toms/494 Low order, no spatial error control. toms/553 M3RK Werner, no spatial error control. cheney-kincaid/pde1.f Text. Also 2, 3. ode/rkc.f for: explicit solver for parabolic PDEs by: Sommeijer, Shampine, Verwer ref: J. Comp. Appl. Math., submitted 1997 prec: double lang: Fortran77 alg: second-order explicit Runge-Kutta-Chebyshev formulae toms/690 ref: TOMS 17,2 for: chebyshev polynomial software for elliptic-parabolic systems of pdes No error control. toms/494 keywords: partial and ordinary differential equations, method of lines gams: I2a1a title: PDEONE for: systems of nonlinear parabolic partial differential equations in one space dimension alg: method of lines by: R.F. Sincovec and N.K. Madsen ref: ACM TOMS 1 (1975) 261-263 Fixed order difference approximations. No error control. ode/rkc.f for: explicit solver for parabolic PDEs by: Sommeijer, Shampine, Verwer ref: J. Comp. Appl. Math., submitted 1997 prec: double lang: Fortran77 alg: second-order explicit Runge-Kutta-Chebyshev formulae gams: I1a1a No spatial error control, toms/540 keywords: collocation, PDE, method of lines gams: I2a1a,I2a2 title: PDECOL for: coupled systems of nonlinear partial differential equations in one space and one time dimension. The solution method uses finite element collocation based upon piecewise polynomials for spatial discretization. The time discretization is done by general-purpose software for ordinary initial value problems by: N.K. Madsen and R.F. Sincovec ref: ACM TOMS 5 (1979) 326-351 No spatial error control. toms/731 ref: TOMS 20,2 (JUN 1994) 194 alg: adaptive moving grid for: univariate partial differential equation by: J. G. Blom and P. A. Zegeling Moving grid method. Equi-distribution algorithm? Looked at in the BACOL comparison paper.