of opinion words in OM • Hatzivassiloglou&McKeown’97 note that conjunctions (and, or, but,…) help in classifying the semantic orientation of adjectives (excellent and useful; good but expensive;…); not used in classification experiments • Riloff&al’03 create a list of subjective words by bootstrapping an initial set of 20 subjective words over a corpus; using the induced list and other features achieves 76% classification accuracy (objective vs subjective distinction) • Turney’02 uses pair-wise mutual information to detect the polarity of words (mutual information wrt “excellent” and “poor”); using the list in a classifier he achieves 74% classification accuracy • Devitt&Ahmad’07 use SentiWordNet for detecting the polarity of a piece of news (7-point scale) achieving 55% accuracy

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