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- ちえこ みねむら
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1 July 14, 2007
2
3 Brouwer f f(x) = x x
4 f(z) = 0
5 2 f : S 2 R 2 f(x) = f( x) x S 2
6 3 3 2
7 - - -
8
9 1. X x X U(x) U(x) x U = {U(x) x X} X 1. U(x) A U(x) x 2. A U(x), A B B U(x) 3. A, B U(x) A B U(x) 4. A U(x), B U(x) s.t. y B A U(y) U X X
10 1. X x X U(x) U(x) x U = {U(x) x X} X 1. U(x) A U(x) x 2. A U(x), A B B U(x) 3. A, B U(x) A B U(x) 4. A U(x), B U(x) s.t. y B A U(y) U X X
11 1. X = R n x R n ǫ > 0 B(x, ǫ) = {y R n y x < ǫ} A U(x) ǫ > 0 s.t. B(x, ǫ) A U = {U(x) x R n }
12 1. U X x U, U U(x) U R n x U, ǫ s.t. B(x, ǫ) U X O 1., X O 2. U, V O U V O 3. U λ O (λ Λ) λ Λ U λ O
13 1. U X x U, U U(x) U R n x U, ǫ s.t. B(x, ǫ) U X O 1., X O 2. U, V O U V O 3. U λ O (λ Λ) λ Λ U λ O
14 1. F X X F X X F 1., X F 2. F, G F F G F 3. F λ F (λ Λ) λ Λ F λ O
15 1. F X X F X X F 1., X F 2. F, G F F G F 3. F λ F (λ Λ) λ Λ F λ O
16 1. X B x B B U(x) Int B = {B }... B x B A U(x), A B B = {B }... B x B x B B = {B } = B IntB... B
17 1. X B 1. IntB B 2. B B 3. B
18 1. [U O] U O x U, U U(x) [O U] U U(x) O O s.t. x O U [O F] F F X F O [F O] U O X U F
19 1. [U O] U O x U, U U(x) [O U] U U(x) O O s.t. x O U [O F] F F X F O [F O] U O X U F
20 1. [U O] U O x U, U U(x) [O U] U U(x) O O s.t. x O U [O F] F F X F O [F O] U O X U F
21 1. [U O] U O x U, U U(x) [O U] U U(x) O O s.t. x O U [O F] F F X F O [F O] U O X U F
22 1. [U O] U O x U, U U(x) [O U] U U(x) O O s.t. x O U [O F] F F X F O [F O] U O X U F
23 1. U O (1), (2), (3) (4) O U U (4) U = U (4) A U(x) x B IntA A B IntA (4) A U (x) (1) (2) (3)
24 1. U 0 (x) U(x) x A U(x), B U 0 s.t. B A U 0 = {U 0 (x) x X} 1. U 0 (x) A U 0 (x) x 2. A, B U 0 (x) C U 0 (x) s.t. C A B 3. A U 0 (x), B U 0 (x) s.t. b B, C U 0 (b) s.t. C A U 0 U
25 1. U 0 (x) U(x) x A U(x), B U 0 s.t. B A U 0 = {U 0 (x) x X} 1. U 0 (x) A U 0 (x) x 2. A, B U 0 (x) C U 0 (x) s.t. C A B 3. A U 0 (x), B U 0 (x) s.t. b B, C U 0 (b) s.t. C A U 0 U
26 1. {B(x, ǫ) ǫ > 0} R n X U 0 (x) = {x } U 0 = {U 0 (x)}
27 1. {B(x, ǫ) ǫ > 0} R n X U 0 (x) = {x } U 0 = {U 0 (x)}
28 1. O 0 O U O, U λ O 0 (λ Λ) s.t. U = λ Λ U λ 1. X = U O 0 U ( x X, U O 0 s.t. x U) 2. U, V O 0, x U V, W O 0 s.t. x W U V O 0 O {B(x, ǫ) x R n, ǫ > 0} R n
29 1. O 0 O U O, U λ O 0 (λ Λ) s.t. U = λ Λ U λ 1. X = U O 0 U ( x X, U O 0 s.t. x U) 2. U, V O 0, x U V, W O 0 s.t. x W U V O 0 O {B(x, ǫ) x R n, ǫ > 0} R n
30 1. O 0 O U O, U λ O 0 (λ Λ) s.t. U = λ Λ U λ 1. X = U O 0 U ( x X, U O 0 s.t. x U) 2. U, V O 0, x U V, W O 0 s.t. x W U V O 0 O {B(x, ǫ) x R n, ǫ > 0} R n
31 1. O 0 O U O, U λ O 0 (λ Λ) s.t. U = λ Λ U λ 1. X = U O 0 U ( x X, U O 0 s.t. x U) 2. U, V O 0, x U V, W O 0 s.t. x W U V O 0 O {B(x, ǫ) x R n, ǫ > 0} R n
32 1. S O S = { n i=1 U i U 1,, U n S} O 1. X = U S U S O (, a) (b, + ) R
33 1. S O S = { n i=1 U i U 1,, U n S} O 1. X = U S U S O (, a) (b, + ) R
34 1. S O S = { n i=1 U i U 1,, U n S} O 1. X = U S U S O (, a) (b, + ) R
35 1. S O S = { n i=1 U i U 1,, U n S} O 1. X = U S U S O (, a) (b, + ) R
36
37
38 2. x X U(x) = {X} X O = {, X}
39 2. x X {x} U(x) X O X
40 2. K n K n K n Zariski
41 2. X U 0 (x) = {x } U 0 = {U 0 (x)}
42 2. d: X X R X 1. d(x, y) 0 d(x, y) = 0 x = y 2. d(x, y) = d(y, x) 3. d(x, y) d(x, z) + d(z, y)... d(x, y) = y x = (y 1 x 1 ) (y n x n ) 2 R n
43 2. x X ǫ > 0 B(x, ǫ) = {y X d(y, x) < ǫ} {B(x, ǫ) ǫ > 0} R n d(x, y) = y x n = 1 R
44 2. V K K = R C V R, v v V 1. v 0 v = 0 v = 0 2. av = a v (a K, v V ) 3. v + w v + w d(x, y) = y x d: V V R
45 2. R n x x2 n x x n max{ x 1,..., x n } q x x2 2 < ǫ x 1 + x 2 < ǫ max{ x 1, x 2 } < ǫ Figure: R 2
46 V v V c v 0 v 1 C v 0 c C 0 1 V
47 2. R n V
48 2. J = [a, b] V C(J, V ) V C(J, V ) max f(x) a x b b f(x) dx a J R n J C(J, V ) J V sup x J f(x)
49 3. X Y f : X Y x X f(x) V x U f(u) V U V x X f(x) V f 1 (V ) x
50 3. f : R m R n x X ǫ > 0 y x < δ = f(y) f(x) < ǫ ǫ > 0
51 3. 1. f : X Y 2. V f(x) = f 1 (V ) x 3. V Y = f 1 (V ) X 4. F Y = f 1 (F) X 5. X A f(a) f(a)
52 3. X f : X Y Y f : X Y
53 3. C C R 2, x + yi (x, y),
54 3. X T T 1. T T 2. T T 3. T T 4. (X, T ) (X, T )
55 3. T T T T X
56 3. f X Y X f Y f f 1 (V ) X Y V Y f X f Y V f 1 (V )
57 4. A X i: A A A X U O A O X U A (x) = {B A B U(x)}, O A = {U A U O} U A {z C z = 1} S 1 S 1
58 4. X q: X X/ Y = X/ Y X O X Y O Y = {U X f 1 (U) O X } R x y x y Z R/ S 1
59 4. X X i {f i : X X i i I} f i X (initial topology) (U i ) U i X i (i I)} {fi 1 X X i (i I) i I X i X X i X = i I X i
60 4. I = {1,...,n} i I X i = X 1 X n {U 1 U n U i O Xi } x = (x 1,...,x n ) {U i U n U i U Xi (x i )} R n
61 4. I i I X i { i I U i U i O Xi i U i = X i } x = (x i ) { i I U i U i U Xi (x i ) i U i = X i } { i I U i U i O Xi } i I X i (box topology)
62 4. Z X = i I U i U i O Xi f : Z X i p i f : Z X i i I
63 5. X U O F T 1 : a, b X, U U(a) s.t. b U. T 2 : a, b X, U U(a), V U(b) s.t. U V =. T 3 : A F, b X A, U, V O s.t. A U, b V, U V =. T 4 : A, B F s.t. A B =, U, V O s.t. A U, B V, U V =. T 0 T 2+1/2 T 3+1/2 T 5 T 6
64 5. T 1 T 1 T 2 T 1 + T 3 T 1 + T 4
65 5. X 1. X 2. X a {a} 3. = {(x, x) x X} X X (a,b) U V for all U V U(a,b) U V for all U U(a), V U(b) b U U(a)
66 5. X 1. X 2. X a {a} 3. = {(x, x) x X} X X (a,b) U V for all U V U(a,b) U V for all U U(a), V U(b) b U U(a)
67 5. X = i I X i 1. X i X 2. X X i
68 6. Y X Y i I U i X {U i i I} Y X Y U = {U i i I} Y i I 0 U i I I 0 Y X X
69 X Y Y f : X Y X Y f(x)
70 6. X, Y X Y X Y X Y R n
71 6. {X i i I} i X i i X i X i
72 7. X Y X X U V, U V X = Y U V X U X V
73 7. f X Y f(x) Y X A A B A B X {A i i I} i I A i i I A i X Y X Y
74 7. X a a a {a} X a
75 7. n J 1 J n R n J i,..., J n J 1 J n X 1 S n
76 7. f : I I f(x) = x x I f : S 1 R f(x) = f( x) x S 1 2
77 7. [0, 1] X α: [0, 1] X X α(0) α(1) X
78 7. f : X Y X f(x) X Y X Y S 1 S 1 S 1 R 2 A B A B A = {(0, y) 0 < y 1} B = {(x,0) 0 < x 1} {(1/n, y) 0 < y 1}
79 7. X X X X π 0 X A B π 0 (A B) = {A, B}
80 8. X α: [0, 1] X α(0) = α(1) α β α: [0, 1] [0.1] X α β α β x 0 X π 1 (X, x 0 ) x 0 1 S 1 C x 0 S 1 X π 1 (X, x 0 ) X
81 8. π 1 (X, x 0 ) ([α], [β]) [α] [β] = [α β] α(2t), α β(t) = β(2t 1), t 1 2 t 1 2 π 1 (X, x 0 ) c x0 (t) x 0 [α] α α(t) = α(1 t)
82 8. ([α] [β]) [γ] = [α] ([β] [γ]) (α β) γ α (β γ) [α] [c x0 ] = [c x0 ] [α] = [α] α c x0 c x0 α α [α] [α] = [α] [α] = [c x0 ] α α α α c x0 α β α β α X x 0 x 1 l l ([α]) = [l α l] l : π 1 (X, x 0 ) π 1 (X, x 1 ) l
83 8. f : X Y f : π 1 (X, x 0 ) π(y, y 0 ) y 0 = f(x 0 ) (X, x 0 ) (Y, y 0 ) f g H(x,0) = f(x), H(x,1) = g(x) H : (X [0, 1], {x 0 } [0, 1] ) (Y, y 0 ) f g f g f : (X, x 0 ) (Y, y 0 ) g f 1 X f g 1 Y g: (Y, y 0 ) (X, x 0 ) f ( )
84 8. 1. f : (X, x 0 ) (Y, y 0 ) g: (Y, y 0 ) (X, z 0 ) (g f) = g f 2. 1 X : (X, x 0 ) (X, x 0 ) 3. f g: (X, x 0 ) (Y, y 0 ) f = g 1, 2 f : (X, x 0 ) (Y, y 0 ) f 3
85 8. f : (X, x 0 ) (Y, y 0 ) f : π 1 (X, x 0 ) π 1 (Y, y 0 ) X x 0 π 1 (X, x 0 ) = {1} x 0 X π 1 (X, x 0 ) 1 1 n D n 1
86 8. S 1 C S 1 Z π 1 (S 1, e 0 ) Z e: R S 1 e(t) = cos2πt + i sin2πt S 1 e V 0 = S 1 { 1} V 1 = S 1 {1} {V 0, V 1 } S 1 U n = (n/2 1/2, n/2 + 1/2) {U n n Z} R e U n e U n : U n V n (n = n mod 2)
87 8. 1. l: I S 1 p(a) = l(0) a R e l = l, l(0) = a l: I R l 2. L: I I S 1 p(a) = L(0, 0) a R p L = L, L(0, 0) = a L: I I R
88 8. π 1 (S 1, 1) [α] α χ([α]) = α(1) α(0) α χ: π 1 (S 1, 1) Z
89 8. C 0 S 1 Z π 1 (C 0, x 0 ) z z x 0 π 1 (S 1, 1) = π 1 (C 0, x 0 ) Z f : S 1 C 0 W(f,0) = f (1) π 1 (C 0, x 0 ) = Z f (winding number)
90 8. arg f(e(t)) = 2πθ(t) (0 t 1) θ: [0, 1] R W(f,0) = θ(1) θ(0) e(t) = cos2πt + i sin2πt x c x W(c x, 0) = 0 n W(z n, 0) = n W(f g, 0) = W(f,0) + W(g, 0) W(f/g,0) = W(f,0) W(g, 0)
91 8. f g: (S 1, 1) (C 0, x 0 ) W(f,0) = W(g, 0) f g C 0 (f g: S 1 C 0) W(f,0) = W(g, 0) f(z) W(f,0) = 0
92 8. f D 2 S 1 f S 1 W(f S 1, 0) 0 f(z) = 0 z D 2 0 f(d 2 ) f c f(0) : S 1 C 0 W(f,0) = W(c f(0), 0) = 0 c f(0) (z) f(0) (z S 1 )
93 8. Brouwer f : D 2 D 2 f(x) = x x D 2
94 8. n + 1 S n f( x) = f(x) f : S n R m f : S 1 C 0 W(f,0) f : S 2 R 2 f(s 2 )
95 8. f : S 2 R 2 f(x) = f( x) x S 2 S 2 3 2
III 1 (X, d) d U d X (X, d). 1. (X, d).. (i) d(x, y) d(z, y) d(x, z) (ii) d(x, y) d(z, w) d(x, z) + d(y, w) 2. (X, d). F X.. (1), X F, (2) F 1, F 2 F
III 1 (X, d) d U d X (X, d). 1. (X, d).. (i) d(x, y) d(z, y) d(x, z) (ii) d(x, y) d(z, w) d(x, z) + d(y, w) 2. (X, d). F X.. (1), X F, (2) F 1, F 2 F F 1 F 2 F, (3) F λ F λ F λ F. 3., A λ λ A λ. B λ λ
1 1 sin cos P (primary) S (secondly) 2 P S A sin(ω2πt + α) A ω 1 ω α V T m T m 1 100Hz m 2 36km 500Hz. 36km 1
sin cos P (primary) S (secondly) 2 P S A sin(ω2πt + α) A ω ω α 3 3 2 2V 3 33+.6T m T 5 34m Hz. 34 3.4m 2 36km 5Hz. 36km m 34 m 5 34 + m 5 33 5 =.66m 34m 34 x =.66 55Hz, 35 5 =.7 485.7Hz 2 V 5Hz.5V.5V V
6 2 2 x y x y t P P = P t P = I P P P ( ) ( ) ,, ( ) ( ) cos θ sin θ cos θ sin θ, sin θ cos θ sin θ cos θ y x θ x θ P
6 x x 6.1 t P P = P t P = I P P P 1 0 1 0,, 0 1 0 1 cos θ sin θ cos θ sin θ, sin θ cos θ sin θ cos θ x θ x θ P x P x, P ) = t P x)p ) = t x t P P ) = t x = x, ) 6.1) x = Figure 6.1 Px = x, P=, θ = θ P
1 1.1 ( ). z = a + bi, a, b R 0 a, b 0 a 2 + b 2 0 z = a + bi = ( ) a 2 + b 2 a a 2 + b + b 2 a 2 + b i 2 r = a 2 + b 2 θ cos θ = a a 2 + b 2, sin θ =
1 1.1 ( ). z = + bi,, b R 0, b 0 2 + b 2 0 z = + bi = ( ) 2 + b 2 2 + b + b 2 2 + b i 2 r = 2 + b 2 θ cos θ = 2 + b 2, sin θ = b 2 + b 2 2π z = r(cos θ + i sin θ) 1.2 (, ). 1. < 2. > 3. ±,, 1.3 ( ). A
1. 1 A : l l : (1) l m (m 3) (2) m (3) n (n 3) (4) A α, β γ α β + γ = 2 m l lm n nα nα = lm. α = lm n. m lm 2β 2β = lm β = lm 2. γ l 2. 3
1. 1 A : l l : (1) l m (m 3) (2) m (3) n (n 3) (4) A 2 1 2 1 2 3 α, β γ α β + γ = 2 m l lm n nα nα = lm. α = lm n. m lm 2β 2β = lm β = lm 2. γ l 2. 3 4 P, Q R n = {(x 1, x 2,, x n ) ; x 1, x 2,, x n R}
x () g(x) = f(t) dt f(x), F (x) 3x () g(x) g (x) f(x), F (x) (3) h(x) = x 3x tf(t) dt.9 = {(x, y) ; x, y, x + y } f(x, y) = xy( x y). h (x) f(x), F (x
[ ] IC. f(x) = e x () f(x) f (x) () lim f(x) lim f(x) x + x (3) lim f(x) lim f(x) x + x (4) y = f(x) ( ) ( s46). < a < () a () lim a log xdx a log xdx ( ) n (3) lim log k log n n n k=.3 z = log(x + y ),
(ii) (iii) z a = z a =2 z a =6 sin z z a dz. cosh z z a dz. e z dz. (, a b > 6.) (z a)(z b) 52.. (a) dz, ( a = /6.), (b) z =6 az (c) z a =2 53. f n (z
B 4 24 7 9 ( ) :,..,,.,. 4 4. f(z): D C: D a C, 2πi C f(z) dz = f(a). z a a C, ( ). (ii), a D, a U a,r D f. f(z) = A n (z a) n, z U a,r, n= A n := 2πi C f(ζ) dζ, n =,,..., (ζ a) n+, C a D. (iii) U a,r
2000年度『数学展望 I』講義録
2000 I I IV I II 2000 I I IV I-IV. i ii 3.10 (http://www.math.nagoya-u.ac.jp/ kanai/) 2000 A....1 B....4 C....10 D....13 E....17 Brouwer A....21 B....26 C....33 D....39 E. Sperner...45 F....48 A....53
20 4 20 i 1 1 1.1............................ 1 1.2............................ 4 2 11 2.1................... 11 2.2......................... 11 2.3....................... 19 3 25 3.1.............................
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II 231017 1 1.1. R n k +1 v 0,, v k k v 1 v 0,, v k v 0 1.2. v 0,, v k R n 1 a 0,, a k a 0 v 0 + a k v k v 0 v k k k v 0,, v k σ kσ dimσ = k 1.3. k σ {v 0,...,v k } {v i0,...,v il } l σ τ < τ τ σ 1.4.
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6,,3,4,, 3 4 8 6 6................................. 6.................................. , 3, 6 = 3, 3,,,, 3,, 9, 3, 9, 3, 3, 4, 43, 4, 3, 9, 6, 6,, 0 p, p, p 3,..., p n N = p p p 3 p n + N p n N p p p,
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A 2563 15 4 21 1 3 1.1................................................ 3 1.2............................................. 3 2 3 2.1......................................... 3 2.2............................................
4 4 θ X θ P θ 4. 0, 405 P 0 X 405 X P 4. () 60 () 45 () 40 (4) 765 (5) 40 B 60 0 P = 90, = ( ) = X
4 4. 4.. 5 5 0 A P P P X X X X +45 45 0 45 60 70 X 60 X 0 P P 4 4 θ X θ P θ 4. 0, 405 P 0 X 405 X P 4. () 60 () 45 () 40 (4) 765 (5) 40 B 60 0 P 0 0 + 60 = 90, 0 + 60 = 750 0 + 60 ( ) = 0 90 750 0 90 0
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145 13 13.1 13.1.1 0 m mg S 13.1 F 13.1 F /m S F F 13.1 F mg S F F mg 13.1: m d2 r 2 = F + F = 0 (13.1) 146 13 F = F (13.2) S S S S S P r S P r r = r 0 + r (13.3) r 0 S S m d2 r 2 = F (13.4) (13.3) d 2
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1 I 1.1 ± e = = - = C C MKSA [m], [Kg] [s] [A] 1C 1A 1 MKSA 1C 1C +q q +q q 1
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9 2 1 f(x, y) = xy sin x cos y x y cos y y x sin x d (x, y) = y cos y (x sin x) = y cos y(sin x + x cos x) x dx d (x, y) = x sin x (y cos y) = x sin x
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1 θ i (1) A B θ ( ) A = B = sin 3θ = sin θ (A B sin 2 θ) ( ) 1 2 π 3 < = θ < = 2 π 3 Ax Bx3 = 1 2 θ = π sin θ (2) a b c θ sin 5θ = sin θ f(sin 2 θ) 2
θ i ) AB θ ) A = B = sin θ = sin θ A B sin θ) ) < = θ < = Ax Bx = θ = sin θ ) abc θ sin 5θ = sin θ fsin θ) fx) = ax bx c ) cos 5 i sin 5 ) 5 ) αβ α iβ) 5 α 4 β α β β 5 ) a = b = c = ) fx) = 0 x x = x =
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1 X X A, B X = A B A B A B X 1.1 R R I I a, b(a < b) I a x b = x I 1.2 R A 1.3 X : (1)X (2)X X (3)X A, B X = A B A B = 1.4 f : X Y X Y ( ) A Y A Y A f
1 X X A, B X = A B A B A B X 1.1 R R I I a, b(a < b) I a x b = x I 1. R A 1.3 X : (1)X ()X X (3)X A, B X = A B A B = 1.4 f : X Y X Y ( ) A Y A Y A f 1 (A) f X X f 1 (A) = X f 1 (A) = A a A f f(x) = a x
最新耐震構造解析 ( 第 3 版 ) サンプルページ この本の定価 判型などは, 以下の URL からご覧いただけます. このサンプルページの内容は, 第 3 版 1 刷発行時のものです.
最新耐震構造解析 ( 第 3 版 ) サンプルページ この本の定価 判型などは, 以下の URL からご覧いただけます. http://www.morikita.co.jp/books/mid/052093 このサンプルページの内容は, 第 3 版 1 刷発行時のものです. i 3 10 3 2000 2007 26 8 2 SI SI 20 1996 2000 SI 15 3 ii 1 56 6
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A. A. A-- [ ] f(x) x = f 00 (x) f 0 () =0 f 00 () > 0= f(x) x = f 00 () < 0= f(x) x = A--2 [ ] f(x) D f 00 (x) > 0= y = f(x) f 00 (x) < 0= y = f(x) P (, f()) f 00 () =0 A--3 [ ] y = f(x) [, b] x = f (y)
.5 z = a + b + c n.6 = a sin t y = b cos t dy d a e e b e + e c e e e + e 3 s36 3 a + y = a, b > b 3 s363.7 y = + 3 y = + 3 s364.8 cos a 3 s365.9 y =,
[ ] IC. r, θ r, θ π, y y = 3 3 = r cos θ r sin θ D D = {, y ; y }, y D r, θ ep y yddy D D 9 s96. d y dt + 3dy + y = cos t dt t = y = e π + e π +. t = π y =.9 s6.3 d y d + dy d + y = y =, dy d = 3 a, b
1. 2 P 2 (x, y) 2 x y (0, 0) R 2 = {(x, y) x, y R} x, y R P = (x, y) O = (0, 0) OP ( ) OP x x, y y ( ) x v = y ( ) x 2 1 v = P = (x, y) y ( x y ) 2 (x
. P (, (0, 0 R {(,, R}, R P (, O (0, 0 OP OP, v v P (, ( (, (, { R, R} v (, (, (,, z 3 w z R 3,, z R z n R n.,..., n R n n w, t w ( z z Ke Words:. A P 3 0 B P 0 a. A P b B P 3. A π/90 B a + b c π/ 3. +
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1 8, : 8.1 1, z = ax + by + c ax by + z c = a b +1 x y z c = 0, (0, 0, c), n = ( a, b, 1). f = a ii x i + i
量子力学 問題
3 : 203 : 0. H = 0 0 2 6 0 () = 6, 2 = 2, 3 = 3 3 H 6 2 3 ϵ,2,3 (2) ψ = (, 2, 3 ) ψ Hψ H (3) P i = i i P P 2 = P 2 P 3 = P 3 P = O, P 2 i = P i (4) P + P 2 + P 3 = E 3 (5) i ϵ ip i H 0 0 (6) R = 0 0 [H,
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p1 i 2 = 1 i 2 x, y x + iy 2 (x + iy) + (γ + iδ) = (x + γ) + i(y + δ) (x + iy)(γ + iδ) = (xγ yδ) + i(xδ + yγ) i 2 = 1 γ + iδ 0 x + iy γ + iδ xγ + yδ xδ = γ 2 + iyγ + δ2 γ 2 + δ 2 p7 = x 2 +y 2 z z p13
1 : f(z = re iθ ) = u(r, θ) + iv(r, θ). (re iθ ) 2 = r 2 e 2iθ = r 2 cos 2θ + ir 2 sin 2θ r f(z = x + iy) = u(x, y) + iv(x, y). (x + iy) 2 = x 2 y 2 +
1.3 1.4. (pp.14-27) 1 1 : f(z = re iθ ) = u(r, θ) + iv(r, θ). (re iθ ) 2 = r 2 e 2iθ = r 2 cos 2θ + ir 2 sin 2θ r f(z = x + iy) = u(x, y) + iv(x, y). (x + iy) 2 = x 2 y 2 + i2xy x = 1 y (1 + iy) 2 = 1
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第1章 微分方程式と近似解法
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1. A0 A B A0 A : A1,...,A5 B : B1,...,B12 2. 3. 4. 5. A0 A, B Z Z m, n Z m n m, n A m, n B m=n (1) A, B (2) A B = A B = Z/ π : Z Z/ (3) A B Z/ (4) Z/ A, B (5) f : Z Z f(n) = n f = g π g : Z/ Z A, B (6)
, 1 ( f n (x))dx d dx ( f n (x)) 1 f n (x)dx d dx f n(x) lim f n (x) = [, 1] x f n (x) = n x x 1 f n (x) = x f n (x) = x 1 x n n f n(x) = [, 1] f n (x
![, 1 ( f n (x))dx d dx ( f n (x)) 1 f n (x)dx d dx f n(x) lim f n (x) = [, 1] x f n (x) = n x x 1 f n (x) = x f n (x) = x 1 x n n f n(x) = [, 1] f n (x](/thumbs/93/113428934.jpg ", 1 ( f n (x))dx d dx ( f n (x)) 1 f n (x)dx d dx f n(x) lim f n (x) = [, 1] x f n (x) = n x x 1 f n (x) = x f n (x) = x 1 x n n f n(x) = [, 1] f n (x")
1 1.1 4n 2 x, x 1 2n f n (x) = 4n 2 ( 1 x), 1 x 1 n 2n n, 1 x n n 1 1 f n (x)dx = 1, n = 1, 2,.. 1 lim 1 lim 1 f n (x)dx = 1 lim f n(x) = ( lim f n (x))dx = f n (x)dx 1 ( lim f n (x))dx d dx ( lim f d
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