diff --git a/6-NLP/2-Tasks/README.md b/6-NLP/2-Tasks/README.md
index dcd92e99..da238cd7 100644
--- a/6-NLP/2-Tasks/README.md
+++ b/6-NLP/2-Tasks/README.md
@@ -1,31 +1,34 @@
# Common natural language processing tasks and techniques
-For most *natural language processing* tasks, the text to be processed must be broken down, examined, and the results stored or cross referenced with rules and data sets. This allows the programmer to derive the meaning or intent or only the frequency of terms and words in a text.
+For most *natural language processing* tasks, the text to be processed, must be broken down, examined, and the results stored or cross referenced with rules and data sets. These tasks, allows the programmer to derive the _meaning_ or _intent_ or only the _frequency_ of terms and words in a text.
+
## [Pre-lecture quiz](https://jolly-sea-0a877260f.azurestaticapps.net/quiz/33/)
Let's discover common techniques used in processing text. Combined with machine learning, these techniques help you to analyse large amounts of text efficiently. Before applying ML to these tasks, however, let's understand the problems encountered by an NLP specialist.
## Tasks common to NLP
-π **Tokenization**
+There are different ways to analyse a text you are working on. There are tasks you can perform and through these tasks you are able to gauge an understanding of the text and draw conclusions. You usually carry out these tasks in a sequence.
+
+### Tokenization
-Probably the first thing most NLP algorithms have to do is split the text into tokens, or words. While this sounds simple, having to account for punctuation and different languages' word and sentence delimiters can make it tricky. You might have to use various methods to determine demarcations.
+Probably the first thing most NLP algorithms have to do is to split the text into tokens, or words. While this sounds simple, having to account for punctuation and different languages' word and sentence delimiters can make it tricky. You might have to use various methods to determine demarcations.
![tokenization](images/tokenization.png)
> Tokenizing a sentence from **Pride and Prejudice**. Infographic by [Jen Looper](https://twitter.com/jenlooper)
-π **Embeddings**
+### Embeddings
-[Word embeddings](https://wikipedia.org/wiki/Word_embedding) are a way to convert your text data numerically. This is done in a way so that words with a similar meaning or words used together cluster together.
+[Word embeddings](https://wikipedia.org/wiki/Word_embedding) are a way to convert your text data numerically. Embeddings are done in a way so that words with a similar meaning or words used together cluster together.
![word embeddings](images/embedding.png)
> "I have the highest respect for your nerves, they are my old friends." - Word embeddings for a sentence in **Pride and Prejudice**. Infographic by [Jen Looper](https://twitter.com/jenlooper)
β
Try [this interesting tool](https://projector.tensorflow.org/) to experiment with word embeddings. Clicking on one word shows clusters of similar words: 'toy' clusters with 'disney', 'lego', 'playstation', and 'console'.
-π **Parsing & Part-of-speech Tagging**
+### Parsing & Part-of-speech Tagging
-Every word that has been tokenized can be tagged as a part of speech - a noun, verb, or adjective etc. The sentence `the quick red fox jumped over the lazy brown dog` might be POS tagged as *fox* = noun, *jumped* = verb etc.
+Every word, that has been tokenized, can be tagged as a part of speech - a noun, verb, or adjective etc. The sentence `the quick red fox jumped over the lazy brown dog` might be POS tagged as *fox* = noun, *jumped* = verb etc.
![parsing](images/parse.png)
@@ -33,14 +36,13 @@ Every word that has been tokenized can be tagged as a part of speech - a noun, v
Parsing is recognizing what words are related to each other in a sentence - for instance `the quick red fox jumped` is an adjective-noun-verb sequence that is separate from the `lazy brown dog` sequence.
-π **Word and Phrase Frequencies**
+### Word and Phrase Frequencies
-A useful tool when analyzing a large body of text is to build a dictionary of every word or phrase of interest and how often it appears. The phrase `the quick red fox jumped over the lazy brown dog` has a word frequency of 2 for `the`.
-### Example:
+A useful tool when analyzing a large body of text is to build a dictionary of every word or phrase of interest and how often it appears. The phrase `the quick red fox jumped over the lazy brown dog` has a word frequency of 2 for `the`.
-The Rudyard Kipling poem *The Winners* has a verse:
+Let's look at an example text, where we count the frequency of words, from the Rudyard Kipling poem *The Winners* has a verse:
-```
+```output
What the moral? Who rides may read.
When the night is thick and the tracks are blind
A friend at a pinch is a friend, indeed,
@@ -51,10 +53,9 @@ He travels the fastest who travels alone.
As phrase frequencies can be case insensitive or case sensitive as required, the phrase `a friend` has a frequency of 2 and `the` has a frequency of 6, and `travels` is 2.
-π **N-grams**
+### N-grams
A text can be split into sequences of words of a set length, a single word (unigram), two words (bigrams), three words (trigrams) or any number of words (n-grams).
-### Example
For instance `the quick red fox jumped over the lazy brown dog` with a n-gram score of 2 produces the following n-grams:
@@ -68,7 +69,7 @@ For instance `the quick red fox jumped over the lazy brown dog` with a n-gram sc
8. lazy brown
9. brown dog
-It might be easier to visualise it as a sliding box over the sentence. Here it is for n-grams of 3 words, the n-gram is in bold in each sentence:
+It might be easier to visualize it as a sliding box over the sentence. Here it is for n-grams of 3 words, the n-gram is in bold in each sentence:
1. **the quick red** fox jumped over the lazy brown dog
2. the **quick red fox** jumped over the lazy brown dog
@@ -83,32 +84,31 @@ It might be easier to visualise it as a sliding box over the sentence. Here it i
> N-gram value of 3: Infographic by [Jen Looper](https://twitter.com/jenlooper)
-π **Noun phrase Extraction**
+### Noun phrase Extraction
In most sentences, there is a noun that is the subject, or object of the sentence. In English, it is often identifiable as having 'a' or 'an' or 'the' preceding it. Identifying the subject or object of a sentence by 'extracting the noun phrase' is a common task in NLP when attempting to understand the meaning of a sentence.
β
In the sentence "I cannot fix on the hour, or the spot, or the look or the words, which laid the foundation. It is too long ago. I was in the middle before I knew that I had begun.", can you identify the noun phrases?
-### Example
In the sentence `the quick red fox jumped over the lazy brown dog` there are 2 noun phrases: **quick red fox** and **lazy brown dog**.
-π **Sentiment analysis**
+### Sentiment analysis
-A sentence or text can be analysed for sentiment, or how *positive* or *negative* it is. Sentiment is measured in *polarity* and *objectivity/subjectivity*. Polarity is measured from -1.0 to 1.0 (negative to positive) and 0.0 to 1.0 (most objective to most subjective).
+A sentence or text can be analysed for sentiment, or how *positive* or *negative* it is. Sentiment is measured in *polarity* and *objectivity/subjectivity*. Polarity is measured from -1.0 to 1.0 (negative to positive) and 0.0 to 1.0 (most objective to most subjective).
β
Later you'll learn that there are different ways to determine sentiment using machine learning, but one way is to have a list of words and phrases that are categorized as positive or negative by a human expert and apply that model to text to calculate a polarity score. Can you see how this would work in some circumstances and less well in others?
-π **Inflection**
+### Inflection
Inflection enables you to take a word and get the singular or plural of the word.
-π **Lemmatization**
+### Lemmatization
A *lemma* is the root or headword for a set of words, for instance *flew*, *flies*, *flying* have a lemma of the verb *fly*.
There are also useful databases available for the NLP researcher, notably:
-π **WordNet**
+### WordNet
[WordNet](https://wordnet.princeton.edu/) is a database of words, synonyms, antonyms and many other details for every word in many different languages. It is incredibly useful when attempting to build translations, spell checkers, or language tools of any type.
@@ -116,27 +116,31 @@ There are also useful databases available for the NLP researcher, notably:
Luckily, you don't have to build all of these techniques yourself, as there are excellent Python libraries available that make it much more accessible to developers who aren't specialized in natural language processing or machine learning. The next lessons include more examples of these, but here you will learn some useful examples to help you with the next task.
+### Exercise - using `TextBlob` library
+
Let's use a library called TextBlob as it contains helpful APIs for tackling these types of tasks. TextBlob "stands on the giant shoulders of [NLTK](https://nltk.org) and [pattern](https://github.com/clips/pattern), and plays nicely with both." It has a considerable amount of ML embedded in its API.
> Note: A useful [Quick Start](https://textblob.readthedocs.io/en/dev/quickstart.html#quickstart) guide is available for TextBlob that is recommended for experienced Python developers
-When attempting to identify *noun phrases*, TextBlob offers several options of extractors to find noun phrases. Take a look at `ConllExtractor`.
+When attempting to identify *noun phrases*, TextBlob offers several options of extractors to find noun phrases.
-```python
-from textblob import TextBlob
-from textblob.np_extractors import ConllExtractor
-# import and create a Conll extractor to use later
-extractor = ConllExtractor()
-
-# later when you need a noun phrase extractor:
-user_input = input("> ")
-user_input_blob = TextBlob(user_input, np_extractor=extractor) # note non-default extractor specified
-np = user_input_blob.noun_phrases
-```
+1. Take a look at `ConllExtractor`.
-> What's going on here? [ConllExtractor](https://textblob.readthedocs.io/en/dev/api_reference.html?highlight=Conll#textblob.en.np_extractors.ConllExtractor) is "A noun phrase extractor that uses chunk parsing trained with the ConLL-2000 training corpus." ConLL-2000 refers to the 2000 Conference on Computational Natural Language Learning. Each year the conference hosted a workshop to tackle a thorny NLP problem, and in 2000 it was noun chunking. A model was trained on the Wall Street Journal, with "sections 15-18 as training data (211727 tokens) and section 20 as test data (47377 tokens)". You can look at the procedures used [here](https://www.clips.uantwerpen.be/conll2000/chunking/) and the [results](https://ifarm.nl/erikt/research/np-chunking.html).
+ ```python
+ from textblob import TextBlob
+ from textblob.np_extractors import ConllExtractor
+ # import and create a Conll extractor to use later
+ extractor = ConllExtractor()
+
+ # later when you need a noun phrase extractor:
+ user_input = input("> ")
+ user_input_blob = TextBlob(user_input, np_extractor=extractor) # note non-default extractor specified
+ np = user_input_blob.noun_phrases
+ ```
-## Task: Improving your bot with a little NLP
+ > What's going on here? [ConllExtractor](https://textblob.readthedocs.io/en/dev/api_reference.html?highlight=Conll#textblob.en.np_extractors.ConllExtractor) is "A noun phrase extractor that uses chunk parsing trained with the ConLL-2000 training corpus." ConLL-2000 refers to the 2000 Conference on Computational Natural Language Learning. Each year the conference hosted a workshop to tackle a thorny NLP problem, and in 2000 it was noun chunking. A model was trained on the Wall Street Journal, with "sections 15-18 as training data (211727 tokens) and section 20 as test data (47377 tokens)". You can look at the procedures used [here](https://www.clips.uantwerpen.be/conll2000/chunking/) and the [results](https://ifarm.nl/erikt/research/np-chunking.html).
+
+### Challenge - improving your bot with NLP
In the previous lesson you built a very simple Q&A bot. Now, you'll make Marvin a bit more sympathetic by analyzing your input for sentiment and printing out a response to match the sentiment. You'll also need to identify a `noun_phrase` and ask about it.
@@ -155,18 +159,18 @@ Here is the code snippet to determine sentiment using TextBlob. Note there are o
```python
if user_input_blob.polarity <= -0.5:
- response = "Oh dear, that sounds bad. "
+ response = "Oh dear, that sounds bad. "
elif user_input_blob.polarity <= 0:
- response = "Hmm, that's not great. "
+ response = "Hmm, that's not great. "
elif user_input_blob.polarity <= 0.5:
- response = "Well, that sounds positive. "
+ response = "Well, that sounds positive. "
elif user_input_blob.polarity <= 1:
- response = "Wow, that sounds great. "
+ response = "Wow, that sounds great. "
```
Here is some sample output to guide you (user input is on the lines with starting with >):
-```
+```output
Hello, I am Marvin, the friendly robot.
You can end this conversation at any time by typing 'bye'
After typing each answer, press 'enter'
@@ -182,6 +186,7 @@ Hmm, that's not great. Can you tell me more about old hounddogs?
> bye
It was nice talking to you, goodbye!
```
+
One possible solution to the task is [here](solution/bot.py)
β
Knowledge Check
@@ -191,6 +196,7 @@ One possible solution to the task is [here](solution/bot.py)
3. Why would extracting a 'noun phrase' from a sentence a useful thing to do?
---
+
## πChallenge
Take a task in the prior knowledge check and try to implement it. Test the bot on a friend. Can it trick them? Can you make your bot more 'believable?'
@@ -200,6 +206,7 @@ Take a task in the prior knowledge check and try to implement it. Test the bot o
## Review & Self Study
In the next few lessons you will learn more about sentiment analysis. Research this interesting technique in articles such as these on [KDNuggets](https://www.kdnuggets.com/tag/nlp)
+
## Assignment
[Make a bot talk back](assignment.md)