Lucene basically uses a
Vector Space Model (VSM) with a
tf-idf scheme. So, in the standard setting we have:
- A collection of documents each represented as a vector
- A text query also represented as a vector
We determine the
K documents of the collection with the highest vector space scores on the query
q. Typically, we seek these K top documents ordered by score in decreasing order; for instance many search engines use K = 10 to retrieve and rank-order the first page of the ten best results.
The basic algorithm for computing vector space scores is:
float Scores[N] = 0
for each query term t
do calculate w(t,q) and fetch postings list for t (stored in the index)
for each pair d,tf(t,d) in postings list
do Scores[d] += wf(t,d) X w(t,q) (dot product)
Read the array Length[d]
for each d
do Scored[d] = Scores[d] / Length[d]
return Top K components of Scores
- The array
Length holds the lengths (normalization factors) for each of the
documents, whereas the array
Scores holds the scores for each of the documents.
tf is the term frequency of a term in a document.
w(t,q) is the weight of the submitted query for a given term. Note that query is treated as a
bag of words and the vector of weights can be considered (as if it was another document).
wf(d,q) is the logarithmic term weighting for query and document
As described here: Complexity of vector dot-product, vector dot-product is
O(n). Here the dimension is the number of terms in our vocabulary:
T is the set of terms.
So, the time complexity of this algorithm is:
O(|Q|· |D| · |T|) = O(|D| · |T|)
we consider |Q| fixed, where
Q is the set of words in the query (which average size is low, in average a query has between 2 and 3 terms) and
D is the set of all documents.
However, for a search, these sets are bounded and indexes don't tend to grow very often. So, as a result, searches using VSM are really fast (when
D are large the search is really slow and one has to find an alternative approach).