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- Tue Feb 10 12:26:51 2004 run on Linux
- % Tests and demonstrations for the ODESolve 1+ package --
- % an updated version of the original odesolve test file.
- % Original Author: M. A. H. MacCallum
- % Maintainer: F.J.Wright@Maths.QMW.ac.uk
- ODESolve_version;
- ODESolve 1.065
- on trode, combinelogs;
- %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
- % First-order differential equations
- % (using automatic variable and dependence declaration).
- % First-order quadrature case:
- odesolve(df(y,x) - x^2 - e^x);
- *** Dependent var(s) assumed to be y
- *** Independent var assumed to be x
- *** depend y , x
- This is a linear ODE of order 1.
- It is solved by quadrature.
- x 3
- 3*arbconst(1) + 3*e + x
- {y=---------------------------}
- 3
- % First-order linear equation, with initial condition y = 1 at x = 0:
- odesolve(df(y,x) + y * tan x - sec x, y, x, {x=0, y=1});
- This is a linear ODE of order 1.
- It is solved by the integrating factor method.
- General solution is {y=arbconst(2)*cos(x) + sin(x)}
- Applying conditions {{x=0,y=1}}
- {y=cos(x) + sin(x)}
- odesolve(cos x * df(y,x) + y * sin x - 1, y, x, {x=0, y=1});
- This is a linear ODE of order 1.
- It is solved by the integrating factor method.
- General solution is {y=arbconst(3)*cos(x) + sin(x)}
- Applying conditions {{x=0,y=1}}
- {y=cos(x) + sin(x)}
- % A simple separable case:
- odesolve(df(y,x) - y^2, y, x, explicit);
- This is a nonlinear ODE of order 1.
- It is separable.
- Solution before trying to solve for dependent variable is
- arbconst(4)*y - x*y - 1=0
- 1
- {y=-----------------}
- arbconst(4) - x
- % A separable case, in different variables, with the initial condition
- % z = 2 at w = 1/2:
- odesolve((1-z^2)*w*df(z,w)+(1+w^2)*z, z, w, {w=1/2, z=2});
- *** depend z , w
- This is a nonlinear ODE of order 1.
- It is separable.
- 2 2
- General solution is {4*arbconst(5) - 2*log(w*z) - w + z =0}
- 1
- Applying conditions {{w=---,z=2}}
- 2
- 2 2
- { - 8*log(w*z) - 4*w + 4*z - 15=0}
- % Now a homogeneous one:
- odesolve(df(y,x) - (x-y)/(x+y), y, x);
- This is a nonlinear ODE of order 1.
- It is of algebraically homogeneous type
- solved by a change of variables of the form `y = vx'.
- 2 2
- {arbconst(6) + sqrt( - x + 2*x*y + y )=0}
- % Reducible to homogeneous:
- % (Note this is the previous example with origin shifted.)
- odesolve(df(y,x) - (x-y-3)/(x+y-1), y, x);
- This is a nonlinear ODE of order 1.
- It is quasi-homogeneous if the result of shifting the origin is homogeneous ...
- It is of algebraically homogeneous type
- solved by a change of variables of the form `y = vx'.
- 2 2
- {arbconst(7) + sqrt( - x + 2*x*y + 6*x + y - 2*y - 7)=0}
- % and the special case of reducible to homogeneous:
- odesolve(df(y,x) - (2x+3y+1)/(4x+6y+1), y, x);
- This is a nonlinear ODE of order 1.
- 2
- It is separable after letting y + ---*x => y
- 3
- {49*arbconst(8) - 3*log(14*x + 21*y + 5) - 21*x + 42*y=0}
- % A Bernoulli equation:
- odesolve(x*(1-x^2)*df(y,x) + (2x^2 -1)*y - x^3*y^3, y, x);
- This is a nonlinear ODE of order 1.
- It is of Bernoulli type.
- 5
- 1 5*arbconst(9) + 2*x
- {----=----------------------}
- 2 4 2
- y 5*x - 5*x
- % and finally, in this set, an exact case:
- odesolve((2x^3 - 6x*y + 6x*y^2) + (-3x^2 + 6x^2*y - y^3)*df(y,x), y, x);
- This is a nonlinear ODE of order 1.
- It is exact and is solved by quadrature.
- 4 2 2 2 4
- {4*arbconst(10) + 2*x + 12*x *y - 12*x *y - y =0}
- %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
- % Now for higher-order linear equations with constant coefficients
- % First, examples without driving terms
- % A simple one to start:
- odesolve(6df(y,x,2) + df(y,x) - 2y, y, x);
- This is a linear ODE of order 2.
- It has constant coefficients.
- (7*x)/6
- e *arbconst(12) + arbconst(11)
- {y=--------------------------------------}
- (2*x)/3
- e
- % An example with repeated and complex roots:
- odesolve(ode := df(y,x,4) + 2df(y,x,2) + y, y, x);
- This is a linear ODE of order 4.
- It has constant coefficients.
- {y=arbconst(16)*sin(x) + arbconst(15)*cos(x) + arbconst(14)*sin(x)*x
- + arbconst(13)*cos(x)*x}
- % A simple right-hand-side using the above example:
- odesolve(ode = exp(x), y, x);
- This is a linear ODE of order 4.
- It has constant coefficients.
- Constructing particular integral using `D-operator method'.
- {y=(4*arbconst(20)*sin(x) + 4*arbconst(19)*cos(x) + 4*arbconst(18)*sin(x)*x
- x
- + 4*arbconst(17)*cos(x)*x + e )/4}
- ode := df(y,x,2) + 4df(y,x) + 4y - x*exp(x);
- x
- ode := df(y,x,2) + 4*df(y,x) - e *x + 4*y
- % At x=1 let y=0 and df(y,x)=1:
- odesolve(ode, y, x, {x=1, y=0, df(y,x)=1});
- This is a linear ODE of order 2.
- It has constant coefficients.
- Constructing particular integral using `D-operator method'.
- 3*x 3*x
- 27*arbconst(22) + 27*arbconst(21)*x + 3*e *x - 2*e
- General solution is {y=---------------------------------------------------------
- 2*x
- 27*e
- }
- Applying conditions {{x=1,y=0,df(y,x)=1}}
- 3*x 3*x 3 3 2 2
- 3*e *x - 2*e - 6*e *x + 5*e + 27*e *x - 27*e
- {y=-----------------------------------------------------}
- 2*x
- 27*e
- % For simultaneous equations you can use the machine, e.g. as follows:
- depend z,x;
- ode1 := df(y,x,2) + 5y - 4z + 36cos(7x);
- ode1 := 36*cos(7*x) + df(y,x,2) + 5*y - 4*z
- ode2 := y + df(z,x,2) - 99cos(7x);
- ode2 := - 99*cos(7*x) + df(z,x,2) + y
- ode := df(ode1,x,2) + 4ode2;
- ode := - 2160*cos(7*x) + df(y,x,4) + 5*df(y,x,2) + 4*y
- y := rhs first odesolve(ode, y, x);
- This is a linear ODE of order 4.
- It has constant coefficients.
- Constructing particular integral using `D-operator method'.
- y := arbconst(26)*sin(x) + arbconst(25)*cos(x) + arbconst(24)*sin(2*x)
- + arbconst(23)*cos(2*x) + cos(7*x)
- z := rhs first solve(ode1,z);
- z := (4*arbconst(26)*sin(x) + 4*arbconst(25)*cos(x) + arbconst(24)*sin(2*x)
- + arbconst(23)*cos(2*x) - 8*cos(7*x))/4
- clear ode1, ode2, ode, y, z;
- nodepend z,x;
- % A "homogeneous" n-th order (Euler) equation:
- odesolve(x*df(y,x,2) + df(y, x) + y/x + (log x)^3, y, x);
- This is a linear ODE of order 2.
- It has non-constant coefficients.
- It is of the homogeneous (Euler) type and is reducible to a simpler ODE ...
- It has constant coefficients.
- Constructing particular integral using `D-operator method'.
- 3
- {y=(2*arbconst(28)*sin(log(x)) + 2*arbconst(27)*cos(log(x)) - log(x) *x
- 2
- + 3*log(x) *x - 3*log(x)*x)/2}
- % The solution here remains symbolic (because neither REDUCE nor Maple
- % can evaluate the resulting integral):
- odesolve(6df(y,x,2) + df(y,x) - 2y + tan x, y, x);
- This is a linear ODE of order 2.
- It has constant coefficients.
- Constructing particular integral using `D-operator method'.
- But cannot evaluate the integrals, so ...
- Constructing particular integral using `variation of parameters'.
- 7
- The Wronskian is --------
- x/6
- 6*e
- (7*x)/6 (7*x)/6 sin(x)
- {y=(7*e *arbconst(30) + 7*arbconst(29) - e *int(-------------,x)
- x/2
- e *cos(x)
- (2*x)/3
- e *sin(x) (2*x)/3
- + int(-----------------,x))/(7*e )}
- cos(x)
- end;
- Time for test: 510 ms, plus GC time: 40 ms
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