- Elasticsearch Guide: other versions:
- Getting Started
- Set up Elasticsearch
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- Percentiles Bucket Aggregation
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- Overview
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- Tutorial: Getting started with security
- Tutorial: Encrypting communications
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- Definitions
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- Release Notes
- Elasticsearch version 6.5.4
- Elasticsearch version 6.5.3
- Elasticsearch version 6.5.2
- Elasticsearch version 6.5.1
- Elasticsearch version 6.5.0
- Elasticsearch version 6.4.3
- Elasticsearch version 6.4.2
- Elasticsearch version 6.4.1
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- Elasticsearch version 6.2.2
- Elasticsearch version 6.2.1
- Elasticsearch version 6.2.0
- Elasticsearch version 6.1.4
- Elasticsearch version 6.1.3
- Elasticsearch version 6.1.2
- Elasticsearch version 6.1.1
- Elasticsearch version 6.1.0
- Elasticsearch version 6.0.1
- Elasticsearch version 6.0.0
- Elasticsearch version 6.0.0-rc2
- Elasticsearch version 6.0.0-rc1
- Elasticsearch version 6.0.0-beta2
- Elasticsearch version 6.0.0-beta1
- Elasticsearch version 6.0.0-alpha2
- Elasticsearch version 6.0.0-alpha1
- Elasticsearch version 6.0.0-alpha1 (Changes previously released in 5.x)
More Like This Query
editMore Like This Query
editThe More Like This Query finds documents that are "like" a given set of documents. In order to do so, MLT selects a set of representative terms of these input documents, forms a query using these terms, executes the query and returns the results. The user controls the input documents, how the terms should be selected and how the query is formed.
The simplest use case consists of asking for documents that are similar to a provided piece of text. Here, we are asking for all movies that have some text similar to "Once upon a time" in their "title" and in their "description" fields, limiting the number of selected terms to 12.
GET /_search { "query": { "more_like_this" : { "fields" : ["title", "description"], "like" : "Once upon a time", "min_term_freq" : 1, "max_query_terms" : 12 } } }
A more complicated use case consists of mixing texts with documents already existing in the index. In this case, the syntax to specify a document is similar to the one used in the Multi GET API.
GET /_search { "query": { "more_like_this" : { "fields" : ["title", "description"], "like" : [ { "_index" : "imdb", "_type" : "movies", "_id" : "1" }, { "_index" : "imdb", "_type" : "movies", "_id" : "2" }, "and potentially some more text here as well" ], "min_term_freq" : 1, "max_query_terms" : 12 } } }
Finally, users can mix some texts, a chosen set of documents but also provide documents not necessarily present in the index. To provide documents not present in the index, the syntax is similar to artificial documents.
GET /_search { "query": { "more_like_this" : { "fields" : ["name.first", "name.last"], "like" : [ { "_index" : "marvel", "_type" : "quotes", "doc" : { "name": { "first": "Ben", "last": "Grimm" }, "_doc": "You got no idea what I'd... what I'd give to be invisible." } }, { "_index" : "marvel", "_type" : "quotes", "_id" : "2" } ], "min_term_freq" : 1, "max_query_terms" : 12 } } }
How it Works
editSuppose we wanted to find all documents similar to a given input document.
Obviously, the input document itself should be its best match for that type of
query. And the reason would be mostly, according to
Lucene scoring formula,
due to the terms with the highest tf-idf. Therefore, the terms of the input
document that have the highest tf-idf are good representatives of that
document, and could be used within a disjunctive query (or OR
) to retrieve similar
documents. The MLT query simply extracts the text from the input document,
analyzes it, usually using the same analyzer at the field, then selects the
top K terms with highest tf-idf to form a disjunctive query of these terms.
The fields on which to perform MLT must be indexed and of type
text
or keyword`
. Additionally, when using like
with documents, either
_source
must be enabled or the fields must be stored
or store
term_vector
. In order to speed up analysis, it could help to store term
vectors at index time.
For example, if we wish to perform MLT on the "title" and "tags.raw" fields,
we can explicitly store their term_vector
at index time. We can still
perform MLT on the "description" and "tags" fields, as _source
is enabled by
default, but there will be no speed up on analysis for these fields.
PUT /imdb { "mappings": { "movies": { "properties": { "title": { "type": "text", "term_vector": "yes" }, "description": { "type": "text" }, "tags": { "type": "text", "fields" : { "raw": { "type" : "text", "analyzer": "keyword", "term_vector" : "yes" } } } } } } }
Parameters
editThe only required parameter is like
, all other parameters have sensible
defaults. There are three types of parameters: one to specify the document
input, the other one for term selection and for query formation.
Document Input Parameters
edit
|
The only required parameter of the MLT query is |
|
The |
|
A list of fields to fetch and analyze the text from. Defaults to the |
|
The text to find documents like it. |
|
A list of documents following the same syntax as the Multi GET API. |
Term Selection Parameters
edit
|
The maximum number of query terms that will be selected. Increasing this value
gives greater accuracy at the expense of query execution speed. Defaults to
|
|
The minimum term frequency below which the terms will be ignored from the
input document. Defaults to |
|
The minimum document frequency below which the terms will be ignored from the
input document. Defaults to |
|
The maximum document frequency above which the terms will be ignored from the
input document. This could be useful in order to ignore highly frequent words
such as stop words. Defaults to unbounded ( |
|
The minimum word length below which the terms will be ignored. The old name
|
|
The maximum word length above which the terms will be ignored. The old name
|
|
An array of stop words. Any word in this set is considered "uninteresting" and ignored. If the analyzer allows for stop words, you might want to tell MLT to explicitly ignore them, as for the purposes of document similarity it seems reasonable to assume that "a stop word is never interesting". |
|
The analyzer that is used to analyze the free form text. Defaults to the
analyzer associated with the first field in |
Query Formation Parameters
edit
|
After the disjunctive query has been formed, this parameter controls the
number of terms that must match.
The syntax is the same as the minimum should match.
(Defaults to |
|
Controls whether the query should fail (throw an exception) if any of the
specified fields are not of the supported types
( |
|
Each term in the formed query could be further boosted by their tf-idf score.
This sets the boost factor to use when using this feature. Defaults to
deactivated ( |
|
Specifies whether the input documents should also be included in the search
results returned. Defaults to |
|
Sets the boost value of the whole query. Defaults to |
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