FOR DIFFERENTIAL EQUATIONS OF FRACTIONAL ORDER
FOR DIFFERENTIAL EQUATIONS OF FRACTIONAL ORDER
FOR DIFFERENTIAL EQUATIONS OF FRACTIONAL ORDER
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76 T. S. Aleroev, H. T. Aleroeva, Ning-Ming Nie, and Yi-Fa TangAccording to the above lemma, we get the error estimate∣∣y(t; ξ ∗ ) − y(t; ˜ξ) ∣ ∣ ≤≤ |ξ ∗ − ˜ξ|(t − a)E α (K f (t − a) α ) ≤ C 1 |ξ ∗ − ˜ξ|, t ∈ [a, b], (3.61)where C 1 := max (t − a)E α(K f (t − a) α ).t∈[a,b]Another part of the error is from numerical solving procedure of FIVP(3.50) by scheme (3.33), (3.35). Suppose that the scheme of FIVP convergeswith order r, and denote the approximate solution of y(t n ; ˜ξ) as y n (˜ξ). Weget ∃ C 2 > 0, s.t.∣max ∣y(t n ; ˜ξ) − y n (˜ξ) ∣ ≤ C 2 h r . (3.62)0≤n≤NTo sum up, we have∣∣y(t n ; ξ ∗ ) − y n (˜ξ) ∣ ∣ = ∣ ∣y(t n ; ξ ∗ ) − y(t n ; ˜ξ) + y(t n ; ˜ξ) − y n (˜ξ) ∣ ∣ ≤that is,≤ ∣ ∣y(t n ; ξ ∗ ) − y(t n ; ˜ξ) ∣ ∣ + ∣ ∣y(t n ; ˜ξ) − y n (˜ξ) ∣ ∣max0≤n≤N∣∣y(t n ; ξ ∗ ) − y n (˜ξ) ∣ ≤ C 1 |ξ ∗ − ˜ξ| + C 2 h r . (3.63)As to (3.7), (3.41), we turn it into its corresponding FIVPRLa D γ t y(t) + f (t, y(t)) = 0, a ≤ t ≤ b, 1 < γ ≤ 2, (3.64)RLa D γ−1t y(t) ∣ = ξ, lim J 2−γt=a t→a + a y(t) = 0. (3.65)The numerical procedure of simulating (3.7), (3.41) is completely similar tothat of (3.1), (3.41).Again, the procedures of shooting method for (3.2) and (3.8) with homogenousboundary conditions (3.41) are similar to the case of (3.1), (3.41)and (3.7), (3.41), respectively.4. Numerical Experiments for Solving FBVPsIn this section, two numerical examples are given to show the feasibilityand validity of single shooting methods for the FBVPs.First, let us introduce the parameters. a = 0 = t 0 < t 1 < · · · < t n = bis a given equispaced mesh with stepsize h = (b − a)/n, n = 100, γ = 1.5,θ = 0.5. For the linear cases in Examples 1, the two “initial speeds” ξ 1 = 0.5,ξ 2 = 1.5. For the nonlinear cases in Examples 2, ɛ = 10 −12 , ξ (0) = 0,△ξ (k) ≡ 10 −8 .Example 3.1. Consider the following linear FBVPC0 D 1.5C0 D 0.5t y(t) + 1 3 y(t) + 1 4t y(t) = r(t), 0 < t < 1,y(0) = 0, y(1) = 0,