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Table of Contents
Michael Collins, Nigel Duffy: Convolution kernels for natural language
Questions
- What is a generative model, what is a discriminative model and what is their main difference?
- What are the “fairly strong independence assumptions” in PCFG? Come up with an example tree that can't be modelled by a PCFG.
- Derive and explain the formula for h(T1)*h(T2) on page 3 at the bottom.
- What is a convolution? Why are “convolution” kernels called like this?
- Find an error in one of the formulae in the paper.
Answers
- Generative models use a two-step setup. They learn class-conditional (likelihood) <latex>P(x|y)</latex>, prior <latex>P(y)</latex> and use the Bayes rule to obtain the posterior.
- they learn the joint distributions: marginalize P(y), condition P(y|x) = P(x,y) / P(x)
- They learn more than is actually needed, but are not prone to partially missing input data.
- They are able to “generate” fake inputs, but this feat is not used very often.
- Examples: Naive Bayes, Mixtures of Gaussians, HMM, Bayesian Networks, Markov Random Fields
- Discriminative models do everything in one-step – they learn the posterior <latex>P(y|x)</latex> as a function of some features of <latex>x</latex>.
- They are simpler and can use many more features, but are prone to missing inputs.
- Examples: SVM, Logistic Regression, Neuron. sítě, k-NN, Conditional Random Fields
- Each CFG rule generates just one level of the derivation tree. Therefore, using “standard” nonterminals, it is not possible to generate e.g. this sentence:
(S (NP (PRP He)) (VP (VBD saw)(NP (PRP himself))))
- It could be modelled with an augmentation of the nonterminal labels.
- CFGs can't generate non-projective sentences.
- But they can be modelled using traces.
- The derivation is actually quite simple:
- <latex>h(T_a)\cdot h(T_b) = \sum_i h_i(T_a) \cdot h_i(T_b)</latex> – (definition of the dot product)
- <latex>= \sum_i \left(\sum_{n_a \in N_a} I_i(n_a)\right) \left(\sum_{n_b \in N_b} I_i(n_b)\right)</latex> (from the definition of <latex>I</latex> in the paragraph above the formula)
- <latex>= \sum_i\sum_{n_a \in N_a}\sum_{n_b \in N_b} I_i(n_b)\cdot I_i(n_a)</latex> (since <latex>(a+b)(c+d) = ac+ad+bc+bd</latex>)
- <latex>= \sum_{n_a \in N_a}\sum_{n_b \in N_b}\sum_i I_i(n_b)\cdot I_i(n_a)</latex> (change summation order)
- <latex>= \sum_{n_a \in N_a}\sum_{n_b \in N_b}C(n_a, n_b)</latex> (definition of <latex> C </latex>)