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- % Title: Examples of Laplace Transforms.
- % Author: L. Kazasov.
- % Date: 24 October 1988.
- order p;
- % Elementary functions with argument k*x, where x is object var.
- laplace(1,x,p);
- laplace(c,x,p);
- laplace(sin(k*x),x,p); laplace(sin(x/a),x,p);
- laplace(sin(17*x),x,p);
- laplace(sinh x,x,p);
- laplace(cosh(k*x),x,p);
- laplace(x,x,p); laplace(x**3,x,p);
- off mcd; laplace(e**(c*x) + a**x, x, s);
- laplace(e**x - e**(a*x) + x**2, x, p);
- laplace(one(k*t) + sin(a*t) - cos(b*t) - e**t, t, p);
- laplace(sqrt(x),x,p); laplace(x**(1/2),x,p); on mcd;
- laplace(x**(-1/2),x,p); laplace(x**(5/2),x,p);
- laplace(-1/4*x**2*c*sqrt(x), x, p);
- % Elementary functions with argument k*x - tau,
- % where k>0, tau>=0, x is object var.
- laplace(cos(x-a),x,p);
- laplace(one(k*x-tau),x,p);
- laplace(sinh(k*x-tau),x,p); laplace(sinh(k*x),x,p);
- laplace((a*x-b)**c,x,p);
- % But ...
- off mcd; laplace((a*x-b)**2,x,p); on mcd;
- laplace(sin(2*x-3),x,p);
- on lmon; laplace(sin(2*x-3),x,p); off lmon;
- off mcd; laplace(cosh(t-a) - sin(3*t-5), t, p); on mcd;
- % More complicated examples - multiplication of functions.
- % We use here on lmon - a new switch that forces all
- % trigonometrical functions which depend on object var
- % to be represented as exponents.
- laplace(x*e**(a*x)*cos(k*x), x, p);
- laplace(x**(1/2)*e**(a*x), x, p);
- laplace(-1/4*e**(a*x)*(x-k)**(-1/2), x, p);
- laplace(x**(5/2)*e**(a*x), x, p);
- laplace((a*x-b)**c*e**(k*x)*const/2, x, p);
- off mcd; laplace(x*e**(a*x)*sin(7*x)/c*3, x, p); on mcd;
- laplace(x*e**(a*x)*sin(k*x-tau), x, p);
- % The next is unknown if lmon is off.
- laplace(sin(k*x)*cosh(k*x), x, p);
- laplace(x**(1/2)*sin(k*x), x, p);
- on lmon; % But now is OK.
- laplace(x**(1/2)*sin(a*x)*cos(a*b), x, p);
- laplace(sin(x)*cosh(x), x, p);
- laplace(sin(k*x)*cosh(k*x), x, p);
- % Off exp leads to very messy output in this case.
- % off exp; laplace(sin(k*x-t)*cosh(k*x-t), x, p); on exp;
- laplace(sin(k*x-t)*cosh(k*x-t), x, p);
- laplace(cos(x)**2,x,p);laplace(c*cos(k*x)**2,x,p);
- laplace(c*cos(2/3*x)**2, x, p);
- laplace(5*sinh(x)*e**(a*x)*x**3, x, p);
- off exp; laplace(sin(2*x-3)*cosh(7*x-5), x, p); on exp;
- laplace(sin(a*x-b)*cosh(c*x-d), x, p);
- % To solve this problem we must tell the program which one-function
- % is rightmost shifted. However, in REDUCE 3.4, this rule is still
- % not sufficient.
- for all x let one(x-b/a)*one(x-d/c) = one(x-b/a);
- laplace(sin(a*x-b)*cosh(c*x-d), x, p);
- for all x clear one(x-b/a)*one(x-d/c) ;
- off lmon;
- % Floating point arithmetic.
- % laplace(3.5/c*sin(2.3*x-4.11)*e**(1.5*x), x, p);
- on rounded;
- laplace(3.5/c*sin(2.3*x-4.11)*e**(1.5*x), x, p);
- laplace(x**2.156,x,p);
- laplace(x**(-0.5),x,p);
- off rounded; laplace(x**(-0.5),x,p); on rounded;
- laplace(x*e**(2.35*x)*cos(7.42*x), x, p);
- laplace(x*e**(2.35*x)*cos(7.42*x-74.2), x, p);
- % Higher precision works, but uses more memory.
- % precision 20; laplace(x**2.156,x,p);
- % laplace(x*e**(2.35*x)*cos(7.42*x-74.2), x, p);
- off rounded;
- % Integral from 0 to x, where x is object var.
- % Syntax is intl(<expr>,<var>,0,<obj.var>).
- laplace(c1/c2*intl(2*y**2,y,0,x), x,p);
- off mcd; laplace(intl(e**(2*y)*y**2+sqrt(y),y,0,x),x,p); on mcd;
- laplace(-2/3*intl(1/2*y*e**(a*y)*sin(k*y),y,0,x), x, p);
- % Use of delta function and derivatives.
- laplace(-1/2*delta(x), x, p); laplace(delta(x-tau), x, p);
- laplace(c*cos(k*x)*delta(x),x,p);
- laplace(e**(a*x)*delta(x), x, p);
- laplace(c*x**2*delta(x), x, p);
- laplace(-1/4*x**2*delta(x-pi), x, p);
- laplace(cos(2*x-3)*delta(x-pi),x,p);
- laplace(e**(-b*x)*delta(x-tau), x, p);
- on lmon;
- laplace(cos(2*x)*delta(x),x,p);
- laplace(c*x**2*delta(x), x, p);
- laplace(c*x**2*delta(x-pi), x, p);
- laplace(cos(a*x-b)*delta(x-pi),x,p);
- laplace(e**(-b*x)*delta(x-tau), x, p);
- off lmon;
- laplace(2/3*df(delta x,x),x,p);
- off exp; laplace(e**(a*x)*df(delta x,x,5), x, p); on exp;
- laplace(df(delta(x-a),x), x, p);
- laplace(e**(k*x)*df(delta(x),x), x, p);
- laplace(e**(k*x)*c*df(delta(x-tau),x,2), x, p);
- on lmon;laplace(e**(k*x)*sin(a*x)*df(delta(x-t),x,2),x,p);off lmon;
- % But if tau is positive, Laplace transform is not defined.
- laplace(e**(a*x)*delta(x+tau), x, p);
- laplace(2*c*df(delta(x+tau),x), x, p);
- laplace(e**(k*x)*df(delta(x+tau),x,3), x, p);
- % Adding new let rules for Laplace operator. Note the syntax.
- for all x let laplace(log(x),x) = -log(gam*il!&)/il!&;
- laplace(-log(x)*a/4, x, p); laplace(-log(x),x,p);
- laplace(a*log(x)*e**(k*x), x, p);
- for all x clear laplace(log(x),x);
- operator f; for all x let
- laplace(df(f(x),x),x) = il!&*laplace(f(x),x) - sub(x=0,f(x));
- for all x,n such that numberp n and fixp n let
- laplace(df(f(x),x,n),x) = il!&**n*laplace(f(x),x) -
- for i:=n-1 step -1 until 0 sum
- sub(x=0, df(f(x),x,n-1-i)) * il!&**i ;
- for all x let laplace(f(x),x) = f(il!&);
- laplace(1/2*a*df(-2/3*f(x)*c,x), x,p);
- laplace(1/2*a*df(-2/3*f(x)*c,x,4), x,p);
- laplace(1/2*a*e**(k*x)*df(-2/3*f(x)*c,x,2), x,p);
- clear f;
- % Or if the boundary conditions are known and assume that
- % f(i,0)=sub(x=0,df(f(x),x,i)) the above may be overwritten as:
- operator f; for all x let
- laplace(df(f(x),x),x) = il!&*laplace(f(x),x) - f(0,0);
- for all x,n such that numberp n and fixp n let
- laplace(df(f(x),x,n),x) = il!&**n*laplace(f(x),x) -
- for i:=n-1 step -1 until 0 sum il!&**i * f(n-1-i,0);
- for all x let laplace(f(x),x) = f(il!&);
- let f(0,0)=0, f(1,0)=1, f(2,0)=2, f(3,0)=3;
- laplace(1/2*a*df(-2/3*f(x)*c,x), x,p);
- laplace(1/2*a*df(-2/3*f(x)*c,x,4), x,p);
- clear f(0,0), f(1,0), f(2,0), f(3,0); clear f;
- % Very complicated examples.
- on lmon;
- laplace(sin(a*x-b)**2, x, p);
- off mcd; laplace(x**3*(sin x)**4*e**(5*k*x)*c/2, x,p);
- a:=(sin x)**4*e**(5*k*x)*c/2; laplace(x**3*a,x,p); clear a; on mcd;
- % And so on, but is very time consuming.
- % laplace(e**(k*x)*x**2*sin(a*x-b)**2, x, p);
- % for all x let one(a*x-b)*one(c*x-d) = one(c*x-d);
- % laplace(x*e**(-2*x)*cos(a*x-b)*sinh(c*x-d), x, p);
- % for all x clear one(a*x-b)*one(c*x-d) ;
- % laplace(x*e**(c*x)*sin(k*x)**3*cosh(x)**2*cos(a*x), x, p);
- off lmon;
- % Error messages.
- laplace(sin(-x),x,p);
- on lmon; laplace(sin(-a*x), x, p); off lmon;
- laplace(e**(k*x**2), x, p);
- laplace(sin(-a*x+b)*cos(c*x+d), x, p);
- laplace(x**(-5/2),x,p);
- % With int arg, can't be shifted.
- laplace(intl(y*e**(a*y)*sin(k*y-tau),y,0,x), x, p);
- laplace(cosh(x**2), x, p);
- laplace(3*x/(x**2-5*x+6),x,p);
- laplace(1/sin(x),x,p); % But ...
- laplace(x/sin(-3*a**2),x,p);
- % Severe errors.
- % laplace(sin x,x,cos y);
- % laplace(sin x,x,y+1);
- % laplace(sin(x+1),x+1,p);
- Comment Examples of Inverse Laplace transformations;
- symbolic(ordl!* := nil); % To nullify previous order declarations.
- order t;
- % Elementary ratio of polynomials.
- invlap(1/p, p, t);
- invlap(1/p**3, p, t);
- invlap(1/(p-a), p, t); invlap(1/(2*p-a),p,t); invlap(1/(p/2-a),p,t);
- invlap(e**(-k*p)/(p-a), p, t); invlap(b**(-k*p)/(p-a), p, t);
- invlap(1/(p-a)**3, p, t);
- invlap(1/(c*p-a)**3, p, t); invlap(1/(p/c-a)**3, p, t);
- invlap((c*p-a)**(-1)/(c*p-a)**2, p, t);
- invlap(c/((p/c-a)**2*(p-a*c)), p, t);
- invlap(1/(p*(p-a)), p, t);
- invlap(c/((p-a)*(p-b)), p, t);
- invlap(p/((p-a)*(p-b)), p, t);
- off mcd; invlap((p+d)/(p*(p-a)), p, t);
- invlap((p+d)/((p-a)*(p-b)), p, t);
- invlap(1/(e**(k*p)*p*(p+1)), p, t); on mcd;
- off exp; invlap(c/(p*(p+a)**2), p, t); on exp;
- invlap(1, p, t); invlap(c1*p/c2, p, t);
- invlap(p/(p-a), p, t); invlap(c*p**2, p, t);
- invlap(p**2*e**(-a*p)*c, p, t);
- off mcd;invlap(e**(-a*p)*(1/p**2-p/(p-1))+c/p, p, t);on mcd;
- invlap(a*p**2-2*p+1, p, x);
- % P to non-integer power in denominator - i.e. gamma-function case.
- invlap(1/sqrt(p), p, t); invlap(1/sqrt(p-a), p, t);
- invlap(c/(p*sqrt(p)), p, t); invlap(c*sqrt(p)/p**2, p, t);
- invlap((p-a)**(-3/2), p, t);
- invlap(sqrt(p-a)*c/(p-a)**2, p, t);
- invlap(1/((p-a)*b*sqrt(p-a)), p, t);
- invlap((p/(c1-3)-a)**(-3/2), p, t);
- invlap(1/((p/(c1-3)-a)*b*sqrt(p/(c1-3)-a)), p, t);
- invlap((p*2-a)**(-3/2), p, t);
- invlap(sqrt(2*p-a)*c/(p*2-a)**2, p, t);
- invlap(c/p**(7/2), p, t); invlap(p**(-7/3), p, t);
- invlap(gamma(b)/p**b,p,t); invlap(c*gamma(b)*(p-a)**(-b),p,t);
- invlap(e**(-k*p)/sqrt(p-a), p, t);
- % Images that give elementary object functions.
- % Use of new switches lmon, lhyp.
- invlap(k/(p**2+k**2), p, t);
- % This is made more readable by :
- on ltrig; invlap(k/(p**2+k**2), p, t);
- invlap(p/(p**2+1), p, t);
- invlap((p**2-a**2)/(p**2+a**2)**2, p, t);
- invlap(p/(p**2+a**2)**2, p, t);
- invlap((p-a)/((p-a)**2+b**2), p, t); off ltrig;
- on lhyp; invlap(s/(s**2-k**2), s, t);
- invlap(e**(-tau/k*p)*p/(p**2-k**2), p, t); off lhyp;
- % But it is not always possible to convert expt. functions, e.g.:
- on lhyp; invlap(k/((p-a)**2-k**2), p, t); off lhyp;
- on ltrig; invlap(e**(-tau/k*p)*k/(p**2+k**2), p, t); off ltrig;
- % In such situations use the default switches:
- invlap(k/((p-a)**2-k**2), p, t); % i.e. e**(a*t)*cosh(k*t).
- invlap(e**(-tau/k*p)*k/(p**2+k**2), p, t); % i.e. sin(k*t-tau).
- % More complicated examples.
- off exp,mcd; invlap((p+d)/(p**2*(p-a)), p, t);
- invlap(e**(-tau/k*p)*c/(p*(p-a)**2), p, t);
- invlap(1/((p-a)*(p-b)*(p-c)), p, t);
- invlap((p**2+g*p+d)/(p*(p-a)**2), p, t); on exp,mcd;
- invlap(k*c**(-b*p)/((p-a)**2+k**2), p, t);
- on ltrig; invlap(c/(p**2*(p**2+a**2)), p, t);
- invlap(1/(p**2-p+1), p, t); invlap(1/(p**2-p+1)**2, p, t);
- invlap(2*a**2/(p*(p**2+4*a**2)), p, t);
- % This is (sin(a*t))**2 and you can get this by using the let rules :
- for all x let sin(2*x)=2*sin x*cos x, cos(2*x)=(cos x)**2-(sin x)**2,
- (cos x)**2 =1-(sin x)**2;
- invlap(2*a**2/(p*(p**2+4*a**2)), p, t);
- for all x clear sin(2*x),cos(2*x),cos(x)**2; off ltrig;
- on lhyp;invlap((p**2-2*a**2)/(p*(p**2-4*a**2)),p,t);
- off lhyp; % Analogously, the above is (cosh(a*t))**2.
- % Floating arithmetic.
- invlap(2.55/((0.5*p-2.0)*(p-3.3333)), p, t);
- on rounded;
- invlap(2.55/((0.5*p-2.0)*(p-3.3333)), p, t);
- invlap(1.5/sqrt(p-0.5), p, t);
- invlap(2.75*p**2-0.5*p+e**(-0.9*p)/p, p, t);
- invlap(1/(2.0*p-3.0)**3, p, t); invlap(1/(2.0*p-3.0)**(3/2), p, t);
- invlap(1/(p**2-5.0*p+6), p, t);
- off rounded;
- % Adding new let rules for the invlap operator. note the syntax:
- for all x let invlap(log(gam*x)/x,x) = -log(lp!&);
- invlap(-1/2*log(gam*p)/p, p, t);
- invlap(-e**(-a*p)*log(gam*p)/(c*p), p, t);
- for all x clear invlap(1/x*log(gam*x),x);
- % Very complicated examples and use of factorizer.
- off exp,mcd; invlap(c**(-k*p)*(p**2+g*p+d)/(p**2*(p-a)**3), p, t);
- on exp,mcd;
- invlap(1/(2*p**3-5*p**2+4*p-1), p, t);
- on ltrig,lhyp; invlap(1/(p**4-a**4), p, t);
- invlap(1/((b-3)*p**4-a**4*(2+b-5)), p, t); off ltrig,lhyp;
- % The next three examples are the same:
- invlap(c/(p**3/8-9*p**2/4+27/2*p-27)**2,p,t);invlap(c/(p/2-3)**6,p,t);
- off exp; a:=(p/2-3)**6; on exp; invlap(c/a, p, t); clear a;
- % The following two examples are the same :
- invlap(c/(p**4+2*p**2+1)**2, p, t); invlap(c/((p-i)**4*(p+i)**4),p,t);
- % The following three examples are the same :
- invlap(e**(-k*p)/(2*p-3)**6, p, t);
- invlap(e**(-k*p)/(4*p**2-12*p+9)**3, p, t);
- invlap(e**(-k*p)/(8*p**3-36*p**2+54*p-27)**2, p, t);
- % Error messages.
- invlap(e**(a*p)/p, p, t);
- invlap(c*p*sqrt(p), p, t);
- invlap(sin(p), p, t);
- invlap(1/(a*p**3+b*p**2+c*p+d),p,t);
- invlap(1/(p**2-p*sin(p)+a**2),p,t);
- on rounded; invlap(1/(p**3-1), p, t); off rounded;
- % Severe errors:
- %invlap(1/(p**2+1), p+1, sin(t) );
- %invlap(p/(p+1)**2, sin(p), t);
- end;
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