This work is licensed under the Creative Commons Attribution 4.0 International License.
Gilson, C. and Pickering, A. (1995), Factorization and Painlev analysis of a class of nonlinear third order partial differential equations, J. Phys. A: Math. Gen, 28, 2871–2888.GilsonC.PickeringA.1995Factorization and Painlev analysis of a class of nonlinear third order partial differential equationsJ. Phys. A: Math. Gen282871288810.1088/0305-4470/28/10/017Search in Google Scholar
Rosenau, P. and Hyman, J. M. (1993), Compactons: solitons with finite wavelength, Phys. Rev. Lett, 70, 564–567.RosenauP.HymanJ.M.1993Compactons: solitons with finite wavelengthPhys. Rev. Lett7056456710.1103/PhysRevLett.70.564Search in Google Scholar
Clarkson, P. A., Mansfield, E. L. and Priestley, T. J. (1997), Symmetries of a class of nonlinear third order partial differential equations, Math. Comput. Model, 25, 195–212.ClarksonP.A.MansfieldE.L.PriestleyT.J.1997Symmetries of a class of nonlinear third order partial differential equationsMath. Comput. Model2519521210.1016/S0895-7177(97)00069-1Search in Google Scholar
Baskonus, H. M. (2019), Complex soliton solutions to the Gilson-Pickering model, Axioms, 8, 18.BaskonusH.M.2019Complex soliton solutions to the Gilson-Pickering modelAxioms81810.3390/axioms8010018Search in Google Scholar
Clarkson, P. A., Mansfield, E. L. and Priestley, T. J. (1997), Symmetries of a class of nonlinear third-order partial differential equations, Mathl. Comput. Modeling Vol. 25, No. S/9, 195–212.ClarksonP.A.MansfieldE.L.PriestleyT.J.1997Symmetries of a class of nonlinear third-order partial differential equationsMathl. Comput. Modeling25S/919521210.1016/S0895-7177(97)00069-1Search in Google Scholar
Senol, M., Tasbozan, O. and Kurt, A. (2019), Comparison of two reliable methods to solve fractional Rosenau-Hyman equation, Mathematical Methods in the Applied Sciences. doi.org/10.1002/mma.5497.SenolM.TasbozanO.KurtA.2019Comparison of two reliable methods to solve fractional Rosenau-Hyman equationMathematical Methods in the Applied Sciencesdoi.org/10.1002/mma.5497Open DOISearch in Google Scholar
Yulita, R. and Noorani, M. S. M. (2012), Solving the fractional Rosenau-Hyman equation via variational iteration method and homotopy perturbation method, Int. J. Diff. Eq., 14.YulitaR.NooraniM.S.M.2012Solving the fractional Rosenau-Hyman equation via variational iteration method and homotopy perturbation methodInt. J. Diff. Eq.1410.1155/2012/472030Search in Google Scholar
Garralo’n, J. and Villatoro, F. R. (2012), Dissipative perturbations for the K(n,n) Rosenau-Hyman equation, Commun. Nonlinear Sci. Numer. Simulat., 17, 4642–4648.Garralo’nJVillatoroF.R.2012Dissipative perturbations for the K(n,n) Rosenau-Hyman equationCommun. Nonlinear Sci. Numer. Simulat.174642464810.1016/j.cnsns.2012.05.017Search in Google Scholar
Dehghan, M., Manafian, J. and Saadatmandi, A. (2012), Application of semi-analytical methods for solving the Rosenau-Hyman equation arising in the pattern formation in liquid drops, Int. J. Numer. Meth. Heat Fluid Flow, 22 (6), 777–790.DehghanM.ManafianJ.SaadatmandiA.2012Application of semi-analytical methods for solving the Rosenau-Hyman equation arising in the pattern formation in liquid dropsInt. J. Numer. Meth. Heat Fluid Flow22677779010.1108/09615531211244916Search in Google Scholar
El-Tawil, M. A. and Huseen, S. N. (2012), The Q-homotopy analysis method (Q-HAM), Int. J. Appl. Math. Mech., 8(15), 51–75.El-TawilM.A.HuseenS.N.2012The Q-homotopy analysis method (Q-HAM)Int. J. Appl. Math. Mech.815517510.12988/ijcms.2013.13048Search in Google Scholar
Iyiola, O., Soh, M. E. and Enyi, C. D. (2013), Generalised homotopy analysis method (q-HAM) for solving foam drainage equation of time fractional type, Math. Eng. Sci. Aerospace, 4(4), 105–116.IyiolaO.SohM.E.EnyiC.D.2013Generalised homotopy analysis method (q-HAM) for solving foam drainage equation of time fractional typeMath. Eng. Sci. Aerospace44105116Search in Google Scholar
Mohamed, M. S. and Hamed, Y. S. (2016), Solving the convection-diffusion equation by means of the optimal qhomotopy analysis method (Oq-HAM), Results Phys. 6, 20–25.MohamedM.S.HamedY.S.2016Solving the convection-diffusion equation by means of the optimal qhomotopy analysis method (Oq-HAM)Results Phys6202510.1016/j.rinp.2015.12.008Search in Google Scholar
Ayaz, F. (2003), On the two-dimensional differential transform method, Applied Mathematics and Computation, 1432(2–3), 361–374.AyazF.2003On the two-dimensional differential transform methodApplied Mathematics and Computation14322–336137410.1016/S0096-3003(02)00368-5Search in Google Scholar
Cakir, M. and Arslan, D. (2015), The Adomian decomposition method and the differential transform method for numerical solution of multi-pantograph delay differential equations, Applied Mathematics, 6(8), 1332–1343.CakirM.ArslanD.2015The Adomian decomposition method and the differential transform method for numerical solution of multi-pantograph delay differential equationsApplied Mathematics681332134310.4236/am.2015.68126Search in Google Scholar
Cakir, M. and Arslan, D. (2016), Reduced differential transform method for sixth-order Boussinesq equation, Mathematics and Statistics, 2:(014).CakirM.ArslanD.2016Reduced differential transform method for sixth-order Boussinesq equationMathematics and Statistics2014Search in Google Scholar
Chen, C. K. and Ho, S. H. (1999), Solving partial differential equations by two dimensional differential transform method, Applied Mathematics and Computation, 106, 171–179.ChenC.K.HoS.H.1999Solving partial differential equations by two dimensional differential transform methodApplied Mathematics and Computation10617117910.1016/S0096-3003(98)10115-7Search in Google Scholar
Zhou, J. K. (1986), Differential transformation and its applications for electrical circuits, Huazhong University Press, Wuhan, China.ZhouJ.K.1986Differential transformation and its applications for electrical circuitsHuazhong University PressWuhan, ChinaSearch in Google Scholar
Haghbin, A. and Hesam, S. (2012), Reduced differential transform method for solving seventh order Sawada-Kotera equations, The Journal of Mathematics and Computer Science, 5, 53–59.HaghbinA.HesamS.2012Reduced differential transform method for solving seventh order Sawada-Kotera equationsThe Journal of Mathematics and Computer Science5535910.22436/jmcs.05.01.06Search in Google Scholar
Hosseinzadeh, H. and Salehpour, E. (2013), Reduced differential transform method for solving partial differential equations with variable coefficients, Technical Journal of Engineering and Applied Sciences, 3788–3791.HosseinzadehH.SalehpourE.2013Reduced differential transform method for solving partial differential equations with variable coefficientsTechnical Journal of Engineering and Applied Sciences37883791Search in Google Scholar
Gupta, P. K. (2011), Approximate analytical solutions of fractional Benney-Lin equation by reduced differential transform method and the homotopy perturbation method, Computers Mathematics with Applications, 61(9), 2829–2842.GuptaP.K.2011Approximate analytical solutions of fractional Benney-Lin equation by reduced differential transform method and the homotopy perturbation methodComputers Mathematics with Applications6192829284210.1016/j.camwa.2011.03.057Search in Google Scholar
Mohamed, M. S. and Gepreel, K. A. (2017), Reduced differential transform method for nonlinear integral member of Kadomtsev-Petviashvili hierarchy differential equations, Journal of the Egyptian Mathematical Society, 25(1), 1–7.MohamedM.S.GepreelK.A.2017Reduced differential transform method for nonlinear integral member of Kadomtsev-Petviashvili hierarchy differential equationsJournal of the Egyptian Mathematical Society2511710.1016/j.joems.2016.04.007Search in Google Scholar
Rawashdeh, M. (2013), Using the reduced differential transform method to solve nonlinear pdes arises in biology and physics, World Applied Sciences Journal, 23, 1037–1043.RawashdehM.2013Using the reduced differential transform method to solve nonlinear pdes arises in biology and physicsWorld Applied Sciences Journal2310371043Search in Google Scholar
Saravanan, A. and Magesh, N. (2013), A comparison between the reduced differential transform method and the Adomian decomposition method for the Newell-Whitehead-Segel equation, Journal of the Egyptian Mathematical Society, 21(3), 259–265.SaravananA.MageshN.2013A comparison between the reduced differential transform method and the Adomian decomposition method for the Newell-Whitehead-Segel equationJournal of the Egyptian Mathematical Society21325926510.1016/j.joems.2013.03.004Search in Google Scholar
Srivastava, V. K., Mishra, N., Kumar, S., Singh, B. K. and Awasthi, M. K. (2014), Reduced differential transform method for solving (1 + n)-dimensional burgers equation, Egyptian Journal of Basic and Applied Sciences, 1(2), 115–119.SrivastavaV.K.MishraN.KumarS.SinghB.K.AwasthiM.K.2014Reduced differential transform method for solving (1 + n)-dimensional burgers equationEgyptian Journal of Basic and Applied Sciences1211511910.1016/j.ejbas.2014.05.001Search in Google Scholar
Chen, C. K., Lai, H. Y. and Liu, C. C. (2009), Nonlinear micro circular plate analysis using hybrid differential transformation / finite difference method, CMES 40, 155–174.ChenC.K.LaiH.Y.LiuC.C.2009Nonlinear micro circular plate analysis using hybrid differential transformation / finite difference methodCMES40155174Search in Google Scholar
Chu, S. P. (2014), Hybrid differential transform and finite difference method to solve the nonlinear heat conduction problems, WHAMPOA - An Interdisciplinary Journal, 66, 15–26.ChuS.P.2014Hybrid differential transform and finite difference method to solve the nonlinear heat conduction problemsWHAMPOA - An Interdisciplinary Journal66152610.1016/j.cnsns.2007.03.002Search in Google Scholar
Chu, H. P. and Chen, C. L. (2008), Hybrid differential transform and finite difference method to solve the nonlinear heat conduction problem, Communication in Nonlinear Science and Numerical Simulation, 13, 1605–1614.ChuH.P.ChenC.L.2008Hybrid differential transform and finite difference method to solve the nonlinear heat conduction problemCommunication in Nonlinear Science and Numerical Simulation131605161410.1016/j.cnsns.2007.03.002Search in Google Scholar
Sungu, I. and Demir, H. (2012), Solutions of the system of differential equations by differential transform / finite difference method, Nwsa-Physical Sciences, 7, 1308–7304.SunguI.DemirH.2012Solutions of the system of differential equations by differential transform / finite difference methodNwsa-Physical Sciences713087304Search in Google Scholar
Sungu, I, and Demir, H. (2015), A new approach and solution technique to solve time fractional nonlinear reaction-diffusion equations, Hindawi Publishing Corporation Mathematical Problems in Engineering, 13 pages.SunguIDemirH.2015A new approach and solution technique to solve time fractional nonlinear reaction-diffusion equationsHindawi Publishing Corporation Mathematical Problems in Engineering1310.1155/2015/457013Search in Google Scholar
Sungu, I, and Demir, H. (2012), Application of the hybrid differential transform method to the nonlinear equations, Applied Mathematics, 3, 246–250.SunguIDemirH.2012Application of the hybrid differential transform method to the nonlinear equationsApplied Mathematics324625010.4236/am.2012.33039Search in Google Scholar
Yeh, Y. L. Wang, C. C. and Jang, M. J. (2007), Using finite difference and differential transformation method to analyze of large deflections of orthotropic rectangular plate problem, Applied Mathematics and Computation 190(2007), 1146–1156.YehY.L.WangC.C.JangM.J.2007Using finite difference and differential transformation method to analyze of large deflections of orthotropic rectangular plate problemApplied Mathematics and Computation19020071146115610.1016/j.amc.2007.01.099Search in Google Scholar
Cattani, C., Sulaiman, T. A., Baskonus, H. M. and Bulut, H. (2018), Solitons in an inhomogeneous Murnaghan’s rod, European Physical Journal Plus, 133(228), 1–12.CattaniC.SulaimanT.A.BaskonusH.M.BulutH.2018Solitons in an inhomogeneous Murnaghan’s rodEuropean Physical Journal Plus13322811210.1140/epjp/i2018-12085-ySearch in Google Scholar
Cattani, C., Sulaiman, T. A., Baskonus, H. M. and Bulut, H. (2018), On the soliton solutions to the Nizhnik-Novikov-Veselov and the Drinfel’d-Sokolov systems, Optical and Quantum Electronics, 50(3), 138.CattaniC.SulaimanT.A.BaskonusH.M.BulutH.2018On the soliton solutions to the Nizhnik-Novikov-Veselov and the Drinfel’d-Sokolov systemsOptical and Quantum Electronics50313810.1007/s11082-018-1406-3Search in Google Scholar
Ciancio, A., Baskonus, H. M., Sulaiman, T. A. and Bulut, H. (2018), New structural dynamics of isolated waves via the coupled nonlinear Maccari’s system with complex structure, Indian Journal of Physics, 92(10), 1281–1290.CiancioA.BaskonusH.M.SulaimanT.A.BulutH.2018New structural dynamics of isolated waves via the coupled nonlinear Maccari’s system with complex structureIndian Journal of Physics92101281129010.1007/s12648-018-1204-6Search in Google Scholar
Baskonus, H. M., Sulaiman, T. A. and Bulut, H. (2018), Novel complex and hyperbolic forms to the strain wave equation in micro structured solids, Optical and Quantum Electronics, 50(14), 1–9.BaskonusH.M.SulaimanT.A.BulutH.2018Novel complex and hyperbolic forms to the strain wave equation in micro structured solidsOptical and Quantum Electronics50141910.1007/s11082-017-1279-xSearch in Google Scholar
Yel, G., Baskonus, H. M. and Bulut, H. (2017), Novel archetypes of new coupled Konno–Oono equation by using sine-Gordon expansion method, Optical and Quantum Electronics, 49(285), 1–10.YelG.BaskonusH.M.BulutH.2017Novel archetypes of new coupled Konno–Oono equation by using sine-Gordon expansion methodOptical and Quantum Electronics4928511010.1007/s11082-017-1127-zSearch in Google Scholar
