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1 001Y219E

2 () 73 75

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6 1, (1993 ) 3(1997 ) 4(2001 ) S.40 (S.45 )(S.49 )S.50 (S.55 )(S.57 )(S.58)(S.58 ) 4

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19 ,986 17, %8.3% 3,600 3, , ,900 22, % , , 750 3, % , %-2.4%-3.2%-3.6%-5.6% ,550 2,241 2,364 1, %-4.4% 2,

20 1-3.b & % , ,325 (-7%)1,249 (-5.7%) 1,096 (-12.3%) () , % 18

21 96 1, % 2,500 2, , % , , % % 94 2, , % % , , ,519-17% % % 19

22 1-3.c & % , , % % % % % , , ,248 36%11%96 1, %97 1,

23 8.6% %-19.5% % % , , ,940-1% , 380 1,820 1,340-25% , , ,014 2, %-18.5% , % 3, %16.9% 4.4%

24 % % 2% 27% 30% 72% 70% 5% 18% 48% 30% 29% 70% 1% 14% 14% 41% 55% 59% TDR HTB 22

25 TDR 72%HTB 29% USJ 55%TDR 2% HTB 5% TDRHTBUSJ 70%70%59% ,

26 97 5% 10%

27

28 N i N x i = D i ( p) i i ( p) = x = D ( p) D N i N i N i N p D i ( p) p M y j = S j ( p) j M S j j ( p) = y = S ( p) j M j M 2-1 D ( p) S( p) 26

29 2-1 p S( p) * p E D( p) 0 * x 1999p.143 x y x E D p = S ( ) ( p) ( x *, p * ) (seasonality) (off-season) (on-season)

30 1)2) 3)4)5) 6)5) Newton Newton GM i M I ij = D 2 ij j I ij i j G M ij i j D i j ij ( M ) ( D ) 1992Crampon

31 I ij n i =1 I ij = G P d i b ij I i j Pi ij i d i j G, b ij i j i j Crampon r b 1.88 b b JudMalamud 1 Smith 2 Wolfe (momentum) 2 Smith

32 (full cost principle) P = V + mv + m V ( + m + m ) = V 1 = V ( 1+ r) V m m q r p P V ( 1+ r) V V 30

33 2-3 P MC p M E A AC D B 0 x M MR 1999p.303 xe x p x D( p) c( x) π = pd ( p) c[ D( p) ] ( x) π = p ( x) x c( x) p p < 0 1 ( TR ) 2 ( TC ) ( x) p ( x) x = c ( x) p + ( MR )( MC ) ( x) + p ( x) x < c ( x) 2 p ( M xm MR = MC p p x ) MR M MC 2-2 x M 31

34 + dp x dx p ε x dx p p 1 ( ) dp x 1 p ( x) 1 = c ( x) ε ( x) p c ε > 1 x = p α > 0, β > 1 α β ε = β c p M p M ( 1 1 β ) = c 1 ( 1 1 β ) X P T XP + Y = M T X > 0 Y = M X =

35 M Y U U ( X, Y ) = P U U x y = P T Y U U ( X, Y ) U ( 0, M ) = 0 = U U x y < P X = 0 Y = M P M T X D( P M T ) =, M T M T ( M T ) dx dm dx = dt π = XP + T C ( X ) C ( X ) dπ = P dt T dx dt + 1 c dx dt = 1 ( P c ) c Y dx dm 33

36 T 1) T * T Y * T U U, 0 = ( 0 M ) 0 U X ϕ( P) = P * T P T * = P ϕ ( P ) dp = ϕ ( P ) = X dt dp * P * T T ) π P P π dπ = X + P dp dx dp * dt + dp c dx dp P * T P dx P c P = c dp ( ) = 0 P * T P ϕ( P) P ) 34

37 ( ) x U y U ( c 1) Y T P ϕ 1 ϕ 2 ϕ 1 ϕ 2 C T C π = π π = 2( ABC) P T P PD * X 1 = 35

38 A A P C D D E B E B ϕ 2 ϕ 1 0 * X1 X1 * X 2 X 2 * π 1 = π 1 π 1 = [( ADP ) + ( PDEC )] [ ABC ] = ( DBE ) * π 2 = π 2 π 2 = [( ADP ) + ( PD E C )] [ ABC ] = + ( DD E B ) T P P T 36

39 A A C P B E D B E D ϕ 1 ϕ 2 0 * * X 2 X 2 X 1 X 1 * X 1 = PD P T π 1 = π 1 π 1 * = [( ADP ) ( CEDP )] [ ABC ] = ( BED ) P π = π [( ADP ) ( CE ' D ' P )] [ ABC ] = + ( E ' ') * 2 π 2 = BDD 37

40 P T T P P π ( N ) = XP + NT C( X ) X T = T 1 C ( X ) dπ dp * c = P 1 N s E s1 = x1 X E 1 N ( 1 N ) > 0 P c ( 1 N ) < 0 s 1 s 1 38

41 π ( n) π S π A 0 n n P T = T 1 ) π ( n) ( n) π π nt π = ( P c)x S T π T π A * A = A 39

42 T P π = ( P c)x S ( P C) X π S dπ n dn dπ dπ ( ) = + = 0 dn A dn S π A π S ( P, T ) π T ε P ( XP + T ) M A 40

43 X P T j * (seasonality) (off-season)(on-season) 2 Newton Crampon b b Jud Malamud 41

44 3 Walter Y.Oi 1 ) (1) p ( dx ) + ( dy ) = 1 dy = 1 p( dx ) dm dm dm dm (6) d π = dy + c ( dx ) dt dm dm c 0 Y ( dy dm ) > 0 dπ dt 2 ) * R = XP + T P 3 ) x j = ϕ j ( p) j U 0 ( X ) 1 p * p j T j (7) 4 ) p (10) ( 1 N ) > 0 p s 1 42

45 X 1, X 2,, i X k Y = β β β1x 1i + β 2 X 2i + + k X ki ui ( i = 1,2,, n) β 0, β1,, β k u i X 1, X 2,, X k Yi Yi X 1, X 2,, X k ( Y X ) ( X YY X ) identification bias ( X Y ) () P Q 43

46 3-1 P A ( P, Q ) P P S 1 A 1 S3 S S 1 2 A A A 3 1 A 2 A 3 2 D 1 A 1 D 2 A 2 S 2 A 3 S 3 D 3 Q D D p D 3 Q Q P Q 3-1 A P, ) A P, ) A P, Q ) 1 ( 1 Q1 2 ( 2 Q 3 n ( n n Q P P P,, D,,, S, S1 S 2 3 mongrel S D1 D2 3 D1 1 Q P P 1 (1) (2) 1 44

47 k < G 1 k = G 1 k > G 1 k = G = ordinary least square,ols indirect least square,ils two stage least square,tsls ILS TSLS 2 45

48 2 1 R&D 1 2 f f () () 1 Q d = f ( p, y, QP ) 2 Q s = f ( p, Q, Q, PR I w ) ( Q )( p ) 2 ( y )( QP )( QI )( Qw )( PR )

49 () 2 () 47

50 () Q Q d 1 2 Q s ( ) ( +, ) ( + ) = f ( p, y, QP ( + ) ( + ) ( ) ( + = f ( p, Q, Q, PR I w ) ) ) () ( ) P = 2002 ( kwh ) 9 ( 3 m ) 48

51 ( km )( km ) PR = 100 y % USJ 55% km 150 km 4 2 () 3 y = E1 CPI n1 N E2 + CPI n2 N + + E i CPI ni N 1,2,, i ( E )( CPI )( n ) 49

52 ( N ) y CramponJudMalamud (23 ) Yahoo!

53 QP i POP POP POP POP = i D D D D, i, i, i, i ( POP ) i ( D ) ( QP )( POP )( D ) 2 () ( QP ) 1 51

54 Q d = f ( p, y, QP ) Q s = f ( p, Q, Q, PR I w ) ( t ) Q d = f ( p, y, QP, t ).a Q s = f ( p, Q, Q, PR, t ).b I w ( Q ) ( p ) 2 ( y )( QP )( QI ) ( Q )( PR )( t ) 6 w G 1 = 2 1= 1 k.a k = 8 5 = 3.b k = 8 6 = Q d = f ( p, y, QP ).a Q s = f ( p, Q, Q, PR ).b I w ( Q ) ( p ) 2 ( y )( QP )( QI ) ( Q )( PR ) 5 G 1 = 2 1= 1k w.a k = 7 4 = 3.b k = 7 5 =

55 lnq d = f (ln p,ln y,lnqp, t).a ln Q s = f (ln p, ln Q I, ln Q w, PR, t ).b ( lnq ) ( ln p ) 2 ( lny)( lnqp) ( ln )( lnq )( PR )( t ) 6 Q I w G 1 = 2 1= 1 k.a k = 8 5 = 3.b k = 8 6 = a.b ( 2 R ) t.a t % t %

56 3-1 p y QP Q I Q w PR t R 2 t % b t % t % t t

57 p 3-2 y QP Q I Q w PR t R 2 5% a.b ( 2 R ) %.a t t %

58 ln p 3-3 ln y ln QP ln Q I ln Q w PR t R 2 t % b t % t % 56

59 t % a.b ( 2 R ) % 80%.a t % t b t t % t % t 1% 57

60 58

61 1 1 59

62 3 60

63 3 61

64

65

66

67 3 3 5%

68

69

70 1 3 68

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72 It s my life!! 2 70

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75 1Walter Y.Oi1971A Disneyland Dilemma:Two-part Tariffs For A Mickey Mouse Monopoly,The Quarterly Journal Of Economics,Vol.LXXXV,No1,pp , Report Leisure no

76 & & & (

77 1 TDL HTB TUE NEM SW SPL TWS SG KTK PE & 2001 (TDL)(HTB)(TUE) (NEM)(SW)(SPL) (TWS)(SG)(KTK) (PE) 75

78 2 TDL HTB TUE NEM SW SPL TWS SG KTK PE & 76

79 3 km (TDL)(HTB)(TUE) (NEM TWS)(SW)(SPL)(SG)(KTK)(PE) 77

80 4 100 kwh m^

81 6 TDL HTB NEM SW SPL TWS SG (TDL)(HTB)(NEM) (SW)(SPL)(TWS) (SG) 79

82 7 TDL HTB NEM SW SPL TWS SG (TDL)(HTB)(NEM) (SW)(SPL)(TWS) (SG) 80

83 km (TDL)(HTB)(NEM) (SW)(SPL)(TWS) (SG) 81

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1. (8) (1) (x + y) + (x + y) = 0 () (x + y ) 5xy = 0 (3) (x y + 3y 3 ) (x 3 + xy ) = 0 (4) x tan y x y + x = 0 (5) x = y + x + y (6) = x + y 1 x y 3 ( 1 1.1 (1) (1 + x) + (1 + y) = 0 () x + y = 0 (3) xy = x (4) x(y + 3) + y(y + 3) = 0 (5) (a + y ) = x ax a (6) x y 1 + y x 1 = 0 (7) cos x + sin x cos y = 0 (8) = tan y tan x (9) = (y 1) tan x (10) (1 +

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