keyword extraction
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@ -9,6 +9,11 @@ torch = "*"
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requests = "*"
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keybert = "*"
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progressbar = "*"
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rake-nltk = "*"
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nltk = "*"
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spacy = "*"
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numpy = "*"
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gensim = "*"
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[dev-packages]
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163
key-scrub-evaluate.py
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163
key-scrub-evaluate.py
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import warnings
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from transformers import AutoTokenizer, AutoModel
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from keybert import KeyBERT
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import torch
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import torch.nn.functional as F
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import requests
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import progressbar
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from itertools import combinations
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# Me
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#subject = "Experiments, numerical models and optimization of carbon-epoxy plates damped by a frequency-dependent interleaved viscoelastic layer"
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#query = "composite viscoelastic damping"
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# Anne
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#subject = "State of the art on the identification of wood structure natural frequencies. Influence of the mechanical properties and interest in sensitivity analysis as prospects for reverse identification method of wood elastic properties."
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#query = "wood frequency analysis mechanical properties"
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# Axel
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#subject = "Characterization of SiC MOSFET using double pulse test method."
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#query = "SiC MOSFET double pulse test"
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# Paul
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#subject = "Thermo-Mechanical Impact of temperature oscillations on bonding and metallization for SiC MOSFETs soldered on ceramic substrate"
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#query = "thermo mechanical model discrete bonding SiC MOSFET"
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# Jam
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#subject = "tig welding of inconel 625 and influences on micro structures"
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#query = "tig welding inconel 625"
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subject = "artificial inetlligence for satellite detection"
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widgets = [' [',
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progressbar.Timer(format= 'elapsed time: %(elapsed)s'),
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'] ',
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progressbar.Bar('*'),' (',
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progressbar.ETA(), ') ',
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]
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# Suppress FutureWarnings and other warnings
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warnings.simplefilter(action='ignore', category=FutureWarning)
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print("\n### Fetching Data ###\n")
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# Load the tokenizer and the model
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tokenizer = AutoTokenizer.from_pretrained('allenai/scibert_scivocab_uncased')
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print("* Got tokenizer")
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model = AutoModel.from_pretrained('allenai/scibert_scivocab_uncased')
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print("* Got model")
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kw_model = KeyBERT()
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print("* Got Keybert")
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# Function to compute sentence embeddings by pooling token embeddings (CLS token)
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def get_sentence_embedding(text):
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inputs = tokenizer(text, return_tensors="pt", padding=True, truncation=True, max_length=512)
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with torch.no_grad():
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outputs = model(**inputs)
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# Pooling strategy: Use the hidden state of the [CLS] token as the sentence embedding
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cls_embedding = outputs.last_hidden_state[:, 0, :] # Shape: (batch_size, hidden_size)
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return cls_embedding
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# Function to compute cosine similarity
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def compute_similarity(embedding1, embedding2):
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similarity = F.cosine_similarity(embedding1, embedding2)
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return similarity.item()
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print("\n### Getting Keywords ###\n")
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keywords = kw_model.extract_keywords(subject, keyphrase_ngram_range=(1, 2), stop_words='english', use_mmr=True, diversity=0.7)
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print("* keywords extracted")
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sorted_keywords = sorted(keywords, key=lambda x: -x[1])
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text_keywords = [x[0] for x in sorted_keywords]
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queries = []
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for r in range(1, len(text_keywords) + 1):
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comb = combinations(text_keywords, r)
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queries.extend(comb)
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final_query = [" OR ".join(query) for query in queries]
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final_query.append(subject)
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print("* query generated")
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print("\n### Fetching Web data ###\n")
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# Define the SearxNG instance URL and search query
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searxng_url = "https://search.penwing.org/search" # Replace with your instance URL
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params = {
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"q": final_query, # Your search query
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"format": "json", # Requesting JSON format
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"categories": "science", # You can specify categories (optional)
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}
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# Send the request to SearxNG API
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response = requests.get(searxng_url, params=params)
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# Check if the request was successful
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if response.status_code == 200:
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print("* Got response")
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# Parse the JSON response
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data = response.json()
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subject_embedding = get_sentence_embedding(subject)
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print("* Tokenized subject")
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# List to store results with similarity scores
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scored_results = []
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results = data.get("results", [])
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progress = 0
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print("\n### Starting result processing (",len(results),") ###\n")
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bar = progressbar.ProgressBar(widgets=[progressbar.Percentage(), progressbar.Bar()],
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maxval=len(results)).start()
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# Process each result
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for result in results :
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title = result['title']
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url = result['url']
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snippet = result['content']
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# Get embedding for the snippet (abstract)
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snippet_embedding = get_sentence_embedding(snippet)
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# Compute similarity between subject and snippet
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similarity = compute_similarity(subject_embedding, snippet_embedding)
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# Store the result with its similarity score
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scored_results.append({
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'title': title,
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'url': url,
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'snippet': snippet,
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'similarity': similarity
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})
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progress += 1
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bar.update(progress)
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# Sort the results by similarity (highest first)
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top_results = sorted(scored_results, key=lambda x: x['similarity'], reverse=True)[:10]
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print("\n\n### Done ###\n")
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# Print the top 10 results
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for idx, result in enumerate(top_results, 1):
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print(f"Rank {idx} ({result['similarity']:.4f}):")
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print(f"Title: {result['title']}")
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print(f"URL: {result['url']}")
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print(f"Snippet: {result['snippet']}")
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print("-" * 40)
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else:
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print(f"Error: {response.status_code}")
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36
key.py
36
key.py
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@ -1,25 +1,43 @@
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from keybert import KeyBERT
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from transformers import AutoTokenizer, AutoModel
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from itertools import combinations
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# Load the SciBERT model and tokenizer
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tokenizer = AutoTokenizer.from_pretrained('allenai/scibert_scivocab_uncased')
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#tokenizer = AutoTokenizer.from_pretrained('allenai/scibert_scivocab_uncased')
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#print("* Tokenizer")
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print("* Tokenizer")
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model = AutoModel.from_pretrained('allenai/scibert_scivocab_uncased')
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print("* Scibert model")
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#model = AutoModel.from_pretrained('allenai/scibert_scivocab_uncased')
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#print("* Scibert model")
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# Define a KeyBERT model using SciBERT embeddings
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kw_model = KeyBERT(model=model)
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#kw_model = KeyBERT(model=model)
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kw_model = KeyBERT()
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print("* Keybert model")
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# Define the subject from which to extract keywords
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subject = "tig welding of inconel 625 and influences on micro structures"
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subject = "Thermo-Mechanical Impact of temperature oscillations on bonding and metallization for SiC MOSFETs soldered on ceramic substrate"
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# Extract keywords from the subject
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keywords = kw_model.extract_keywords(subject, keyphrase_ngram_range=(1, 2), stop_words='english', use_maxsum=True)
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keywords = kw_model.extract_keywords(subject, keyphrase_ngram_range=(1, 2), stop_words='english', use_mmr=True, diversity=0.7)
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# Print extracted keywords
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for keyword, score in keywords:
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print(f"Keyword: {keyword}, Score: {score:.4f}")
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print("-"*40)
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sorted_keywords = sorted(keywords, key=lambda x: -x[1])
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text_keywords = [x[0] for x in sorted_keywords]
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queries = []
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for r in range(1, len(text_keywords) + 1): # r is the length of combinations
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comb = combinations(text_keywords, r)
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queries.extend(comb)
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#print([" OR ".join(query) for query in queries])
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text_queries = [" OR ".join(query) for query in queries]
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text_queries.append(subject)
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print(text_queries)
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8
key2.py
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8
key2.py
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from rake_nltk import Rake
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import nltk
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rake_nltk_var = Rake()
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text = "Characterization of SiC MOSFET using double pulse test method."
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rake_nltk_var.extract_keywords_from_text(text)
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keyword_extracted = rake_nltk_var.get_ranked_phrases()
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print(keyword_extracted)
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5
key3.py
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key3.py
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import spacy
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nlp = spacy.load("en_core_sci_lg")
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text = "Characterization of SiC MOSFET using double pulse test method"
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doc = nlp(text)
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print(doc.ents)
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key4.py
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key4.py
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from gensim.summarization import keywords
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text_en = ('Characterization of SiC MOSFET using double pulse test method.')
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print(keywords(text_en,words = 5,scores = True, lemmatize = True))
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