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1 1.1 Excel Excel Excel log 1, log 2, log 3,, log 10 e = ln 10 log cm 1mm 1 10 =0.1mm = f(x) f(x) = n

1 1.1 Excel Excel Excel log 1, log, log,, log e.7188188 ln log 1. 5cm 1mm 1 0.1mm 0.1 4 4 1 4.1 fx) fx) n0 f n) 0) x n n! n + 1 R n+1 x) fx) f0) + f 0) 1! x + f 0)! x + + f n) 0) x n + R n+1 x) n! 1 .

[FX8/FX8C]シリーズカタログ

2018.6 FX8-120 P - SV 192 1 2 3 1 2 3 4 5 6 6 B 4 5 6 B 0.6±0.1 B +0.05 _0.2 C +0.05 _0.2 D±0.2 6.5 _0.3 0 5.1±0.3 2.45±0.25 (0.4) (0.75) (Ø0.9) t0.2±0.03 w0.25±0.03 (Ø0.6) 2-(C0.2) (1.5) E±0.1 FX8-60P-SV(**)

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2014.9w FX8-120 P - SV 192 1 2 3 1 2 3 4 5 6 6 B 4 5 6 B 0.6±0.1 B +0.05 _0.2 C +0.05 _0.2 D±0.2 6.5 _0.3 0 5.1±0.3 2.45±0.25 (0.4) (0.75) (Ø0.9) t0.2±0.03 w0.25±0.03 (Ø0.6) 2-(C0.2) (1.5) E±0.1 FX8-60P-SV(92)

( ) ( ) 1729 (, 2016:17) = = (1) 1 1

1729 1 2016 10 28 1 1729 1111 1111 1729 (1887 1920) (1877 1947) 1729 (, 2016:17) 12 3 1728 9 3 729 1729 = 12 3 + 1 3 = 10 3 + 9 3 (1) 1 1 2 1729 1729 19 13 7 = 1729 = 12 3 + 1 3 = 10 3 + 9 3 13 7 = 91

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Tempest XGA Pocket FX Model:DSE-001 Multimedia Series PC Video Encoder http://www.ad-techno.com/regist/ FAX:03-5213-5323 Tempest XGA PocketFX Tempest XGA PocketFX Tempest XGA PocketFX Tempest XGA

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+ + + + n S (n) = + + + + n S (n) S (n) S 0 (n) S (n) 6 4 S (n) S (n) 7 S (n) S 4 (n) 8 6 S k (n) 0 7 (k + )S k (n) 8 S 6 (n), S 7 (n), S 8 (n), S 9 (

k k + k + k + + n k 006.7. + + + + n S (n) = + + + + n S (n) S (n) S 0 (n) S (n) 6 4 S (n) S (n) 7 S (n) S 4 (n) 8 6 S k (n) 0 7 (k + )S k (n) 8 S 6 (n), S 7 (n), S 8 (n), S 9 (n), S 0 (n) 9 S (n) S 4

( ) ( ) ( ) i (i = 1, 2,, n) x( ) log(a i x + 1) a i > 0 t i (> 0) T i x i z n z = log(a i x i + 1) i=1 i t i ( ) x i t i (i = 1, 2, n) T n x i T i=1 z = n log(a i x i + 1) i=1 x i t i (i = 1, 2,, n) n

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[FX18]シリーズカタログ

ICR (db) 6 5 3 2 ICR 1 ICR IEEE spec 2 4 6 8 1 Z (Ohms) 11 15 1 95 Impedance 9.2.4.6.8 1 Time (ns) 213.9 FX18-6 S -.8 SH FX18-6 P -.8 SH FX18-6 P -.8 SV 1 FX18-6 S -.8 SV 15 FX18-6 PS -.8 H 15 Signal

春期講座 ~ 極限 1 1, 1 2, 1 3, 1 4,, 1 n, n n {a n } n a n α {a n } α {a n } α lim n an = α n a n α α {a n } {a n } {a n } 1. a n = 2 n {a n } 2, 4, 8, 16,

春期講座 ~ 極限 1 1, 1 2, 1 3, 1 4,, 1 n, n n {a n } n a n α {a n } α {a n } α lim an = α n a n α α {a n } {a n } {a n } 1. a n = 2 n {a n } 2, 4, 8, 16, 32, n a n {a n } {a n } 2. a n = 10n + 1 {a n } lim an

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5 3 3. 9. 4. x, x. 4, f(x, ) :=x x + =4,x,.. 4 (, 3) (, 5) (3, 5), (4, 9) 95 9 (g) 4 6 8 (cm).9 3.8 6. 8. 9.9 Phsics 85 8 75 7 65 7 75 8 85 9 95 Mathematics = ax + b 6 3 (, 3) 3 ( a + b). f(a, b) ={3 (a

() 3 3 2 5 3 6 4 2 5 4 2 (; ) () 8 2 4 0 0 2 ex. 3 n n =, 2,, 20 : 3 2 : 9 3 : 27 4 : 8 5 : 243 6 : 729 7 : 287 8 : 656 9 : 9683 0 : 59049 : 7747 2 : 5344 3 : 594323 4 : 4782969 5 : 4348907 6 : 4304672

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

t χ 2 F Q t χ 2 F 1 2 µ, σ 2 N(µ, σ 2 ) f(x µ, σ 2 ) = 1 ( exp (x ) µ)2 2πσ 2 2σ 2 0, N(0, 1) (100 α) z(α) t χ 2 *1 2.1 t (i)x N(µ, σ 2 ) x µ σ N(0, 1

t χ F Q t χ F µ, σ N(µ, σ ) f(x µ, σ ) = ( exp (x ) µ) πσ σ 0, N(0, ) (00 α) z(α) t χ *. t (i)x N(µ, σ ) x µ σ N(0, ) (ii)x,, x N(µ, σ ) x = x+ +x N(µ, σ ) (iii) (i),(ii) z = x µ N(0, ) σ N(0, ) ( 9 97.

ax 2 + bx + c = n 8 (n ) a n x n + a n 1 x n a 1 x + a 0 = 0 ( a n, a n 1,, a 1, a 0 a n 0) n n ( ) ( ) ax 3 + bx 2 + cx + d = 0 4

20 20.0 ( ) 8 y = ax 2 + bx + c 443 ax 2 + bx + c = 0 20.1 20.1.1 n 8 (n ) a n x n + a n 1 x n 1 + + a 1 x + a 0 = 0 ( a n, a n 1,, a 1, a 0 a n 0) n n ( ) ( ) ax 3 + bx 2 + cx + d = 0 444 ( a, b, c, d

【改改】FX取引×自己アフィリマスター講座

渚ひろし 自己アフィリ FX取引マスター講座 Ⅰ FX取引 自己アフィリエイト このレポートでは FXの口座開設または取引を通じて報酬を得る 自己ア フィリエイトの方法を解説します なぜアフィリエイトとFXが関係あるのか ということですが ハピタスやA8.netセルフバックに代表される自己アフィリエイトで大きな金 額を稼ぐにはFXプログラムのマスターが不可欠です FX FX FX FX このように

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1 (1) ( i ) 60 (ii) 75 (iii) 315 (2) π ( i ) (ii) π (iii) 7 12 π ( (3) r, AOB = θ 0 < θ < π ) OAB A 2 OB P ( AB ) < ( AP ) (4) 0 < θ < π 2 sin θ

1 (1) ( i ) 60 (ii) 75 (iii) 15 () ( i ) (ii) 4 (iii) 7 1 ( () r, AOB = θ 0 < θ < ) OAB A OB P ( AB ) < ( AP ) (4) 0 < θ < sin θ < θ < tan θ 0 x, 0 y (1) sin x = sin y (x, y) () cos x cos y (x, y) 1 c

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2016 3 11 ( ) 2016 3 11 1 / 16 t VaR ( vs 5 t ) t ( ) 2016 3 11 2 / 16 () Crouhy (2008) Table: ( ) 2016 3 11 3 / 16 VaR (2010) Table: ( ) 2016 3 11 4 / 16 Tang and Valdez(2006) 5 t Brockmann and Kaklbrener(2010)

π, R { 2, 0, 3} , ( R),. R, [ 1, 1] = {x R 1 x 1} 1 0 1, [ 1, 1],, 1 0 1,, ( 1, 1) = {x R 1 < x < 1} [ 1, 1] 1 1, ( 1, 1), 1, 1, R A 1

sup inf (ε-δ 4) 2018 1 9 ε-δ,,,, sup inf,,,,,, 1 1 2 3 3 4 4 6 5 7 6 10 6.1............................................. 11 6.2............................... 13 1 R R 5 4 3 2 1 0 1 2 3 4 5 π( R) 2 1 0

arctan 1 arctan arctan arctan π = = ( ) π = 4 = π = π = π = =

arctan arctan arctan arctan 2 2000 π = 3 + 8 = 3.25 ( ) 2 8 650 π = 4 = 3.6049 9 550 π = 3 3 30 π = 3.622 264 π = 3.459 3 + 0 7 = 3.4085 < π < 3 + 7 = 3.4286 380 π = 3 + 77 250 = 3.46 5 3.45926 < π < 3.45927

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JNB-FX PLUS JNB-FX PLUS 2p 3p 6p 7p 9p 10p 11p 12p 13p 14p 1

JNB-FX PLUS 624 JNB-FX PLUS JNB-FX PLUS 2p 3p 6p 7p 9p 10p 11p 12p 13p 14p 1 JNB-FX PLUS JNB-FX 0120-828986 917 PHS 03-6739-5010/ 2 JNB-FX PLUS JNB-FX PLUS 2006 3 FX 1. 2. 3 3. 25 25 2 4 4. JNB-FX PLUS

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Geographic Information System 11 12 GIS 13 GIS 14 GIS 31 51 9.12 12 FX 32 33 1976 9.21 1976 9.21 2000 34 35 36 1 1 37 38 39 40 UML 6 1 / 1 /10 C 10 B 10 C 10 B 1 FX B C 3 B 1 FX B ID WebGIS GIS DB DB SP

() x + y + y + x dy dx = 0 () dy + xy = x dx y + x y ( 5) ( s55906) 0.7. (). 5 (). ( 6) ( s6590) 0.8 m n. 0.9 n n A. ( 6) ( s6590) f A (λ) = det(a λi)

0. A A = 4 IC () det A () A () x + y + z = x y z X Y Z = A x y z ( 5) ( s5590) 0. a + b + c b c () a a + b + c c a b a + b + c 0 a b c () a 0 c b b c 0 a c b a 0 0. A A = 7 5 4 5 0 ( 5) ( s5590) () A ()

1 I 1.1 ± e = = - = C C MKSA [m], [Kg] [s] [A] 1C 1A 1 MKSA 1C 1C +q q +q q 1

1 I 1.1 ± e = = - =1.602 10 19 C C MKA [m], [Kg] [s] [A] 1C 1A 1 MKA 1C 1C +q q +q q 1 1.1 r 1,2 q 1, q 2 r 12 2 q 1, q 2 2 F 12 = k q 1q 2 r 12 2 (1.1) k 2 k 2 ( r 1 r 2 ) ( r 2 r 1 ) q 1 q 2 (q 1 q 2

1 c Koichi Suga, ISBN

c Koichi Suga, 4 4 6 5 ISBN 978-4-64-6445- 4 ( ) x(t) t u(t) t {u(t)} {x(t)} () T, (), (3), (4) max J = {u(t)} V (x, u)dt ẋ = f(x, u) x() = x x(t ) = x T (), x, u, t ẋ x t u u ẋ = f(x, u) x(t ) = x T x(t

7 27 7.1........................................ 27 7.2.......................................... 28 1 ( a 3 = 3 = 3 a a > 0(a a a a < 0(a a a -1 1 6

26 11 5 1 ( 2 2 2 3 5 3.1...................................... 5 3.2....................................... 5 3.3....................................... 6 3.4....................................... 7

(, ) (, ) S = 2 = [, ] ( ) 2 ( ) 2 2 ( ) 3 2 ( ) 4 2 ( ) k 2,,, k =, 2, 3, 4 S 4 S 4 = ( ) 2 + ( ) ( ) (

B 4 4 4 52 4/ 9/ 3/3 6 9.. y = x 2 x x = (, ) (, ) S = 2 = 2 4 4 [, ] 4 4 4 ( ) 2 ( ) 2 2 ( ) 3 2 ( ) 4 2 ( ) k 2,,, 4 4 4 4 4 k =, 2, 3, 4 S 4 S 4 = ( ) 2 + ( ) 2 2 + ( ) 3 2 + ( 4 4 4 4 4 4 4 4 4 ( (

dy + P (x)y = Q(x) (1) dx dy dx = P (x)y + Q(x) P (x), Q(x) dy y dx Q(x) 0 homogeneous dy dx = P (x)y 1 y dy = P (x) dx log y = P (x) dx + C y = C exp

+ P (x)y = Q(x) (1) = P (x)y + Q(x) P (x), Q(x) y Q(x) 0 homogeneous = P (x)y 1 y = P (x) log y = P (x) + C y = C exp{ P (x) } = C e R P (x) 5.1 + P (x)y = 0 (2) y = C exp{ P (x) } = Ce R P (x) (3) αy

1 (1) () (3) I 0 3 I I d θ = L () dt θ L L θ I d θ = L = κθ (3) dt κ T I T = π κ (4) T I κ κ κ L l a θ L r δr δl L θ ϕ ϕ = rθ (5) l

1 1 ϕ ϕ ϕ S F F = ϕ (1) S 1: F 1 1 (1) () (3) I 0 3 I I d θ = L () dt θ L L θ I d θ = L = κθ (3) dt κ T I T = π κ (4) T I κ κ κ L l a θ L r δr δl L θ ϕ ϕ = rθ (5) l : l r δr θ πrδr δf (1) (5) δf = ϕ πrδr

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L11(2011-07-06 Wed) :Time-stamp: 2011-07-06 Wed 13:08 JST hig 1,,. 2. http://hig3.net () (L11) 2011-07-06 Wed 1 / 18 ( ) 1 V = (xy2 ) x + (2y) y = y 2 + 2. 2 V = 4y., D V ds = 2 2 ( ) 4 x 2 4y dy dx =

Abstract :

17 18 3 : 3604U079- Abstract : 1 3 1.1....................................... 4 1................................... 4 1.3.................................. 4 5.1..................................... 6.................................

Chap9.dvi

.,. f(),, f(),,.,. () lim 2 +3 2 9 (2) lim 3 3 2 9 (4) lim ( ) 2 3 +3 (5) lim 2 9 (6) lim + (7) lim (8) lim (9) lim (0) lim 2 3 + 3 9 2 2 +3 () lim sin 2 sin 2 (2) lim +3 () lim 2 2 9 = 5 5 = 3 (2) lim

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Contents 1. 1 2. 2 3. 2 4. 2 5. 3 6. 3 7. 3 8. 4 9. 5 10. 6 11. 8 12. 9 13. - 10 14. 12 15. 13 16. 14 17. 14 18. 15 19. 15 20. 16 21. 16 References 16 1......, 1 2,.,. 4. 2. 2.,. 8.,,,..,.,,... 3....,....,..,...

II 2014 2 (1) log(1 + r/100) n = log 2 n log(1 + r/100) = log 2 n = log 2 log(1 + r/100) (2) y = f(x) = log(1 + x) x = 0 1 f (x) = 1/(1 + x) f (0) = 1

II 2014 1 1 I 1.1 72 r 2 72 8 72/8 = 9 9 2 a 0 1 a 1 a 1 = a 0 (1+r/100) 2 a 2 a 2 = a 1 (1 + r/100) = a 0 (1 + r/100) 2 n a n = a 0 (1 + r/100) n a n a 0 2 n a 0 (1 + r/100) n = 2a 0 (1 + r/100) n = 2

09 II 09/11/ y = e x y = log x = log e x 2. ( e x ) = e x 3. ( ) log x = 1 x 1 Warming Up 1 u = log a M a u = M log a 1 a 0 a 1 a r+s 0 a r

09 II 09/11/16 1 5.6 1. y = e x y = log x = log e x 2. e x ) = e x 3. ) log x = 1 x 1 Warming Up 1 u = log a M a u = M log a 1 a 0 a 1 a r+s 0 a r a s 1 a 2 f g) = f g + f g 1. fx) = x e x f x) = 2. fx)

1 X X T T X (topology) T X (open set) (X, T ) (topological space) ( ) T1 T, X T T2 T T T3 T T ( ) ( ) T1 X T2 T3 1 X T = {, X} X (X, T ) indiscrete sp

1 X X T T X (topology) T X (open set) (X, T ) (topological space) ( ) T1 T, X T T2 T T T3 T T ( ) ( ) T1 X T2 T3 1 X T = {, X} X (X, T ) indiscrete space T1 T2 =, X = X, X X = X T3 =, X =, X X = X 2 X

(1) 3 A B E e AE = e AB OE = OA + e AB = (1 35 e ) e OE z 1 1 e E xy e = 0 e = 5 OE = ( 2 0 0) E ( 2 0 0) (2) 3 E P Q k EQ = k EP E y 0

(1) 3 A B E e AE = e AB OE = OA + e AB = (1 35 e 0 1 15 ) e OE z 1 1 e E xy 5 1 1 5 e = 0 e = 5 OE = ( 2 0 0) E ( 2 0 0) (2) 3 E P Q k EQ = k EP E y 0 Q y P y k 2 M N M( 1 0 0) N(1 0 0) 4 P Q M N C EP

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[email protected] II 2009 6 11 [A] D B A B A B A B DVD y = 2x + 5 x = 3 y = 11 x = 5 y = 15. Google Web (2 + 3) 5 25 2 3 5 25 Windows Media Player Media Player (typed lambda calculus) (computer

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 =

1 1 1 1 1 1 2 f z 2 C 1, C 2 f 2 C 1, C 2 f(c 2 ) C 2 f(c 1 ) z C 1 f f(z) xy uv ( u v ) = ( a b c d ) ( x y ) + ( p q ) (p + b, q + d) 1 (p + a, q + c) 1 (p, q) 1 1 (b, d) (a, c) 2 3 2 3 a = d, c = b