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What is the functional domain of this node?

. . . . . . . . . . What is the functional domain of this node?. . What is the functional domain of this node?  (VPmain).  -1. . What is the functional domain of this node?  -1 (  (VPmain)). The  -mapping is defined by equations annotated to the

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What is the functional domain of this node?

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  3.  

  4.   

  5. What is the functional domain of this node?

  6. What is the functional domain of this node? (VPmain)

  7. -1  What is the functional domain of this node? -1((VPmain))

  8. The -mapping is defined by equations annotated to the c-structure nodes.

  9. ( SUBJ) The -mapping is defined by equations annotated to the c-structure nodes.

  10.  ( XCOMP) ( SUBJ) The -mapping is defined by equations annotated to the c-structure nodes.

  11.   ( XCOMP) ( SUBJ) ( OBJ) The -mapping is defined by equations annotated to the c-structure nodes.

  12.   ( XCOMP) ( SUBJ) ( OBJ)   The -mapping is defined by equations annotated to the c-structure nodes.

  13.   ( XCOMP) ( SUBJ) ( OBJ)     The -mapping is defined by equations annotated to the c-structure nodes.

  14.   ( XCOMP) ( SUBJ) ( OBJ)       The -mapping is defined by equations annotated to the c-structure nodes.

  15.   ( OBJ) ( SUBJ) ( XCOMP)                   The -mapping is defined by equations annotated to the c-structure nodes.

  16. Grammatical Functions TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT

  17. Grammatical Functions TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT a-fns

  18. Grammatical Functions TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT non-a-fns non-a-fns a-fns

  19. Grammatical Functions d-fns TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT non-a-fns non-a-fns a-fns

  20. Grammatical Functions non-d-fns d-fns TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT non-a-fns non-a-fns a-fns

  21. Grammatical Functions non-d-fns d-fns TOP FOC SUBJ OBJ OBJ OBL COMPL ADJUNCT non-a-fns non-a-fns a-fns

  22. X'-syntax Basic schema: XP YP X' X0 ZP X0: N, V, A, P, C, I, D (Left-to-right order unspecified)

  23. X'-syntax Basic schema: XP Specifier YP X' Head Complement X0 ZP X0: N, V, A, P, C, I, D (Left-to-right order unspecified)

  24. X'-syntax Basic schema: Lexical projections: LP XP YP L' YP X' L0 ZP X0 ZP X0: N, V, A, P, C, I, D L0: N, V, A, P

  25. X'-syntax Basic schema: Lexical projections: NP XP YP N' YP X' Cæsar's N0 ZP X0 ZP conquest of Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P

  26. X'-syntax Basic schema: Lexical projections: VP XP YP V' YP X' Cæsar V0 ZP X0 ZP conquered Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P

  27. X'-syntax Basic schema: Lexical projections: XP VP YP X' V0 ZP X0 ZP conquered Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P

  28. X'-syntax Basic schema: Lexical projections: XP AP YP X' A0 ZP X0 ZP afraid of dogs X0: N, V, A, P, C, I, D L0: N, V, A, P

  29. X'-syntax Basic schema: Lexical projections: PP XP YP P' YP X' three miles P0 ZP X0 ZP past the border X0: N, V, A, P, C, I, D L0: N, V, A, P

  30. X'-syntax Basic schema: Lexical projections: XP PP YP X' P0 ZP X0 ZP on the table X0: N, V, A, P, C, I, D L0: N, V, A, P

  31. X'-syntax Functional projections: Basic schema: Lexical projections: LP FP XP YP L' YP F' YP X' L0 ZP F0 ZP X0 ZP X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D

  32. X'-syntax Functional projections: Basic schema: Lexical projections: LP XP YP L' CP YP X' L0 ZP C0 ZP X0 ZP that Mary left X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D

  33. X'-syntax Functional projections: Basic schema: Lexical projections: LP IP XP YP L' YP I' YP X' Mary L0 ZP I0 ZP X0 ZP may leave John X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D

  34. X'-syntax Functional projections: Basic schema: Lexical projections: LP XP YP L' DP YP X' L0 ZP D0 ZP X0 ZP this theory X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D

  35. X'-syntax Adjunction: XP Functional projections: Lexical projections: LP FP WP XP YP L' YP F' YP X' L0 ZP F0 ZP X0 ZP X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D

  36. X'-syntax Functional projections: Basic schema: Lexical projections: LP FP XP YP L' YP F' YP X' L0 ZP F0 ZP X0 ZP X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D Lexical integrity: "Morphological complete words are leaves of the c-structure tree and each leaf corresponds to one and only one c-structure node."

  37. X'-syntax Functional projections: Basic schema: Lexical projections: LP FP XP YP L' YP F' YP X' L0 ZP F0 ZP X0 ZP X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D Economy of Expression: "All syntactic phrase structure nodes are optional and are not used unless required by independent principles (completeness, coherence, semantic expressivity)."

  38. X'-syntax Functional projections: Basic schema: Example of optionality: FP XP VP YP F' YP X' V0 NP F0 ZP X0 ZP conquered Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D Economy of Expression: "All syntactic phrase structure nodes are optional and are not used unless required by independent principles (completeness, coherence, semantic expressivity)."

  39. X'-syntax Functional projections: Basic schema: Example of optionality: FP XP VP YP F' YP X' NP F0 ZP X0 ZP Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D Economy of Expression: "All syntactic phrase structure nodes are optional and are not used unless required by independent principles (completeness, coherence, semantic expressivity)."

  40. X'-syntax Functional projections: Basic schema: Example of optionality: FP XP VP YP F' YP X' NP F0 ZP X0 ZP Gallia X0: N, V, A, P, C, I, D L0: N, V, A, P F0: C, I, D Economy of Expression: "All syntactic phrase structure nodes are optional and are not used unless required by independent principles (completeness, coherence, semantic expressivity)."

  41.         Two kinds of 'heads' c-structure heads (according to X' theory): XP XP XP YP X' X YP YP X X0 ZP f-structure heads: A A A B C B C B C

  42. The Mapping Principles Lexical projections: Functional projections: LP FP YP L' YP F' L0 ZP F0 ZP

  43.         The Mapping Principles C-structure heads are f-structure heads. Lexical projections: Functional projections: LP FP YP L' YP F' L0 ZP F0 ZP

  44. ( DF)         The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Lexical projections: Functional projections: LP FP YP L' YP F' L0 ZP F0 ZP

  45. ( SUBJ)         The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Example ([SPEC, IP] as SUBJ): Lexical projections: Functional projections: LP IP YP L' NP I' Mary L0 ZP I0 VP may leave John

  46. ( DF)           The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Complements of functional categories are f-structure co-heads. Lexical projections: Functional projections: LP FP YP L' YP F' L0 ZP F0 ZP

  47. ( SUBJ)           The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Complements of functional categories are f-structure co-heads. Example 1 (VP as co-head with I): Lexical projections: Functional projections: LP IP YP L' NP I' Mary L0 ZP I0 VP may leave John

  48.           The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Complements of functional categories are f-structure co-heads. Example 2 (NP as co-head with D): Lexical projections: Functional projections: LP YP L' DP L0 ZP D0 NP this theory

  49.  ( DF) ( CF)           The Mapping Principles C-structure heads are f-structure heads. Specifiers of functional categories are the grammaticalized discourse functions DF. Complements of functional categories are f-structure co-heads. Complements of lexical categories are the nondiscourse argument functions CF. Lexical projections: Functional projections: LP FP YP L' YP F' L0 ZP F0 ZP

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