Page:EB1911 - Volume 08.djvu/244

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DIFFERENTIAL EQUATION

227

particular solution whatever; but if there be one root θ₁ repeated r times, the terms A₁ e^{θ₁ x} + ... + A_r e^{θ_r x} must be replaced by (A₁ + A₂x + ... + A_rx^r−1)e^{θ₁ x} where A₁, ... A_n are arbitrary constants; the remaining terms in the complementary function will similarly need alteration of form if there be other repeated roots.

To complete the solution of the differential equation we need some method of determining a particular integral u; we explain a procedure which is effective for this purpose in the cases in which R is a sum of terms of the form e^axφ(x), where φ(x) is an integral polynomial in x; this includes cases in which R contains terms of the form cos bx·φ(x) or sin bx·φ(x). Denote d/dx by D; it is clear that if u be any function of x, D(e^axu) = e^axDu + ae^axu, or say, D(e^axu) = e^ax(D + a)u; hence D²(e^axu), i.e. d ²/dx² (e^axu), being equal to D(e^axv), where v = (D + a)u, is equal to e^ax(D + a)v, that is to e^ax(D + a)²u. In this way we find Dⁿ(e^axu) = e^ax(D + a)ⁿu, where n is any positive integer. Hence if ψ(D) be any polynomial in D with constant coefficients, ψ(D) (e^axu) = e^axψ(D + a)u. Next, denoting ∫ udx by D⁻¹u, and any solution of the differential equation dz/dx + az = u by z = (d + a)⁻¹u, we have D[e^ax(D + a)⁻¹u] = D(e^axz) = e^ax(D + a)z = e^axu, so that we may write D⁻¹(e^axu) = e^ax(D + a)⁻¹u, where the meaning is that one value of the left side is equal to one value of the right side; from this, the expression D^-2(e^axu), which means D⁻¹[D⁻¹(e^axu)], is equal to D⁻¹(e^axz) and hence to e^ax(D + a)⁻¹z, which we write e^ax(D + a)^-2u; proceeding thus we obtain

D^-n(e^axu)＝e^ax(D + a)^-nu,

where n is any positive integer, and the meaning, as before, is that one value of the first expression is equal to one value of the second. More generally, if ψ(D) be any polynomial in D with constant coefficients, and we agree to denote by [1/ψ(D)]u any solution z of the differential equation ψ(D)z = u, we have, if v = [1/ψ(D + a)]u, the identity ψ(D)(e^axv) = e^axψ(D + a)v = e^axu, which we write in the form

${\frac {1}{\psi (\mathrm {D} )}}(e^{ax}u)=e^{ax}{\frac {1}{\psi (\mathrm {D} +a)}}u.$

This gives us the first step in the method we are explaining, namely that a solution of the differential equation ψ(D)y = e^axu + e^bxv + ... where u, v, ... are any functions of x, is any function denoted by the expression

$e^{ax}{\frac {1}{\psi (\mathrm {D} +a)}}u+e^{bx}{\frac {1}{\psi (\mathrm {D} +b)}}v+\ldots .$

It is now to be shown how to obtain one value of ${\frac {1}{\psi (\mathrm {D} +a)}}u$ , when u is a polynomial in x, namely one solution of the differential equation ψ(D + a)z = u. Let the highest power of x entering in u be x^m; if t were a variable quantity, the rational fraction in t, ${\frac {1}{\psi (t+a)}}u$ by first writing it as a sum of partial fractions, or otherwise, could be identically written in the form

K_rt^-r + K_r−1t^-r+1 + ... + K₁t⁻¹ + H + H₁t + ... + H_mt^m + t^m+1φ(t)/ψ(t + a),

where φ(t) is a polynomial in t; this shows that there exists an identity of the form

1＝ψ(t + a)(K_rt^−r + ... + K₁t⁻¹ + H + H₁t + ... + H_mt^m) + φ(t)t^m+1,

and hence an identity

u＝ψ(D + a) [K_rD^−r + ... + K₁D⁻¹ + H + H₁D + ... + H_mD^m] u + φ(D) D^m+1u;

in this, since u contains no power of x higher than x^m, the second term on the right may be omitted. We thus reach the conclusion that a solution of the differential equation ψ(D + a)z = u is given by

z＝(K_rD^−r + ... + K₁D⁻¹ + H + H₁D + ... + H_mD^m)u,

of which the operator on the right is obtained simply by expanding 1/ψ(D + a) in ascending powers of D, as if D were a numerical quantity, the expansion being carried as far as the highest power of D which, operating upon u, does not give zero. In this form every term in z is capable of immediate calculation.

Example.—For the equation

${\frac {d^{4}v}{dx^{4}}}+2{\frac {d^{2}y}{dx^{3}}}+y=x^{3}\cos x$ or $\displaystyle (\mathrm {D} ^{2}+1)^{2}=x^{3}\cos x,$

the roots of the associated algebraic equation (θ² + 1)² = 0 are θ = ±i, each repeated; the complementary function is thus

(A + Bx)e^ix + (C + Dx)e^−ix,

where A, B, C, D are arbitrary constants; this is the same as

(H + Kx) cos x + (M + Nx) sin x,

where H, K, M, N are arbitrary constants. To obtain a particular integral we must find a value of (1 + D²)−²x³ cos x; this is the real part of (1 + D²)−² e^ixx³ and hence of e^ix [1 + (D + i)²]−² x³ or

e^ix [2iD(1 + 1/2iD)]−² x³,

or

−1/4e^ix D−² (1 + iD − 3/4D² − 1/2iD³ + 5/16D⁴ + 3/16iD⁵ ...)x³,

or

−1/4e^ix (1/20x⁵ + 1/4ix⁴ − 3/4x³ − 3/2 ix² + 15/8 x + 9/8 i);

the real part of this is

−1/4 (1/20 x⁵ − 3/4x² + 15/8x) cos x + 1/4 (1/4x⁴ − 3/2x² + 9/8) sin x.

This expression added to the complementary function found above gives the complete integral; and no generality is lost by omitting from the particular integral the terms −15/32x cos x + 9/32 sin x, which are of the types of terms already occurring in the complementary function.

The symbolical method which has been explained has wider applications than that to which we have, for simplicity of explanation, restricted it. For example, if ψ(x) be any function of x, and a₁, a₂, ... a_n be different constants, and [(t + a₁) (t + a₂) ... (t + a_n)]⁻¹ when expressed in partial fractions be written Σc_m(t + a_m)⁻¹, a particular integral of the differential equation (D + a₁)(D + a₂) ... (D + a_n)y = ψ(x) is given by

y＝Σc_m(D + a_m)⁻¹ ψ(x)＝Σc_m (D + a_m)⁻¹ e^−am^xe^am^x ψ(x)＝Σc_me^−am^xD⁻¹ (e^am^xψ(x) )＝Σc_me^−am^x ∫ e^am^xψ(x)dx.

The particular integral is thus expressed as a sum of n integrals. A linear differential equation of which the left side has the form

$x^{n}{\frac {d^{n}y}{dx^{n}}}+\mathrm {P} _{1}x^{n-1}{\frac {d^{n-1}y}{dx^{n-1}}}+\ldots +\mathrm {P} _{n-1}x{\frac {dy}{dx}}+\mathrm {P} _{n}y,$

where P₁, ... P_n are constants, can be reduced to the case considered above. Writing x = e^t we have the identity

$x^{m}{\frac {d^{m}u}{dx^{m}}}=\theta (\theta -1)(\theta -2)\ldots (\theta -m+1)u,$ where θ＝d/dt

When the linear differential equation, which we take to be of the second order, has variable coefficients, though there is no general rule for obtaining a solution in finite terms, there are some results which it is of advantage to have in mind. We have seen that if one solution of the equation obtained by putting the right side zero, say y₁, be known, the equation can be solved. If y₂ be another solution of

${\frac {d^{2}y}{dx^{2}}}+\mathrm {P} {\frac {dy}{dx}}+\mathrm {Q} =0,$

there being no relation of the form my₁ + ny₂ = k, where m, n, k are constants, it is easy to see that

${\frac {d}{dx}}(y_{1}'y_{2}-y_{1}y_{2}')=\mathrm {P} (y_{1}'y_{2}-y_{1}y_{2}'),$

so that we have

y₁′y₂ − y₁y₂′＝A exp. (∫ Pdx),

where A is a suitably chosen constant, and exp. z denotes e^z. In terms of the two solutions y₁, y₂ of the differential equation having zero on the right side, the general solution of the equation with R = φ(x) on the right side can at once be verified to be Ay₁ + By₂ + y₁u − y₂v, where u, v respectively denote the integrals

u＝∫ y₂φ(x) (y₁′y₂ − y₂′y₁)⁻¹dx, v＝∫ y₁φ(x) (y₁′y₂ − y₂′y₁)⁻¹dx.

The equation

${\frac {d^{2}y}{dx^{2}}}+\mathrm {P} {\frac {dy}{dx}}+\mathrm {Q} =0,$

by writing y = v exp. (−1/2 ∫ Pdx), is at once seen to be reduced to d ²v/dx² + Iv = 0, where I = Q − 1/2dP/dx − 1/4P². If η = − 1/v dv/dx, the equation d ²v/dx² + Iv = 0 becomes dη/dx = I + η², a non-linear equation of the first order.

More generally the equation

${\frac {d\eta }{dx}}=\mathrm {A} +\mathrm {B} \eta +\mathrm {C} \eta ^{2}$

where A, B, C are functions of x, is, by the substitution

$\eta =-{\frac {1}{\mathrm {C} y}}{\frac {dy}{dx}}$

reduced to the linear equation

${\frac {d^{2}y}{dx^{2}}}-\left(\mathrm {B} +{\frac {1}{\mathrm {C} }}{\frac {d\mathrm {C} }{dx}}\right){\frac {dy}{dx}}+\mathrm {AC} =0.$

The equation

${\frac {d\eta }{dx}}=\mathrm {A} +\mathrm {B} \eta +\mathrm {C} \eta ^{2}$

known as Riccati’s equation, is transformed into an equation of the same form by a substitution of the form η = (aY + b)/(cY + d), where a, b, c, d are any functions of x, and this fact may be utilized to obtain a solution when A, B, C have special forms; in particular if any particular solution of the equation be known, say η₀, the

Page:EB1911 - Volume 08.djvu/244

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