Tokenization

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Tokenization is the process of segmenting the input into [[Grammar_Specs#Node|nodes]], i.e., the tokens or processing units of the UNL framework. In [[UNLization]], tokenization corresponds to splitting the natural language input into lexical items, i.e., to recognize that the string "Barking dogs seldom bite" contains 7 tokens: [barking][ ][dogs][ ][seldom][ ][bite]. In [[NLization]], tokenization  corresponds to splitting the UNL graph into UWs, relations and attributes, i.e., to recognize that, in the graph "agt(bite,dog.@pl)mod(dog.@pl,bark)tim(bite,seldom)", there is three relations ("agt", "mod" and "tim"), one attribute ("@pl") and 4 UWs ("bite", "dog", "bark" and "seldom").
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Tokenization is the process of segmenting the input into [[Grammar_Specs#Node|nodes]], i.e., the tokens or processing units of the UNL framework. In [[UNLization]], tokenization corresponds to splitting the natural language input into lexical items, i.e., to recognize that the string "Barking dogs seldom bite" contains 7 tokens: [barking][ ][dogs][ ][seldom][ ][bite], if these entries are provided in the dictionary. In [[NLization]], tokenization  corresponds to splitting the UNL graph into UWs, relations and attributes, i.e., to recognize that, in the graph "agt(bite,dog.@pl)mod(dog.@pl,bark)tim(bite,seldom)", there is three relations ("agt", "mod" and "tim"), one attribute ("@pl") and 4 UWs ("bite", "dog", "bark" and "seldom").
  
 
== UNLization (tokenization of natural language input) ==
 
== UNLization (tokenization of natural language input) ==

Revision as of 00:22, 28 July 2012

Tokenization is the process of segmenting the input into nodes, i.e., the tokens or processing units of the UNL framework. In UNLization, tokenization corresponds to splitting the natural language input into lexical items, i.e., to recognize that the string "Barking dogs seldom bite" contains 7 tokens: [barking][ ][dogs][ ][seldom][ ][bite], if these entries are provided in the dictionary. In NLization, tokenization corresponds to splitting the UNL graph into UWs, relations and attributes, i.e., to recognize that, in the graph "agt(bite,dog.@pl)mod(dog.@pl,bark)tim(bite,seldom)", there is three relations ("agt", "mod" and "tim"), one attribute ("@pl") and 4 UWs ("bite", "dog", "bark" and "seldom").

Contents

UNLization (tokenization of natural language input)

The tokenization of the natural language input follows the general principles below:

  1. Except for digits, the tokenization algorithm is strictly dictionary-based
    The system tries to match the strings of the natural language input against the entries existing in the dictionary. In case it does not succeed, the string is treated as a temporary entry. There is not predefined token: spaces and punctuation signs have to be inserted in the dictionary in order to be treated as non-temporary entries. For instance, if the dictionary is empty, the string "Barking dogs seldom bite" will be considered as a single token. If the dictionary contains only the entry [d], the input will be tokenized as [Barking ][d][ogs sel][d][om bite].
  2. The tokenization algorithm tries to match first the longest entries in the dictionary.
    The system tries to match first the longest entries. If the dictionary contains only two entries: [d] and [do], the string "Barking dogs seldom bite" will be tokenized as [Barking ][do][gs sel][do][m bite], instead of [Barking ][d][ogs sel][d][om bite], because the length of [do] is larger than the lenght of [d].
  3. The tokenization algorithm goes from left to right.
    The system tokenizes first the leftmost entries. If the dictionary contains only two entries: [do] and [og], with the same length and with the same frequency, the string "Barking dogs seldom bite" will be tokenized as [Barking ][do][gs sel][do][m bite], instead of [Barking d][og][s sel][do][m bite], because [do] appears first than [og].
  4. The tokenization algorithm observes the frequency of the entries informed the dictionary (the highest frequent entries come first).
    The system observes the frequency defined in the dictionary. If the dictionary contains only two entries: [do] and [og], but the frequency of [og] is higher than the frequency of [og], the string "Barking dogs seldom bite" will be tokenized as [Barking d][og][s sel][do][m bite], instead of [Barking ][do][gs sel][do][m bite].
  5. The tokenization algorithm observes the order of the entries in the dictionary (the system selects the first to appear in case of same frequency)
    The system observes the order defined in the dictionary. If the dictionary contains only two entries: [do] and [og], but [og] appears first in the dictionary, the string "Barking dogs seldom bite" will be tokenized as [Barking d][og][s sel][do][m bite], instead of [Barking ][do][gs sel][do][m bite].
  6. The tokenization algorithm is case-insensitive, except in case of regular expressions
    the string "a" will matched by both [a] and [A], but the entry [/a/] will match only the string "a"
  7. The tokenization algorithm assigns the feature TEMP (temporary) to the strings that were not found in the dictionary.
    If the dictionary contains only the entry [d], the input will be tokenized as [Barking ][d][ogs sel][d][om bite], and the tokens [Barking ],[ogs sel] and [om bite] will receive the feature TEMP.
  8. The tokenization algorithm blocks tokens or sequences of tokens prohibited by disambiguation rules.
    If the disambiguation grammar contains the rule ("do")("gs sel")=0, and the dictionary contains only two entries: [do] and [og], the string "Barking dogs seldom bite" will be tokenized as [Barking d][og][s sel][do][m bite], regardless the frequency and the order of [do] and [og], because the the possibility of "do" being followed by "gs sel" is prohibited by the grammar.
  9. In case of several possible candidates, the tokenization algorithm picks the ones induced by disambiguation rules, if any.
    If the disambiguation grammar contains the rule ("og")("s sel")=1, and the dictionary contains only two entries: [do] and [og], the string "Barking dogs seldom bite" will be tokenized as [Barking d][og][s sel][do][m bite], regardless the frequency and the order of [do] and [og], because the the possibility of "og" being followed by "s sel" is induced by the grammar.
  10. Retokenization can be done only in the case of entries having the feature TEMP

Tokenization of spaces, punctuation signs and symbols

The tokenization does not have any system-defined tokens except for digits. Any token has be to inserted in the dictionary in order to recognized as a non-temporary entry.

input dictionary tokenization output
a b empty ["a b"], where "a b" = TEMP
a b [a] {} "a" (A) <,,>; [a][" b"], where [" b"] = TEMP
a b [b] {} "b" (B) <,,>; ["a "][b], where ["a "] = TEMP
a b [a] {} "a" (A) <,,>;
[b] {} "b" (B) <,,>;
[a][" "][b], where [" "] = TEMP
a b [a] {} "a" (A) <,,>;
[b] {} "b" (B) <,,>;
[ ] {} "" (BLK) <,,>;
[a][ ][b] (no temporary entries)

Tokenization of digits

Any sequence of isolated digits (i.e., sided by non-temporary tokens) is considered one single token and receives the features TEMP and DIGIT. The UW is considered to be the digit.

input dictionary tokenization output
1234 empty [1234] {} "1234" (TEMP,DIGIT) <,,>;
1,234 empty [1,234]{}""(TEMP)<,,>;
1,234 [,]{}""(COMMA)<,,> [1]{}""(TEMP,DIGIT)<,,>;
[,]{}""(COMMA)<,,>;
[234]{}"234"(TEMP,DIGIT)<,,>;
abc123 empty ["abc123"]{}""(TEMP)<,,>;
abc123 [abc]{}"abc"{}(A)<,,>; [abc]{}"abc"(A)<,,>;
[123]{}"123"(DIGIT)<,,>;

Tokenization of temporary entries

Any sequence of characters except digits (and including special symbols, such as space and punctuation signs) not found in the dictionary is considered a temporary entry and receives the feature TEMP. The UW is considered to be empty.

input dictionary tokenization output
asdfg empty ["asdfg"]{}""(TEMP) <,,>;
asdfg hijkl empty ["asdfg hijkl"]{}""(TEMP)<,,>;
asdfg hijlk [ ]{}""(BLK)<,,>; ["asdfg"]{}""(TEMP)<,,>;
[ ]{}""(BLK)<,,>;
["hijlk"]{}""(TEMP)<,,>;

Tokenization of natural language entries

Dictionary

[abcde]{}""(...)<...>;
[abcd]{}""(...)<...>;
[bcde]{}""(...)<...>;
[abc]{}""(...)<...>;
[bcd]{}""(...)<...>;
[cde]{}""(...)<...>;
[ab]{}""(...)<...>;
[bc]{}""(...)<...>;
[cd]{}""(...)<...>;
[de]{}""(...)<...>;
[a]{}""(A1,...)<...>;
[a]{}""(A2,...)<...>;
[b]{}""(B1,...)<...>;
[b]{}""(B2,...)<...>;
[c]{}""(C1,...)<...>;
[c]{}""(C2,...)<...>;
[d]{}""(D1,...)<...>;
[d]{}""(D2,...)<...>;
[e]{}""(E1,...)<...>;
[e]{}""(E2,...)<...>;


Case 1
input: "abcde"
disambiguation rule: NONE
tokenization output: [abcde] (the longest entry in the dictionary)
Case 2
input: "abcde"
disambiguation rule: ("abcde")=0; (prohibits the sequence "abcde")
tokenization output: [abcd][e] (the second longest possibility from left to right according to the dictionary)
Case 3
input: "abcde"
disambiguation rules: ("abcde")=0;("abcd")("e")=0;
tokenization output: [a][bcde] (the third longest possibility from left to right according to the dictionary)
Case 4
input: "abcde"
disambiguation rules: ("abcde")=0;("abcd")("e")=0;("a")("bcde")=0;
tokenization output: [abc][de] (the fourth longest possibility from left to right according to the dictionary)
Case 5
input: "abcde"
disambiguation rules: ("/.{3,5}/")=0; (prohibits any token made of 3, 4 or 5 characters)
tokenization output: [ab][cd][e]
Case 6
input: "abXcYde"
disambiguation rule: NONE
tokenization output: [ab][X][c][Y][de] (where [X] and [Y] are temporary entries)

Properties of tokenization

Positive disambiguation rules only apply over candidates to the same position with the same length
Case 7
input: "abcde"
disambiguation rule: ("abcd")("e")=100; (induces the sequence [abcd][e])
tokenization output: [abcde] (positive disambiguation rules do not prevail over the principle of longest first)
Case 8
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (prohibits any token made of 2, 3, 4 or 5 characters)
tokenization output: [a,A1][b,B1][c,C1][d,D1][e,E1] (among the candidates, these entries come first in the dictionary)
Case 9
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (A2)(B2)=1; (induces the sequence [A2][B2])
tokenization output: [a,A2][b,B2][c,C1][d,D1][e,E1] (A2 and B2 were chosen instead of A1 and B1)
Positive disambiguation rules apply according to their probability and, inside the same probability, according to their order in the grammar
Case 10
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (A2)(B2)=1; (A2)(B1)=1; (induces the sequence [A2][B1])
tokenization output: [a,A2][b,B2][c,C1][d,D1][e,E1] (the rule [A2][B2] has the some probability as [A2][B1] and comes first in the grammar)
Case 11
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (A2)(B2)=1; (A2)(B1)=2; (induces the sequence [A2][B1])
tokenization output: [a,A2][b,B1][c,C1][d,D1][e,E1] (the priority of the rule [A2][B1] is higher than [A2][B2])
Case 12
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (A2)(B2)=1; (B1)(C2)=2; (induces the sequence [A2][B1])
tokenization output: [a,A1][b,B1][c,C2][d,D1][e,E1] (the priority of the rule [B1][C2] is higher than [A2][B2])
The attribute #FINAL is used to indicate context
Case 13
input: "abcde"
disambiguation rule: ("/.{2,5}/")=0; (A2)(B2)=1; (B1,#FINAL)(C2)=5; (if B1 is fixed, C2 must be chosen)
tokenization output: [a,A2][b,B2][c,C1][d,D1][e,E1] (the same as case 11; compare with case 12 - note that the rule (B1,#FINAL)(C2) does not induce the choice of B1; it applies only to C2, i.e., it indicates that, if B1, then C2)
The tokenization algorithm backtracks in case of dead-ends.

In case of backtracking, the tokenization starts merging nodes from left to right, but considering their size, i.e., the shortest combinations appear first.

Case 14
input: "abcde"
dictionary:

[a]{}""(...)<...>;
[b]{}""(...)<...>;
[c]{}""(...)<...>;
[d]{}""(...)<...>;
[e]{}""(...)<...>;

disambiguation rule: ("a")("b")("c")("d")("e")=0;
tokenization output: [ab][b][c][d][e] (the first combination of shortest temporary nodes from left to right after [a][b][c][d][e], which was blocked by the disambiguation rule. Note that [ab] is not in the dictionary and, therefore, will be treated as TEMP)

Retokenization

Temporary nodes (i.e., nodes having the feature TEMP) may be retokenized. In order to retokenize (split) a non-temporary node, it is necessary to assign the feature TEMP to it (but this does not affect any existing feature, including the headword and the UW).
Examples:

  • Infixation: add the character "c" between the characters "b" and "d" in case of verbs (V) in the past tense (PAS): abde > abcde, bbdd > bbcde, xbdy > xbcdy, etc.

Grammar

  1. ("/.+bd.+/",V,PAS,%x):=(%x,+TEMP,+SPLIT); (assigns TEMP to the node %x if it is V and PAS and contains the string "bd" inside)
  2. ("/.+b/",SPLIT,%x1)("/d.+/",SPLIT,%x2):=(%x1,-SPLIT,+MERGE)("c",MERGE)(%x2,[],[[]],-SPLIT,+MERGE); (split the string and add "c" after "b" and before "d")
  3. (%x,MERGE)(%y,MERGE):=(%x&%y); (merge two adjacent nodes having the feature MERGE)
  4. (%x,^MERGE)(%y,MERGE)(%z,^MERGE); (delete the feature MERGE if there is nothing else to be merged)
  5. (%x,^MERGE,^SPLIT,^[[]],TEMP):=(%x,-TEMP); (delete the feature TEMP if there is nothing to be merged or split and the node has a UW)

Trace
0 ("abde",[abde],[[abde]],V,PAS) original node
1 ("abde",[abde],[[abde]],V,PAS,TEMP,SPLIT) after applying rule 1 (add TEMP and SPLIT)
2 ("ab",[abde],[[abde]],V,PAS,TEMP,MERGE)("c",MERGE)("de",[],[[]],V,PAS,TEMP,MERGE) after applying rule 2 (split "abde" and create "c" in the middle)
3 ("abc",[abde],[[abde]],V,PAS,TEMP,MERGE) after applying rule 3 (merge "ab" with "c")
4 ("abcde",[abde],[[abde]],V,PAS,TEMP,MERGE) after applying rule 3 (merge "abc" with "de")
5 ("abcde",[abde],[[abde]],V,PAS,TEMP) after applying rule 4 (remove MERGE)
6 ("abcde",[abde],[[abde]],V,PAS) after applying rule 5 (remove TEMP)
Observations:

Splitting operations affect only strings. All the features of the source node, including headword and UW, are preserved in the target nodes

Given the node ("abcd",[abcd],[[abcd]],A),
the retokenization rule ("ab",%x)("cd",%y):=(%x)("1",%z)(%y);
does not affect the original headword, UW and feature, i.e.:
the nodes ("ab") and ("cd") still have, each one, the features [abcd],[[abcd]],A.
Because of that, it is important (as indicated in the rule 2 above) to delete the UW and the headword of all split nodes except one; otherwise, when we merge them back, the UW and the headword will be multiplied, because the merge rule concatenates strings, UWs and headwords. For instance, if the rule 2 in the grammar above were:
2 ("/.+b/",SPLIT,%x1)("/d.+/",SPLIT,%x2):=(%x1,-SPLIT,+MERGE)("c",MERGE)(%x2,-SPLIT,+MERGE); (i.e., if it did not contain [],[[]])
The final result would have been:
6 ("abcde",[abdeabde],[[abdeabde]],V,PAS)

NLization (tokenization of UNL input)

The tokenization of the UNL input does not involve special issues. It simply follows the structure of the UNL document, which is not ambiguous.

Case 15
Dictionary:

[x]{}"x"(...)<...>;
[xa]{}"x.@a"(...)<...>;
[xab]{}"x.@a.@b"(...)<...>;
[y]{}"y"(...)<...>;

Input:

agt(x.@a.@b,y)

Tokenization output

agt([xab],[y])

Software