NONNEGATIVITY OF SOLUTIONS OF NONLINEAR FRACTIONAL DIFFERENTIAL-ALGEBRAIC EQUATIONS

被引:0
|
作者
Ding, Xiaoli [1 ]
Jiang, Yaolin [2 ]
机构
[1] Xian Polytech Univ, Dept Math, Xian 710048, Shaanxi, Peoples R China
[2] Xi An Jiao Tong Univ, Dept Math, Xian 710049, Shaanxi, Peoples R China
来源
ACTA MATHEMATICA SCIENTIA | 2018年 / 38卷 / 03期
关键词
Fractional differential-algebraic equations; nonnegativity of solutions; waveform relaxation; monotone convergence; WAVE-FORM RELAXATION; INTEGRODIFFERENTIAL EQUATIONS; POSITIVE SOLUTIONS;
D O I
暂无
中图分类号
O1 [数学];
学科分类号
0701 ; 070101 ;
摘要
Nonlinear fractional differential-algebraic equations often arise in simulating integrated circuits with superconductors. How to obtain the nonnegative solutions of the equations is an important scientific problem. As far as we known, the nonnegativity of solutions of the nonlinear fractional differential-algebraic equations is still not studied. In this article, we investigate the nonnegativity of solutions of the equations. Firstly, we discuss the existence of nonnegative solutions of the equations, and then we show that the nonnegative solution can be approached by a monotone waveform relaxation sequence provided the initial iteration is chosen properly. The choice of initial iteration is critical and we give a method of finding it. Finally, we present an example to illustrate the efficiency of our method.
引用
收藏
页码:756 / 768
页数:13
相关论文
共 50 条
  • [41] Construction of inverse system for nonlinear differential-algebraic equations subsystems
    Key Laboratory of Measurement and Control of Complex Systems of Engineering, School of Automation, Southeast University, Nanjing 210096, China
    Zidonghua Xuebao Acta Auto. Sin., 2009, 8 (1094-1100):
  • [42] Analytical Solutions for Systems of Singular Partial Differential-Algebraic Equations
    Filobello-Nino, U.
    Vazquez-Leal, H.
    Benhammouda, B.
    Perez-Sesma, A.
    Jimenez-Fernandez, V. M.
    Cervantes-Perez, J.
    Sarmiento-Reyes, A.
    Huerta-Chua, J.
    Morales-Mendoza, L. J.
    Gonzalez-Lee, M.
    Diaz-Sanchez, A.
    Pereyra-Diaz, D.
    Lopez-Martinez, R.
    DISCRETE DYNAMICS IN NATURE AND SOCIETY, 2015, 2015
  • [43] Nonlinear Stochastic differential-algebraic equations with application to particle filtering
    Gerdin, Markus
    Sjoberg, Johan
    PROCEEDINGS OF THE 45TH IEEE CONFERENCE ON DECISION AND CONTROL, VOLS 1-14, 2006, : 6630 - 6635
  • [44] LEAST-SQUARES COMPLETIONS FOR NONLINEAR DIFFERENTIAL-ALGEBRAIC EQUATIONS
    CAMPBELL, SL
    NUMERISCHE MATHEMATIK, 1993, 65 (01) : 77 - 94
  • [45] HARMONIC SOLUTIONS TO A CLASS OF DIFFERENTIAL-ALGEBRAIC EQUATIONS WITH SEPARATED VARIABLES
    Bisconti, Luca
    ELECTRONIC JOURNAL OF DIFFERENTIAL EQUATIONS, 2012,
  • [46] On an invariance principle for differential-algebraic equations with jumps and its application to switched differential-algebraic equations
    Pablo Ñañez
    Ricardo G. Sanfelice
    Nicanor Quijano
    Mathematics of Control, Signals, and Systems, 2017, 29
  • [47] The Legendre Wavelets Method for Approximate Solution of Fractional Differential-Algebraic Equations
    Karabacak, Mesut
    Yigider, Muhammed
    INTERNATIONAL JOURNAL OF APPLIED MATHEMATICS & STATISTICS, 2018, 57 (04): : 161 - 173
  • [48] Numerical comparison of methods for solving fractional differential-algebraic equations (FDAEs)
    Ibis, Birol
    Bayram, Mustafa
    COMPUTERS & MATHEMATICS WITH APPLICATIONS, 2011, 62 (08) : 3270 - 3278
  • [49] Application of Said Ball Curve for Solving Fractional Differential-Algebraic Equations
    Ghomanjani, Fateme
    Noeiaghdam, Samad
    MATHEMATICS, 2021, 9 (16)
  • [50] Fractional step methods for index-1 differential-algebraic equations
    Vijalapura, PK
    Strain, J
    Govindjee, S
    JOURNAL OF COMPUTATIONAL PHYSICS, 2005, 203 (01) : 305 - 320
12345