{
"paper_id": "A00-1030",
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"date_generated": "2023-01-19T01:12:33.823046Z"
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"title": "Aggressive Morphology for Robust Lexical Coverage",
"authors": [
{
"first": "William",
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"A"
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"last": "Woods",
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"affiliation": {},
"email": "william.woods@east.sun.corn"
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"abstract": "This paper describes an approach to providing lexical information for natural language processing in unrestricted domains. A system of approximately 1200 morphological rules is used to extend a core lexicon of 39,000 words to provide lexical coverage that exceeds that of a lexicon of 80,000 words or 150,000 word forms. The morphological system is described, and lexical coverage is evaluated for random words chosen from a previously unanalyzed corpus.",
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"abstract": [
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"text": "This paper describes an approach to providing lexical information for natural language processing in unrestricted domains. A system of approximately 1200 morphological rules is used to extend a core lexicon of 39,000 words to provide lexical coverage that exceeds that of a lexicon of 80,000 words or 150,000 word forms. The morphological system is described, and lexical coverage is evaluated for random words chosen from a previously unanalyzed corpus.",
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"section": "Abstract",
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"text": "Many applications of natural language processing have a need for a large vocabulary lexicon. However, no matter how large a lexicon one starts with, most applications will encounter terms that are not covered. This paper describes an approach to the lexicon problem that emphasizes recognition of morphological structure in unknown words in order to extend a relatively small core lexicon to allow robust natural language processing in unrestricted domains. This technique, which extends functionality originally developed for the Lunar system (Woods et al., 1972) , has been most recently applied in a conceptual indexing and retrieval system (Woods, 1997; Ambroziak and Woods, 1998; Woods et ai., 2000) .",
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"start": 544,
"end": 564,
"text": "(Woods et al., 1972)",
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"start": 644,
"end": 657,
"text": "(Woods, 1997;",
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"text": "Ambroziak and Woods, 1998;",
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"text": "Woods et ai., 2000)",
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"section": "Motivation",
"sec_num": "1"
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"text": "The system described here uses a collection of approximately 1200 knowledge-based morphological rules to extend a core lexicon of approximately 39,000 words to give coverage that exceeds that of an English lexicon of more than 80,000 base forms (or 150,000 base plus inflected forms). To illustrate the need for a robust extensible lexicon, a random sample of 100 words from the vocabulary of the millionword Brown corpus (Kucera and Francis, 1967) , contained 24 words that were not included in a 300,000word list of English word forms. This suggests that approximately 25% of the words in the Brown corpus would not be covered by an independent lexicon of even 300,000 words.",
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"start": 422,
"end": 448,
"text": "(Kucera and Francis, 1967)",
"ref_id": "BIBREF2"
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"section": "Motivation",
"sec_num": "1"
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"text": "In a recent experiment, 54% of approximately 34,000 word types (numbers and hyphenated words excluded) from a 3.1-million-word corpus of technical literature would not be covered by our hypothet-ical 300,O00-word lexicon. Many of these are special forms (e.g., Nb203 and Ti/tin), and some are apparent misspellings (e.g., auniprocessor and sychronized), but the following are a sampling of fairly normal words that were not in the 300,O00-word list: busmaster copyline hereabove preprocessing uniprocessors unreacted 2 Integrated, Preferential, Heuristic Morphology There are a number of systems that have been used to describe natural language morphology for computational use. The most popular of these is perhaps the finite-state Kimmo system (Koskenniemi, 1983 ). Other approaches are described in (Sproat, 1992) . The system described here differs from other systems in a number of dimensions. First, it is integrated with an extensive lexicon, a semantic ontology, and a syntactic analysis system, which it both consults and augments. For example, subsumption relationships in the semantic ontology enable the system to determine whether a proposed root is a container or a mental attitude, so that cupful is interpreted as a unit of measure (a kind of noun), while hopeful is interpreted as an adjective.",
"cite_spans": [
{
"start": 746,
"end": 764,
"text": "(Koskenniemi, 1983",
"ref_id": "BIBREF1"
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"start": 802,
"end": 816,
"text": "(Sproat, 1992)",
"ref_id": "BIBREF3"
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"section": "Motivation",
"sec_num": "1"
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"text": "Second, it uses ordered preferential rules that attempt to choose a small number of correct analyses of a word (usually 1-3) from the many potential analyses that might be found. Finally, it uses rules that are heuristic in that they are not guaranteed to give correct analyses, but rather are designed to deal with various states of lack of knowledge and to make plausible inferences in the face of uncertainty. The focus is to use what it knows (or can infer) to determine a usable set of part-of-speech classifications for the word and to determine any root-plus-affix or internal compound structure that is apparent. If possible, it also assigns a semantic categorization to the word. It deals with unknown as well as known roots, and it indicates relative confidences in its classifications when its rules indicate uncertainty in the result.",
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"section": "Motivation",
"sec_num": "1"
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"text": "The role of the morphological analysis component in this system is to construct lexical entries for words that do not already have entries, so that subsequent encounters with the same word will find an already existing lexical entry. Thus, morphological analysis happens only once for each encountered word type that is not already in the core lexicon. The resulting lexical entries can be saved in a supplementary lexicon that is constructed as a side-effect of analyzing text. The rules of the morphological analysis system can ask syntactic and semantic questions about potential base forms. The system handles prefixes, suffixes, and lexical compounds (e.g., bitmap and replybuffer). It also handles multiword lexical items and many special forms, including Roman numerals, dates, and apparent phone numbers.",
"cite_spans": [],
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"section": "Motivation",
"sec_num": "1"
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"text": "The morphological analysis system makes use of a number of different kinds of morphological rules, applied in the following preferential order to words that are not already in the lexicon:",
"cite_spans": [],
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"eq_spans": [],
"section": "Morphological rules and the lexicon",
"sec_num": "2.1"
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"text": "1. Morph-precheck for special forms 2. Phase one pass with suffix rules (allow only \"known\" roots in phase one) Generally, the rules are ordered in decreasing order of specificity, confidence and likelihood. Very specific tests are applied in Step 1 to identify and deal with \"words\" that are not ordinary sequences of alphabetic characters. These include numbers, alphanumeric sequences, and expressions involving special characters. Falling this, an ordered sequence of suffix rules is applied in Step 2 in a first pass that will allow a match only if the proposed root word is \"known.\" The same list of rules will be applied later in a second pass without this known-root condition if an earlier analysis does not succeed. This issue of \"known\" roots is a subtle one that can involve consulting external lists of known words as well as words already in the lexicon, and can also consider certain derived forms of known roots to be \"known,\" even when they have not been previously encountered.",
"cite_spans": [],
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"section": "Morphological rules and the lexicon",
"sec_num": "2.1"
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"text": "For example, if.fish is a known word, then fishing is as good as known, so is considered a \"known\" root for this purpose. In general, suffix rules applied to \"known\" roots are more reliable than applications of rules to unknown roots or to words with no identifiable root.",
"cite_spans": [],
"ref_spans": [],
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"section": "Morphological rules and the lexicon",
"sec_num": "2.1"
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"text": "If no phase-one suffix rules apply, prefix rules are tried in Step 3 to see if an interpretation of this word as a prefix combined with some other \"known\" word is possible. Falling this, a set of lexical compound rules is tried, in Step 4, to see if the word is interpretable as a compound of two or more words, and failing that, lists of first and last names of people and names of cities are checked in Step 5. All of steps 3-5 are considered more reliable if they succeed than the phase-two pass of the suffix rules that comes in Step 6. This ordering allows prefixes and compounding to be tried before less confident suffix analyses are attempted, and avoids applying weak suffix analyses to known names. Various other ways to order these rules have been tried, but this order has been found to be the most effective.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Morphological rules and the lexicon",
"sec_num": "2.1"
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"text": "Before trying pattern-based rules for suffixes, prefixes, and lexical compounds, the morphological analyzer makes a number of tests for special forms that require idiosyncratic treatment. These tests include the following:",
"cite_spans": [],
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"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
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"text": "\u2022 number (including integer, floating, and exponential notations, including numbers too large to be represented internally as numbers in the machine),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 Roman numeral (vii, mcm),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 ordinal (1st, 2nd, twenty-third), \u2022 alphanum (Al203, 79D), \u2022 letter (b, x), \u2022 initial (B.),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 phone number (123-4567),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 hyphenated adjective (all-volunteer),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 ratio (s/S, V/R),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "\u2022 multiword lexical item (snake_in_the_grass),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "\u2022 special proper nouns (gls@mit.edu, /usr/bin, http://www.sun.com, C+ + )",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
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"text": "2.3 Pattern-action rules Suffix rules in this system are pattern-action rules that specify:",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "1. a pattern of characters to match at the end of the word to be analyzed, 2. possibly a number of characters to remove and/or a sequence of characters to add to form a root (or base form),",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
{
"text": "3. a sequence of tests and action clauses indicating possible interpretations of a word matching this pattern.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "These rules are organized into blocks that are typically indexed by a shared final letter, and are applied in order within a block until a rule is encountered that generates one or more interpretations. At that point, no further rules are tried, and the interpretations generated by that rule are used to construct a lexical entry for the analyzed word.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "The following is an example of a fairly specific, but productive, knowledge-rich morphological suffix rule:",
"cite_spans": [],
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"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "((f i s h) (kill 4) (test (plausible-root root)) (cat nmsp (is-root-of-cat root '(adj n)) eval (progu (mark-dict lex (mark-dict (mark-dict (mark-dict '-es))) 'false-root root t t) lex 'kindof 'fish t t) lex 'has-prefix root t t) lex 'root 'fish t t)",
"cite_spans": [],
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"section": "Special form tests",
"sec_num": "2.2"
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"text": "This rule matches a word that ends in fish and removes four letters from the end (the fish part) to produce a root word which it then tests to see if it is a plausible root (e.g., does it at least have a vowel in it?). If it gets this fax, the rule will construct a category nmsp interpretation (a kind of noun), if the condition (is-root-of-cat root ' (adj n)) is true (i.e., if the root is a known adjective or noun).",
"cite_spans": [],
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"section": "Special form tests",
"sec_num": "2.2"
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"text": "This rule deals with words like hagfish and goatfish and comes before the rules that handle words with ish as a suffix, like doltish and oafish. Incidentally, this rule doesn't apply to oafish because the hypothesized root on, which would result from removing four letters, is not known to be an adjective or noun. When this rule succeeds, it specifies that the word will be assigned the category nmsp, a category indicating a word that has a mass sense, a singular count sense, and can also be used as a plural (e.g., Goatfish are 1%nny-looking.). (The category nmsp comes from a collection of 91 syntactic categories, organized in a hierarchy based on generality, so that, for example, nm subsumes nmsp.) The action part of this rule specifies that (contrary to the usual case) the \"root\" obtained by removing characters from the end of the word (e.g., goat) is in this case a false root. The real root is fish, and the false root (goat) is actually a prefix. The rule also specifies that the word refers to a kind of fish and that the inflectional paradigm for this word is -es (thus allowing goatfishes as an alternative plural).",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "The rules within a block are ordered in decreasing order of confidence and specificity. Thus, rules with conditions that check explicit inflectional paradigms of known roots are ordered before rules that guess the inflectional paradigm from the spelling of the root, and rules with more specific conditions are ordered before rules with less specific conditions so that the latter can assume that the former will already have been tested and rejected. The rules within a block of suffix rules will typically try for interpretations in roughly the following order: The last rule in this sequence is a default guessing rule that depends on a flag that tells it whether it is running with a core lexicon that is believed to contain most nonobvious verbs. If so, then only the noun part-of-speech is assigned, but with a smaller core lexicon, the guessing rules would also assign a less likely interpretation as a verb, in order to provide a way for unknown verbs to be parsed correctly in sentences.",
"cite_spans": [],
"ref_spans": [],
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"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "Prefix rules are similar in structure to suffix rules, except that the pattern is matched at the beginning of the word, and the rule blocks are indexed by the initial letter of the word. Lexical compound rules have a slightly different format and are called by a specialized interpreter that looks for places to divide a word into two pieces of sufficient size. The points of potential decomposition are searched from right to left, and the first such point that has an interpretation is taken, with the following exception: The morph compound analyzer checks for special cases where, for example, the first word is plural and ends in an s, but there is an alternative segmentation in which the singular of the first word is followed by a word starting with the s. In such cases, the decomposition using the singular first word is preferred over the one using the plural. For example, the word minesweeper will be analyzed as mine+sweeper rather than mines+weeper. This preference heuristic is specific to English and might be different for other languages.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Special form tests",
"sec_num": "2.2"
},
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"text": "When attempting to apply a rule to a word, the morphological analyzer can be applied recursively to analyze the hypothesized root. A simple caching technique is used to control the potential for combinatoric explosion and to block looping. This is sufficiently effective that the time required for morphological analysis is a negligible part of the time required for processing large amounts of natural language text. Protection against looping is especially important for a kind of morphological rule that derives one word from another without either of them being a root of the other in the usual sense (e.g., deriving communist from communism or external from internal). Operating in a loop-safe environment allows rules like these to identify the relationship between a new word and a known word in either direction, whichever of the two forms is encountered first.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Recursive application of rules",
"sec_num": "2.4"
},
{
"text": "Since analyzing a word is done once per unknown word type and consumes a negligible fraction of the overall text-processing time, speed of operation is not considered a factor for evaluation. The interesting dimension of evaluation deals with the coverage of the rules and the kinds of errors that are made. This was tested by applying the system to two word lists randomly selected from the Brown corpus and provided to me by Philip Resnik, using some sampling tools that he developed. The first of these (the token sample) consists of 100 word tokens selected randomly, without eliminating duplicates, and the second (the type sample) consists of 100 distinct word types selected randomly from the vocabulary of the Brown corpus. Prior to a single test run on each of these samples, neither the lexicon nor the morphological rule system had any exposure to the Brown corpus, nor had either of these word lists been looked at by the experimenter. Consequently, the results are a fair evaluation of the expected performance of this system on an unknown domain.",
"cite_spans": [],
"ref_spans": [],
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"section": "Evaluation",
"sec_num": "3"
},
{
"text": "Since different syntactic category errors have different consequences for parsing text, it is useful to grade the syntactic category assignments of the analyzer on an A-B-C-D-F scale according to the severity of any mistakes. Grades are assigned to a lexical entry as follows:",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Grading rule performance",
"sec_num": "3.1"
},
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"text": "A if all appropriate syntactic categories are assigned and no incorrect categories are assigned B if all categories are correct, allowing for categorizing an adjective or a name as a noun or a noun as a name C if an entry has at least one correct category and is correct except for missing a noun category or having a single extra category D if there is more than one extra category or if there is a missing category other than one of the above cases, provided that there is at least one correct category F if there are no correct categories Both A and B grades are considered acceptable assignments for the sake of evaluation, since category B errors would allow a reasonable parse to be found. This is because the grammar used for parsing sentences and phrases allows a noun to be used as an adjective modifier and a proper noun to be used in place of a noun. One parser/grammar that uses this lexicon also allows any other categoo; to be used as a noun, at the expense of a penalty, so that a C grade will still enable a parse, although with a penalty and a substantial likelihood that other false parses might score better. Similarly, a D grade increases the likelihood that a false parse might score better.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Grading rule performance",
"sec_num": "3.1"
},
{
"text": "Separately, we measure whether count/mass distinctions are made correctly (for nouns only), and whether roots of derived and inflected forms are identified correctly.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Grading rule performance",
"sec_num": "3.1"
},
{
"text": "We are interested in the count/mass distinction because, like the common/proper noun distinction, it affects the grammaticality and likelihood of a noun phrase interpretation for a singular noun in absence of an explicit determiner.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Grading rule performance",
"sec_num": "3.1"
},
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"text": "The morphological analyzer has been applied to the words from the two sample word lists that were not already in its core lexicon. There were 17 such words from the token sample and 72 such words from the type sample. Of the 17 unknown tokensample words, 100% were graded B or better (88% A and 12% B); 85% of the roots were identified correctly (all but one); 85% of the count noun senses were found (all but one); and 100% of the mass noun senses were found. Token-sample performance is not a very challenging test for a morphological analyzer because it is biased toward a relatively small number of frequently occurring word types. Token-sample performance is used to assess the per-token error rate that one would expect in analyzing large amounts of running text. In contrast, type-sample performance gives a measure of the expected performance on new words the analyzer is likely to encounter. For the 72 words in the type sample that are not covered by the lexicon, Tables 1-3 show the syntactic category performance of the analyzer and its abilities to make count/mass distinctions and identify roots.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Sampling rule performance",
"sec_num": "3.2"
},
{
"text": "Notes on incorrect or debatable analyses:",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Sampling rule performance",
"sec_num": "3.2"
},
{
"text": "1. One N (noun) for a probable name (Tonio), counted as B. 2. Two NPR(proper name) for abbreviations;",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Sampling rule performance",
"sec_num": "3.2"
},
{
"text": "(A. V. may be ADJ, W.B. is correct), counted as one B and one A.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Sampling rule performance",
"sec_num": "3.2"
},
{
"text": "3. One wrong root when suffix ism was identified as root of hooliganism in a hypothesized compound hooligan+ism (arguably justifiable as a kind of ism, which is known in the lexicon, but counted as an error anyway). Reanalyzing this word after hooligan is a known word gets the correct interpretation. 4. One debatable root in the hyphenated phrase reference-points whose root was listed as points rather than reference-point. This is due to a bug that caused the hyphenated word rules to incorrectly identify this as a verb, rather than a noun (counted as F for syntax). 5. One extra root for embouchure from embouche (but a correct form of the French root?). 6. One missing category N for bobbles, which was given category V but not N because the core lexicon incorrectly listed bobble only as a verb (counted as C for syntax). This is corrected by adding the missing category to the lexical entry for bobble.",
"cite_spans": [],
"ref_spans": [],
"eq_spans": [],
"section": "Sampling rule performance",
"sec_num": "3.2"
},
{
"text": "We have described an approach to robust lexical coverage for unrestricted text applications that makes use of an aggressive set of morphological rules to supplement a core lexicon of approximately 39,000 words to give lexical coverage that exceeds that of a much larger lexicon. This morphological analyzer is integrated with an extensive lexicon, an ontology, and a syntactic analysis system, which it both consults and augments. It uses ordered preferential rules that attempt to choose a small number of correct analyses of a word and are designed to deal with various states of lack of knowledge. When applied to 72 unknown words from a random sample of 100 distinct word types from the Brown corpus, its syntactic category assignments received a grade of B or better (using a grading system explained herein) for 97% of the words, and it correctly identified 95% of the root words. This performance demonstrates that one can obtain robust lexical coverage for natural language processing applications in unrestricted domains, using a relatively small core lexicon and an aggressive collection of morphological rules.",
"cite_spans": [],
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"section": "Conclusions",
"sec_num": "4"
}
],
"back_matter": [],
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"BIBREF0": {
"ref_id": "b0",
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"authors": [
{
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"first": "A",
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"ref_entries": {
"TABREF2": {
"html": null,
"text": "Syntactic cate ;ory performance of the analyzer.",
"num": null,
"type_str": "table",
"content": "
Category Grade
A
B
C
D
F B or better
Number
62
8
1
0
1
70
Percent
86% 11% 1.5% 0% 1.5%
97%
"
},
"TABREF3": {
"html": null,
"text": "Count/mass distinction performance of the analyzer. Count/mass Good count Extra count Good mass Missing mass",
"num": null,
"type_str": "table",
"content": "
Number
39
1
14
1
Percent
100%
2.6%
93%
6.7%
"
},
"TABREF4": {
"html": null,
"text": "Root identification performance of the analyzer.",
"num": null,
"type_str": "table",
"content": "