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200 14$aThe Mobile Commerce Prospects: A Strategic Analysis of Opportunities in the Banking Sector
210   $aHamburg$cHamburg University Press$d2007
215   $a1 online resource (233) 
311   $a3-937816-31-3 
330   $aMobile Commerce has gained increasing acceptance amongst various sections of the society in previous years. The reasons for its growth can be traced back to technological and demographical developments that have influenced many aspects of the socio-cultural behaviour in today's world. The need (and/or wish) for mobility seems to be the driving force behind Mobile Commerce. The launch of UMTS technology has provided Mobile Commerce with the necessary verve.Mobile Banking presents an opportunity for banks to retain their existing, technology-savvy customer base by offering value-added, innovative services and to attract new customers from corresponding sections of the society. The customer survey provides evidence that such sections in the meanwhile include the affluent and financially relevant groups of the society in Germany. The time seems to be ripe to convert this non-negligible customer interest into business-driving customer demand. A proactive attitude on the part of the banks seems to be therefore recommendable.Many banks in Germany have come to regard Mobile Banking as a necessary tool for thwarting negative differentiation vis-à-vis rivals and to foster/retain an innovative image. This self-reinforcing dynamism is expected to gain currency in near-future so that Mobile Banking services could soon advance to a standard product - on the lines of Online Banking - offered by more or less each and every bank.
517   $aMobile Commerce Prospects
606   $aComputer programming / software development$2bicssc
615  7$aComputer programming / software development
700   $aTiwari$b Rajnish$4aut$0972844
702   $aBuse$b Stephan$4aut
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200 10$aMultiscale problems$b[electronic resource] $etheory, numerical approximation and applications /$feditors, Alain Damlamian, Bernadette Miara, Tatsien Li
210   $aBeijing, China $cHigher Education Press$d2011
215   $a1 online resource (314 p.)
225 1 $aSeries in contemporary applied mathematics ;$v16
300   $aDescription based upon print version of record.
311   $a981-4366-88-9 
320   $aIncludes bibliographical references.
327   $aPreface; Contents; Alain Damlamian An Introduction to Periodic Homogenization; 1 Introduction; 2 The main ideas of Homogenization; The three steps of Homogenization; 3 The model problem and three theoretical methods; 3.1 The multiple-scale expansion method; 3.2 The oscillating test functions method; 3.2.1 The proof of Theorem 3.4; 3.2.2 Convergence of the energy; 3.3 The two-scale convergence method; References; Alain Damlamian The Periodic Unfolding Method in Homogenization; 1 Introduction; 2 Unfolding in Lp-spaces; 2.1 The unfolding operator T; 2.2 The averaging operator U
327   $a2.3 The connection with two-scale convergence2.4 The local average operator M; 3 Unfolding and gradients; 4 Periodic unfolding and the standard homogenization problem; 4.1 The model problem and the standard homogenization result; 4.2 The Unfolding result: the case of strong convergence of the right-hand side; 4.3 Proof of Theorem 4.3; 4.4 The convergence of the energy and its consequences; 4.5 Some corrector results and error estimates; 4.6 The case of weak convergence of the right-hand side; 5 Periodic unfolding and multiscales; 6 Further developments; References
327   $aGabriel Nguetseng and Lazarus Signing Deterministic Homogenization of Stationary Navier-Stokes Type Equations1 Introduction; 2 Periodic homogenization of stationary Navier-Stokes type equations; 2.1 Preliminaries; 2.2 A global homogenization theorem; 2.3 Macroscopic homogenized equations; 3 General deterministic homogenization of stationary Navier-Stokes type equations; 3.1 Preliminaries and statement of the homogenization problem; 3.2 A global homogenization theorem; 3.3 Macroscopic homogenized equations; 3.4 Some concrete examples
327   $a4 Homogenization of the stationary Navier- Stokes equations in periodic porous media4.1 Preliminaries; 4.2 Homogenization results; References; Patricia Donato Homogenization of a Class of Imperfect Transmission Problems; 1 Introduction; 2 Setting of the problem and main results; 3 Some preliminary results; 4 A priori estimates; 5 A class of suitable test functions; 5.1 The test functions in the reference cell Y; 5.2 The test functions in; 6 Proofs of Theorems 2.1 and 2.2; 6.1 Identification of 1 + 2; 6.2 Identification of  1 and  2 for -1 <  < 1; 6.3 Identification of u2
327   $a7 Proof of Theorem 2.4 (case  > 1)7.1 A priori estimates; 7.2 Identification of 1; 7.3 Identification of 2; References; Georges Griso Decompositions of Displacements of Thin Structures; 1 Introduction; 2 The main theorem; 2.1 Poincar ?e-Wirtinger's inequality in an open bounded set star-shaped with respect to a ball; 2.2 Distances between a displacement and the space of the rigid body displacements; 3 Decomposition of curved rod displacements; 3.1 Notations; 3.2 Elementary displacements and decomposition; 4 Decomposition of shell displacements; 4.1 Notations and preliminary
327   $a4.2 Elementary displacements and decompositions
330   $aThe focus of this is on the latest developments related to the analysis of problems in which several scales are presented. After a theoretical presentation of the theory of homogenization in the periodic case, the other contributions address a wide range of applications in the fields of elasticity (asymptotic behavior of nonlinear elastic thin structures, modeling of junction of a periodic family of rods with a plate) and fluid mechanics (stationary Navier-Stokes equations in porous media). Other applications concern the modeling of new composites (electromagnetic and piezoelectric materials) 
410  0$aSeries in contemporary applied mathematics ;$v16.
606   $aHomogenization (Differential equations)$vCongresses
606   $aDifferential equations, Nonlinear$vCongresses
606   $aMathematical analysis$vCongresses
615  0$aHomogenization (Differential equations)
615  0$aDifferential equations, Nonlinear
615  0$aMathematical analysis
676   $a515.353
676   $a518.5
686   $aSK 950$2rvk
701   $aDamlamian$b Alain$0768005
701   $aMiara$b Bernadette$01149832
701   $aLi$b Daqian$0755910
801  0$bMiAaPQ
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801  2$bMiAaPQ
906   $aBOOK
912   $a9910779068003321
996   $aMultiscale problems$93810910
997   $aUNINA