Bibliography

Next: About this document ... Up: No Title Previous: Career Development Plan

Bibliography

1: CML Reference, August 1998.
http://www.xml-cml.org/cmlref.html.
2: MoDL for Chemical Visualization, June 1999.
cite found at http://violet.csa.iisc.ernet.in/ modl/.
3: Ibm unveils $100 million research initiative to build world's fastest supercomputer, April 2000.
4: A. Agarwal.
Performance Tradeoffs in Multithreaded Processors.
Private Communication, 1989.
5: M. P. Allen and D. J. Tildesley.
Computer Simulation of Liquids.
Clarendon Press, Oxford, New York, 1987.
Reprinted in paperback in 1989 with corrections.
6: H. E. Alper, D. Bassolino, and T. R. Stouch.
J. Chem. Phys., 98:9798, 1993.
7: H. C. Andersen.
Molecular dynamics simulations at constant pressure and/or temperature.
J. Chem. Phys., 72:2384-2393, 1980.
8: V. Andronache and J. A. Izaguirre.
H-bond calculation in mollified impulse integrators.
To be presented in SIAM Computational Science and Engineering, 2000.
9: C. Anfinsen.
Principles that govern the folding of protein chains.
Science, 181:223-230, 1973.
10: P. Auffinger and D. L. Beveridge.
Chem. Phys. Lett., 234:413, 1995.
11: F. Avbelj, J. Moult, H. Kitson, M. James, and A. Hagler.
Molecular dynamics study of the structure and dynamics of a protein molecule in crystalline ionic environment, streptomyces griseus protease a.
Biochemistry, 29:8658-8679, 1990.
12: J. S. Bader and D. Chandler.
J. Phys. Chem., 96:6423, 1992.
13: D. Bai and A. Brandt.
Local mesh refinement multilevel techniques.
Siam J. Sci. Stat. Comp., 8:109-134, 1987.
14: E. Barth and T. Schlick.
Extrapolation versus impulse in multiple-timestepping schemes. II. Linear analysis and applications to Newtonian and Langevin dynamics.
J. Chem. Phys., 109(5):1633-1642, aug 1998.
15: E. Barth and T. Schlick.
Overcoming stability limitations in biomolecular dynamics. I. Combining force splitting via extrapolation with Langevin dynamics in LN.
J. Chem. Phys., 109(5):1617-1632, August 1998.
16: D. M. Beazley and P. S. Lomdahl.
Message-passing multi-cell molecular dynamics on the connection machine 5.
Parallel Computing, 20:173-195, 1994.
17: D. M. Beazley and P. S. Lomdahl.
Lightweight computational steering of very large scale molecular dynamics simulations.
In Proceedings of Supercomputing 96, 1996.
18: H. M. Berman, J. Westbrook, Z. Feng, G. Gilliland, T.N.Bhat, H.Weissig, I.N.Shindyalov, and P.E.Bourne.
The protein data bank.
Nucleic Acids Research, pages 235-242, 2000.
cite found at http://www.rcsb.org/pdb/citing.html.
19: M. Bhandarkar, G. Budescu, W. F. Humphrey, J. A. Izaguirre, S. Izrailev, L. V. Kalé, D. Kosztin, F. Molnar, J. C. Phillips, and K. Schulten.
BioCoRE: A collaboratory for structural biology.
In A. G. Bruzzone, A. Uchrmacher, and E. H. Page, editors, Proceedings of the SCS International Conference on Web-Based Modeling and Simulation, pages 242-251, San Francisco, California, 1999.
20: J. J. Biesiadecki and R. D. Skeel.
Dangers of multiple-time-step methods.
J. Comput. Phys., 109(2):318-328, Dec. 1993.
21: T. Bishop, R. D. Skeel, and K. Schulten.
Difficulties with multiple timestepping and the fast multipole algorithm in molecular dynamics.
J. Comput. Chem., 18(14):1785-1791, Nov. 15, 1997.
22: T. Blundell.
Structure-based drug design.
Nature, 384:23-26, 1996.
23: S. D. Bond, B. J. Leimkuhler, and B. B. Laird.
The Nosé-Poincaré method for constant temperature molecular dynamics.
J. Comput. Phys, 151(1):114-134, may 1 1999.
24: M. Born and T. V. Karman.
Physik, 13:297, 1912.
25: J. Bosak.
Xml, java, and the futrue of the web, 1997.
http://www.oasis-open.org/cover/xmlIntro.html.
26: A. Brandt.
Multilevel computations of integral transforms and particle interactions with oscillatory kernels.
Computer Phys. Comm., 65:24-38, 1991.
27: A. Brandt and A. A. Lubrecht.
Multilevel matrix multiplication and fast solution of integral equations.
J. Comput. Phys., 90:348-370, 1990.
28: A. Brass, B. J. Pendleton, Y. Chen, and B. Robson.
Hybrid Monte Carlo simulations theory and initial comparison with molecular dynamics.
Biopolymers, 33:1307-1315, 1993.
29: T. Bray, J. Paoli, and C. M. Sperberg-McQueen.
Extensible Markup Language(XML) 1.0, October 1998.
download at http://www.w3.org/TR/1998/REC-xml-19980210.pdf.
30: B. R. Brooks and M. Hodoscek.
Parallelization of CHARMm for MIMD machines.
CDA, 7:16-22, Dec. 1992.
31: D. Brown, H. Minoux, and B. Maigret.
A domain decomposition parallel processing algorithm for molecular dynamics simulations of systems of arbitrary connectivity.
Computer Physics Communications, 103:170-186, 1997.
32: A. T. Brünger.
X-PLOR, Version 3.1: A System for X-ray Crystallography and NMR.
Yale University Press, New Haven and London, 1992.
33: J. Bryson, S. Betz, H. Lu, D. Suich, H. Zhou, K. O'Neil, and W. DeGrado.
Protein design: a hierarchic approach.
Science, 270:935-941, 1995.
34: A. M. Brzozowski, A. C. W. Pike, Z. Dauter, R. E. Hubbard, T. Bonn, O. Engstrom, L. Ohman, G. L. Greene, J. Ake Gustafsson, and M. Carlquist.
Molecular basis of agonism and antagonism in the oestrogen receptor.
Nature, 389:753-758, October 1997.
35: C. E. Bugg, W. M. Carson, and J. A. Montgomery.
Drugs by design.
Scient. Am., pages 92-98, 1993.
36: Z. M. Chen, T. Cagin, and W. A. Goddard.
Fast Ewald sums for general van der Waals potentials.
J. Comp. Chem., 18:1365-1370, 1997.
37: C. T. Choma and P. T. T. Wong.
The structure of anhydrous and hydrated dimyristoylphosphatidyl glycerol: a pressure tuning infrared spectroscopic study.
Chem. Phys. Lipids, 61:131-137, 1992.
38: C. K. Chui.
An introduction to wavelets.
Academic Press, Boston, 1992.
39: M. E. Clamp, P. G. Baker, C. J. Stirling, and A. Brass.
Hybrid Monte Carlo: An efficient algorithm for condensed matter simulation.
J. Comput. Chem., 15(8):838-846, 1994.
40: D. E. Clark and S. D. Pickett.
Computational methods for the prediction of 'drug-likeness'.
Drug Discovery Today, 5(2), February 2000.
Elsevier Science Ltd.
41: T. W. Clark, R. v. Hanxleden, J. A. McCammon, and L. R. Scott.
Parallelizing molecular dynamics using spatial decomposition.
In Proceedings of the Scalable High-Performance Computing Conference, pages 95-102, Los Alamitos, Calif., 1994. IEEE Computer Society Press.
42: B. A.-F. D. Agnusdei, S. Liu-Leage.
Results of international clinical trials with raloxifene.
Ann Endocrinol (Paris), 60(3):242-246, September 1999.
43: I. Daubechies.
Ten lectures on wavelets.
In CBMS-NSF regional Conf. Ser. in Appl. Math. SIAM, Philadelphia, 1992.
44: D. M. Deazley.
SWIG: An easy to use tool for integrating scripting languages with c and c++.
In Proceeding of The Forth Annual Tcl/Tk Workshop '96, pages 129-139. USENIX Association, July 1996.
45: G. S. Delbuono, T. S. Cohen, and P. J. Rossky.
Effects of long-range interactions on the dynamics of ions in aqueous-solution.
J. Mol. Liq., 60:221, 1994.
46: M. Deserno and C. Holm.
How to mesh up Ewald sums. I.A theoretical and numerical comparison of various particle mesh routines.
J. Chem. Phys., 109:7678-7693, 1998.
47: K. A. Dill and H. S. Chan.
From levinthal to pathways to funnels.
Nature Struct. Biol., 4:10-19, 1997.
48: H. Dufner, S. M. Kast, J. Brickmann, and M. Schlenkrich.
Ewald summation versus direct summation of shifted-force potentials for the calculation of electrostatic interactions in solids: A quantitative study.
J. Comp. Chem., 18:660-676, 1997.
49: M. Eriksson and L. Nilsson.
Theoretical and computational methods in genome research.
Number 279-286. Plenum Press, New York, 1997.
50: P. Ewald.
Ann. Phys., 64:253-287, 1921.
51: A. Fischer, F. Cordes, and C. Schütte.
Hybrid Monte Carlo with adaptive temperature in a mixed-canonical ensemble: Efficient conformational analysis of rna.
Technical Report SC 97-67, Konrad-Zuse-Zentrum für Informationstechnik Berlin, Dec. 1997.
Available via http://www.zib.de/bib/pub/pw/.
52: T. Forester and W. Smith.
On multiple time-step algorithms and the Ewald sum.
Mol. Sim., 13(3):195-204, 1994.
53: B. M. Forrest and U. W. Suter.
Hybrid Monte Carlo simulations of dense polymer systems.
J. Chem. Phys., 101, 1994.
54: B. García-Archilla, J. M. Sanz-Serna, and R. D. Skeel.
Long-time-step methods for oscillatory differential equations.
SIAM J. Sci. Comput., 20(3):930-963, Oct. 20, 1998.
55: B. B. Goldman and W. T. Wipke.
Qsd quadratic shape descriptors. 2. Molecular docking using quadratic shape descriptors (qsdock).
PROTEINS: Structure, Function, and Genetics, 38(1):79-94, 2000.
56: M. Gottardis, S. Robinson, P. Satyaswaroop, and V. Jordan.
Contrasting actions of tamoxifen on endometrial and breast tumor growth in the athymic mouse.
Cancer Research, 48:812-815, 1988.
57: D. G. Gromov and J. J. de Pablo.
Structure of binary polymer blends - multiple time step hybrid Monte Carlo simulations and self-consistent integral-equation theory.
J. Chem. Phys., 103(18):8247-8256, November 1995.
58: H. Grubmüller.
Dynamiksimulation sehr großer auf einem Parallelrechner.
Master's thesis, , Munich, 1989.
59: H. Grubmüller, H. Heller, A. Windemuth, and K. Schulten.
Generalized Verlet algorithm for efficient molecular dynamics simulations with long-range interactions.
Molecular Simulation, 6:121-142, 1991.
60: A. Grzybowski, E. Gwozdz, and A. Brodka.
Ewald summation of electrostatic interactions in molecular dynamics of a three-dimensional system with periodicity in two directions.
Phys. Rev., 61:6706-6712, 2000.
61: J. Gullingsrud, R. Braun, and K. Schulten.
Reconstructing potentials of mean force through time series analysis of steered molecular dynamics simulations.
J. Comp. Phys., 151:190-211, 1999.
62: S. Haney and J. Crotinger.
How templates enable high-performance scientific computing in C++.
Computing In Science & Engineering, 1(4):66-72, Jul-Aug 1999.
POOMA reference.
63: U. H. E. Hansmann, Y. Okamoto, and F. Eisenmenger.
Molecular dynamics, Langevin and hybrid Monte Carlo simulations in a multicanonical ensemble.
Chem. Phys. Lett., 259:321-330, September 1996.
64: D. Hardy.
Molecular Dynamics API.
Theoretical Biophysics Group, University of Illinois at Urbana-Champaign, 405 North Matthews Avenue, Urbana, IL 61801, 0.96 edition, October 1999.
Download at http://www.ks.uiuc.edu/dhardy/mdapi/doc.ps.gz.
65: D. M. Heyes.
Electrostatic potentials and fields in infinite point charge lattices.
J. Chem. Phys., 74:1924, 1981.
66: K. Hoogsteen.
The crystal and molecular structure of a hydrogen-bonded complex between 1-methyl thymin and 9-methyl adenine.
Acta Cryst., 16:907-916, 1963.
67: W. G. Hoover.
Canonical dynamics: Equilibrium phase-space distribution.
Phys. Rev. A, 31(3):1695-1697, March 1985.
68: W. G. Hoover.
Constant-pressure equations of motion.
Phys. Rev. A, 34(3):2499-2500, 1986.
69: G. A. Huber and J. A. McCammon.
Oompaa--object-oriented model for probing assemblages of atoms.
J. Comput. Phys, 151(1):264-282, May 1, 1999.
70: W. F. Humphrey, A. Dalke, and K. Schulten.
VMD - Visual Molecular Dynamics.
J. Mol. Graphics, 14:33-38, 1996.
71: D. D. Humphreys, R. A. Friesner, and B. J. Berne.
A multiple-time-step molecular dynamics algorithm for macromolecules.
J. Phys. Chem., 98(27):6885-6892, July 7, 1994.
72: Y.-S. Hwang, R. Das, J. H. Saltz, M. Hodoscek, and B. R. Brooks.
Parallelizing molecular dynamics programs for distributed-memory machines.
IEEE Computational Science & Engineering, 2(2):18-29, Summer 1995.
73: A. Irbäck.
Hybrid Monte Carlo simulation of polymer chains.
J. Chem. Phys., 101(2):1661-1667, July 1994.
74: J. A. Izaguirre.
Longer Time Steps for Molecular Dynamics.
PhD thesis, University of Illinois at Urbana-Champaign, 1999.
Also UIUC Technical Report UIUCDCS-R-99-2107.
75: J. A. Izaguirre.
Generalized mollified multiple time stepping methods for molecular dynamics.
In A. Brandt, K. Binder, and J. Bernholc, editors, Multiscale Computational Methods in Chemistry and Biology, Amsterdam, Netherlands, April 2000. IOS Press.
to appear.
76: J. A. Izaguirre, D. P. Catarello, J. M. Wozniak, and R. D. Skeel.
Langevin stabilization of molecular dynamics.
Submitted to J. Chem. Phys., 2000.
77: J. A. Izaguirre, S. Reich, and R. D. Skeel.
Longer time steps for molecular dynamics.
J. Chem. Phys., 110(19):9853-9864, May 15, 1999.
78: J. A. Izaguirre, J. J. Willcock, T. S. Slabach, and G. V. Viamontes.
Object oriented program for molecular dynamics.
In Proc. Midwest Numerical Analysis Day, 2000.
to appear?
79: S. Izrailev, S. Stepaniants, B. Isralewitz, D. Kosztin, H. Lu, F. Molnar, W. Wriggers, and K. Schulten.
Steered molecular dynamics.
In P. Deuflhard, J. Hermans, B. Leimkuhler, A. E. Mark, S. Reich, and R. D. Skeel, editors, Computational Molecular Dynamics: Challenges, Methods, Ideas, volume 4 of Lecture Notes in Computational Science and Engineering, pages 39-65. Springer-Verlag, Berlin, 1998.
80: W. Kabsch and C. Sander.
Dictionary of protein secondary structure: pattern recognition of hydrogen-bonded and geometrical features.
Biopolymers, 22:2577-637, 1983.
81: L. Kalé, R. Skeel, M. Bhandarkar, R. Brunner, A. Gursoy, N. Krawetz, J. Phillips, A. Shinozaki, K. Varadarajan, and K. Schulten.
NAMD2: Greater scalability for parallel molecular dynamics.
J. Comp. Phys., 151:283-312, 1999.
82: L. Kalé, R. Skeel, R. Brunner, M. Bhandarkar, A. Gursoy, N. Krawetz, J. Phillips, A. Shinozaki, K. Varadarajan, and K. Schulten.
NAMD2: Greater scalability for parallel molecular dynamics.
J. Comput. Phys, 151(1):283-312, May 1, 1999.
83: M. Kawata and M. Mikami.
Acceleration of the canonical molecular dynamics simulation by the particle mesh Ewald method combined with the multiple time-step integrator algorithm.
Chem. Phys. Lett., 313:261-266, 1999.
84: D. Kosztin, S. Izrailev, and K. Schulten.
Unbinding of retinoic acid from its receptor studied by steered molecular dynamics.
Biophys. J., 76:188-197, 1999.
85: I. D. Kuntz.
Structure-based strategies for drug design and discovery.
Science, 257:1078-1082, Aug 1992.
86: I. D. Kuntz.
Theory and simulation: Editorial overview.
Current Opinion in Structural Biology, 4:231-233, 1994.
87: S. Kuwajima and A. Warshel.
The extended Ewald method - A general treatment of long-range lectrostatic interactions in microscopic simulations.
J. Chem. Phys., 89:3751-3759, 1988.
88: R. l. Pfeiffer.
Xml tutorials for programmers.
http://www.oasis-open.org/cover/xmlIntro.html, 1999.
89: A. R. Leach.
Molecular Modelling, Principles and Applications.
Addison Wesley Longman Limited, Essex, 1996.
90: S. W. D. Leeuw, J. W. Perram, and E. R. Smith.
Simulation of electrostatic systems in periodic boundary conditions. i. lattice sums and dielectric constants.
Proc. R. Soc. Lond., A 373:27-56, 1980.
91: C. S. Lent.
Molecular electronics: Bypassing the transistor paradigm.
Science, 288:1597-1599, June 2000.
92: M. Levitt.
Molecular dynamics of native protein.
J. Mol. Biol., 168:595-620, 1983.
93: J. Liang, H. Edelsbrunner, P. Fu, P. V. Sudhakar, and S. Subramaniam.
Analytical shape computation of macromolecules: I. Molecular area and volume through Alpha Shape.
PROTEINS: Structure, Function, and Genetics, 33:1-17, 1998.
94: J. Liang, H. Edelsbrunner, P. Fu, P. V. Sudhakar, and S. Subramaniam.
Analytical shape computation of macromolecules: II. Inaccessible cavities in proteins.
PROTEINS: Structure, Function, and Genetics, 33:18-29, 1998.
95: J. Liang, H. Edelsbrunner, and C. Woodward.
Anatomy of protein pockets and cavities: Measurement of binding site geometry and implications for ligand design.
Protein Science, 7:1884-1897, 1998.
96: P. S. Lomdahl and D. M. Beazley.
Multi-million particle molecular dynamics on MPPs.
In PARA'95, Second International Workshop, volume 1041 of In Lecture Notes in Computer Science, pages 391-407, Lyngby, Denmark, August 1996. Springer-Verlag.
97: H. Lu and K. Schulten.
Steered molecular dynamics simulation of conformational changes of immunoglobulin domain I27 interpret atomic force microscopy observations.
Chem. Phys., 247:141-153, 1999.
98: B. A. Luty, M. E. Davis, I. G. Tironi, and W. F. Vangunsteren.
A comparison of particle-particle, particle-mesh and Ewald methods for calculating electrostatic interactions in periodic molecular systems.
Molecular Simulation, 14:11-20, 1994.
99: M. D. Macedonia and E. J. Maginn.
A biased grand canonical Monte Carlo method for simulating adsorption using all-atom and branched united atom models.
Mol. Phys., 96(9):1375-1390, 1999.
100: J. I. MacGregor and V. C. Jordan.
Basic guide to the mechanisms of antiestrogen action.
Pharmacological Reviews, 50(2):151-196, June 1998.
101: S. Mallat.
Molecular Modelling, Principles and Applications.
Academic Press, San Diego, 1998.
102: G. J. Martyna, M. L. Klein, and M. E. Tuckerman.
Nose-hoover chains:the canonical ensemble via continuous dynamics.
J. Chem. Phys., 97(4):2635-2643, 1992.
103: G. J. Martyna, D. J. Tobias, and M. L. Klein.
Constant pressure molecular dynamics.
J. Chem. Phys., 101(5):4177-4189, 1994.
104: G. J. Martyna and M. E. Tuckerman.
Symplectic reversible integrators: Predictor-corrector methods.
J. Chem. Phys, 102(20):8071-8077, 22 May 1995.
105: G. J. Martyna, M. E. Tuckerman, D. J. Tobias, and M. L. Klein.
Explicit reversible integrators for extended system dynamics.
Mol. Phys., 87(5):1117-1157, Apr. 10, 1996.
106: T. Matthey and J. P. Hansen.
Evaluation of MPI's one-sided communication mechanism for short-range molecular dynamics on the Origin2000.
In PARA2000 and Workshop on Applied Parallel Computing, 2000.
107: J. A. McCammon and S. C. Harvey.
Dynamics of Proteins and Nucleic Acids.
Cambridge University Press, Cambridge, 1987.
108: J. A. McCammon and S. C. Harvey.
Dynamics of Proteins and Nucleic Acids.
Cambridge University Press, Cambridge, 1987.
109: I. K. McDonald and J. M. Thornton.
Satisfying hydrogen bonding potential in proteins.
J. Mol. Biol., 238:777-793, 1994.
110: B. Mehlig, D. W. Heermann, and B. M. Forrest.
Hybrid Monte Carlo method for condensed-matter systems.
Phys. Rev. B, 45(2):679-685, Jan. 1, 1992.
111: Y. Meyer.
Algorithms and applications.
In SIAM, Philadelphia, 1993.
112: Micro Data Base Systems, Inc., Research Park, 1305 Cumberland Avenue, P. O. Box 2438, West Lafayette, IN 47996-2438.
TITANIUM (R) Database Engine, 2000.
downloaded at http://www.mdbs.com/products/titanium/t8wpaper/t8_whpap.pdf.
113: MPI-forum.
MPI-2:Extensions to the Message-Passing Interface.
http://www.mpi-forum.org/docs/docs.html.
114: M. Nelson, W. Humphrey, A. Gursoy, A. Dalke, L. Kalé, R. D. Skeel, and K. Schulten.
NAMD--a parallel, object-oriented molecular dynamics program.
Intl. J. Supercomput. Applics. High Performance Computing, 10(4):251-268, Winter 1996.
115: A. Neumaier.
Molecular modeling of proteins and mathematical prediction of protein structure.
SIAM Rev., 39(3):407-460, Sep. 1997.
116: S. Nose.
A unified formulation of the constant temperature molecular dynamics methods.
J. Chem. Phys., 81(1):511-519, July 1984.
117: T. M. Nymand and P. Linse.
Ewald summation and reaction field methods for potentials with atomic charges, dipoles, and polarizabilities.
J. Chem. Phys., 112:6152-6160, 2000.
118: D. Okunbor and R. Murty.
Parallel molecular dynamics using force decomposition.
In P. Deuflhard, J. Hermans, B. Leimkuhler, A. Mark, S. Reich, and R. D. Skeel, editors, Computational Molecular Dynamics: Challenges, Methods, Ideas, volume 4 of Lecture Notes in Computational Science and Engineering, pages 483-494. Springer-Verlag, Nov. 1998.
119: L. Perera, U. Essmann, and M. L. Berkowitz.
J. Chem. Phys., 102:450, 1995.
120: G. C. Pimentel and A. L. McClellan.
The Hydrogen Bond.
W. H. Freeman and Co., San Francisco and London, 1960.
121: S. Plimpton and B. Hendrickson.
A new parallel method for molecular dynamics simulation of macromolecular systems.
J. Comput. Chem., 17(3):326, 1996.
122: E. L. Pollock and J. Glosli.
Comments on P³M, FMM, and the Ewald method for large periodic coulombic systems.
Computer Phys. Commun., 95(2 and 3):93-110, June 6 1996.
123: W. Porod, C. S. Lent, G. H. Berstein, A. O. Orlov, I. Amlani, G. L. Snider, and J. L. Merz.
Quantum-dot cellular automata: Computing with coupled quantum dots.
International Journal of Electronics, 86:549 - 590, 1999.
124: J. F. Prins, J. Hermans, G. Mann, L. S. Nyland, and M. Simons.
A virtual environment for steered molecular dynamics.
Future Generation Computer Systems, 15:485-495, 1999.
125: C. J. Roberts and P. G. Debenedetti.
Structure and dynamics in concentrated, amorphous carbohydrate-water systems by molecular dynamics simulation.
J. Phys. Chem. B, 103:7308-7318, 1999.
126: J. E. Roberts and J. Schnitker.
J. Chem. Phys., 101:5024, 1994.
127: B. Sandak, R. Nussinov, and H. J. Wolfson.
A method for biomolecular and structural recognition and docking allowing conformational flexibility.
Journal of Computational Biology, 5(4):631-654, 1998.
128: B. Sandak, H. J. Wolfson, and R. Nussinov.
Flexible docking allowing induced fit in proteins: Insights from an open to closed conformational isomers.
PROTEINS: Structure, Function, and Genetics, 32(2):159-174, 1998.
129: J. Sanz-Serna and M. Calvo.
Numerical Hamiltonian Problems.
Chapman and Hall, London, 1994.
130: K. E. Schmidt and M. A. Lee.
Multipole Ewald sums for the fast multipole method.
J. Stat. Phys., 89:411-424, 1997.
131: H. Schreiber and O. Steinhauser.
Taming cut-off induced artifacts in molecular dynamics studies of solvated polypeptides.
J. Mol. Biol., 228:909-923, 1992.
132: SGI.
The Standard Template Library: Introduction.
http://www.sgi.com/Technology/STL/stl_introduction.html.
133: Y. Y. Sham, Z. T. Chu, H. Tao, and A. Warshel.
Examining methods for calculations of binding free energies: LRA,LIE,PDLD-LRA, and PDLD/S-LRA calculations of ligands binding to an HIV protease.
PROTEINS: Structure, Function, and Genetics, 39(4):393-407, 2000.
134: J. G. Siek and A. Lumsdaine.
The matrix template library: A unifying for numerical linear algebra.
In International Symposium on Computing in Object-Oriented Parallel, 1998.
Also available from http://lsc.nd.edu/downloads/research/mtl/papers/mtl_poosc.pdf.
135: R. D. Skeel.
Macromolecular dynamics on a shared-memory multiprocessor.
J. Comp. Chem., 12(2):175-179, 1991.
136: R. D. Skeel.
Integration schemes for molecular dynamics and related applications.
In M. Ainsworth, J. Levesley, and M. Marletta, editors, The Graduate Student's Guide to Numerical Analysis, SSCM, pages 119-176. Springer-Verlag, Berlin, 1999.
137: R. D. Skeel.
Multilevel summation methods for N-body interactions.
In A. Brandt, K. Binder, and J. Bernholc, editors, Multiscale Computational Methods in Chemistry and Biology, Amsterdam, Netherlands, April 2000. IOS Press.
to appear.
138: R. D. Skeel and J. Izaguirre.
The five femtosecond time step barrier.
In P. Deuflhard, J. Hermans, B. Leimkuhler, A. Mark, S. Reich, and R. D. Skeel, editors, Computational Molecular Dynamics: Challenges, Methods, Ideas, volume 4 of Lecture Notes in Computational Science and Engineering, pages 303-318. Springer-Verlag, Nov. 1998.
139: D. M. Small.
The Physical Chemistry of Lipids.
Number 4 in Handbook of Lipid Research. Plenum Publishing Corp., New York, 1986.
140: G. R. Smith and M. S. P. Sansom.
Dynamic properties of Na⁺ ions in models of ion channels: a molecular dynamics study.
Biophys. J., 75:2767-2782, 1998.
141: P. E. Smith and B. M. Pettitt.
Efficient Ewald electrostatic calculations for large systems.
CPC, 91(1):339-344, September 1995.
142: D. Solvason, J. Kolafa, H. G. Petersen, and J. W. Perram.
A rigorous comparison of the Ewald method and the fast multipole method in 2 dimensions.
Comp. Phys. Comm., 87:307-318, 1995.
143: C. S. Strom and P. Hartman.
Comparison between Gaussian and exponential charge-distributions in Ewald surface-potentials and fields.
Acta Crystalographica section A, 45:371-380, 1989.
144: B. Stroustrup.
The C++ Programming Language.
Addison-Wesley, third edition, 1997.
145: D. J. Tobia, G. J. Martyna, and M. L. Klein.
Molecular dynamics simulations of a protein in the canonical ensemble.
J. Phys. Chem., 97(49):12959-12966, 1993.
146: G. Toth and C. S. Lent.
Quasi-adiabatic switching for metal-island quantum-dot cellular automata.
Journal of Applied Physics, 85:2977-2984, 1999.
147: T. M. Truskett, P. G. Debenedetti, S. Sastry, and S. Torquato.
A single-bond approach to orientation-dependent interactions and its implications for liquid water.
J. Chem. Phys., 111(6), 8 August 1999.
148: M. Tuckerman, B. J. Berne, and G. J. Martyna.
Reversible multiple time scale molecular dynamics.
J. Chem. Phys, 97(3):1990-2001, 1992.
149: M. E. Tuckerman, D. Yarne, S. O. Samuelson, A. L. Hughes, and G. J. Martyna.
Exploiting multiple levels of parallelism in Molecular Dynamics based calculations via modern techniques and software paradigms on distributed memory computers.
CPC, 128:333-376, 2000.
150: W. van Gunsteren.
Validation of molecular dynamics simulation.
J. Comput. Phys., 108:6109-6116, 1998.
151: T. Veldhuizen.
Blitz++: The library that thinks it is a compiler.
Conference presentation, Extreme! Computing Laboratory, Indiana University Computer Science Department, Sep 1998.
http://oonumerics.org/blitz/blitztalk.ps.gz.
152: J. Vincent and K. M. Merz.
A highly portable parallel implementation of Amber using the message passing interface standard.
J. Comp. Chem., 11:1420-1427, 1995.
153: M. S. Warren, T. C. Germann, P. S. Lomdahl, D. . Beazley, and J. K. Salmon.
Avalon: An Alpha/Linux cluster achieves 10 GFlops for $150k.
154: M. Watanabe and M. Karplus.
Dynamics of molecules with internal degrees of freedom by multiple time-step methods.
J. Chem. Phys., 99(10):8063-8074, Nov 15 1993.
155: J. Willcock.
Samd2: A molecular dynamics simulator using blitz++.
Proceedings of CSE598E, University of Notre Dame, 2000.
156: J. J. Willcock and J. A. Izaguirre.
Samd 2: Object oriented program for prototyping of molecular dynamics programs.
to be submitted to J. Comp. Phys.
157: W. Wriggers and K. Schulten.
Investigating a back door mechanism of actin phosphate release by steered molecular dynamics.
PROTEINS: Struc., Func., and Genetics, 35:262-273, 1999.
158: D. York and W. T. Yang.
The fast Fourier-Poisson method for calculating Ewald sums.
J. Chem. Phys., 101:3298-3300, 1994.
159: H. Zhang.
A new hybrid Monte Carlo algorithm for protein potential function test and structure refinement.
Proteins, 34:464-471, 1999.
160: H. Zhou, S. T. Wlodek, and J. A. McCammon.
Conformation gating as a mechanism for enzyme specificity.
Proc. Natl. Acad. Sci. USA, 95:9280-9283, August 1998.
Biophysics.

Thomas Brandon Slabach
2000-07-28