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Lexical Functional Grammar

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Lexical Functional Grammar History: Joan Bresnan (linguist, MIT and Stanford) Ron Kaplan (computational psycholinguist, Xerox PARC) Around 1978 What is Linguistic ... – PowerPoint PPT presentation

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Title: Lexical Functional Grammar


1
Lexical Functional Grammar
  • History
  • Joan Bresnan (linguist, MIT and Stanford)
  • Ron Kaplan (computational psycholinguist, Xerox
    PARC)
  • Around 1978

2
What is Linguistic Theory
  • Delimit the range of possible human languages.
  • What do all languages have in common?
  • Semantic roles, grammatical relations, pragmatic
    relations, some constituent structure only
    subjects can be controllees in matrix coding as
    subject constructions etc.
  • What are the ways in which they can differ from
    each other?
  • Relative prominence of grammatical or pragmatic
    relations word order reflects grammatical
    relations in English and reflects focus (new
    information) in Hungarian Topic takes precedence
    over subject in Chinese in determining antecedent
    of null pronouns Subject is more prominent in
    English.
  • What never happens in a human language?
  • Make a question by saying the sentence backwards.

3
Universalist view of language
  • There is a common organizing structure of all
    languages that underlies their superficial
    variations in modes of expression (Bresnan)
  • E.g., Passives that look very different in
    different languages can be described by a
    universal passive rule.
  • The common organizing structure is part of human
    biology.

4
Some differences between English and Warlpiri
Aux
V NP
The two small children are chasing that
dog.
S
NP AUX V
NP NP NP
Wita-jarra-rlu ka-pala
wajili-pi-nyi yalumpu kurdu-jarra-rlu maliki.
Small-DU-ERG pres-3duSUBJ chase-NPAST
that.ABS child-DU-ERG dog.ABS
5
Possible word orders in Warlpiri that are not
possible in English
  • The two small are chasing that children dog.
  • The two small are dog chasing that children.
  • Chasing are the two small that dog children.
  • That are children chasing the two small dog.

6
Non-configurational languages
  • Free word order.
  • May have discontinuous constituents.
  • Tests for constituency do not yield evidence for
    VP constituent.

7
Something that English and Warlpiri have in common
  • Lucy is hitting herself.
  • Herself is hitting Lucy.
  • Napaljarri-rli ka-nyanu paka-rni
  • Napaljarri-ERG PRES-REFL hit-NONPAST
  • Napaljarri is hitting herself.
  • Napaljarri ka-nyanu paka-rni
  • Napaljarri.ABS PRES-REFL hit-NONPAST
  • Herself is hitting Napaljarri.

8
What English and Warlpiri have in common
according to Chomsky
Deep structure
English
Surface Structure
9
What English and Warlpiri have in common
according to Chomsky
Deep structure
Warlpiri
Surface Structure
S
NP Aux V NP NP NP
10
What English and Warlpiri have in common
according to Bresnan
  • Same grammatical relations and semantic roles
  • SUBJECT the two small children AGENT
  • PREDICATE are chasing
  • OBJECT that dog PATIENT
  • Different codings of grammatical relations
  • English subject NP immediately under S
  • Warlpiri subject Ergative case marked NP (if
    verb is transitive)

11
Strength of Chomskys approach
  • Proposing that there is a VP in all languages
    explains why there are subject-object asymmetries
    in all languages.

12
Strength of Bresnans approach
  • Doesnt propose non-existent VPs
  • phrase structure is used for representing
    constituency
  • A different representation is used for
    grammatical relations

13
Challenges for Bresnan and Chomsky
  • Bresnan
  • explain subject-object asymmetries in the absence
    of a VP
  • Explain in a principled way the range of possible
    coding properties of grammatical relations
  • Chomsky
  • explain in a principled way how the words get
    scrambled out of VP
  • The phrase structure tree has to represent both
    grammatical relations and constituent structure,
    which may conflict with each other.

14
Levels of Representation in LFG
s np The bear vp ate np a sandwich
constituent structure
Grammatical encoding
SUBJ PRED OBJ
functional structure
Lexical mapping
Agent eat patient
thematic roles
Eat lt agent patient gt lexical
mapping SUBJ OBJ
Grammatical Encoding For English!!!
S
NP
SUBJ
15
A surprise
  • Syntax is not about the form (phrase structure)
    of sentences.
  • It is about how strings of words are associated
    with their semantic roles.
  • Phrase structure is only part of the solution.
  • Sam saw Sue
  • Sam perceiver
  • Sue perceived

16
Surprise (continued)
  • Syntax is also about how to tell that two
    sentences are thematic paraphrases of each other
    (same phrases filling the same semantic roles).
  • It seems that Sam ate the sandwich.
  • It seems that the sandwich was eaten by Sam.
  • Sam seems to have eaten the sandwich.
  • The sandwich seems to have been eaten by Sam.

17
How to associate phrases with their semantic
roles in LFG
  • Starting from a constituent structure tree
  • Grammatical encoding tells you how to find the
    subject.
  • The bear is the subject.
  • Lexical mapping tells you what semantic role the
    subject has.
  • The subject is the agent.
  • Therefore, the bear is the agent.

18
Levels of Representation in LFG
s np The sandwich vp was eaten pp by the
bear constituent structure
Grammatical encoding
SUBJ PRED OBL
functional structure
Lexical mapping
patient eat
agent thematic roles
Eat lt agent patient gt lexical
mapping OBL SUBJ
Grammatical Encoding For English!!!
S
NP
SUBJ
19
Active and Passive
  • Active
  • Patient is mapped to OBJ in lexical mapping.
  • Passive
  • Patient is mapped to SUBJ in lexical mapping.
  • Notice that the grammatical encodings are the
    same for active and passive sentences!!!

20
Passive mappings
  • Starting from the constituent structure tree.
  • The grammatical encoding tells you that the
    sandwich is the subject.
  • The lexical mapping tells you that the subject is
    the patient.
  • Therefore, the sandwich is the patient.
  • The grammatical encoding tells you that the bear
    is oblique.
  • The lexical mapping tells you that the oblique is
    the agent.
  • Therefore, the bear is the agent.

21
How you know that the active and passive have the
same meaning
  • In both sentences, the mappings connect the bear
    to the agent role.
  • In both sentences, the mappings connect the
    sandwich to the patient role (roll?)
  • In both sentences, the verb is eat.

22
Levels of Representation in LFG
s-bar np what s did np the bear
eat constituent structure
Grammatical encoding
OBJ SUBJ
PRED functional structure
Lexical mapping
patient agent
eat thematic roles
Eat lt agent patient gt lexical
mapping SUBJ OBJ
Grammatical Encoding For English!!!
23
Wh-question
  • Different grammatical encoding
  • In this example, the OBJ is encoded as the NP
    immediately dominated by S-bar
  • Same lexical mappings are used for
  • What did the bear eat?
  • The bear ate the sandwich.

24
Principles
  • Variability
  • Phrase structures and grammatical encodings vary
    across languages.
  • Universality
  • Functional structures are largely invariant
    across languages.

25
Functional Structure
SUBJ PRED bear
NUM sg PERS
3 DEF PRED
eatlt agent patient gt
SUBJ OBJ TENSE past OBJ
PRED sandwich
NUM sg PERS 3
DEF -

26
Functional Structure
  • Pairs of attributes (features) and values
  • Attributes (in this example) SUBJ, PRED, OBJ,
    NUM, PERS, DEF, TENSE
  • Values
  • Atomic sg, past, , etc.
  • Feature structure
  • num sg, pred bear, def , person 3
  • Semantic form eatltsubj obgt, bear, sandwich

27
Semantic Forms
  • Why are they values of a feature called PRED?
  • In some approaches to semantics, even nouns like
    bear are predicates (function) that take one
    argument and returns true or false.
  • Bear(x) is true when the variable x is bound to a
    bear.
  • Bear(x) is false when x is not bound to a bear.

28
Why is it called a Functional Structure?
  • X squared
  • 1
  • 4
  • 9
  • 16
  • 25

Each feature has a unique value.
Also, another term for grammtical relation is
grammatical function.
features
values
29
We will use the terms functional structure,
f-structure and feature structure
interchangeably.
30
Give a name to each function
f1
SUBJ PRED bear
NUM sg PERS
3 DEF PRED
eatlt agent patient gt
SUBJ OBJ TENSE past OBJ
PRED sandwich
NUM sg PERS 3
DEF -
f2

f3
31
How to describe an f-structure
  • F1(TENSE) past
  • Function f1 applied to TENSE gives the value
    past.
  • F1(SUBJ) PRED bear, NUM sg, PERS 3, DEF
  • F2(NUM) sg

32
Descriptions can be true or false
  • F(a) v
  • Is true if the feature-value pair a v is in f.
  • Is false if the feature-value pair a v is not
    in f.

33
This is the notation we really use
  • (f1 TENSE) past
  • Read it this way
  • f1s tense is past.
  • (f1 SUBJ) PRED bear, NUM sg, PERS 3, DEF
  • (f2 NUM) sg

34
Chains of function application
  • (f1 SUBJ) f2
  • (f2 NUM) sg
  • ((f1 SUBJ) NUM) sg
  • Write it this way.
  • (f1 SUBJ NUM) sg
  • Read it this way.
  • f1s subjects number is sg.

35
More f-descriptions
  • (f a) v
  • f is something that evaluates to a function.
  • a is something that evaluates to an attribute.
  • v is something that evaluates to a function,
    symbol, or semantic form.
  • (f1 subj) (f1 xcomp subj)
  • Used for matrix coding as subject. A subject is
    shared by the main clause and the complement
    clause (xcomp).
  • (f1 (f6 case)) f6
  • Used for obliques

36
SUBJ PRED lion
NUM pl
PERS 3 PRED seem lt
theme gt SUBJ
XCOMP TENSE pres VFORM
fin XCOMP SUBJ
VFORM INF
PRED livelt theme loc gt
SUBJ
OBL-loc OBJ
OBL-loc CASE OBL-loc
PRED
inltOBJgt
OBJ PRED forest

NUM sg

PERS 3
DEF

S
NP VP
N V VP-bar
COMP VP
V PP
P NP
DET N
Lions seem to live in the forest
37
SUBJ PRED lion
NUM pl
PERS 3 PRED seem lt
theme gt SUBJ
XCOMP TENSE pres VFORM
fin XCOMP SUBJ
VFORM INF
PRED livelt theme loc gt
SUBJ
OBL-loc OBJ
OBL-loc CASE OBL-loc
PRED
inltOBJgt
OBJ PRED forest

NUM sg

PERS 3
DEF

f1
f2
S
n1
f3
NP VP
n4
n2
N V VP-bar
n5
n3
n6
f4
COMP VP
n7
n8
f5
f6
V PP
n10
n9
P NP
n12
n11
DET N
n13
n14
Lions seem to live in the forest
38
SUBJ PRED lion
NUM pl
PERS 3 PRED seem lt
theme gt SUBJ
XCOMP TENSE pres VFORM
fin XCOMP SUBJ
VFORM INF
PRED livelt theme loc gt
SUBJ
OBL-loc OBJ
OBL-loc CASE OBL-loc
PRED
inltOBJgt
OBJ PRED forest

NUM sg

PERS 3
DEF

f1
f2
S
n1
f3
NP VP
n4
n2
N V VP-bar
n5
n3
n6
f4
COMP VP
n7
n8
f5
f6
V PP
n10
n9
P NP
n12
n11
DET N
n13
n14
Lions seem to live in the forest
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