I'm reading the paper below and I have some trouble , understanding the concept of negative sampling.
http://arxiv.org/pdf/1402.3722v1.pdf
Can anyone help , please?
I'm reading the paper below and I have some trouble , understanding the concept of negative sampling.
http://arxiv.org/pdf/1402.3722v1.pdf
Can anyone help , please?
The idea of word2vec
is to maximise the similarity (dot product) between the vectors for words which appear close together (in the context of each other) in text, and minimise the similarity of words that do not. In equation (3) of the paper you link to, ignore the exponentiation for a moment. You have
v_c * v_w
-------------------
sum(v_c1 * v_w)
The numerator is basically the similarity between words c
(the context) and w
(the target) word. The denominator computes the similarity of all other contexts c1
and the target word w
. Maximising this ratio ensures words that appear closer together in text have more similar vectors than words that do not. However, computing this can be very slow, because there are many contexts c1
. Negative sampling is one of the ways of addressing this problem- just select a couple of contexts c1
at random. The end result is that if cat
appears in the context of food
, then the vector of food
is more similar to the vector of cat
(as measures by their dot product) than the vectors of several other randomly chosen words (e.g. democracy
, greed
, Freddy
), instead of all other words in language. This makes word2vec
much much faster to train.
word2vec
, for any given word you have a list of words that need to be similar to it (the positive class) but the negative class (words which are not similar to the targer word) is compiled by sampling.
– mbatchkarov
Jan 30 '16 at 18:28
Computing Softmax (Function to determine which words are similar to the current target word) is expensive since requires summing over all words in V (denominator), which is generally very large.
What can be done?
Different strategies have been proposed to approximate the softmax. These approaches can be grouped into softmax-based and sampling-based approaches. Softmax-based approaches are methods that keep the softmax layer intact, but modify its architecture to improve its efficiency (e.g hierarchical softmax). Sampling-based approaches on the other hand completely do away with the softmax layer and instead optimise some other loss function that approximates the softmax (They do this by approximating the normalization in the denominator of the softmax with some other loss that is cheap to compute like negative sampling).
The loss function in Word2vec is something like:
Which logarithm can decompose into:
With some mathematic and gradient formula (See more details at 3) it converted to:
As you see it converted to binary classification task (y=1 positive class, y=0 negative class). As we need labels to perform our binary classification task, we designate all context words c as true labels (y=1, positive sample), and k randomly selected from corpora as false labels (y=0, negative sample).
Look at the following paragraph. Assume our target word is "Word2vec". With window of 3, our context words are: The
, widely
, popular
, algorithm
, was
, developed
. These context words consider as positive labels. We also need some negative labels. We randomly pick some words from corpus (produce
, software
, Collobert
, margin-based
, probabilistic
) and consider them as negative samples. This technique that we picked some randomly example from corpus is called negative sampling.
Reference :
I wrote an tutorial article about negative sampling here.
Why do we use negative sampling? -> to reduce computational cost
The cost function for vanilla Skip-Gram (SG) and Skip-Gram negative sampling (SGNS) looks like this:
The probability distribution p(w_t+j|w_t)
in SG is computed for all V
vocabs in the corpus with:
V
can easily exceed tens of thousand when training Skip-Gram model. The probability needs to be computed V
times, making it computationally expensive. Furthermore, the normalization factor in the denominator requires extra V
computations.
On the other hand, the probability distribution in SGNS is computed with:
c_pos
is a word vector for positive word, and W_neg
is word vectors for all K
negative samples in the output weight matrix. With SGNS, the probability needs to be computed only K + 1
times, where K
is typically between 5 ~ 20. Furthermore, no extra iterations are necessary to compute the normalization factor in the denominator.
With SGNS, only a fraction of weights are updated for each training sample, whereas SG updates all millions of weights for each training sample.
How does SGNS achieve this? -> by transforming multi-classification task into binary classification task.
With SGNS, word vectors are no longer learned by predicting context words of a center word. It learns to differentiate the actual context words (positive) from randomly drawn words (negative) from the noise distribution.
In real life, you don't usually observe regression
with random words like Gangnam-Style
, or pimples
. The idea is that if the model can distinguish between the likely (positive) pairs vs unlikely (negative) pairs, good word vectors will be learned.
In the above figure, current positive word-context pair is (drilling
, engineer
). K=5
negative samples are randomly drawn from the noise distribution: minimized
, primary
, concerns
, led
, page
. As the model iterates through the training samples, weights are optimized so that the probability for positive pair will output p(D=1|w,c_pos)≈1
, and probability for negative pairs will output p(D=1|w,c_neg)≈0
.