SOFIA LAPLACE AND INVERSE LAPLACE TRANSFORM PACKAGE C. Kazasov, M. Spiridonova, V. Tomov Reference: Christomir Kazasov, Laplace Transformations in REDUCE 3, Proc. Eurocal '87, Lecture Notes in Comp. Sci., Springer-Verlag (1987) 132-133. Some hints on how to use to use this package: Syntax: LAPLACE(,,) INVLAP(,,) where is the expression to be transformed, is the source variable (in most cases depends explicitly of this variable) and is the target variable. If is omitted, the package uses an internal variable lp!& or il!&, respectively. The following switches can be used to control the transformations: lmon: If on, sin, cos, sinh and cosh are converted by LAPLACE into exponentials, lhyp: If on, expressions e**(~x) are converted by INVLAP into hyperbolic functions sinh and cosh, ltrig: If on, expressions e**(~x) are converted by INVLAP into trigonometric functions sin and cos. The system can be extended by adding Laplace transformation rules for single functions by rules or rule sets. In such a rule the source variable MUST be free, the target variable MUST be il!& for LAPLACE and lp!& for INVLAP and the third parameter should be omitted. Also rules for transforming derivatives are entered in such a form. Examples: let {laplace(log(~x),x) => -log(gam * il!&)/il!&, invlap(log(gam * ~x)/x,x) => -log(lp!&)}; operator f; let{ laplace(df(f(~x),x),x) => il!&*laplace(f(x),x) - sub(x=0,f(x)), 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 when fixp n, laplace(f(~x),x) = f(il!&) }; Remarks about some functions: The DELTA and GAMMA functions are known. ONE is the name of the unit step function. INTL is a parametrized integral function intl(,,0,) which means "Integral of wrt taken from 0 to ", e.g. intl(2*y**2,y,0,x) which is formally a function in x. We recommend reading the file LAPLACE.TST for a further introduction.