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NLP Twitter Analysis ID #
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NLP Twitter Analysis ID #
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import nltk
import numpy as np
from nltk import sent_tokenize, word_tokenize, pos_tag
import matplotlib.pyplot as plt
from pylab import *
from bs4 import BeautifulSoup
from nltk import sent_tokenize, word_tokenize, pos_tag
import nltk
import numpy as np
import matplotlib.pyplot as plt
import tweepy
from tweepy import OAuthHandler
from tweepy import Stream
from tweepy.streaming import StreamListener
import re
consumer_key = '12345'
consumer_secret = '12345'
access_token = '123-12345'
access_secret = '12345'
auth = OAuthHandler(consumer_key, consumer_secret)
auth.set_access_token(access_token, access_secret)
api = tweepy.API(auth)
number_tweets=10
data=[]
for status in tweepy.Cursor(api.user_timeline,id="cnn").items(number_tweets):
try:
URLless_string = re.sub(r'\w+:\/{2}[\d\w-]+(\.[\d\w-]+)*(?:(?:\/[^\s/]*))*', '', status.text)
print(URLless_string,'\n')
data.append(URLless_string)
except:
pass
number_tweets=500
data=[]
for status in tweepy.Cursor(api.search,q="fakenews").items(number_tweets):
try:
URLless_string = re.sub(r'\w+:\/{2}[\d\w-]+(\.[\d\w-]+)*(?:(?:\/[^\s/]*))*', '', status.text)
print(URLless_string,'\n')
data.append(URLless_string)
except:
pass
### print(tweet.entities.get('hashtags'))
text=data
sentences = sent_tokenize(str(text))
sentences2=sentences
sentences2
tokens = word_tokenize(str(text))
tokens
len(tokens)
tagged_tokens = pos_tag(tokens)
tagged_tokens
## NOUNS
text2 = word_tokenize(str(text))
is_noun = lambda pos: pos[:2] == 'NN'
b=nltk.pos_tag(text2)
b
nouns = [word for (word, pos) in nltk.pos_tag(text2) if is_noun(pos)]
nouns
V = set(nouns)
long_words1 = [w for w in tokens if 4<len(w) < 10]
sorted(long_words1)
fdist01 = nltk.FreqDist(long_words1)
fdist01
a1=fdist01.most_common(40)
a1
names0=[]
value0=[]
for i in range(0,len(a1)):
names0.append(a1[i][0])
value0.append(a1[i][1])
names0.reverse()
value0.reverse()
val = value0 # the bar lengths
pos = arange(len(a1))+.5 # the bar centers on the y axis
pos
val
plt.figure(figsize=(9,9))
barh(pos,val, align='center',alpha=0.7,color='blue')
yticks(pos, names0)
xlabel('Mentions')
title(['Nouns'])
grid(True)
def lexical_diversity(text):
return len(set(text)) / len(text)
lexical_diversity(text)
vocab = set(text)
vocab_size = len(vocab)
vocab_size
' '.join(['Monty', 'Python'])
'Monty Python'.split()
a="This is a text.'"
chars_to_remove = ['.', '!', '?',"'"]
sc = set(chars_to_remove)
''.join([c for c in a if c not in sc])
V = set(text)
long_words = [w for w in tokens if 4<len(w) < 13]
sorted(long_words)
text2 = nltk.Text(word.lower() for word in long_words)
print(text2.similar('wound'))
fdist1 = nltk.FreqDist(long_words)
fdist1
a=fdist1.most_common(15)
a
names=[]
value=[]
for i in range(0,len(a)):
names.append(a[i][0])
value.append(a[i][1])
names.reverse()
value.reverse()
val = value # the bar lengths
pos = arange(15)+.5 # the bar centers on the y axis
pos
plt.figure(figsize=(9,9))
barh(pos,val, align='center',alpha=0.7,color='rgbcmyk')
yticks(pos, names)
xlabel('Mentions')
grid(True)
list(nltk.bigrams(tokens))
list(nltk.trigrams(tokens))
sorted(w for w in set(tokens) if w.endswith('ing'))
[w.upper() for w in tokens]
for token in tokens:
if token.islower():
print(token, 'is a lowercase word')
elif token.istitle():
print(token, 'is a titlecase word')
else:
print(token, 'is punctuation')
########################################################
import logging
logging.basicConfig(format='%(asctime)s : %(levelname)s : %(message)s', level=logging.INFO)
import matplotlib.pyplot as plt
from gensim import corpora
from string import punctuation
def strip_punctuation(s):
return ''.join(c for c in s if c not in punctuation)
documents=[strip_punctuation(re.sub(r'\w+:\/{2}[\d\w-]+(\.[\d\w-]+)*(?:(?:\/[^\s/]*))*', '',sentences2[i])) for i in range(0,len(sentences2))]
# remove common words and tokenize
stoplist = set('for a of the and to in is the he she on i will it its us as that at who be '.split())
texts = [[word for word in document.lower().split() if word not in stoplist]
for document in long_words]
texts
# remove words that appear only once
from collections import defaultdict
frequency = defaultdict(int)
for text in texts:
for token in text:
frequency[token] += 1
frequency
texts = [[token for token in text if frequency[token] > 1]
for text in texts]
from pprint import pprint # pretty-printer
pprint(texts)
dictionary = corpora.Dictionary(texts)
dictionary.save('/tmp/deerwester4.dict')
print(dictionary.token2id)
## VETOR DAS FRASES
corpus = [dictionary.doc2bow(text) for text in texts]
corpora.MmCorpus.serialize('/tmp/deerwester4.mm', corpus) # store to disk, for later use
print(corpus)
from gensim import corpora, models, similarities
tfidf = models.TfidfModel(corpus) # step 1 -- initialize a model
corpus_tfidf = tfidf[corpus]
for doc in corpus_tfidf:
print(doc)
lsi = models.LsiModel(corpus_tfidf, id2word=dictionary, num_topics=2)
corpus_lsi = lsi[corpus_tfidf] # create a double wrapper over the original corpus: bow->tfidf->fold-in-lsi
lsi.print_topics(2)
## COORDENADAS DOS TEXTOS
todas=[]
for doc in corpus_lsi: # both bow->tfidf and tfidf->lsi transformations are actually executed here, on the fly
todas.append(doc)
todas
from gensim import corpora, models, similarities
dictionary = corpora.Dictionary.load('/tmp/deerwester4.dict')
corpus = corpora.MmCorpus('/tmp/deerwester4.mm') # comes from the first tutorial, "From strings to vectors"
print(corpus)
np.array(corpus).shape
lsi = models.LsiModel(corpus, id2word=dictionary, num_topics=2)
p=[]
for i in range(0,len(documents)):
doc1 = documents[i]
vec_bow2 = dictionary.doc2bow(doc1.lower().split())
vec_lsi2 = lsi[vec_bow2] # convert the query to LSI space
p.append(vec_lsi2)
p
index = similarities.MatrixSimilarity(lsi[corpus]) # transform corpus to LSI space and index it
index.save('/tmp/deerwester4.index')
index = similarities.MatrixSimilarity.load('/tmp/deerwester4.index')
#################
import gensim
import numpy as np
import matplotlib.colors as colors
import matplotlib.cm as cmx
import matplotlib as mpl
matrix1 = gensim.matutils.corpus2dense(p, num_terms=4)
matrix3=matrix1.T
matrix3
from sklearn import manifold, datasets, decomposition, ensemble,discriminant_analysis, random_projection
def norm(x):
return (x-np.min(x))/(np.max(x)-np.min(x))
X=norm(matrix3)
tsne = manifold.TSNE(n_components=2, init='pca', random_state=0,perplexity=50,verbose=1,n_iter=1500)
X_tsne = tsne.fit_transform(X)
### WORK HERE - COMO DESCOBRI QUE TINHA 3 CLUSTERS ???? SORT X_tsne
## DEFINE K-MEANS
plt.hist(X_tsne)
from sklearn.cluster import KMeans
model3=KMeans(n_clusters=4,random_state=0)
model3.fit(X_tsne)
cc=model3.predict(X_tsne)
## ALSO TRY COM X PARA VER QUE TOPICO SELECIONA
tokens2 = word_tokenize(str(sentences2))
long_words12 = [w for w in tokens2 if len(w) > 6]
sorted(long_words12)
fdist012 = nltk.FreqDist(long_words12)
a12=fdist012.most_common(5)
from matplotlib.colors import LinearSegmentedColormap
print('TOPIC 1\n')
print(a12,'\n')
for i in np.where(cc==2)[0][2:10]:
print(i,sentences2[i])
n_classes=4
colors = [(1, 0, 0), (0, 1, 0), (0, 0, 1),(0,0,0)]
cm = LinearSegmentedColormap.from_list(
cc, colors, N=4)
cor=[colors[cc[i]] for i in range(0,len(cc))]
h=[]
label=[]
fig = plt.figure(figsize=(10,4))
plt.title('NATURAL LANGUAGE PROCESSING\n\n'+'TOPIC MODELING at TWITTER HASHTAG: '+'#fakenews',fontweight="bold")
for i in range(0,4):
label.append('Topic {}'.format([0,1,2,3][i]))
plt.scatter(X_tsne[:, 0], X_tsne[:, 1],c=cc,cmap=cm,marker='o',s=100)
h1,=plt.plot(1,1,color=colors[i],linewidth=3)
h.append(h1)
plt.legend(h,label,loc="upper left")
plt.show()
model = models.LdaModel(corpus, id2word=dictionary, num_topics=4)
model.print_topics(4)