[1]

Quadratic Optimal Control in Reorienting a Spacecraft in a Fixed Time Period in a Dynamic Problem Statement


Journal of Computer and Systems Sciences International,
2018 


[2]

КВАДРАТИЧНО ОПТИМАЛЬНОЕ УПРАВЛЕНИЕ ПЕРЕОРИЕНТАЦИЕЙ КОСМИЧЕСКОГО АППАРАТА ЗА ФИКСИРОВАННОЕ ВРЕМЯ В ДИНАМИЧЕСКОЙ …


2018 


[3]

Dynamic Zero Finding for Algebraic Equations


2018 


[4]

Numerical Analysis in Nonlinear Least Squares Methods and Applications


2017 


[5]

EnergyEfficient Digital Hardware Platform for Learning Complex Systems


2017 


[6]

Zero finding via feedback stabilisation


IFACPapersOnLine,
2017 


[7]

Solving a Boundary Value Problem from Chapra, Part 2


2016 


[8]

Solving a Boundary Value Problem from Chapra


2016 


[9]

J22= 1 and each unknown= 0 or 1. The first equation above is based on the Rosenbrock function in Schitkowski [11, pp. 118123]. The second ccmes from Schitkowski [11, p. 194]. 0 REM DEFDBL AZ 3 DEFINT X


2016 


[10]

12 FOR JJJJ=32000 TO 32000 15 RANDOMIZE JJJJ 16 M=1D+ 37 41 FOR J44= 1 TO 9500 42 A (J44)=2+ FIX (RND* 5)


2016 


[11]

Solving in General Integers a Nonlinear System of Five Simultaneous Nonlinear Equations with Cold Starts A (KK)=300000+ FIX (RND* 600001)


2016 


[12]

The General Mixed Integer Nonlinear Programming (MINLP) Computer Program/Solver Previously Illustrated Here Numerous Times Applied to Solving a Nonlinear System of Two Simultaneous Nonlinear Equations Involving 150,000 Binary (or 01) Integer Variables


2016 


[13]

Solving in General Integers a Nonlinear System of Four Simultaneous Nonlinear Equations, Second Edition


2016 


[14]

A Nonlinear Integer Programming Code/Software/Solver Applied to Solving a Nonlinear System of 10500 Simultaneous Diophantine Equations Based on the Brown Almost Linear Function, Second Edition


2016 


[15]

Simultaneously Solving in General Integers a Nonlinear System of Six Simultaneous Nonlinear Equations with 1<= X (i)<= 17


2016 


[16]

The Domino Method of Nonlinear Integer/Continuous/Discrete Programming Seeking To Solve a 19X19 System of Nonlinear Equations, Third Edition


2016 


[17]

Testing the Domino Method of Nonlinear Integer/Continuous/Discrete Programming with a Nonlinear System of Diophantine Equations from the Literature


2016 


[18]

A Unified Computer Program for Schittkowski’s Test Problem 395 but with 15000 Unknowns instead of 50 Unknowns


2016 


[19]

Solving Load Flow Problems of Power System by Explicit PseudoTransient Continuation (Eψtc) Method


Energy and Power Engineering,
2016 


[20]

Testing the Domino Method of General Integer/Continuous/Mixed Nonlinear Programming with Brown's Almost Linear System of 2000 Equations/Unknowns


2015 


[21]

A double optimal iterative algorithm in an affine Krylov subspace for solving nonlinear algebraic equations


Computers & Mathematics with Applications,
2015 


[22]

Seeking an Integer Solution to a System of 5010 Nonlinear Equations from the Literature, Second Edition


REM,
2015 


[23]

Seeking an Integer Solution to a Rosenbrock System of 13100 Simultaneous Equations


2015 


[24]

A New Fast Method Used For Calculating Power Flow Based on ODE


2014 


[25]

Explicit pseudotransient continuation


Computing,
2013 


[26]

Numerical Solution for Super Large Scale Systems


T Han, Y Han  ieeexplore.ieee.org,
2013 


[27]

Applied research of a new ODE method in the power flow computation of power system


Power Engineering and Automation Conference (PEAM), 2012 IEEE,
2012 


[28]

A Globally Optimal Iterative Algorithm Using the Best Descent Vector x= λ [αcF+ BT F], with the Critical Value αc, for Solving a System of Nonlinear Algebraic Equations F (x)= 0


Computer Modeling in Engineering and Sciences,
2012 


[29]

A globally optimal iterative algorithm using the best descent vector x= λ [αcF+ BT F], with the critical value αc, for solving a system of nonlinear algebraic …


2012 


[30]

A globally optimal iterative algorithm using the best descent vector x= λ [αcF+ BT F], with the critical value αc, for solving a system of nonlinear algebraic …


2012 


[31]

An Iterative Algorithm for Solving a System of Nonlinear Algebraic Equations, F (x)= 0, Using the System of ODEs with an Optimum α in x= λ [αF+(1α) BTF]; Bij= …


2011 


[32]

A Further Study on Using x= λ [αR+ βP](P= FR (F. R)/ R 2) and x= λ [αF+ βP*](P*= RF (F. R)/ F 2) in Iteratively Solving the Nonlinear System of Algebraic Equations F (x)= 0


Computer Modeling in Engineering and Sciences,
2011 


[33]

Solving Various Large Scale Systems by a New ODE Method


Proceedings 2011 world congress on Engineering and Technology (CET 2011),
2011 


[34]

Simple" residualnorm" based algorithms, for the solution of a large system of nonlinear algebraic equations, which converge faster than the Newton's method


Computer Modeling in Engineering & Sciences(CMES),
2011 


[35]

An Iterative Algorithm for Solving a System of Nonlinear Algebraic Equations, F(x) = 0, Using the System of ODEs with an Optimum α in ˙x = λ[ αF+(1−α)BTF];Bij = ∂Fi/∂xj


Computer Modeling in Engineering & Sciences(CMES),
2011 


[36]

Solving large scale unconstrained minimization problems by a new ODE numerical integration method


Applied Mathematics,
2011 


[37]

Novel algorithms based on the conjugate gradient method for inverting illconditioned matrices, and a new regularization method to solve illposed linear systems


Computer Modeling in Engineering & Sciences(CMES),
2010 


[38]

Novel algorithms based on the conjugate gradient method for inverting illconditioned matrices, and a new regularization method to solve illposed linear …


2010 


[39]

Novel algorithms based on the conjugate gradient method for inverting illconditioned matrices, and a new regularization method to solve illposed linear …


2010 


[40]

A Computer Program Solving a Nonlinear System of Equations with Continuous Variables, Improved Edition


2016


