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From Structural Syntax to Constructive Adpositional Grammars
F. Gobbo & M. BeniniUniversity of Insubria, Italy
CC© BY:© $\© C©
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What is dependency?
The posthumous book by Tesniere (1959) is considered a masterpiece,as it introduces the two key concepts of dependency and valency.
Nonetheless, unlike valency, there is no agreement among scholars andspecialists on how to treat precisely the concept of dependency.
� How Tesniere really defined dependency?
� What can be saved – and adapted – from his work nowadays?
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What is dependency?
The posthumous book by Tesniere (1959) is considered a masterpiece,as it introduces the two key concepts of dependency and valency.
Nonetheless, unlike valency, there is no agreement among scholars andspecialists on how to treat precisely the concept of dependency.
� How Tesniere really defined dependency?
� What can be saved – and adapted – from his work nowadays?
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Tesniere talked about connection, not dependency!
parle
IAlfred
Stemma 1
parle
Iami
Imon
Stemma 2
In Alfred parle (‘Alfred speaks’), the verb parle is the governor(regissant), the noun Alfred being the dependent (elementsubordonne).
Their relation “indicated by nothing” (1, A, ch. 1, 4) is theirconnection (connexion). Connections are recursive (stemma 2).
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Tesnierian Structural Syntax triple
For instance, in Alfred parle (Alfred speaks, stemma 1):
1. governor (parle)
2. dependent (Alfred)
3. connector (ε) – empty? yes, but it does exist indeed!
Tesnierian unary trees – even if recursive – tend to obscure theconnector in the triple, especially when it is collocational (syntactic)instead than morphological.
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Tesnierian Structural Syntax triple
For instance, in Alfred parle (Alfred speaks, stemma 1):
1. governor (parle)
2. dependent (Alfred)
3. connector (ε) – empty? yes, but it does exist indeed!
Tesnierian unary trees – even if recursive – tend to obscure theconnector in the triple, especially when it is collocational (syntactic)instead than morphological.
4 of 14
Tesnierian Structural Syntax triple
For instance, in Alfred parle (Alfred speaks, stemma 1):
1. governor (parle)
2. dependent (Alfred)
3. connector (ε)
– empty? yes, but it does exist indeed!
Tesnierian unary trees – even if recursive – tend to obscure theconnector in the triple, especially when it is collocational (syntactic)instead than morphological.
4 of 14
Tesnierian Structural Syntax triple
For instance, in Alfred parle (Alfred speaks, stemma 1):
1. governor (parle)
2. dependent (Alfred)
3. connector (ε) – empty? yes, but it does exist indeed!
Tesnierian unary trees – even if recursive – tend to obscure theconnector in the triple, especially when it is collocational (syntactic)instead than morphological.
4 of 14
Tesnierian Structural Syntax triple
For instance, in Alfred parle (Alfred speaks, stemma 1):
1. governor (parle)
2. dependent (Alfred)
3. connector (ε) – empty? yes, but it does exist indeed!
Tesnierian unary trees – even if recursive – tend to obscure theconnector in the triple, especially when it is collocational (syntactic)instead than morphological.
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From unary to binary trees
Stemma 2 in Constructive Adpositional Grammars (CxAdG):
mon
D
����
p↔εF
AAAA
ami
G
����
p↔εF
AAAA
parle
G
� G indicates the grammar character of governors
� D indicates the grammar character of dependents
� F indicates the grammar character of adpositions (= connectors)
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From unary to binary trees
Stemma 2 in Constructive Adpositional Grammars (CxAdG):
mon
D
����
p↔εF
AAAA
ami
G
����
p↔εF
AAAA
parle
G
� G indicates the grammar character of governors
� D indicates the grammar character of dependents
� F indicates the grammar character of adpositions (= connectors)
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From unary to binary trees
Stemma 2 in Constructive Adpositional Grammars (CxAdG):
mon
D
����
p↔εF
AAAA
ami
G
����
p↔εF
AAAA
parle
G
� G indicates the grammar character of governors
� D indicates the grammar character of dependents
� F indicates the grammar character of adpositions (= connectors)
5 of 14
From unary to binary trees
Stemma 2 in Constructive Adpositional Grammars (CxAdG):
mon
D
����
p↔εF
AAAA
ami
G
����
p↔εF
AAAA
parle
G
� G indicates the grammar character of governors
� D indicates the grammar character of dependents
� F indicates the grammar character of adpositions
(= connectors)
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From unary to binary trees
Stemma 2 in Constructive Adpositional Grammars (CxAdG):
mon
D
����
p↔εF
AAAA
ami
G
����
p↔εF
AAAA
parle
G
� G indicates the grammar character of governors
� D indicates the grammar character of dependents
� F indicates the grammar character of adpositions (= connectors)
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Dependency in adpositional trees
In adpositional trees (adtrees):
� governors are put on the right, dependents on the left;
� adpositions are put in evidence; they define the structure ofconstructions through the adtree final grammar character (F);
� left-to-right indicators (→) sign dependency, where theinformation prominence is in the dependent;
� right-to-left indicators (←) sign government, where theinformation prominence is in the governor;
� left-to-right & right-to-left indicators (↔) signunderspecification, where the information prominence is notrelevant.
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The only mention of “dependency” in Tesniere (1959)
ruisseaux
Ipetits
Sl ettrma 2L
rulsseaux
J,petits
INCIDENCESTRUCTURALE
Stemma 22
ruisseauxfpetits
INCIDENCESÉMANTIQUE
Stemma 23
In adtrees, indicators are interpretations of incidence structural andincidence semantique (a kind of “dependency”) in terms ofinformation prominence, adapted from the dichotomy trajectors(tr) vs. landmarks (lm) by Langacker (1987).
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The role of grammar characters
chante
cousrne délicie usement
T/4.OE,4AA
Sternma virtuel
Stemrna 44
votrc je,une
S Lern ln a réel
Stenlma 43
Tesniere borrowed from Esperanto final suffixes the letters of the fouruniversal grammar characters (same characters already in Whorf1945).
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Adtrees put all Tesnierian structure together
�
D
�����
q→-ment
E
AAAAA
delicieuse
A
�����
q←εI
AAAAAAAAAA
votre
A
�����
q←εO
AAAAA
jeune
A
�����
q←εO
AAAAA
cousine
O
�����
q→εI
AAAAA
chante
I
This adtree renders both stemmas 43 (reel) and 44 (virtuel) in one.
CxAdGrams are a derivative work of Tesniere’s...
� the original concept of valency is preserved
� the Structural Syntax triple gives the form to CxAdTrees
� dependency is “only” a form of connection, as put by Tesniere
� the four grammar characters are general in CxAdGrams
� information prominence is adapted from Langacker’s tr/lmdichotomy, (at least) sketched by Tesniere himself
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CxAdGrams are a derivative work of Tesniere’s...
� the original concept of valency is preserved
� the Structural Syntax triple gives the form to CxAdTrees
� dependency is “only” a form of connection, as put by Tesniere
� the four grammar characters are general in CxAdGrams
� information prominence is adapted from Langacker’s tr/lmdichotomy, (at least) sketched by Tesniere himself
10 of 14
CxAdGrams are a derivative work of Tesniere’s...
� the original concept of valency is preserved
� the Structural Syntax triple gives the form to CxAdTrees
� dependency is “only” a form of connection, as put by Tesniere
� the four grammar characters are general in CxAdGrams
� information prominence is adapted from Langacker’s tr/lmdichotomy, (at least) sketched by Tesniere himself
10 of 14
CxAdGrams are a derivative work of Tesniere’s...
� the original concept of valency is preserved
� the Structural Syntax triple gives the form to CxAdTrees
� dependency is “only” a form of connection, as put by Tesniere
� the four grammar characters are general in CxAdGrams
� information prominence is adapted from Langacker’s tr/lmdichotomy, (at least) sketched by Tesniere himself
10 of 14
CxAdGrams are a derivative work of Tesniere’s...
� the original concept of valency is preserved
� the Structural Syntax triple gives the form to CxAdTrees
� dependency is “only” a form of connection, as put by Tesniere
� the four grammar characters are general in CxAdGrams
� information prominence is adapted from Langacker’s tr/lmdichotomy, (at least) sketched by Tesniere himself
10 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;� it was never done before.
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...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;� it was never done before.
11 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;� it was never done before.
11 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:
� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;� it was never done before.
11 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;
� (linguistic) information can be hidden and recalled entirely in a veryprecise way, without being lost, with every piece clearly described;
� it was never done before.
11 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;
� it was never done before.
11 of 14
...based on a up-to-date formal model
� adtrees and construction together form a (mathematical) category
� the possible finite sequences of morphemes of a language are amonoid M
� the presheaf over M mapping in the monoid gives thelexicalizations of adtrees
� the presheaves space is a Grothendieck topos, so languagestructure can be analysed through the power of the up-to-datemathematical methods of topos theory, which makes sense as:� it is the most general and formal mathematical theory we have;� (linguistic) information can be hidden and recalled entirely in a very
precise way, without being lost, with every piece clearly described;� it was never done before.
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How to delve into CxAdGramsOur book published by Cambridge Scholars (C-S-P). Available now.
Warning! This Is An Advertisement
How to delve into CxAdGramsOur book published by Cambridge Scholars (C-S-P). Available now.
Warning! This Is An Advertisement
Conclusion: there is always more in languages...
Figure: from Monty Python’s The Meaning of Life
...than in grammars!
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Conclusion: there is always more in languages...
Figure: from Monty Python’s The Meaning of Life
...than in grammars!
13 of 14
Conclusion: there is always more in languages...
Figure: from Monty Python’s The Meaning of Life
...than in grammars!13 of 14
¡Thanks for your attention!
¿Questions?
For proposals, ideas & comments:
{federico.gobbo,marco.benini}@uninsubria.it
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CC© BY:© $\© C© Federico Gobbo & Marco Benini 2011
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