Stiff computation (Differential equations)See also what's at your library, or elsewhere.
Broader terms:Narrower term:Used for: Computation, Stiff (Differential equations)
 Equations, Stiff (Differential equations)
 Stiff equations (Differential equations)
 Stiff systems (Differential equations)
 Systems, Stiff (Differential equations)

Filed under: Stiff computation (Differential equations)  Computer programs
Items below (if any) are from related and broader terms.
Filed under: Differential equations  Numerical solutions Advanced methods for the solution of differential equations (Scientific and Technical Information Office, National Aeronautics and Space Administration; [for sale by the Supt. of Docs., U.S. Govt. Print. Off.], 1973), by Marvin E. Goldstein and Willis H. Braun (page images at HathiTrust)
 Introduction to numerical analysis. (McGrawHill, 1956), by Francis Begnaud Hildebrand (page images at HathiTrust)
 Theory and practice of solving ordinary differential equations (ODEs) (for sale by the National Technical Information Service?, 1980), by Lawrence F. Shampine (page images at HathiTrust)
 Certain devices for the numerical treatment of ordinary differential equations (Urbana, 1966), by Henry L. Langhaar (page images at HathiTrust; US access only)
 A matrix equation arising in statistical filter theory (National Aeronautics and Space Administration, 1965), by James E. Potter, Massachusetts Institute of Technology, and United States National Aeronautics and Space Administration (page images at HathiTrust)
 Differential systems. (National Aeronautics and Space Administration]; for sale by the Clearinghouse for Federal Scientific and Technical Information, Springfield, Va., 1968), by Robert Bradley McNeill and Pennsylvania State University (page images at HathiTrust; US access only)
 An operational unification of finite difference methods for the numerical integration of ordinary differential equations. (National Aeronautics and Space Administration; for sale by the Clearinghouse for Federal Scientific and Technical Information, Springfield, Va., 1967), by Harvard Lomax (page images at HathiTrust; US access only)
 Classical eighth and lowerorder RungeKuttaNyström formulas with a new stepsize control procedure for special secondorder differential equations (National Aeronautics and Space Administration ;, 1973), by Erwin Fehlberg and George C. Marshall Space Flight Center (page images at HathiTrust)
 Classical seventh, sixth, and fifthorder RungeKuttaNyström formulas with stepsize control for general secondorder differential equations (National Aeronautics and Space Administration ;, 1974), by Erwin Fehlberg and George C. Marshall Space Flight Center (page images at HathiTrust)
 A series solution for some periodic orbits in the restricted threebody problem according to the perturbation method (National Aeronautics and Space Administration :, 1964), by SuShu Huang and Goddard Space Flight Center (page images at HathiTrust)
 NASA TN D3760 (National Aeronautics and Space Administration ;, 1967), by Robert N. Lea, Manned Spacecraft Center (U.S.), and United States National Aeronautics and Space Administration (page images at HathiTrust; US access only)
 NASA TN D3721 (National Aeronautics and Space Administration [for sale by the Clearinghouse for Federal Scientific and Technical Information, Springfield, Virginia], 1966), by Peter Musen, Goddard Space Flight Center, and United States National Aeronautics and Space Administration (page images at HathiTrust; US access only)
 Multistep RungeKutta methods (National Aeronautics and Space Administration; for sale by the Clearinghouse for Federal Scientific and Technical Information, Springfield , Va., 1968), by Joseph S. Rosen (page images at HathiTrust; US access only)
 Stable implicit and explicit numerical methods for integrating quasilinear differential equations with parasiticstiff and parasiticsaddle eigenvalues (National Aeronautics and Space Administration ;, 1968), by Harvard Lomax, United States National Aeronautics and Space Administration, and Ames Research Center (page images at HathiTrust)
 NASA TN D4478 (National Aeronautics and Space Administration ;, 1968), by William E. Miner, United States National Aeronautics and Space Administration, and Electronics Research Center (U.S.) (page images at HathiTrust)
 Numerical solution of differential equations using Obrechkoff corrector formulas (National Aeronautics and Space Administration ;, 1969), by Joseph S. Rosen, United States National Aeronautics and Space Administration, and George C. Marshall Space Flight Center (page images at HathiTrust)
 On the construction of highly stable, explicit, numerical methods for integrating coupled ordinary differential equations with parasitic eigenvalues (National Aeronautics and Space Administration ;, 1968), by Harvard Lomax, United States National Aeronautics and Space Administration, and Ames Research Center (page images at HathiTrust)
 NASA TN D4082 (National Aeronautics and Space Administration ;, 1967), by Joseph S. Rosen, United States National Aeronautics and Space Administration, and George C. Marshall Space Flight Center (page images at HathiTrust)
 Numerically stable interpolation formulas with favorable error propagation for first and secondorder differential equations (National Aeronautics and Space Administration, 1961), by Erwin Fehlberg and George C. Marshall Space Flight Center (page images at HathiTrust)
 Numerical method for the solution of large systems of differential equations of the boundarylayer type (National Aeronautics and Space Administration ;, 1972), by Michael J. Green, Philip R. Nachtsheim, United States National Aeronautics and Space Administration, and Ames Research Center (page images at HathiTrust)
 Stability of multistep methods in numerical integration (National Aeronautics and Space Administration ;, 1965), by Robert N. Lea and Manned Spacecraft Center (U.S.) (page images at HathiTrust)
 A study of solution multiplicity in some problems of mathematical physics (Los Alamos Scientific Laboratory of the University of California, 1960), by George H. Pimbley, Los Alamos Scientific Laboratory, and U.S. Atomic Energy Commission (page images at HathiTrust)
 The kinetics of a system of consecutive first and second order reactions in the nonsteady state region (Los Alamos Scientific Laboratory of the University of California, 1961), by T. W. Newton, F. B. Baker, U.S. Atomic Energy Commission, and Los Alamos Scientific Laboratory (page images at HathiTrust)
 Groupdependent boundary conditions for zoom (United States Atomic Energy Commission, Division of Technical Information ;, 1959), by B. A. Kerr, J. L. Russell, Vallecitos Atomic Laboratory, General Electric Company, and U.S. Atomic Energy Commission (page images at HathiTrust)
 Über eine neue Methode der Berechnung der Planetenstörungen (Königl. Akademie der Wissenschaften ;, 1851), by Johann Franz Encke (page images at HathiTrust)
 1979 SIGNUM Meeting on Numerical Ordinary Differential Equations, April 35, 1979, University Inn, Champaign, Illinois : jointly sponsored by Association for Computing Machinery, Special Interest Group on Numerical Mathematics; Department of Computer Science, University of Illinois at UrbanaChampaign; National Science Foundation (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1979), by Ill.) SIGNUM Meeting on Numerical Ordinary Differential Equations (1979 : Champaign, R D. Skeel, National Science Foundation (U.S.), University of Illinois at UrbanaChampaign. Dept. of Computer Science, and Association for Computing Machinery. Special Interest Group on Numerical Mathematics (page images at HathiTrust)
 Asymptotic estimation of errors and derivatives for the numerical solution of ordinary differential equations (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1973), by C. William Gear (page images at HathiTrust)
 An automatic integrator for ordinary differential equations for ILLIAC IV (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1969), by Thomas Edmund McCarthy, U.S. Atomic Energy Commission, and University of Illinois at UrbanaChampaign. Dept. of Computer Science (page images at HathiTrust)
 Hybrid methods for initial value problems in ordinary differential equations (Urbana, 1964), by C. William Gear (page images at HathiTrust)
 Numerical integrators for stiff and highly oscillatory differential equations (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1977), by Simeon Ola Fatunla (page images at HathiTrust)
 Numerical solution of stiff ordinary differential equations using collocation methods (Department of Computer Science, University of Illinois at UrbanaChampaign, 1976), by Bruce David Link (page images at HathiTrust)
 Numerical studies of the Stone algorithm and comparisons with Alternating Direction Implicit methods (Urbana, 1970), by Harold Richard Becker (page images at HathiTrust)
 Optimal stiffly stable methods for ordinary differential equations (Dept. of Computer Science, University of Illinois, 1970), by Mahendra Kumar Jain and V K Srivastava (page images at HathiTrust)
 RungeKutta starters for multistep methods (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1978), by C. William Gear (page images at HathiTrust)
 Stability and convergence of general multistep and multivalue methods with variable step size. (Dept. of Computer Science, University of Illinois, 1972), by Kaiwen Tu (page images at HathiTrust)
 Stability and convergence of variable order multistep methods (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1973), by C. William Gear and D. S. Watanabe (page images at HathiTrust)
 Stability of variablestep methods for ordinary differential equations (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1978), by C. William Gear (page images at HathiTrust)
 A user's view of solving stiff ordinary differential equations (Dept. of Computer Science, University of Illinois at UrbanaChampaign, 1976), by Lawrence F. Shampine and C. William Gear (page images at HathiTrust)
 An introduction to the Lie theory of oneparameter groups : with applications to the solution of differential equations (D.C. Heath, 1911), by Abraham Cohen (page images at HathiTrust)
 Computational results pertaining to use of a timedependent magnetic field perturbation to implement injection or extraction in a FFAG synchrotron by use of the [nu]r = N/3 resonance (Midwestern Universities Research Association ;, 1960), by L. Jackson Laslett, Keith R. Symon, U.S. Atomic Energy Commission, and Midwestern Universities Research Association (page images at HathiTrust)
 Theoretical remarks concerning the 3 [sigma]x + 2 [sigma]y = 2 [pi] resonance in spiral sector accelerators (Midwestern Universities Research Association ;, 1960), by A. M. Sessler, U.S. Atomic Energy Commission, and Midwestern Universities Research Association (page images at HathiTrust)
 Numerical solution of differential equations (Waterways Experiment Station, 1972), by S. I. Kang, James B. Cheek, Waterways Experiment Station (U.S.). Automatic Data Processing Center, and United States. Department of the Army. Office of Research and Development (page images at HathiTrust)
 Multigroup perturbation theory and eigenfunctions (Atomics International, 1959), by F. L. Fillmore, North American Aviation. Atomics International Division, and U.S. Atomic Energy Commission (page images at HathiTrust)
 Generalized functions of Green for systems of ordinary differential equations (Sandia Corporation, Technical Information Division ;, 1959), by Oswald Wyler and Sandia Corporation (page images at HathiTrust)
 A survey of numerical methods in the solution of diffusion problems (Washington, D.C. : Office of Technical Services, Department of Commerce, 1957., 1957), by Gerald G. Bilodeau, Louis A. Hageman, U.S. Atomic Energy Commission, Westinghouse Electric Corporation, and Bettis Atomic Power Laboratory (page images at HathiTrust)
 The numerical integration of ordinary differential equations of various orders (Argonne National Laboratory :, 1966), by C. William Gear, University of Chicago, and Argonne National Laboratory (page images at HathiTrust)
 On a nonlinear two point boundary value problem (Washington D. C. : Mathematical Sciences Directorate, Office of Scientific Research, U.S. Air Force, 1960., 1960), by Milton Lees, N.J.) Institute for Advanced Study (Princeton, and United States. Air Force. Office of Scientific Research (page images at HathiTrust)
 Solutions of a differential equation of pressure tendency. (M.I.T. Dept. of Meteorology, 1951), by Frederick G. Shuman (page images at HathiTrust; US access only)
Filed under: Differential equations  Numerical solutions  Computer programs Description of a computer program and numerical technique for developing linear perturbation models from nonlinear systems simulation (National Aeronautics and Space Administration :, 1978), by James E. Dieudonne, Langley Research Center, and United States. National Aeronautics and Space Administration. Scientific and Technical Information Office (page images at HathiTrust)
 The calculation of the eigenvalues and eigenfunctions of Mathieu's equation (National Aeronautics and Space Administration ;, 1972), by D. B. Hodge, Langley Research Center, and Ohio State University. ElectroScience Laboratory (page images at HathiTrust)
 Accuracy and speed in computing the Chebyshev collocation derivative (National Aeronautics and Space Administration, Office of Management, Scientific and Technical Information Program ;, 1991), by Wai Sun Don, Alex Solomonoff, Langley Research Center, and Brown University. Division of Applied Mathematics (page images at HathiTrust)
 MCDIT 21, a computer code for onedimensional elastic wave problems (National Aeronautics and Space Administration, 1969), by Richard W. Mortimer and James F. Hoburg (page images at HathiTrust)
 A FORTRAN version of Nordsieck's scheme for the numerical integration of differential equations (Los Alamos Scientific Laboratory of the University of California, 1965), by Harry R. Lewis, E. J. Stovall, U.S. Atomic Energy Commission, and Los Alamos Scientific Laboratory (page images at HathiTrust)
 GEARS : a package for the solution of sparse, stiff ordinary differential equations (Lawrence Livermore Laboratory, 1980), by Andrew H. Sherman, A. C. Hindmarsh, Lawrence Radiation Laboratory, and U.S. Atomic Energy Commission (page images at HathiTrust)
 The Sn method and the SNG code (Los Alamos Scientific Laboratory of the University of California, 1959), by Bengt G. Carlson, U.S. Atomic Energy Commission, and Los Alamos Scientific Laboratory (page images at HathiTrust)
 Twodimensional triangular mesh diffusion program for the IBM 704 (Knolls Atomic Power Laboratory, General Electric Company, 1960), by J. L. Fletcher, E. D. Reilly, J. P. Jewett, U.S. Atomic Energy Commission, General Electric Company, and Knolls Atomic Power Laboratory (page images at HathiTrust)
 Efficient algorithms for solving systems of ordinary differential equations for ecosystems modeling (Environmental Research Laboratory, Office of Research and Development, U.S. Environmental Protection Agency ;, 1980), by John Malanchuk, Hubert Bouver, John Otis, Ga.) Environmental Research Laboratory (Athens, and Ga.). Environmental Systems Branch Environmental Research Laboratory (Athens (page images at HathiTrust)
 TRIP1 : a twodimensional P3 program in XY geometry for the IBM704 (Washington, D.C. : Office of Technical Services, Department of Commerce, 1960., 1960), by Ely M. Gelbard, J. Mandel, H. Mitchell, J. Dorsey, J. Davis, Westinghouse Electric Corporation, U.S. Atomic Energy Commission, and Bettis Atomic Power Laboratory (page images at HathiTrust)
 CHIC programs for thermal transients (Washington, D.C. : Office of Technical Services, Department of Commerce, 1962., 1962), by G. Birkhoff, T. F. Kimes, Westinghouse Electric Corporation, U.S. Atomic Energy Commission, and Bettis Atomic Power Laboratory (page images at HathiTrust)
More items available under broader and related terms at left. 