DVIOUT-MTT元原
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- ゆゆこ はぎにわ
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1 TI-92 -MTT-Mathematics Thinking with Technology MTT ACTIVITY Discussion 1
2 1 1.1 v t h h = vt 1 2 gt2 (1.1) xy (5, 0) 20m/s [1] Mode Graph Parametric [2] Y= [3] Window [4] Graph 1.1: Discussion 2 Window tmin,tmax,tstep,xmin,xmax,xscl,ymin,ymax,yscl [1] Y= F6 :style square [2] tblset start 0, 0.5 Table 2
![1.2: Discussion F6 :style Table t (x, y) [1] Y= F6 :style](/docs-images/101/148630967/images/3-0.jpg "[2] F1 :Format: graphorder simul [3] Graph 1.")
3 1.2: Discussion F6 :style Table t (x, y) [1] Y= F6 :style [2] F1 :Format: graphorder simul [3] Graph 1.3: Discussion 3
![1.2 20m/s θ t [1] Mode Angle degree ( x =20 cos θ t y =20 sin θ t 1 2 g t2 (1.](/docs-images/101/148630967/images/4-0.jpg "2) [2] Y= 45 [3] F4 [4] style Line [5] Window [6] Graph 1.")
4 1.2 20m/s θ t [1] Mode Angle degree ( x =20 cos θ t y =20 sin θ t 1 2 g t2 (1.2) [2] Y= 45 [3] F4 [4] style Line [5] Window [6] Graph 1.4: Discussion [1] Home : F2 :Solve [2] Y = yt3) [3] Home [4] Discussion 4
5 1.5: m/s 45 25m 1.4 TI-92 5
6 1.5 BASE BALL t (x, y) t t 2 HOME ( x = v cos θ t y = v sin θ t 1 2 g t2 (1.3) F2 :Solve t 2 y = 4.9 x2 (cos θ) 2 v +tanθ x 2 1.6: 2 Activuty [1] [2] θ [3] [4] 96m 120m m 3 6
7 Mode Graph Function Y= Window F3 trace 1.7: F5 MATH MAXimum Upper Lower 1.8: 45 7
8 km 1.9: 1.10: Discussion 50 8
9 2 2.1 TI-92 APPS geometry 3 NEW F3 circle F2 Point F2 Point on object F2 segment AF F4 Perpendicular Bisector AF 2.1: Discussion AF 9
10 F7 Trace On/off F7 Animation HAND ON CLEAR F1 Pointer 1 AF 2.2: 10
11 [1] [2] [3] 2 a 3 T 2 = ka 3 mercury venus earth 1 1 mars jupiter saturn : 1 = m 3 APPS 6 data/matrix/editor New F1 format cell width 8 name,t,a F2 Plot F1 x y Window Graph 11
12 3.1: 3.2: Discussion APPS data/matrix/editor c4 c2 2 c5 c3 3 c4 c5 3.3: data/matrix/editor F5 3:cubic 3:cubic 3 y = ax 3 + bx 2 + cx + d x c2 y c3 store y1(x) enter 3 Y= Graph data/matrix/editor F5 4:power (power y = a x b x c2 y c3 store y2(x) enter 12
13 3.4: Y= Graph Discussion 2 3 Uranus Neptune Pluto : 1 = m 100 Km) (Kelvin) mercury venus earth mars jupiter saturn Uranus Neptune Pluto : 13
14 4 4.1 Home F2 2 Factor( 4.1: Home F2 3 Expand( 4.2: 14
15 Discussion 2 expand((x + y)(x 2 3xy + y +5),x) (4.1) expand((x + y)(x 2 3xy + y +5),y) (4.2) x n 1 n =2, 3, 4, 5, 6, 15
16 {a n } 1 {b n } {c n } {a n } 100 {b n } 100 {c n } : a n =0.95c n b n =0.8a n 1 c n =0.9b n 1 Y = MODE Graph Sequence 5.1 tblset tblstart=1, 4tbl =1 Table
17 5.1: 5.2: Y = F6 3 style Window 5.3:
18 5.4: Discussion a n b n a n = a n a n b n 1 a n 1 b n = b n b n a n 1 b n 1 a 1 =300 b 1 = Y = F7 18
19 5.5: Window Discussion : 5.3 ABCD : 19
20 5.8: a n 1, a n a n a n
21 6 [1] MODE graph parametric enter 2 [2] Y= ( xt1 =cos(t) yt1 =sin(t) [3] WINDOW t tstep 10 x y [4] Graph ACTIVITY WINDOW t [1] MODE graph function enter 2 [2] Y= y1 =sin(x),y2 =cos(x) [3] WINDOW x y [4] Graph ACTIVITY y =cos2x, y =2sinx,y = cos(3x 90 ),y =sin( x)+2 a,b,c,d y = a sin(bx + c)+d y = a cos(bx + c)+d 21
22 ACTIVITY sin x cos x example) sin x +cosx sin 2 x 1 sin x sin x +sin2x DISCUSSION REPORT ACTIVITY DISCUSSION ( 22
23 y = ax 3 + bx 2 + cx + d 4 y = ax 4 + bx 3 + cx 2 + dx + e [1] MODE graph function [2] Y= 3 window 3 3 ACTIVITY 3 ACTIVITY ACTIVITY
24 [1] MODE Graph parametoric F2 split screen top-bottom enter 1 split 1 app Home split 2 app y=editor enter 2 home y= [2] home x 3 1=0 [3] Y= xt yt [4] window graph 2 2 zoomsqr x 3 1=0 3 ACTIVITY x n 1=0 n 2,3,4,5,6,7,8,9, n n DISCUSSION and REPORT x n 1=0 24
210 資料 TI 89 (1) TI 89 2nd ON HOME ( ) ( ) HOME =! ENTER ( ) = (10) ENTER ( ) [ ] { } ( )! 2 =! ( ) ( ) 2 3x ( 2y + yz) ( ) 3x ( ( ) 2y + y z)
![210 資料 TI 89 (1) TI 89 2nd ON HOME ( ) ( ) HOME =! ENTER ( ) = (10) ENTER ( ) [ ] { } ( )! 2 =! ( ) ( ) 2 3x ( 2y + yz) ( ) 3x ( ( ) 2y + y z)](/thumbs/95/123380956.jpg "210 資料 TI 89 (1) TI 89 2nd ON HOME ( ) ( ) HOME =! ENTER ( ) = (10) ENTER ( ) [ ] { } ( )! 2 =! ( ) ( ) 2 3x ( 2y + yz) ( ) 3x ( ( ) 2y + y z)")
210 資料 TI 89 (1) TI 89 2nd ON HOME () () HOME =! ENTER () = 3 10 3 (10) ENTER ( ) [ ] { } ( )! 2 =! ( ) () 2 3x ( 2y + yz) ( ) 3x ( ( ) 2y + y z) ENTER () 2nd 9 2nd 9) ENTER ( ) 2nd 7) ENTER 7 7 ) ENTER
DVIOUT-講
005-10-14 1 1 [1] [] [3] [4] (a + b) = a +ab + b [5] (a + b) 3 a 3 +a b + ab + a b +ab + b 3 a 3 +3a b +3ab + b 3 [6] (a + b) 4 (a + b) 5 [7] technology expand((a+b) n n =?) [8] technology n =6, 7, 8,
Microsoft Word - 触ってみよう、Maximaに2.doc
i i e! ( x +1) 2 3 ( 2x + 3)! ( x + 1) 3 ( a + b) 5 2 2 2 2! 3! 5! 7 2 x! 3x! 1 = 0 ",! " >!!! # 2x + 4y = 30 "! x + y = 12 sin x lim x!0 x x n! # $ & 1 lim 1 + ('% " n 1 1 lim lim x!+0 x x"!0 x log x
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t θ, τ, α, β S(, 0 P sin(θ P θ S x cos(θ SP = θ P (cos(θ, sin(θ sin(θ P t tan(θ θ 0 cos(θ tan(θ = sin(θ cos(θ ( 0t tan(θ
4 5 ( 5 3 9 4 0 5 ( 4 6 7 7 ( 0 8 3 9 ( 8 t θ, τ, α, β S(, 0 P sin(θ P θ S x cos(θ SP = θ P (cos(θ, sin(θ sin(θ P t tan(θ θ 0 cos(θ tan(θ = sin(θ cos(θ ( 0t tan(θ S θ > 0 θ < 0 ( P S(, 0 θ > 0 ( 60 θ
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mugensho.dvi
1 1 f (t) lim t a f (t) = 0 f (t) t a 1.1 (1) lim(t 1) 2 = 0 t 1 (t 1) 2 t 1 (2) lim(t 1) 3 = 0 t 1 (t 1) 3 t 1 2 f (t), g(t) t a lim t a f (t) g(t) g(t) f (t) = o(g(t)) (t a) = 0 f (t) (t 1) 3 1.2 lim
2 1 x 1.1: v mg x (t) = v(t) mv (t) = mg 0 x(0) = x 0 v(0) = v 0 x(t) = x 0 + v 0 t 1 2 gt2 v(t) = v 0 gt t x = x 0 + v2 0 2g v2 2g 1.1 (x, v) θ
1 1 1.1 (Isaac Newton, 1642 1727) 1. : 2. ( ) F = ma 3. ; F a 2 t x(t) v(t) = x (t) v (t) = x (t) F 3 3 3 3 3 3 6 1 2 6 12 1 3 1 2 m 2 1 x 1.1: v mg x (t) = v(t) mv (t) = mg 0 x(0) = x 0 v(0) = v 0 x(t)
1.1 ft t 2 ft = t 2 ft+ t = t+ t 2 1.1 d t 2 t + t 2 t 2 = lim t 0 t = lim t 0 = lim t 0 t 2 + 2t t + t 2 t 2 t + t 2 t 2t t + t 2 t 2t + t = lim t 0
A c 2008 by Kuniaki Nakamitsu 1 1.1 t 2 sin t, cos t t ft t t vt t xt t + t xt + t xt + t xt t vt = xt + t xt t t t vt xt + t xt vt = lim t 0 t lim t 0 t 0 vt = dxt ft dft dft ft + t ft = lim t 0 t 1.1
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重力方向に基づくコントローラの向き決定方法
( ) 2/Sep 09 1 ( ) ( ) 3 2 X w, Y w, Z w +X w = +Y w = +Z w = 1 X c, Y c, Z c X c, Y c, Z c X w, Y w, Z w Y c Z c X c 1: X c, Y c, Z c Kentaro Yamaguchi@bandainamcogames.co.jp 1 M M v 0, v 1, v 2 v 0 v
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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
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D xy D (x, y) z = f(x, y) f D (2 ) (x, y, z) f R z = 1 x 2 y 2 {(x, y); x 2 +y 2 1} x 2 +y 2 +z 2 = 1 1 z (x, y) R 2 z = x 2 y
5 5. 2 D xy D (x, y z = f(x, y f D (2 (x, y, z f R 2 5.. z = x 2 y 2 {(x, y; x 2 +y 2 } x 2 +y 2 +z 2 = z 5.2. (x, y R 2 z = x 2 y + 3 (2,,, (, 3,, 3 (,, 5.3 (. (3 ( (a, b, c A : (x, y, z P : (x, y, x
No2 4 y =sinx (5) y = p sin(2x +3) (6) y = 1 tan(3x 2) (7) y =cos 2 (4x +5) (8) y = cos x 1+sinx 5 (1) y =sinx cos x 6 f(x) = sin(sin x) f 0 (π) (2) y
No1 1 (1) 2 f(x) =1+x + x 2 + + x n, g(x) = 1 (n +1)xn + nx n+1 (1 x) 2 x 6= 1 f 0 (x) =g(x) y = f(x)g(x) y 0 = f 0 (x)g(x)+f(x)g 0 (x) 3 (1) y = x2 x +1 x (2) y = 1 g(x) y0 = g0 (x) {g(x)} 2 (2) y = µ
di-problem.dvi
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() 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)
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5.. z = f(x, y) y y = b f x x g(x) f(x, b) g x ( ) A = lim h 0 g(a + h) g(a) h g(x) a A = g (a) = f x (a, b)
5 partial differentiation (total) differentiation 5. z = f(x, y) (a, b) A = lim h 0 f(a + h, b) f(a, b) h............................................................... ( ) f(x, y) (a, b) x A (a, b) x
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II Karel Švadlenka * [1] 1.1* 5 23 m d2 x dt 2 = cdx kx + mg dt. c, g, k, m 1.2* u = au + bv v = cu + dv v u a, b, c, d R
![II Karel Švadlenka * [1] 1.1* 5 23 m d2 x dt 2 = cdx kx + mg dt. c, g, k, m 1.2* u = au + bv v = cu + dv v u a, b, c, d R](/thumbs/95/125540821.jpg "II Karel Švadlenka * [1] 1.1* 5 23 m d2 x dt 2 = cdx kx + mg dt. c, g, k, m 1.2* u = au + bv v = cu + dv v u a, b, c, d R")
II Karel Švadlenka 2018 5 26 * [1] 1.1* 5 23 m d2 x dt 2 = cdx kx + mg dt. c, g, k, m 1.2* 5 23 1 u = au + bv v = cu + dv v u a, b, c, d R 1.3 14 14 60% 1.4 5 23 a, b R a 2 4b < 0 λ 2 + aλ + b = 0 λ =
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18 ( ) I II III A B C(100 ) 1, 2, 3, 5 I II A B (100 ) 1, 2, 3 I II A B (80 ) 6 8 I II III A B C(80 ) 1 n (1 + x) n (1) n C 1 + n C
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Gmech08.dvi
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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CALCULUS II (Hiroshi SUZUKI ) f(x, y) A(a, b) 1. P (x, y) A(a, b) A(a, b) f(x, y) c f(x, y) A(a, b) c f(x, y) c f(x, y) c (x a, y b)
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Excel ではじめる数値解析 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/009631 このサンプルページの内容は, 初版 1 刷発行時のものです. Excel URL http://www.morikita.co.jp/books/mid/009631 i Microsoft Windows
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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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24.15章.微分方程式
m d y dt = F m d y = mg dt V y = dy dt d y dt = d dy dt dt = dv y dt dv y dt = g dv y dt = g dt dt dv y = g dt V y ( t) = gt + C V y ( ) = V y ( ) = C = V y t ( ) = gt V y ( t) = dy dt = gt dy = g t dt
. sinh x sinh x) = e x e x = ex e x = sinh x 3) y = cosh x, y = sinh x y = e x, y = e x 6 sinhx) coshx) 4 y-axis x-axis : y = cosh x, y = s
. 00 3 9 [] sinh x = ex e x, cosh x = ex + e x ) sinh cosh 4 hyperbolic) hyperbola) = 3 cosh x cosh x) = e x + e x = cosh x ) . sinh x sinh x) = e x e x = ex e x = sinh x 3) y = cosh x, y = sinh x y =
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