DBLP: Theodore E. Simos

	2012
j60		Ibraheem Alolyan, Zacharias A. Anastassi, Tom E. Simos: A new family of symmetric linear four-step methods for the efficient integration of the Schrödinger equation and related oscillatory problems. Applied Mathematics and Computation 218(9): 5370-5382 (2012)
j59		Pawel Kosinski, Theodore E. Simos: Special issue on Numerical Analysis of Fluid Flow and Heat Transfer: Preface. Applied Mathematics and Computation 219(7): 3291 (2012)
j58		A. A. Kosti, Zacharias A. Anastassi, Tom E. Simos: An optimized explicit Runge-Kutta-Nyström method for the numerical solution of orbital and related periodical initial value problems. Computer Physics Communications 183(3): 470-479 (2012)
j57		Zacharias A. Anastassi, Tom E. Simos: A parametric symmetric linear four-step method for the efficient integration of the Schrödinger equation and related oscillatory problems. J. Computational Applied Mathematics 236(16): 3880-3889 (2012)
	2011
j56		Pawel Kosinski, Theodore E. Simos: Preface. Applied Mathematics and Computation 217(11): 5015 (2011)
j55		A. A. Kosti, Zacharias A. Anastassi, Tom E. Simos: Construction of an optimized explicit Runge-Kutta-Nyström method for the numerical solution of oscillatory initial value problems. Computers & Mathematics with Applications 61(11): 3381-3390 (2011)
j54		Ch. Tsitouras, Ioannis Th. Famelis, T. E. Simos: On modified Runge-Kutta trees and methods. Computers & Mathematics with Applications 62(4): 2101-2111 (2011)
j53		Ibraheem Alolyan, T. E. Simos: A family of high-order multistep methods with vanished phase-lag and its derivatives for the numerical solution of the Schrödinger equation. Computers & Mathematics with Applications 62(10): 3756-3774 (2011)
j52		G. A. Panopoulos, Zacharias A. Anastassi, Theodore E. Simos: A symmetric eight-step predictor-corrector method for the numerical solution of the radial Schrödinger equation and related IVPs with oscillating solutions. Computer Physics Communications 182(8): 1626-1637 (2011)
	2010
j51		Z. Kalogiratou, Th. Monovasilis, T. E. Simos: New modified Runge-Kutta-Nyström methods for the numerical integration of the Schrödinger equation. Computers & Mathematics with Applications 60(6): 1639-1647 (2010)
j50		Th. Monovasilis, Z. Kalogiratou, Tom E. Simos: Symplectic Partitioned Runge-Kutta methods with minimal phase-lag. Computer Physics Communications 181(7): 1251-1254 (2010)
j49		S. Stavroyiannis, T. E. Simos: A nonlinear explicit two-step fourth algebraic order method of order infinity for linear periodic initial value problems. Computer Physics Communications 181(8): 1362-1368 (2010)
j48		Christos Christodouleas, Demetrios Xenides, Theodore E. Simos: Trends of the bonding effect on the performance of DFT methods in electric properties calculations: A pattern recognition and metric space approach on some XY₂ (X = O, S and Y = H, O, F, S, Cl) molecules. Journal of Computational Chemistry 31(2): 412-420 (2010)
j47		T. E. Simos, G. Psihoyios, Zacharias A. Anastassi: Preface. Mathematical and Computer Modelling 51(3-4): 137 (2010)
j46		D. S. Vlachos, Tom E. Simos: Algorithm 901: LMEF - A program for the construction of linear multistep methods with exponential fitting for the numerical solution of ordinary differential equations. ACM Trans. Math. Softw. 37(1) (2010)
	2009
j45		Tom E. Simos: Preface. Applied Mathematics and Computation 209(1): 1 (2009)
j44		Th. Monovasilis, Z. Kalogiratou, T. E. Simos: A family of trigonometrically fitted partitioned Runge-Kutta symplectic methods. Applied Mathematics and Computation 209(1): 91-96 (2009)
j43		T. E. Simos: High order closed Newton-Cotes trigonometrically-fitted formulae for the numerical solution of the Schrödinger equation. Applied Mathematics and Computation 209(1): 137-151 (2009)
j42		T. E. Simos: Closed Newton-Cotes trigonometrically-fitted formulae of high order for long-time integration of orbital problems. Appl. Math. Lett. 22(10): 1616-1621 (2009)
j41		Z. Kalogiratou, Th. Monovasilis, Tom E. Simos: Computation of the eigenvalues of the Schrödinger equation by exponentially-fitted Runge-Kutta-Nyström methods. Computer Physics Communications 180(2): 167-176 (2009)
j40		T. E. Simos: P-stability, Trigonometric-fitting and the numerical solution of the radial Schrödinger equation. Computer Physics Communications 180(7): 1072-1085 (2009)
j39		D. F. Papadopoulos, Zacharias A. Anastassi, T. E. Simos: A phase-fitted Runge-Kutta-Nyström method for the numerical solution of initial value problems with oscillating solutions. Computer Physics Communications 180(10): 1839-1846 (2009)
	2008
j38		T. E. Simos: High-order closed Newton-Cotes trigonometrically-fitted formulae for long-time integration of orbital problems. Computer Physics Communications 178(3): 199-207 (2008)
	2007
j37		T. E. Simos, G. Psihoyios: Preface. Applied Mathematics and Computation 184(1): 1 (2007)
j36		Th. Monovasilis, Z. Kalogiratou, T. E. Simos: Families of third and fourth algebraic order trigonometrically fitted symplectic methods for the numerical integration of Hamiltonian systems. Computer Physics Communications 177(10): 757-763 (2007)
j35		Tom E. Simos, Dimitrios D. Thomakos, Fragiskos A. Batzias: Preface. Mathematical and Computer Modelling 46(1-2): 1 (2007)
	2006
j34		D. S. Vlachos, T. E. Simos: PDSW: A program for the calculation of photon energy distribution resulting from radioactive elements in seawater. Computer Physics Communications 174(5): 391-395 (2006)
	2005
j33		E. G. Varagouli, Theodore E. Simos, G. S. Xeidakis: Fitting a multiple regression line to travel demand forecasting: The case of the prefecture of Xanthi, Northern Greece. Mathematical and Computer Modelling 42(7-8): 817-836 (2005)
j32		Zacharias A. Anastassi, Theodore E. Simos: Trigonometrically fitted fifth-order runge-kutta methods for the numerical solution of the schrödinger equation. Mathematical and Computer Modelling 42(7-8): 877-886 (2005)
j31		George Psihoyios, Theodore E. Simos: A new trigonometrically-fitted sixth algebraic order P-C algorithm for the numerical solution of the radial schrödinger equation. Mathematical and Computer Modelling 42(7-8): 887-902 (2005)
j30		D. P. Sakas, Theodore E. Simos: A fifth algebraic order trigonometrically-fitted modified runge-kutta zonneveld method for the numerical solution of orbital problems. Mathematical and Computer Modelling 42(7-8): 903-920 (2005)
j29		Theodore E. Simos, Jesús Vigo-Aguiar: Preface. Mathematical and Computer Modelling 42(7-8): xiii (2005)
	2004
j28		T. E. Simos: Dissipative trigonometrically-fitted methods for linear second-order IVPs with oscillating solution. Appl. Math. Lett. 17(5): 601-607 (2004)
j27		Theodore E. Simos: A trigonometrically-fitted method for long-time integration of orbital problems. Mathematical and Computer Modelling 40(11-12): 1263-1272 (2004)
j26		Theodore E. Simos, Ian Gladwell: Preface. Mathematical and Computer Modelling 40(11-12): xiii (2004)
	2003
j25		Tom E. Simos, Ioannis Th. Famelis, Ch. Tsitouras: Zero Dissipative, Explicit Numerov-Type Methods for Second Order IVPs with Oscillating Solutions. Numerical Algorithms 34(1): 27-40 (2003)
	2002
j24		Tom E. Simos: Exponentially-fitted Runge-Kutta-Nystro"m method for the numerical solution of initial-value problems with oscillating solutions. Appl. Math. Lett. 15(2): 217-225 (2002)
j23		A. Konguetsof, Tom E. Simos: P-stable Eighth Algebraic Order Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 26(2): 105-111 (2002)
	2001
j22		Tom E. Simos: Preface. Computers & Chemistry 25(1): 1 (2001)
j21		George Avdelas, Tom E. Simos: On Variable-step Methods for the Numerical Solution of Schrödinger Equation and Related Problems. Computers & Chemistry 25(1): 3-13 (2001)
j20		Tom E. Simos, Paul Stefan Williams: New Insights in the Development of Numerov-type Methods with Minimal Phase-lag for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 25(1): 77-82 (2001)
j19		Tom E. Simos, Paul Stefan Williams: Dissipative Exponentially-fitted Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 25(3): 261-273 (2001)
j18		Tom E. Simos, Jesús Vigo-Aguiar: A Modified Runge-Kutta Method with Phase-lag of Order Infinity for the Numerical Solution of the Schrödinger Equation and Related Problems. Computers & Chemistry 25(3): 275-281 (2001)
j17		Tom E. Simos: A Dissipative Exponentially-Fitted Method for the Numerical Solution of the Schrödinger Equation. Journal of Chemical Information and Computer Sciences 41(4): 909-917 (2001)
	2000
j16		George Avdelas, A. Konguetsof, Tom E. Simos: A Generalization of Numerov's Method for the Numerical Solution of the Schrödinger Equation in Two Dimensions. Computers & Chemistry 24(5): 577-584 (2000)
	1999
j15		T. E. Simos: A new finite difference scheme with minimal phase-lag for the numerical solution of the Schrödinger equation. Applied Mathematics and Computation 106(2-3): 245-264 (1999)
j14		Tom E. Simos: An Expert System for the Numerical Solution of the Radial Schrödinger Equation. Computers & Chemistry 23(1): 1-7 (1999)
j13		Tom E. Simos: Dissipative High Phase-lag Order Numerov-type Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 23(5): 439-446 (1999)
j12		Tom E. Simos, Paul Stefan Williams: On Finite Difference Methods for the Solution of the Schrödinger Equation. Computers & Chemistry 23(6): 513-554 (1999)
c5		A. Konguetsof, George Avdelas, Tom E. Simos: A Generalization of Numerov's Method for the Numerical Solution of the Schrödinger Equation in Two Dimensions. PDPTA 1999: 259-264
c4		George Avdelas, Tom E. Simos: A Generator of P-stable Hybrid Methods. PDPTA 1999: 265-272
	1998
j11		Tom E. Simos, Paul Stefan Williams: Computer Algebra Programmes for the Construction of a Family of Numerov-type Exponentially-fitted Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 22(2-3): 185-218 (1998)
j10		Tom E. Simos: New Embedded Explicit Methods with Minimal Phase-lag for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 22(5): 433-440 (1998)
j9		Tom E. Simos: An Eighth Order Exponentially-fitted Method for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 22(6): 467-489 (1998)
j8		T. E. Simos: Some Modified Runge-Kutta Methods for the Numerical Solution of Initial-Value Problems with Oscillating Solutions. J. Sci. Comput. 13(1): 51-63 (1998)
	1997
j7		Tom E. Simos: Accurate Computations for the Elastic Scattering Phase-shift Problem. Computers & Chemistry 21(2): 125-128 (1997)
j6		Tom E. Simos, Paul Stefan Williams: Bessel and Neumann-fitted Methods for the Numerical Solution of the Radial Schrödinger Equation. Computers & Chemistry 21(3): 175-179 (1997)
j5		Tom E. Simos, G. Tougelidis: An Explicit Eighth-order Method with Minimal Phase-lag for Accurate Computations of Eigenvalues, Resonances and Phase Shifts. Computers & Chemistry 21(5): 327-334 (1997)
j4		Tom E. Simos, Paul Stefan Williams: A Family of Numerov-type Exponentially Fitted Methods for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 21(6): 403-417 (1997)
j3		Tom E. Simos: An Exponentially Fitted Method for the Numerical Solution of the Schrödinger Equation. Journal of Chemical Information and Computer Sciences 37(2): 343-348 (1997)
	1996
j2		Tom E. Simos, G. Tougelidis: A Numerov-type Method for Computing Eigenvalues and Resonances of the Radial Schrödinger Equation. Computers & Chemistry 20(4): 397-401 (1996)
c3		G. Papakaliatakis, Tom E. Simos: Integration of Some Constitutive Relations of Plain Strain Alastoplasticity Using Modified Runge-Kutta Methods. WNAA 1996: 365-372
c2		Tom E. Simos, Paul Stefan Williams: Bessel and Neumann Fitted Methods for the Numerical Solution of the Schrödinger Equation. WNAA 1996: 442-449
c1		Paul Stefan Williams, Tom E. Simos: Two-Step P-stable Methods with Phase-Lag of Order Infinity for the Numerical Solution of Special Second Order Initial Value Problems. WNAA 1996: 565-572
	1994
j1		T. E. Simos: Efficient Parallel Methods for Special Second Order Ordinary Differential Equations. Parallel Algorithms Appl. 2(4): 245-250 (1994)

2012

j60

Ibraheem Alolyan, Zacharias A. Anastassi, Tom E. Simos: A new family of symmetric linear four-step methods for the efficient integration of the Schrödinger equation and related oscillatory problems. Applied Mathematics and Computation 218(9): 5370-5382 (2012)

j59

Pawel Kosinski, Theodore E. Simos: Special issue on Numerical Analysis of Fluid Flow and Heat Transfer: Preface. Applied Mathematics and Computation 219(7): 3291 (2012)

j58

A. A. Kosti, Zacharias A. Anastassi, Tom E. Simos: An optimized explicit Runge-Kutta-Nyström method for the numerical solution of orbital and related periodical initial value problems. Computer Physics Communications 183(3): 470-479 (2012)

j57

Zacharias A. Anastassi, Tom E. Simos: A parametric symmetric linear four-step method for the efficient integration of the Schrödinger equation and related oscillatory problems. J. Computational Applied Mathematics 236(16): 3880-3889 (2012)

2011

j56

Pawel Kosinski, Theodore E. Simos: Preface. Applied Mathematics and Computation 217(11): 5015 (2011)

j55

A. A. Kosti, Zacharias A. Anastassi, Tom E. Simos: Construction of an optimized explicit Runge-Kutta-Nyström method for the numerical solution of oscillatory initial value problems. Computers & Mathematics with Applications 61(11): 3381-3390 (2011)

j54

Ch. Tsitouras, Ioannis Th. Famelis, T. E. Simos: On modified Runge-Kutta trees and methods. Computers & Mathematics with Applications 62(4): 2101-2111 (2011)

j53

Ibraheem Alolyan, T. E. Simos: A family of high-order multistep methods with vanished phase-lag and its derivatives for the numerical solution of the Schrödinger equation. Computers & Mathematics with Applications 62(10): 3756-3774 (2011)

j52

G. A. Panopoulos, Zacharias A. Anastassi, Theodore E. Simos: A symmetric eight-step predictor-corrector method for the numerical solution of the radial Schrödinger equation and related IVPs with oscillating solutions. Computer Physics Communications 182(8): 1626-1637 (2011)

2010

j51

Z. Kalogiratou, Th. Monovasilis, T. E. Simos: New modified Runge-Kutta-Nyström methods for the numerical integration of the Schrödinger equation. Computers & Mathematics with Applications 60(6): 1639-1647 (2010)

j50

Th. Monovasilis, Z. Kalogiratou, Tom E. Simos: Symplectic Partitioned Runge-Kutta methods with minimal phase-lag. Computer Physics Communications 181(7): 1251-1254 (2010)

j49

S. Stavroyiannis, T. E. Simos: A nonlinear explicit two-step fourth algebraic order method of order infinity for linear periodic initial value problems. Computer Physics Communications 181(8): 1362-1368 (2010)

j48

Christos Christodouleas, Demetrios Xenides, Theodore E. Simos: Trends of the bonding effect on the performance of DFT methods in electric properties calculations: A pattern recognition and metric space approach on some XY₂ (X = O, S and Y = H, O, F, S, Cl) molecules. Journal of Computational Chemistry 31(2): 412-420 (2010)

j47

T. E. Simos, G. Psihoyios, Zacharias A. Anastassi: Preface. Mathematical and Computer Modelling 51(3-4): 137 (2010)

j46

D. S. Vlachos, Tom E. Simos: Algorithm 901: LMEF - A program for the construction of linear multistep methods with exponential fitting for the numerical solution of ordinary differential equations. ACM Trans. Math. Softw. 37(1) (2010)

2009

j45

Tom E. Simos: Preface. Applied Mathematics and Computation 209(1): 1 (2009)

j44

Th. Monovasilis, Z. Kalogiratou, T. E. Simos: A family of trigonometrically fitted partitioned Runge-Kutta symplectic methods. Applied Mathematics and Computation 209(1): 91-96 (2009)

j43

T. E. Simos: High order closed Newton-Cotes trigonometrically-fitted formulae for the numerical solution of the Schrödinger equation. Applied Mathematics and Computation 209(1): 137-151 (2009)

j42

T. E. Simos: Closed Newton-Cotes trigonometrically-fitted formulae of high order for long-time integration of orbital problems. Appl. Math. Lett. 22(10): 1616-1621 (2009)

j41

Z. Kalogiratou, Th. Monovasilis, Tom E. Simos: Computation of the eigenvalues of the Schrödinger equation by exponentially-fitted Runge-Kutta-Nyström methods. Computer Physics Communications 180(2): 167-176 (2009)

j40

T. E. Simos: P-stability, Trigonometric-fitting and the numerical solution of the radial Schrödinger equation. Computer Physics Communications 180(7): 1072-1085 (2009)

j39

D. F. Papadopoulos, Zacharias A. Anastassi, T. E. Simos: A phase-fitted Runge-Kutta-Nyström method for the numerical solution of initial value problems with oscillating solutions. Computer Physics Communications 180(10): 1839-1846 (2009)

2008

j38

T. E. Simos: High-order closed Newton-Cotes trigonometrically-fitted formulae for long-time integration of orbital problems. Computer Physics Communications 178(3): 199-207 (2008)

2007

j37

T. E. Simos, G. Psihoyios: Preface. Applied Mathematics and Computation 184(1): 1 (2007)

j36

Th. Monovasilis, Z. Kalogiratou, T. E. Simos: Families of third and fourth algebraic order trigonometrically fitted symplectic methods for the numerical integration of Hamiltonian systems. Computer Physics Communications 177(10): 757-763 (2007)

j35

Tom E. Simos, Dimitrios D. Thomakos, Fragiskos A. Batzias: Preface. Mathematical and Computer Modelling 46(1-2): 1 (2007)

2006

j34

D. S. Vlachos, T. E. Simos: PDSW: A program for the calculation of photon energy distribution resulting from radioactive elements in seawater. Computer Physics Communications 174(5): 391-395 (2006)

2005

j33

E. G. Varagouli, Theodore E. Simos, G. S. Xeidakis: Fitting a multiple regression line to travel demand forecasting: The case of the prefecture of Xanthi, Northern Greece. Mathematical and Computer Modelling 42(7-8): 817-836 (2005)

j32

Zacharias A. Anastassi, Theodore E. Simos: Trigonometrically fitted fifth-order runge-kutta methods for the numerical solution of the schrödinger equation. Mathematical and Computer Modelling 42(7-8): 877-886 (2005)

j31

George Psihoyios, Theodore E. Simos: A new trigonometrically-fitted sixth algebraic order P-C algorithm for the numerical solution of the radial schrödinger equation. Mathematical and Computer Modelling 42(7-8): 887-902 (2005)

j30

D. P. Sakas, Theodore E. Simos: A fifth algebraic order trigonometrically-fitted modified runge-kutta zonneveld method for the numerical solution of orbital problems. Mathematical and Computer Modelling 42(7-8): 903-920 (2005)

j29

Theodore E. Simos, Jesús Vigo-Aguiar: Preface. Mathematical and Computer Modelling 42(7-8): xiii (2005)

2004

j28

T. E. Simos: Dissipative trigonometrically-fitted methods for linear second-order IVPs with oscillating solution. Appl. Math. Lett. 17(5): 601-607 (2004)

j27

Theodore E. Simos: A trigonometrically-fitted method for long-time integration of orbital problems. Mathematical and Computer Modelling 40(11-12): 1263-1272 (2004)

j26

Theodore E. Simos, Ian Gladwell: Preface. Mathematical and Computer Modelling 40(11-12): xiii (2004)

2003

j25

Tom E. Simos, Ioannis Th. Famelis, Ch. Tsitouras: Zero Dissipative, Explicit Numerov-Type Methods for Second Order IVPs with Oscillating Solutions. Numerical Algorithms 34(1): 27-40 (2003)

2002

j24

Tom E. Simos: Exponentially-fitted Runge-Kutta-Nystro"m method for the numerical solution of initial-value problems with oscillating solutions. Appl. Math. Lett. 15(2): 217-225 (2002)

j23

A. Konguetsof, Tom E. Simos: P-stable Eighth Algebraic Order Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 26(2): 105-111 (2002)

2001

j22

Tom E. Simos: Preface. Computers & Chemistry 25(1): 1 (2001)

j21

George Avdelas, Tom E. Simos: On Variable-step Methods for the Numerical Solution of Schrödinger Equation and Related Problems. Computers & Chemistry 25(1): 3-13 (2001)

j20

Tom E. Simos, Paul Stefan Williams: New Insights in the Development of Numerov-type Methods with Minimal Phase-lag for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 25(1): 77-82 (2001)

j19

Tom E. Simos, Paul Stefan Williams: Dissipative Exponentially-fitted Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 25(3): 261-273 (2001)

j18

Tom E. Simos, Jesús Vigo-Aguiar: A Modified Runge-Kutta Method with Phase-lag of Order Infinity for the Numerical Solution of the Schrödinger Equation and Related Problems. Computers & Chemistry 25(3): 275-281 (2001)

j17

Tom E. Simos: A Dissipative Exponentially-Fitted Method for the Numerical Solution of the Schrödinger Equation. Journal of Chemical Information and Computer Sciences 41(4): 909-917 (2001)

2000

j16

George Avdelas, A. Konguetsof, Tom E. Simos: A Generalization of Numerov's Method for the Numerical Solution of the Schrödinger Equation in Two Dimensions. Computers & Chemistry 24(5): 577-584 (2000)

1999

j15

T. E. Simos: A new finite difference scheme with minimal phase-lag for the numerical solution of the Schrödinger equation. Applied Mathematics and Computation 106(2-3): 245-264 (1999)

j14

Tom E. Simos: An Expert System for the Numerical Solution of the Radial Schrödinger Equation. Computers & Chemistry 23(1): 1-7 (1999)

j13

Tom E. Simos: Dissipative High Phase-lag Order Numerov-type Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 23(5): 439-446 (1999)

j12

Tom E. Simos, Paul Stefan Williams: On Finite Difference Methods for the Solution of the Schrödinger Equation. Computers & Chemistry 23(6): 513-554 (1999)

A. Konguetsof, George Avdelas, Tom E. Simos: A Generalization of Numerov's Method for the Numerical Solution of the Schrödinger Equation in Two Dimensions. PDPTA 1999: 259-264

George Avdelas, Tom E. Simos: A Generator of P-stable Hybrid Methods. PDPTA 1999: 265-272

1998

j11

Tom E. Simos, Paul Stefan Williams: Computer Algebra Programmes for the Construction of a Family of Numerov-type Exponentially-fitted Methods for the Numerical Solution of the Schrödinger Equation. Computers & Chemistry 22(2-3): 185-218 (1998)

j10

Tom E. Simos: New Embedded Explicit Methods with Minimal Phase-lag for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 22(5): 433-440 (1998)

Tom E. Simos: An Eighth Order Exponentially-fitted Method for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 22(6): 467-489 (1998)

T. E. Simos: Some Modified Runge-Kutta Methods for the Numerical Solution of Initial-Value Problems with Oscillating Solutions. J. Sci. Comput. 13(1): 51-63 (1998)

1997

Tom E. Simos: Accurate Computations for the Elastic Scattering Phase-shift Problem. Computers & Chemistry 21(2): 125-128 (1997)

Tom E. Simos, Paul Stefan Williams: Bessel and Neumann-fitted Methods for the Numerical Solution of the Radial Schrödinger Equation. Computers & Chemistry 21(3): 175-179 (1997)

Tom E. Simos, G. Tougelidis: An Explicit Eighth-order Method with Minimal Phase-lag for Accurate Computations of Eigenvalues, Resonances and Phase Shifts. Computers & Chemistry 21(5): 327-334 (1997)

Tom E. Simos, Paul Stefan Williams: A Family of Numerov-type Exponentially Fitted Methods for the Numerical Integration of the Schrödinger Equation. Computers & Chemistry 21(6): 403-417 (1997)

Tom E. Simos: An Exponentially Fitted Method for the Numerical Solution of the Schrödinger Equation. Journal of Chemical Information and Computer Sciences 37(2): 343-348 (1997)

1996

Tom E. Simos, G. Tougelidis: A Numerov-type Method for Computing Eigenvalues and Resonances of the Radial Schrödinger Equation. Computers & Chemistry 20(4): 397-401 (1996)

G. Papakaliatakis, Tom E. Simos: Integration of Some Constitutive Relations of Plain Strain Alastoplasticity Using Modified Runge-Kutta Methods. WNAA 1996: 365-372

Tom E. Simos, Paul Stefan Williams: Bessel and Neumann Fitted Methods for the Numerical Solution of the Schrödinger Equation. WNAA 1996: 442-449

Paul Stefan Williams, Tom E. Simos: Two-Step P-stable Methods with Phase-Lag of Order Infinity for the Numerical Solution of Special Second Order Initial Value Problems. WNAA 1996: 565-572

1994

T. E. Simos: Efficient Parallel Methods for Special Second Order Ordinary Differential Equations. Parallel Algorithms Appl. 2(4): 245-250 (1994)

1	Ibraheem Alolyan	[j60] [j53]
2	Zacharias A. Anastassi	[j60] [j58] [j57] [j55] [j52] [j47] [j39] [j32]
3	George Avdelas	[j21] [j16] [c5] [c4]
4	Fragiskos A. Batzias	[j35]
5	Christos Christodouleas	[j48]
6	Ioannis Th. Famelis	[j54] [j25]
7	Ian Gladwell	[j26]
8	Z. Kalogiratou	[j51] [j50] [j44] [j41] [j36]
9	A. Konguetsof	[j23] [j16] [c5]
10	Pawel Kosinski	[j59] [j56]
11	A. A. Kosti	[j58] [j55]
12	Th. Monovasilis	[j51] [j50] [j44] [j41] [j36]
13	G. A. Panopoulos	[j52]
14	D. F. Papadopoulos	[j39]
15	G. Papakaliatakis	[c3]
16	G. Psihoyios	[j47] [j37]
17	George Psihoyios	[j31]
18	D. P. Sakas	[j30]
19	S. Stavroyiannis	[j49]
20	Dimitrios D. Thomakos	[j35]
21	G. Tougelidis	[j5] [j2]
22	Ch. Tsitouras	[j54] [j25]
23	E. G. Varagouli	[j33]
24	Jesús Vigo-Aguiar	[j29] [j18]
25	D. S. Vlachos	[j46] [j34]
26	Paul Stefan Williams	[j20] [j19] [j12] [j11] [j6] [j4] [c2] [c1]
27	G. S. Xeidakis	[j33]
28	Demetrios Xenides	[j48]

Theodore E. Simos

Coauthor Index