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
Initialize Length[N]
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[]
```

Where

- The array
`Length`

holds the lengths (normalization factors) for each of the `N`

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|`

, where `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 `T`

and `D`

are large the search is really slow and one has to find an alternative approach).