ORIGINAL_ARTICLE
Commuting $\pi$-regular rings
R is called commuting regular ring (resp. semigroup) if for each x,y $\in$ R there exists a $\in$ R such that xy = yxayx. In this paper, we introduce the concept of commuting $\pi$-regular rings (resp. semigroups) and study various properties of them.
http://jlta.iauctb.ac.ir/article_510051_7ee88bde781db5864d87b43ff9257b0b.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
67
70
Regular
Commuting $pi$-regular
Sh.
Sahebi
true
1
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
LEAD_AUTHOR
M.
Azadi
true
2
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
Department of Mathematics, Faculty of Science, Islamic Azad University,
Central Tehran Branch, PO. Code 14168-94351, Tehran, Iran
AUTHOR
[1] M. Azadi, H. Doostie, L. Pourfaraj, Certain rings and semigroups examining the regularity property, Journal of mathematics, statistics and allied elds., 29(2008), 1:1-6.
1
[2] J. W. Fisher, R. L. Snider, On the Von Neumann regularity of rings with regular prime factor rings, Pacific J. Math., 54(1974),1: 135-144.
2
[3] H. Doostie, L. Pourfaraj, On the minimal of commuting regular rings and semigroups, Intarnal, J. Appl. Math. 19(2006), 2: 201-216.
3
[4] J. M. Howie, Fundamentals of semigroup Theory, Clarendon Press. Oxford, New York (1995).
4
[5] Sh. A. Safari Sabet, Commutativity conditions for rings with unity, Internal. J. Appl. Math. 15 (2004), 9-15.
5
[6] A. H. Yamini, Sh. A. Safari Sabet, Commuting regular rings, Internal. J. Appl. Math. 14 (2003), 357-364.
6
ORIGINAL_ARTICLE
On strongly J-clean rings associated with polynomial identity g(x) = 0
In this paper, we introduce the new notion of strongly J-clean rings associated with polynomial identity g(x) = 0, as a generalization of strongly J-clean rings. We denote strongly J-clean rings associated with polynomial identity g(x) = 0 by strongly g(x)-J-clean rings. Next, we investigate some properties of strongly g(x)-J-clean.
http://jlta.iauctb.ac.ir/article_510052_d11cad8b25bc9742b45b25f407279a7d.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
71
76
strongly g(x)-clean rings
strongly g(x)-J-clean rings
strongly J-clean rings
rings generated by units
H.
Haj Seyyed Javadi
true
1
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
AUTHOR
S.
Jamshidvand
jamshidvand1367@gmail.com
true
2
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
AUTHOR
M.
Maleki
true
3
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
Department of Mathematics, Shahed University, Tehran, Iran
AUTHOR
[1] M. Y. Ahn, (2003). Weakly clean rings and almost clean rings. Ph.D. Thesis, University of Lowa.
1
[2] D. D. Anderson, V. P. Camillo, Commutative rings whose elements are a sum of unit and idempotent. Comm. Algebra 30 (2002), pp. 3327-3336.
2
[3] B. Li, L. Feng, F-clean rings and rings having many full elements. J. Korean Math. Soc. 2 (2010), pp. 247-261.
3
[4] J. Che, W. K. Nicholson, Y. Zhou, Group rings in which every element is uniquely the sum of a unit and idempotent. J. Algebra. 306 (2006), pp. 453-460.
4
[5] H. Chen, Morita contexts with many units. Comm. Algebra. 30 (3) (2002), pp. 1499-1512.
5
[6] A. J. Diesl, Classes of strongly clean rings. Ph.D. Thesis, University of California, Berkeley, (2006).
6
[7] A. Haghany, Hopcity and co-hopcity for Morita Contexts. Comm. Algebra. 27 (1) (1999), pp. 477-492.
7
[8] W. K. Nicholson, Y. Zhou, Rings in which elements are uniquely the some of an idempotent and unit. Clasy. Math. J. 46 (2004), pp. 227-236.
8
ORIGINAL_ARTICLE
A note on unique solvability of the absolute value equation
It is proved that applying sufficient regularity conditions to the interval matrix $[A-|B|,A + |B|]$, we can create a new unique solvability condition for the absolute value equation $Ax + B|x|=b$, since regularity of interval matrices implies unique solvability of their corresponding absolute value equation. This condition is formulated in terms of positive deniteness of a certain point matrix. Special case $B=-I$ is veried too as an application.
http://jlta.iauctb.ac.ir/article_510053_9e8e77449fc3ae8d86aa53b9660b2a19.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
77
81
Eigenvalue
Generalized eigenvalue
Quadratic eigenvalue
Numerical computation
Iterative method
T.
Lotfi
true
1
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
AUTHOR
H.
Vieseh
true
2
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
Department of Mathematics, Hamedan Branch, Islamic Azad University,
Hamedan, Iran
AUTHOR
[1] H. Beeck, Zur Problematik der Hullenbestimmung von Inntervallgleichungssystemen, In: Interval Mathematics, Karlsruhe, 1975, Lecture Notes in Comput. Sci., 29, Springer, Berlin, (1975) 150-159.
1
[2] R. A. Horn and C. R. Johnson, Matrix Analysis, Cambridge: Cambridge University Press 1985.
2
[3] R. Farhadsefat, T. Lot and J. Rohn, A note on regularity and positive deniteness of interval matrices, Cent. Eur. J. Math., 10(1) (2012) 322-328.
3
[4] O. L. Mangasarian, Absolute value programming, Compute Optim Applic, 36, (2007) 43-53.
4
[5] O. L. Mangasarian, R. R. Meyer, Absolute value equations, Linear Algebra Appl, 419(2-3), (2006) 359-367.
5
[6] O. Prokopyev, On equivalent reformulation for absolute value equations, Comput Optim Appl, 44, (2009) 363-372.
6
[7] G. Rex and J. Rohn, Sucient conditions for regularity and singularity of interval matrices, SIAM J. Matrix Anal. Appl., 20(2), (1999) 437-445.
7
[8] J. Rohn, An algorithm for solving the absolute value equation, Electronic Journal of Linear Algebra, 18, (2009) 589-599.
8
[9] J. Rohn, A Handbook of Results on Interval Linear Problems, Prague: Czech Academy of Sciences, 2005.
9
[10] J. Rohn, A theorem of the alternatives for the equation Ax + B|x|= b, Linear, Multilinear Algebra, 52(6) (2004) 421 426.
10
[11] J. Rohn, A theorem of the alternatives for the equation |Ax|- |B||x| = b, Optim Lett, 6, (2012) 585-591.
11
[12] J. Rohn, A residual existence theorem for linear equations, Optim Lett, 4(2), (2010) 287-292.
12
[13] J. Rohn, On unique solvability of the absolute value equation, Optim, Lett., 3, (2003) 603-606.
13
[14] J. Rohn, Checking properties of interval matrices, Technical Report 686, Institute of Computer Science, Academy of Sciences of the Czech Republic, Prague, September 1996.
14
[15] J. Rohn, V. Hooshyarbakhsh and R. Farhadsefat, An iterative method for solving Absolute value equations and sufficient conditions for unique solvability, Optimization Letters, 2012.
15
[16] S. M. Rump, Verication methods for dence and sparse systems of equations, In: Topics in Validated Computations Oldenburg, 1993, Stud. Comput. Math., 5, North-Holland, Amsterdam, (1994) 63-135.
16
ORIGINAL_ARTICLE
On edge detour index polynomials
The edge detour index polynomials were recently introduced for computing the edge detour indices. In this paper we find relations among edge detour polynomials for the 2-dimensional graph of $TUC_4C_8(S)$ in a Euclidean plane and $TUC4C8(S)$ nanotorus.
http://jlta.iauctb.ac.ir/article_510054_51b0bbf91b051396b9b9a7e4ff566afa.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
83
89
Heun equation
Wiener process
Stochastic differential equation
Linear equations system
Sh.
Safari Sabet
true
1
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
AUTHOR
M.
Farmani
true
2
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
Department of Mathematics, Islamic Azad University, Central Tehran Branch,
Tehran, Iran
AUTHOR
O.
Khormali
true
3
Mathematics and Informatics Research Group, ACECR, Tarbiat Modares University,
P. O. Box: 14115-343, Tehran, Iran
Mathematics and Informatics Research Group, ACECR, Tarbiat Modares University,
P. O. Box: 14115-343, Tehran, Iran
Mathematics and Informatics Research Group, ACECR, Tarbiat Modares University,
P. O. Box: 14115-343, Tehran, Iran
AUTHOR
A.
Mahmiani
true
4
Department of Mathematics, Payame Noor University, 19395-4797,
Tehran, Iran
Department of Mathematics, Payame Noor University, 19395-4797,
Tehran, Iran
Department of Mathematics, Payame Noor University, 19395-4797,
Tehran, Iran
AUTHOR
Z.
Bagheri
true
5
Islamic Azad University Branch of Azadshaher, Azadshaher, Iran
Islamic Azad University Branch of Azadshaher, Azadshaher, Iran
Islamic Azad University Branch of Azadshaher, Azadshaher, Iran
AUTHOR
[1] H. Wiener, Structural determination of paran boiling points, J. Am. Chem. Soc., 69 (1997) 17-20.
1
[2] A. A. Dobrynin, R. Entringer and I. Gutman, Wiener index for trees: theory and applications, Acta Appl. Math., 66 (3) (2001) 211-249.
2
[3] F. Harary, Graph Theory, Addison-Wesley, Reading, Massachusetts, 1969.
3
[4] M. V. Diudea, G. Katona, I. Lukovitz and N. Trinajstic, Detour and Cluj-Detour Indices, Croat. Chem. Acta, 71 (1998) 459-471.
4
[5] P. E. John, Ueber die Berechnung des Wiener index fuerausgewaehlte Delta-dimensionale Gitterstrukturen, MATCH Commun. Math. Comput. Chem., 32 (1995) 207-219.
5
[6] R. Jalal Shahkoohi, O. Khormali and A. Mahmiani, The polynomial of detour index for a graph, World Applied Sciences Journal, 15 (10) (2011) 1473-1483.
6
[7] A. Mahmiani, O. Khormali and A. Iranmanesh, The edge versions of detour index, MATCH Commun. Math. Comput. Chem., 62 (2) (2009) 419-431.
7
[8] Sh. Safari Sabet, A. Mahmiani, O. Khormali, M. Farmani and Z. Bagheri, On the edge detour index polynomials, Middle-East Journal of Scientic Research, 10 (4) (2011) 539-548.
8
[9] Sh. Safari Sabet, M. Farmani, O. Khormali, A. Mahmiani and Z. Bagheri, Relations among the edge detour index polynomials in nanotubes, Journal of Mathematical Nanoscience, 3 (1) (2013) 3-12.
9
ORIGINAL_ARTICLE
Operational matrices with respect to Hermite polynomials and their applications in solving linear differential equations with variable coefficients
In this paper, a new and efficient approach is applied for numerical approximation of the linear differential equations with variable coeffcients based on operational matrices with respect to Hermite polynomials. Explicit formulae which express the Hermite expansion coeffcients for the moments of derivatives of any differentiable function in terms of the original expansion coefficients of the function itself are given in the matrix form. The main importance of this scheme is that using this approach reduces solving the linear differential equations to solve a system of linear algebraic equations, thus greatly simplifying the problem. In addition, two experiments are given to demonstrate the validity and applicability of the method.
http://jlta.iauctb.ac.ir/article_510055_7694e7a62ce277393219dc3f08d757f0.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
91
103
Operational matrices
Hermite polynomials
Linear differential equations with variable coefficients
Z.
Kalateh Bojdi
true
1
Department of Mathematics, Birjand University, Birjand, Iran
Department of Mathematics, Birjand University, Birjand, Iran
Department of Mathematics, Birjand University, Birjand, Iran
AUTHOR
S.
Ahmadi-Asl
true
2
Department of Mathematics, Birjand University, Birjand, Iran
Department of Mathematics, Birjand University, Birjand, Iran
Department of Mathematics, Birjand University, Birjand, Iran
AUTHOR
A.
Aminataei
true
3
Faculty of Mathematics, K. N. Toosi University of Technology, P.O. Box 16315-1618, Tehran, Iran
Faculty of Mathematics, K. N. Toosi University of Technology, P.O. Box 16315-1618, Tehran, Iran
Faculty of Mathematics, K. N. Toosi University of Technology, P.O. Box 16315-1618, Tehran, Iran
AUTHOR
[1] R.P. Agraval, and D.O. Oregan, Ordinary and Partial Dierential Equations, Springer, 2009.
1
[2] A. Aminataei, and S.S. Hussaini, The comparison of the stability of decomposition method with numerical methods of equation solution, Appl. Math. Comput. 186 (2007), pp. 665{669.
2
[3] A. Aminataei, and S.S. Hussaini, The barrier of decomposition method, Int. J. Contemp. Math. Sci. 5 (2010), pp. 2487{2494.
3
[4] R. Askey, Orthogonal Polynomials and Special Functions, SIAM-CBMS, Philadelphia, 1975.
4
[5] T. Akkaya, and S. Yalcinbas, Boubaker polynomial approach for solving high-order linear differential-difference equations, AIP Conference Proceedings of 9th international conference on mathematical problems in engineering, 56 (2012), PP. 26-33.
5
[6] G. Ben-yu, The State of Art in Spectral Methods. Hong Kong University, 1996.
6
[7] J.P. Boyd, Chebyshev and Fourier Spectral Methods, Dover Publications, Inc, New York, 2000.
7
[8] C. Canuto, M.Y. Hussaini, A. Quarteroni, and T.A. Zang, Spectral Method in Fluid Dynamics, Prentice Hall, Engelwood Clis, NJ, 1984.
8
[9] C. Canuto, M.Y. Hussaini, A. Quarteroni, and T.A. Zang, Spectral Methods: Fundamentals in Single Domains, Springer-Verlag, 2006.
9
[10] H. Danfu, and S. Xufeng, Numerical solution of integro-dierential equations by using CAS wavelet operational matrix of integration, Appl. Math. Comput. 194 (2007), pp. 460-466.
10
[11] C.F. Dunkl, and Y. Xu, Orthogonal Polynomials of Several Variables, Cambridge University Press, 2001.
11
[12] K. Erdem, and S. Yalcinbas, Bernoulli polynomial approach to high-order linear differential-difference equations, AIP Conference Proceedings of Numerical Analysis and Applied Mathematics, 73 (2012), 360-364.
12
[13] M.R. Eslahchi, and M. Dehghan, Application of Taylor series in obtaining the orthogonal operational matrix, Computers and Mathematics with Applications, 61 (2011), PP. 2596-2604.
13
[14] D. Funaro, Polynomial Approximations of Dierential Equations, Springer-Verlag, 1992.
14
[15] W. Gautschi, Orthogonal Polynomials (Computation and Approximation), Oxford University Press, 2004.
15
[16] D. Gottlieb, and S.A. Orszag,Numerical Analysis of Spectral Methods: Theory and Applications, SIAM-CBMS, Philadelphia, 1977.
16
[17] M. Gulsu, and M. Sezer, A method for the approximate solution of the high-order linear difference equations in terms of Taylor polynomials, Int. J. Comput. Math. 82 (2005), pp. 629-642.
17
[18] M. Gulsu, M. Sezer, and Z. Guney, Approximate solution of general high-order linear non-homogenous difference equations by means of Taylor collocation method, Appl. Math. Comput. 173 (2006), pp. 683-693.
18
[19] M. Gulsu, and M. Sezer, A Taylor polynomial approach for solving differential-difference equations, Comput. Appl. Math. 186 (2006), pp. 349-364.
19
[20] J.S. Hesthaven, S. Gottlieb, and D. Gottlieb, Spectral Methods for Time-Dependent Problems, Cambridge University, 2009.
20
[21] C.H. Hsiao, Hybrid function method for solving Fredholm and Volterra integral equations of the second kind, Comput. Appl. Math. 230 (2009), pp. 59-68.
21
[22] A. Imani, A. Aminataei, and A. Imani, Collocation method via Jacobi polynomials for solving nonlinear ordinary differential equations, Int. J. Math. Math. Sci., Article ID 673085, 11P, 2011.
22
[23] F. Khellat, S. A. Youse, The linear Legendre wavelets operational matrix of integration and its application, J. Frank. Inst. 343 (2006), PP. 181-190.
23
[24] A.C. King, J. Bilingham, and S.R. Otto, Differential Equations (Linear, Nonlinear, Integral, Partial), Cambridge University, 2003.
24
[25] E.L. Ortiz, and L. Samara, An operational approach to the Tau method for the numerical solution of nonlinear differential equations, Computing, 27 (1981), pp. 15-25.
25
[26] E.L. Ortiz, On the numerical solution of nonlinear and functional differential equations with the Tau method, in: Numerical Treatment of Differential Equations in Applications, in: Lecture Notes in Math. 679 (1978), pp. 127-139.
26
[27] F. Marcellan, and W.V. Assche, Orthogonal Polynomials and Special Functions (a Computation and Applications), Springer-Verlag Berlin Heidelberg, 2006.
27
[28] K. Maleknejad, and F. Mirzaee, Numerical solution of integro-differential equations by using rationalized Haar functions method, Kyber. Int. J. Syst. Math. 35 (2006), pp. 1735-1744.
28
[29] M. Razzaghi, and Y. Ordokhani, Solution of nonlinear Volterra Hammerstein integral equations via rationalized Haar functions, Math. Prob. Eng. 7 (2001), PP. 205-219.
29
[30] M. Razzaghi, and S.A. Youse, Legendre wavelets method for the nonlinear Volterra-Fredholm integral equations, Math. Comput. Simul. 70 (2005), pp. 1-8.
30
[31] M.H. Reihani, and Z. Abadi, Rationalized Haar functions method for solving Fredholm and Volterra integral equations, Comput. Appl. Math. 200 (2007), pp. 12-20.
31
[32] M. Sezer, and A.A. Dascioglu, Taylor polynomial solutions of general linear dierential-dierence equations with variable coefficients, Appl. Math. Comput. 174 (2006), pp. 1526-1538.
32
[33] M. Sezer, and M. Gulsu, Polynomial solution of the most general linear Fredholm integro-differential-difference equation by means of Taylor matrix method, Int. J. Complex Variables. 50 (2005), pp. 367-382.
33
[34] J. Shen, T. Tang, and L.L. Wang, Spectral Methods Algorithms, Analysis and Applications, Springer, 2011.
34
[35] L.N. Trefethen, Spectral Methods in Matlab, SIAM, Philadelphia, PA, 2000.
35
[36] A.M. Wazwaz, The combined Laplace transform-Adomian decomposition method for handling nonlinear Volterra integro-differential equations, Appl. Math. Comput. 216 (2010), pp. 1304-1309.
36
ORIGINAL_ARTICLE
A new approach to solve fuzzy system of linear equations by Homotopy perturbation method
In this paper, we present an efficient numerical algorithm for solving fuzzy systems of linear equations based on homotopy perturbation method. The method is discussed in detail and illustrated by solving some numerical examples.
http://jlta.iauctb.ac.ir/article_514256_d54426e4ec1b020014ce00c56967a4ca.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
105
115
Fuzzy number
Fuzzy system of linear equations
Homotopy perturbation method
Auxiliary matrix
M.
Paripour
true
1
Department of Mathematics, Hamedan University of Technology, Hamedan, 65156-579, Iran
Department of Mathematics, Hamedan University of Technology, Hamedan, 65156-579, Iran
Department of Mathematics, Hamedan University of Technology, Hamedan, 65156-579, Iran
AUTHOR
J.
Saeidian
true
2
Faculty of Mathematical Sciences and Computer, Kharazmi University,
50 Taleghani Avenue, Tehran 1561836314, Iran
Faculty of Mathematical Sciences and Computer, Kharazmi University,
50 Taleghani Avenue, Tehran 1561836314, Iran
Faculty of Mathematical Sciences and Computer, Kharazmi University,
50 Taleghani Avenue, Tehran 1561836314, Iran
AUTHOR
A.
Sadeghi
true
3
Department of Mathematics, Science and Research Branch, Islamic Azad University, Arak, Iran
Department of Mathematics, Science and Research Branch, Islamic Azad University, Arak, Iran
Department of Mathematics, Science and Research Branch, Islamic Azad University, Arak, Iran
AUTHOR
[1] S. Abbasbandy, R. Ezzati, Homotopy method for solving fuzzy nonlinear equations, Appl. Sci. 8 (2006), pp. 1-7.
1
[2] T. Allahviranloo, The Adomian decomposition method for fuzzy system of linear equations, Appl. Math. Comput. 163 (2) (2005), pp. 553-563.
2
[3] T. Allahviranloo, Numerical methods for fuzzy system of linear equations, Appl. Math. Comput. 155 (2) (2004), pp. 493-502.
3
[4] T. Allahviranloo, M. Ghanbari, Solving Fuzzy Linear Systems by Homotopy Perturbation Method, Inter. J. Comput. Cognition 8 (2) (2010), pp. 91-61.
4
[5] B. Asady, S. Abbasbandy, M. Alavi, Fuzzy general linear systems, Appl. Math. Comput. 169 (2005), pp. 34-40.
5
[6] E. Babolian, J. Saeidian, M. Paripour, Computing the Fourier Transform via Homotopy perturbation method, Z. Naturforsch. 64a (2009), pp. 671-675.
6
[7] D. Dubois, H. Prade, Fuzzy Set and Systems: Theory and Application, Academic Press, New York, 1980.
7
[8] M. Friedman, M. Ming, A. Kandel, Fuzzy linear systems, Fuzzy Sets Syst. 96 (1998), pp. 201-209.
8
[9] R. Goetschell, W. Voxman, Elementary calculus, Fuzzy Sets Syst. 18 (1986), pp. 31-43.
9
[10] J. H. He, Homotopy perturbation technique, Comp. Meth. Appl. Mech. Eng. 178 (1999), pp. 257-262.
10
[11] J. H. He, A coupling method of homotopy technique and a perturbation technique for non-linear problems, Int. J. Non-Linear Mech. 35 (1) (2000), pp. 37-43.
11
[12] J. H. He, Homotopy perturbation method: a new non-linear analytical technique, Appl. Math. Comput. 135 (1) (2003), pp. 73-79.
12
[13] B. Keramati, An approach to the solution of linear system of equations by He; homotopy perturbation method, Chaos, Solitons and Fractals. 37 (2006), pp. 1528-1537.
13
[14] H. Ku Liu, Application of homotopy perturbation methods for solving systems on linear equations, Appl. Math. Comput. 217 (2011), pp. 5259-5264.
14
[15] S. J. Liao, Beyond perturbation: An introduction to homotopy analysis method, Chapman Hall/CRC Press, Boca Raton, 2003.
15
[16] M. Ma, M. Friedman, A. Kandel, A new fuzzy arithmetic, Fuzzy Sets and Syst. 108 (1999), pp. 83-90.
16
[17] H. Saberi Naja, S. A. Edalatpanah, A. H. Refahi Sheikhani, Application of Homotopy Perturbation Method for Fuzzy Linear Systems and Comparison with Adomians Decomposition Method, Chinese Journal of Mathematics 2013 (2013), pp. 1-7.
17
[18] K. Wang, B. Zheng, Inconsistent fuzzy linear systems, Appl. Math. Comput. 181 (2006), pp. 973-981.
18
[19] B. Zheng, K. Wang, General fuzzy linear systems, Appl. Math. Comput. 181 (2006), pp. 1276-1286.
19
ORIGINAL_ARTICLE
The method of fundamental solutions for transient heat conduction in functionally graded materials: some special cases
In this paper, the Method of Fundamental Solutions (MFS) is extended to solve some special cases of the problem of transient heat conduction in functionally graded materials. First, the problem is transformed to a heat equation with constant coefficients using a suitable new transformation and then the MFS together with the Tikhonov regularization method is used to solve the resulting equation.
http://jlta.iauctb.ac.ir/article_514257_d41d8cd98f00b204e9800998ecf8427e.pdf
2013-06-01T11:23:20
2018-06-23T11:23:20
117
127
Heat conduction
Functionally graded materials
Method of fundamental solutions
M.
Nili Ahmadabadi
nili@phu.iaun.ac.ir
true
1
Department of Mathematics, Islamic Azad University, Najafabad Branch, Najafabad, Iran
Department of Mathematics, Islamic Azad University, Najafabad Branch, Najafabad, Iran
Department of Mathematics, Islamic Azad University, Najafabad Branch, Najafabad, Iran
AUTHOR
M.
Arab
true
2
Department of Mathematics, Yazd University, Yazd, Iran
Department of Mathematics, Yazd University, Yazd, Iran
Department of Mathematics, Yazd University, Yazd, Iran
AUTHOR
F. M.
Maalek Ghaini
true
3
Department of Mathematics, Yazd University, Yazd, Iran
Department of Mathematics, Yazd University, Yazd, Iran
Department of Mathematics, Yazd University, Yazd, Iran
AUTHOR
[1] H. S. Carslaw, J. C. Jaeger, Conduction of heat in solids, 2nd ed. London: Oxford University Press; 1959.
1
[2] C. S. Chen, The method of fundamental solutions for nonlinear thermal explosion, Commun. Numer. Methods Eng. 1995;11:675-81.
2
[3] C. S. Chen, H. A. Cho, M. A. Golberg, Some comments on the ill-conditioning of the method of fundamental solutions. Eng. Anal. Boundary Elem. 2006;30:405-410.
3
[4] F. de Monte, Transient heat conduction in one-dimensional composite slab. A natural approach. Int. J. Heat Mass Transf. 2000;43:3607-19.
4
[5] F. de Monte, Ananalytical approach to the unsteady heat conduction processes in one-dimensional composite media. Int. J. Heat Mass Transf. 2002;26:1333-43.
5
[6] H. W. Engl, M. Hanke, A. Neubauer, Regularization of inverse problems. Mathematics and its applications, vol. 357. Dordrecht: Kluwer Academic Publishers; 1996.
6
[7] G. Fairweather, A. Karageorghis, The method of fundamental solutions for elliptic boundary value problems, Adv. Comput. Math. 1998;9(1-2):69-95.
7
[8] Z. G. Feng, E. E. Michaelides, The use of modied Greens functions in unsteady heat transfer. Int. J. Heat Mass Transf. 1997;40:2997-3002.
8
[9] A. Friedman, Partial dierential equations of parabolic type. Englewood Clis, NJ: Prentice-Hall Inc.; 1964
9
[10] M. A. Golberg, C. S. Chen, The method of fundamental solutions for potential, Hemholtz and diffusion problems. In: Boundary integral methods: numerical and mathematical aspects. Computational engineering, vol. 1. Boston, MA: WIT Press, Computational Mechanics Publications; 1999. p. 103-76.
10
[11] A. Haji-Sheikh, J. V. Beck, Greens function partitioning in Galerkin-base integral solution of the diffusion equation. J. Heat Transf. 1990;112:28-34.
11
[12] P. C. Hansen, Regularization tools: a Matlab package for analysis and solution of discrete ill-posed problems. Numer. Algorithms 1994;6:1-35.
12
[13] P. C. Hansen, Rank-decient and discrete ill-posed problems. Philadelphia: SIAM; 1998.
13
[14] S. C. Huang, Y. P. Chang, Heat conduction in unsteady, periodic and steady states in laminated composites. J. Heat Transf. 1980;102:742-8.
14
[15] B. T. Johansson, D. Lesnic, A method of fundamental solutions for transient heat conduction. Eng. Anal. Boundary Elem. 2008;32:697-703.
15
[16] B. T. Johansson, D. Lesnic, A method of fundamental solutions for transient heat conduction in layered materials. Eng. Anal. Boundary Elem. 2009;33:1362-67.
16
[17] A. Karageorghis, G. Fairweather, The method of fundamental solutions for the numerical solution of the biharmonic equation, J. Comput. Phys. 1987;69:434-59.
17
[18] R. Kress, A. Mohsen, On the simulation source technique for exterior problems in acoustics, Math. Methods Appl. Sci. 1986;8:585-97.
18
[19] V. D. Kupradze, A method for the approximate solution of limiting problems in mathematical physics. USSR Comput. Math. Math. Phys. 1964;4:199-205.
19
[20] V. D. Kupradze, M. A. Aleksidze, The method of functional equations for the approximate solution of certain boundary value problems, USSR Comput. Math. Math. Phys. 1964;4:82-126.
20
[21] O. A. Ladyzhenskaya, V. A. Solonnikov, N. N. Ural'ceva, Linear and quasilinear equations of parabolic type. Translational of mathematical monographs, vol. 23. Providence, RI: AMS; 1968.
21
[22] D. Lesnic, The identication of piecewise homogeneous properties of rocks. In: Ingham DB, Wrobel LC, editors. Boundary integral formulations for inverse analysis. Southampton: Comput. Mech. Publ.; 1997. p. 237-57 [chapter 9].
22
[23] R. Mathon, H. Johnston, The approximate solution of elliptic boundary-value problems by fundamental solutions, SIAM J. Numer. Anal. 1977;14(4):638-50.
23
[24] M. D. Mikhailov, M. N. Ozisik, M. D. Vulchanov, Diusion in composite layers with automatic solution of thee eigenvalue problem. Int. J. Heat Mass Transf. 1983;26:1131-41.
24
[25] M. Nili Ahmadabadi, M. Arab, F. M. Maalek Ghaini, The method of fundamental solutions for the inverse space-dependent heat source problem. Eng. Anal. Boundary Elem. 2009;33:1231-35.
25
[26] P. A. Ramachandran, Method of fundamental solutions: singular value decomposition analysis. Commun. Numer. Methods Eng. 2002;18:789-801.
26
[27] J. N. Reddy, An introduction to the nite element method. NewYork: McGraw-Hill; 1984.
27
[28] M. Talha, B. N. Singh, Stochastic perturbation-based nite element for buckling statistics of FGM plates with uncertain material properties in thermal environments, Composite Structures, Volume 108, February 2014, Pages 823-833, ISSN 0263-8223, http://dx.doi.org/10.1016/j.compstruct.2013.10.013.
28
[29] Z. Tobias, K. Torsten, Functionally graded materials with a soft surface for improved indentation resistance: Layout and corresponding design principles, Computational Materials Science, Volume 86, 15 April 2014, Pages 88-92, ISSN 0927-0256, http://dx.doi.org/10.1016/j.commatsci.2014.01.032.
29
[30] V. Vodicka, Warmeleitung in geschichteten kugel -und zylinderkorpern. Schweiz Arch 1950;10:297-304.
30
[31] Y. Yener, M. N. Ozisik, On the solution of unsteady heat conduction in multi-region nite media with timedependent
31
heat transfer coefficient. In: Proceedings of the fth international heat transfer conference, vol. 1, JSME, Tokyo; 1974. p. 188-92.
32
[32] Zakaria Belabed, Mohammed Sid Ahmed Houari, Abdelouahed Tounsi, Mahmoud SR., Anwar Bg O., An efficient and simple higher order shear and normal deformation theory for functionally graded material (FGM) plates, Composites Part B: Engineering, Volume 60, April 2014, Pages 274-283, ISSN 1359-8368, http://dx.doi.org/10.1016/j.compositesb.2013.12.057.
33