平成13年度

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あいねしまむね
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4 ) ) Lagrange 3) ) 4) 5)

5 3 r r A B C θ ( α ) r r 3

6 4 Lagrange B C x = r cosθ () y = r sinθ () x = r cosθ + r cos( θ + θ ) (3) y = r sinθ + r sin( θ + θ ) (4) x = rθ sinθ (5) y = rθ cosθ (6) (7) (8) B C m m T a T b Ta = m( x + y ) = mrθ (9) Tb = m( x + y ) (0) U U a b U = mr sinθ gcosφ () a U = m { r sinθ + r sin( θ + θ )} gcosφ () b Lagrange L( = T + T U U ) a b a b 4

7 (3) (4) (5) θ (6) θ (7) (8) (9) θ (0) 5

8 5 r r θ θ θ θ α 0 θ = α () θ = 0 () θ (3) (4) 6

9 (5) (6) θ (6) θ θ (6) C r r B r A r r, r r, r r = r sinα r = r + r cosα (6) θ 0 (7) A J 7

10 J = m {( r + r cos α) + ( r sin α) } + mr (8) (9) (7) (9) θ = {( T J) ( r + r cosα r sin α )} = ( Tr Jr ) (30) / / 0 (3) µ ( = m m) γ ( = r r) (3) 3 γ =..4 α π 6 3π 4 δ 4 θ 0 5 α = π π γ.0.5 δ 4 θ 0 r r α α r r 8

11 γ α 3 γ α δ α 4 γ α θ 0 γ r 5 α γ δ r 6 α γ 0 θ 9

12 6 Mathematica η α µ γ (30) (3) η θ η = π 3 α = π µ = 0.3 γ = θ 3π 0 θ θ 0 7 θ θ 8 θ 7 ( η = π 3, α = π, µ = 0.3, γ =.4 ) 8 ( η = π 3, α = π, µ = 0.3, γ =.4 ) 0

13 8 γ = θ θ 0 9 ( η = π 3, α = π, µ = 0.3, γ =.) 0 ( η = π 3, α = π, µ = 0.3, γ =.)

14 η η = π α = π µ = 0. γ =.4 η ( η π =, α = π, µ = 0., γ =.4 ) ( η π =, α = π, µ = 0., γ =.4 )

15 7 Lagrange 3

16 (000) 4

17 m =.0 m = 0.3 r =.0 r =. gdt = 0 q= 3.459ê80 s0 = 0 q alp = 90 q s0 = 360 q alp g= 9.8 fai = 30 q gcf = gcos@faid gdt tr0 = tr@td = tr0 rr = Hr+ r Cos@alpDL + Hr Sin@alpDL jj = m rr+ m r a = tr0êjj v = Sqrt@Ha Hr+ r Cos@alpDL + gcf Cos@s0 alpdl ê Hr Sin@alpDLD unc = v êaê uncêq ank = s0+ unc ankêq NDSolveA9gcf HHm+ ml r Cos@s3@tDD + m r Cos@s3@tD +s@tddl mrrsin@s@tdd s3@td s@td m r r Sin@s@tDD s@td + m r s3'@td + m r s3'@td + m r s3'@td + mrrcos@s@tdd s3'@td + m r s'@td + m r r Cos@s@tDD s'@td tr@td,s3@td == s3'@td, m r Igcf Cos@s3@tD + s@tdd + r Sin@s@tDD s3@td +Hr + r Cos@s@tDDL s3'@td + r s'@tdm 0, s@td == s'@td,s3@0d == v, s3@0d == ank, s@0d == 0, s@0d == alp=, 8s@tD, s@td, s3@td, s3@td<, 8t, 0, 3<E gy3= Plot@Evaluate@s3@tD s0 ê.out@d@@ddd, 8t, 0, 3<, Frame > TrueD gz3= Plot@Evaluate@s3@tD ê. Out@ D@@DDD, 8t, 0, 3<, Frame > TrueD gy= Plot@Evaluate@s@tDê.Out@ 3D@@DDD, 8t, 0, 3<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D gz= Plot@Evaluate@s@tD ê. Out@ 4D@@DDD, 8t, 0, 3<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D gzz= Show@gz, gz3, PlotRange > 80, <, FrameLabel > 8" t "," H θ ê tl,h θ ê tl "<D gyy= Show@gy, gy3, PlotRange > 8, 3<, FrameLabel > 8" t "," θ,θ "<D 5

18 s@tD InterpolatingFunction@880., 3.<<, <>D@tD, s@td InterpolatingFunction@880., 3.<<, <>D@tD, s3@td InterpolatingFunction@880., 3.<<, <>D@tD, s3@td InterpolatingFunction@880., 3.<<, <>D@tD<<

19 H θê tl,h θê tl t 7

20 3 θ,θ t 8

21 r =.0 r =. aln = 30 alx = 35 q= 3.459ê80 fad = 30 fai = fad q gdt = 0 gcf = gdt 9.8 Cos@faiD as = xn = aln q xx = alx q f@x_d = Hr+ r Cos@xD + gcfê aslêhr Sin@xDL gx= Plot@f@xDê, 8x, xn, xx<, Frame > TrueD fv@x_d = Sqrt@f@xDD gv= Plot@fv@xD, 8x, xn, xx<, Frame > TrueD r =.4 f@x_d = Hr+ r Cos@xD + gcfê aslêhr Sin@xDL gx= Plot@f@xDê, 8x, xn, xx<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D fv@x_d = Sqrt@f@xDD gv= Plot@fv@xD, 8x, xn, xx<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D grr= Show@gx, gx, PlotRange > 80, 3.<, FrameLabel > 8" α ", " γ "<D grr= Show@gv, gv, PlotRange > 80, 3.<, FrameLabel > 8" α ", " "<D

22 H è H.+. Cos@xDL Csc@xD H.4+. Cos@xDL Csc@xD è H.4+. Cos@xDL Csc@xD 0

23 γ α α

24 r =.0 q= 3.459ê80 ald = 90 alp = ald q fad = 30 fai = fad q gdt = 0 gcf = gdt 9.8 Cos@faiD as = xn =.0 xx =.5 f@x_d = Hx+ r Cos@alpD + gcfê aslêhr Sin@alpDL gx= Plot@f@xDê, 8x, xn, xx<, Frame > TrueD fv@x_d = Sqrt@f@xD asd gv= Plot@fv@xD, 8x, xn, xx<, Frame > TrueD ald = 0 alp = ald q f@x_d = Hx+ r Cos@alpD + gcfê aslêhr Sin@alpDL gx= Plot@f@xDê, 8x, xn, xx<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D fv@x_d = Sqrt@f@xD asd gv= Plot@fv@xD, 8x, xn, xx<, Frame > True, PlotStyle > 8Dashing@80.0, 0.0<D<D grr= Show@gx, gx, PlotRange > 80, 0.8<, FrameLabel > 8" r "," γ "<D grr= Show@gv, gv, PlotRange > 80, 5<, FrameLabel > 8" r "," "<D

25 ..5. H xl " x H xl è x 3

26 γ r r 4

φ s i = m j=1 f x j ξ j s i (1)? φ i = φ s i f j = f x j x ji = ξ j s i (1) φ 1 φ 2. φ n = m j=1 f jx j1 m j=1 f jx j2. m

φ s i = m j=1 f x j ξ j s i (1)? φ i = φ s i f j = f x j x ji = ξ j s i (1) φ 1 φ 2. φ n = m j=1 f jx j1 m j=1 f jx j2. m 2009 10 6 23 7.5 7.5.1 7.2.5 φ s i m j1 x j ξ j s i (1)? φ i φ s i f j x j x ji ξ j s i (1) φ 1 φ 2. φ n m j1 f jx j1 m j1 f jx j2. m j1 f jx jn x 11 x 21 x m1 x 12 x 22 x m2...... m j1 x j1f j m j1 x