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ISRN Applied Mathematics
Volume 2012 (2012), Article ID 379547, 30 pages
Robust Numerical Methods for Singularly Perturbed Differential Equations: A Survey Covering 2008–2012
TU Dresden, 01062 Dresden, Germany
Received 22 October 2012; Accepted 7 November 2012
Academic Editors: S. W. Gong, X. Liu, and S. Sture
Copyright © 2012 Hans-Görg Roos. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
We present new results in the numerical analysis of singularly perturbed convection-diffusion-reaction problems that have appeared in the last five years. Mainly discussing layer-adapted meshes, we present also a survey on stabilization methods, adaptive methods, and on systems of singularly perturbed equations.
Since the publication of  many new ideas in the numerical analysis of singularly perturbed differential equations appeared. Some of them are contained in  on layer-adapted meshes, some mentioned in the (very short) overview  for the years 2000–2009. In this survey we try to sketch the most important new developments of the last five years, but, of course, the choice is inevitably personal and reflects our own main interests.
We mostly discuss linear convection-diffusion-reaction problems in the case of partial differential equations and present results for boundary value problems of ordinary differential equations only in exceptional cases. One exception is Section 5 on singularly perturbed systems. In Section 2 we describe mostly stabilization methods including discontinuous Galerkin on shape-regular meshes. Uniform estimates with respect to the perturbation parameter are discussed in Section 3, while adaptive methods based on a posteriori error estimation are the contents of Section 4.
2. Semi-Robust Methods
2.1. Steady-State Problems
We consider the two-dimensional convection-diffusion problem
where is a small positive parameter, are smooth, and . Assuming the given problem admits a unique solution , for convex we have moreover .
Let us introduce the -weighted norm by Then for the Galerkin finite element method with piecewise linear or bilinear elements one can prove ( denotes a generic constant that is independent of and of the mesh) on quite general triangulations. However, estimate (2.4) is of no worth: in general, tends to infinity for due to the presence of layers. The very weak stability properties of standard Galerkin lead to wild nonphysical oscillations in the discrete solution.
Therefore, stabilized Galerkin methods should be used. Most stabilized methods modify the standard Galerkin method: find some element from a finite element space such that Instead, a stabilized method satisfies where represents a stabilization term. If the discrete bilinear form is uniformly -elliptic with respect to (or satisfies some inf-sup condition) in some norm , stronger than the -weighted norm, then one can typically prove on a shape-regular mesh for piecewise polynomials of degree Although often is independent of and , the factor , in general, depends strongly on . Thus we call these methods “semi-robust.” Often, one can prove local versions of that estimate which show the numerical solution to behave fine away from layer regions.
The streamline-diffusion FEM (SDFEM or SUPG-streamline upwind Petrov-Galerkin) is the most popular stabilization method. In the SDFEM we have moreover The streamline-diffusion parameters are user chosen. The SDFEM is consistent, that is, Therefore, one can use the orthogonality property for all in the error estimate. Introducing the streamline-diffusion norm we have for bounded coercivity of the bilinear form in the -norm and the error estimate (2.7).
There are many variants of SDFEM, see, for example, the surveys [4, 5]. Here we shall not discuss these variants and other methods closely related to SDFEM like residual free bubbles (RFB) or variational multiscale methods (VMS), see [1, 6–9].
The SDFEM solution is not free of oscillations. See Section in  for the analysis of the related difference equations and its oscillation properties. Similar behavior can be expected for all other stabilization techniques we are going to discuss, although we are not aware of a rigorous analysis for these methods analogously to that of SDFEM.
In 1D one can choose for a problem with constant coefficients in such a way that the discrete solution is exact at the nodes. In two dimensions is usually determined by minimizing the factor under constraints on guaranteeing coercivity. In  the authors propose the smart choice where is the Euclidean norm of the wind at the element center and the element length in the direction of the wind. But for anisotropic meshes the optimal choice of the -parameter is not clear. Later we shall see that near characteristic layers (2.12) is not optimal.
The choice of the -parameter is still the topic of several recent papers. Sometimes the relation between SDFEM and RFB or VMS is used to define new formulae , sometimes just the oscillation properties near boundaries are carefully studied [12, 13] or even optimization methods are used a posteriori .
Because of the observation that solutions computed with SDFEM often possess spurious oscillations in the vicinity of layers, a number of spurious oscillations at layers diminishing (SOLD) methods have been developed. A critical survey of these methods and a number of numerical studies can be found in [15–17].
In  the authors compare the performance of several numerical schemes: an exponentially fitted finite volume scheme (see Section 3), SDFEM, SDFEM with SOLD, continuous interior penalty (CIP), a discontinuous Galerkin method (dG), and a FEM scheme with flux-correction-transport (FCT). The authors draw the conclusion that a favored method could not be identified and there is still the need to construct better methods than those which are currently available!
We now comment on the methods just mentioned, and moreover on LPS (local projection stabilization), which was not discussed in .
CIP is characterized by the symmetric stabilization term which adds jumps of the streamline derivative on interior edges to the Galerkin bilinear form . In  it was pointed out that it is extremely useful to incorporate the Dirichlet boundary conditions weakly. Similarly to SDFEM, a nonlinear term of SOLD-type can be added to the CIP method as proposed in . Tests with several SOLD-terms turned out that the results for CIP-SOLD were generally worse than the results for SDFEM-SOLD .
Much more activity in the last years was directed on LPS, another (inconsistent) symmetric stabilization method. LPS preserves the stability properties of residual-based stabilizations, but LPS is symmetric. Therefore, the analysis of unsteady problems is simpler than for SDFEM (see the next subsection) and applied to optimization problems, discretization, and optimization commute.
The most general version of LPS for convection-diffusion problems was described and analyzed in . Let be a set consisting of a finite number of open subsets of with certain properties , a continuous linear projection operator which maps the space onto some finite-dimensional subspace . Denote by a piecewise constant approximation of and by the so-called fluctuation operator. Then, LPS is characterized by (see also [23–26]).
Surprisingly, under mild conditions LPS is now stable in a norm containing additionally a streamline-derivative term, namely, with More precisely, satisfies for the inf-sup-condition In contrast to the traditional error analysis of LPS , there is no need to use special interpolation operators in the error estimation of the convection term. See also  for some insight in the stabilization mechanism of Galerkin discretizations of higher order.
In  the authors compare the one-level and the two-level approach of LPS, see also , while in  even exponentials are used instead of bubbles to enrich the finite element space in a one-level version of LPS.
In general, dG methods impose Dirichlet boundary conditions weakly. Surprisingly, only in the last years it was observed that in many cases one should prefer weakly imposed boundary conditions, see [20, 37, 38]. Recently  it was proved that the nonsymmetric Nitsche-type method is stable without penalty. Actually, hybrid dG attracts a lot of attention. The key idea of hybrid dG is to introduce additional degrees of freedom at interfaces. For hybrid primal dG see , for mixed hybrid , for convection-reaction-diffusion problems [42–44]. The so called DPG method combines the method of Bottasso et al. [45, 46] with the concept of “optimal” test functions, see [47–49]. There exist also several proposals to combine continuous and discontinuous Galerkin ideas, for instance, [50, 51].
Remark that the numerical experiments in  are only performed for the SIP and NIP version of dG. Thus a final assessment of the many existing dG versions in comparison with other stabilization techniques remains open.
Algebraic flux correction methods (FEM-FCT) are not mentioned in  but achieve in many cases good numerical results. But the methods are nonlinear, and based on the assessment in  quite inefficient for linear convection-diffusion problems. The methods start with a standard discretization, like the Galerkin finite element method. Then, the resulting matrices are changed in order to obtain, for instance, a positivity preserving, but still too diffusive scheme. In a second step the diffusion is locally removed using an appropriate antidiffusive term, see [52, 53].
2.2. Unsteady Problems
We consider the parabolic initial-boundary value problem
Again, standard Galerkin in space is unsuitable and one combines a stabilization technique in space with some discretization in time with nice stability properties, in the simplest case Euler implicit.
For the symmetric stabilization techniques mentioned in Section 2.1, there are semi-robust error estimates in norms typically used for parabolic problems in the literature. Reference  combines CIP or LPS with the -scheme or BDF2 in time,  combines LPS with dG in time while dG in space and time is analyzed in . Reference  study a two stage IMEX RK scheme, where a symmetric stabilization is used and stabilization and convection are handled explicitly, but diffusion implicitly. For non-linear convection-diffusion problems, dG in space and several discretizations in time, see [58, 59].
Streamline diffusion (and other non-symmetric methods) still offer open problems. For consistency reasons, the stabilization term reads and the term which corresponds to testing the derivative in time with the streamline derivative causes trouble. If, for instance, implicit Euler is used for the time discretization with step size , the standard analysis in the convection-dominated regime leads to But it seems not appropriate that the stabilization term disappears if the time step goes to zero. See the detailed discussion in . For semi-discretization in space, optimal error estimates are proved in [60, 61], see also .
3. Uniformly Convergent Methods
3.1. Standard Meshes
Consider the convection-diffusion-reaction problem with where and is polygonal and convex. Let us discretize (3.1) with standard finite elements on a shape-regular mesh. We ask: is it possible to have uniform convergence with respect to in the -weighted norm, that is, and independent of ?
Remark 3.1. Estimates analogously to (3.4) are also known for the fourth-order problem
See  for the first result in that direction and  for a detailed discussion and further references.
A result like (3.4) is possible because the -weighted norm is not balanced with the layer structure, the typical layer term of the reaction-diffusion problem ( in (3.1)) gives We conjecture that for convection-diffusion problems with uniform convergence on standard meshes is also possible if the layers are relatively weak. This can happen for on ( is characteristic) or for other boundary conditions generating weak layers.
Now let us discuss the case of strong layers and uniform convergence on standard meshes. What is new?
Reference  repeat the known fact that in a Petrov-Galerkin scheme it is favorable to use local Green's functions as test functions. But, unfortunately, in 2D those functions cannot be derived in a closed analytical form. Therefore, the authors present a semi-analytical approach.
Optimal test functions play also an important role in the papers [47, 68, 69]. Assuming for the related bilinear form and the inf-sup condition optimal test functions are constructed as follows: If , define by It is remarkable that then the discrete inf-sup condition follows (and, consequently, stability) and, moreover where (see also the discussion in , pages 88–90). In the next step the test functions are approximated; new is the idea to do that in combination with discontinuous Galerkin methods.
Another old idea is to construct difference schemes in such a way that the coefficients of the scheme satisfy certain exactness conditions, including exponentials. Han and Huang call that “tailored finite point method,” see . The error analysis uses an assumption of the type (for the case of a characteristic layer of width ) such that the layer term is small in the interior mesh points.
For exponentials on triangles (see Remark 3.104 in ), there is still no satisfactorily uniform convergence result in 2D, although it is repeatedly the subject of actual research [71, 72]. Let us finally mention  where similar to papers for semiconductor problems [74, 75] an exponential transformation is used to generate a symmetric problem which is approximated by means of a suitable discontinuous Galerkin scheme.
3.2. Layer-Adapted Meshes
3.2.1. Solution Decomposition and Meshes Used
In the simplest case of a one-dimensional problem with an exponential boundary layer at one can estimate where depends on the regularity of the data of the problem. Surprisingly, (3.12) is equivalent to the existence of a decomposition of the solution into a smooth part and a layer component with We call such a decomposition -decomposition because it was introduced by Shishkin to analyze upwind finite difference schemes.
In two dimensions sufficient conditions for the existence of such a decomposition are known in certain special cases and for small values of only: for convection-diffusion problems with exponential layers and for some problems with characteristic layers; see [76–79].
For the analysis and supercloseness analysis of linear and bilinear finite elements for a convection-diffusion problem with exponential layers, one assumes typically the existence of a solution decomposition such that
for all and .
The validity of (3.14a), (3.14b), and (3.14c) requires additional compatibility conditions of the data at the corners which are sometimes unrealistic. Therefore, it is reasonable to search for analysis techniques of FEM on layer-adapted meshes that use the pointwise information of (3.14a), (3.14b) and (3.14c) for, say only, and weaker information for certain third-order derivatives. We are not going to discuss this issue in detail here and refer the reader to . For the analysis of higher order finite element methods one requires a solution decomposition with analogous information on higher order derivatives.
Based on the above solution decomposition we construct layer-adapted meshes. Let us assume that for a one-dimensional problem on the interval a layer of type is located at . As early as 1969, Bakhvalov  proposed a special mesh with mesh points near given by The parameter determines how many mesh points are used to resolve the layer, while controls the spacing within the layer region. Outside the layer an equidistant mesh is used. To be precise, Bakhvalov's mesh is specified by , , where Here is a transition point between the fine and coarse submeshes. Originally Bakhvalov chose to ensure that the mesh generating function lay in with . However the explicit definition is also possible and gives a mesh we shall refer to as a B-type mesh.
From the numerical point of view, the choice of the transition point should reflect the smallness of the layer term with respect to the discretization error instead of the smallness with respect to . Assume the formal order of the method to be . Then imposing yields the choice for the transition point. We call a mesh an S-type mesh if it is generated by In particular, when , the mesh generated is piecewise equidistant. This S-mesh was introduced by Shishkin in 1988. For surveys concerning layer adapted meshes, see [2, 81, 82].
The analysis of certain difference methods for one-dimensional problems in  shows: if the pointwise error of a particular method on an S-mesh is proportional to , then on a B-type mesh (and on S-type meshes with certain optimality properties of the function ) the error is of order .
For finite element methods the situation is different. So far, except for , there are no optimal error estimates for B-type meshes. If a transition point in the sense of Bakhvalov is used and a piecewise constant or locally uniform meshes, then the error weakly depends on (see ). In some papers, for instance in , the different impact of the choice of the transition point in the sense of Bakhvalov or Shishkin is discussed. On a piecewise constant or polynomial graded mesh (i.e., not on the original Bakhvalov mesh) the authors of  demonstrate numerical results which indicate the different error behavior on these two types of meshes.
The simple structure of S-type meshes allows error estimates for many methods as we will see in Section 3.2.2. For simplicity, we restrict ourselves often to S-meshes in this paper—in most cases a generalization of the results to S-type meshes is possible.
For the two-dimensional problem (2.1a) and (2.1b) in with exponential boundary layers let us define This definition allows to include the non-singularly perturbed case. Divide the domain as in Figure 1.
The nodes of our rectangular mesh are obtained from the tensor product of a set of points in -direction and points in -direction. A one-dimensional Shishkin mesh is characterized by an equidistant mesh size in and in , in the transition point the mesh switches from coarse to fine. For simplicity, let us assume Thus How to choose ? For linear or bilinear elements one often chooses (or in supercloseness estimates), for elements based on the polynomial degree we take .
Remark 3.2. In the case , the parabolic boundary layers at and are of width . Therefore, they require a different choice of transition point in -direction: , while remains unchanged; see Figure 2.
For more complicated domains the construction of layer-adapted meshes is of course much more involved; see, for instance,  for a description of the generation of such meshes. If one wants to use non-matching grids, it can be useful to apply Nitsche-mortaring, see .
As also mentioned in , layer-adapted meshes can also be generated using a monitor function or defined recursively. We do not know any paper which analyses layer-adapted meshes defined via a monitor-function in 2D. Assume recursively (first for a 1D problem) We call a mesh G-type mesh (after Gartland), if is of the type while a D-type mesh (after Duran) for convection-diffusion problems is characterized by Finite element methods for G-type meshes in 2D were analysed already 1997 in , for a more recent result for higher order equations but 1D see . Convergence results on D-meshes we shall comment in the next section.
3.2.2. Error Estimates and Supercloseness
For the Galerkin finite element method on Shishkin meshes we know since [90, 91] for convection-diffusion problems with exponential layers and linear or bilinear elements improved for the more general S-type meshes in . Bakhvalov-type meshes are more complicated to analyze, so far we have  with for and . On D-meshes and problems with exponential layers it was proved  D-type meshes are locally uniform (or locally quasi-equidistant), thus it could be that some dependence of the error of is necessary. See the detailed discussion in .
For problems with characteristic or parabolic boundary layers and S-type meshes, see . Remark that optimal error estimates in the norm for the Galerkin method on layer-adapted meshes in 2D are unknown.
In  the authors state that a layer-adapted mesh alone cannot stabilize a scheme in all cases, “a common believe of the community of Shishkin type grids.” But nobody in the community is this stupid; moreover, the authors do not understand the nature of the example presented. In a test case of a problem with characteristic layers and the Galerkin approximation on a Shishkin mesh oscillates strongly depending whether or not the number of mesh points used in the streamline direction is odd or not. The reason: in the continuous problem there is no control on the norm, the continuous problem is already unstable. For an analogous example with this phenomenon disappears.
It was first observed numerically in  that both for a Galerkin method and for streamline diffusion the convergence rates in for linear and bilinear elements on different significantly: the rates for bilinears are twice the rates for linears! This fact can be explained with superconvergence phenomena (supercloseness) for bilinears and is the reason for us to prefer bilinears in layer regions. Thus we have for bilinear elements on a Shishkin mesh (see ) the supercloseness result Supercloseness allows optimal estimates in and is also an important property concerning postprocessing. Often the so called Lin identities for bilinears, see for example , are used to prove supercloseness.
In  Stynes and Tobiska analyzed the SDFEM for bilinears on an S-mesh. The SD-parameter is chosen by—assuming throughout that — A detailed analysis shows, for instance, on the stabilization parameter should satisfy . This value is much smaller than the natural diffusion parameter and therefore, switching of the stabilization by setting is reasonable.
The final supercloseness result reads However, if bilinear elements are used in the layer region on , but linear elements on the coarse-mesh region , then only the standard ingredients of the SDFEM analysis are available to estimate the error contribution on . Fortunately, on the layer components are small. One obtains for the method on a hybrid mesh consisting of rectangles and triangles  Remark that recently  pointwise error estimates were proved for the SDFEM with bilinears on a Shishkin mesh for problems with exponential layers, for linear elements see .
For the problem with characteristic boundary layers it is more difficult to tune the SD-parameter. In the region (see Figure 2) the recommendation (2.12) gives , but this choice is not appropriate . For bilinears it was shown in  that should be satisfied.
Consider a family of S-meshes where we require to be even. Then we can build a coarser mesh composed of disjoint macro rectangles , each comprising four mesh rectangles from , where belongs to only one of the four domains . Associate with each macro rectangle an interpolation operator defined by standard biquadratic interpolation. As usual, can be extended to a continuous global interpolation operator , where is the space of piecewise quadratic elements.
Then properties (7.2), (7.3) and (7.4) of —approximation property, stability of and consistency of —give The proof starts from the consistency of : Then the stability of is applied in order to give The terms on the right-hand side will be bounded using the approximation property of and the supercloseness of the method.
However, when linear elements on triangles are used in , supercloseness results are known only for special triangulations. Moreover, only for isosceles and Friedrichs-Keller triangulations postprocessing procedures are presented in .
One can also prove supercloseness on D-meshes, see  for bilinear elements and convection-diffusion problems with exponential layers. Unfortunately, the final error estimate contains the factor . In  the authors study reaction-diffusion problems and prove energy norm estimates for a graded mesh which is independent of the perturbation parameter . But for such a mesh one cannot have point-wise convergence uniformly in and we conjecture that this result is only possible because the norm is not balanced. For some nonconforming method, see .
For higher order finite elements one can prove the expected error estimates on layer-adapted meshes if one has enough smoothness of the solution and a corresponding solution decomposition. But what about supercloseness for elements?
For the Galerkin finite element method this seems to be an open question, see however the numerical experiments in . For SDFEM it was proved in  Here instead of the standard interpolant the so called vertices-edge-interpolant is used. See also .
Now, let us discuss other stabilization methods on layer-adapted meshes. Often stabilization is only used on the coarse part of the mesh.
First, let us discuss the CIP method for a convection-diffusion problem with exponential layers. Using bilinears and Galerkin in the layer region, otherwise CIP stabilization one can prove for a “mixed” interpolant see  for details of the analysis. The case of characteristic layers is discussed in .
Next we consider the local-projection stabilization on the coarse mesh region of our S-mesh for a problem with exponential layers. We consider the version of LPS-schemes characterized by enrichment of the original finite element space and the use of a single mesh rather than the version based on macro meshes. The stabilization term is given by For the LPS-scheme let be the finite element space consisting of bilinears on and linear elements enriched by a single bubble per element on . Furthermore, let project onto the space of piecewise constants on the triangulation of .
For the analysis of the method a special interpolant of a given function is used. On a triangle it is defined by Note, used on and the standard bilinear interpolant used in match continuously. We call its composite .
The well known results for the bilinear Galerkin method in the layer region and the technique of  give In  the author considers -elements for enriched by six additional functions (such that the element contains ) and local projection stabilization on with . The resulting error estimates are however not optimal; it is better not to enrich the space on as in . Here it is proved for enriched elements on the coarse mesh For problems with characteristic layers, see .
It is also possible to combine the Galerkin finite element method with bilinears in the layer region with discontinuous Galerkin on the coarse mesh.
For NIPG (non-symmetric interior penalty) in the associated dG-norm the supercloseness result was proved in . Here denotes the -projection onto and , respectively, on , but the standard bilinear interpolant on .
For the so-called local discontinuous Galerkin method LDG see [85, 117]. The authors present numerical studies which indicate superconvergence phenomena as well for the norm of the solution as for the one side flux. A first convergence analysis in 2D for problems with exponential layers and bilinear elements was presented in . Recently, a new type of error analysis for elements on Shishkin meshes resulted in a surprising statement: uniform convergence of order for in a dG version of the -weighted energy norm .
For edge stabilization and LPS-stabilization with bilinears one can use the same recovery technique as for SDFEM to get improved approximations with respect to . This is because the finite element spaces used are continuous. However, for dGFEM recovery on requires new ingredients. See, for instance, .
It is possible to apply the so called two-scale finite element method also for singularly perturbed problems on Shishkin meshes. Writing for the maximum number of mesh intervals in each coordinate direction of a tensor-product mesh for bilinear elements, the combination method simply adds or subtracts solutions that have been computed on , and meshes. It is shown for a convection-diffusion problem with exponential layers , that the combination FEM yields (up to a factor ) the same order of accuracy as the Galerkin FEM on an mesh. But it requires only degrees of freedom compared with the used by the Galerkin FEM. For a reaction-diffusion problem, see .
Next we comment recent results concerning balanced norms. Let us first consider reaction-diffusion problems.
When linear or bilinear elements are used on a Shishkin mesh, one can prove under certain additional assumptions concerning for the interpolation error of the Lagrange interpolant on Shishkin meshes (see  or ). For a reaction-diffusion problem it follows immediately that the error also satisfies such an estimate.
However, the typical boundary layer function measured in the norm is of order . That means: for reaction-diffusion problems, the standard energy norm is not balanced. Consequently, error estimates in this norm are less valuable as for convection diffusion equations where the layers are of the structure . Wherefore we first ask the question:
Is it possible to prove error estimates in the balanced norm
A proof is not trivial because the related bilinear form is not coercive with respect to the balanced norm. New ingredients are needed to prove for the Galerkin FEM, see . In  the authors introduce a mixed finite element method and prove also uniform convergence in a new balanced norm.
For convection-diffusion problems with exponential layers only the energy norm is fine and balanced. If, however, layers of different structure exist an error estimate in a balanced norm is stronger than an estimate in the standard energy norm. Consider, for instance, the boundary value problem
with exponential and characteristic layers. Here a balanced norm is given by Again the error analysis in that norm is not easy but could be realized for a version of the SDFEM on the corresponding Shishkin mesh, see .
There exists also an attempt to simulate Shishkin mesh structures and in this way implicitly to stabilize the FEM even in domains with nontrivial geometries .
In general, in the analysis of discretization methods on layer-adapted meshes relatively strong assumptions concerning the smoothness of the solution are posed. Concerning finite difference methods and reaction-diffusion problems, exceptions are [127, 128]. In  the domain is L-shaped, such that one has only . In  a Dirichlet and a Neumann condition meet in the corner of a square, thus with . For finite element methods and reaction-diffusion problems on polygonal domains, see .
The first paper on finite elements on layer-adapted meshes for convection-diffusion problems with a corner singularity is . The authors study a problem with characteristic layers
but without compatibility conditions in the corners, such that in each corner one has a singularity of the type in the solution. For the Galerkin FEM and SDFEM on a classical Shishkin mesh uniform first order convergence is proved. It remains open whether or not supercloseness holds. In  even a problem with a discontinuity in the boundary condition in an inflow corner is studied numerically.
For a convection-diffusion problem with exponential boundary layers in a domain , a square sheared into a parallelogram with interior angle , in  the authors study the supercloseness property of the Galerkin-FEM and SDFEM on Shishkin meshes. Because , new ingredients are required to prove supercloseness. The final supercloseness estimate takes the form with some . See also . For point-wise error estimates of finite difference methods and non-smooth solutions of convection-diffusion problems, see [133, 134].
For unsteady problems of the form
there exist only a few papers from the last years combining some discretization in time with a discretization in space using a layer-adapted mesh.
In  the authors use implicit Euler in time and a second order difference method on a Shishkin mesh and prove for a problem 1D in space In  the given problem was discretized with the -scheme in time and the Galerkin FEM on a Shishkin mesh. In a norm adapted to the nature of the parabolic problem it was proved Using BDF2 with respect to time the order in was improved in . In a recent paper dG in time of arbitrary order is combined with some finite element method in space, see .
4. Adaptive Methods
Adaptive methods refine the mesh (-method) or change locally the polynomial degree (-method) based on an a posteriori error estimator . should be locally computable based on the actual numerical solution and input data. Moreover, preferably should be equivalent to the error in some norm: (remark that in the DWR method one tries to control some functional instead of the norm). If for a singularly perturbed problem the constants are independent of , we call the estimator robust. If for convection-diffusion problems and some norms is independent of but slightly depends on , we call the estimator semi-robust with respect to that norm.
First we discuss error estimators with respect to an energy or some related norm. Based on  in the last years for convection- diffusion problems instead of using the norm robustness of several estimators with respect to the norm was proved, see [140–145]. Unfortunately, this norm is not computable.
Relatively new, not discussed in  and actually used in many papers, is the idea of flux reconstruction in . Consider first, for simplicity a reaction-diffusion problem following . The derivation of the error estimator starts from Now is chosen to approximate the numerical flux . Additionally, shall satisfy For details of the computation of the recovered flux see .
The combination of the first term of (4.3) with (4.4) yields the residual part of the new estimator (with the weights from ) The second term of (4.3) yields after some manipulation (the direct application of Cauchy-Schwarz yields a non-robust estimator) a more complicated diffusive flux estimator . The resulting full estimator of  is robust and equivalent to Verfürth's residual estimator for reaction-diffusion problems.
For convection-diffusion problems the derivation of estimators using flux reconstruction works similarly. Consider a convection-diffusion problem of the form
Now has to approximate and should again satisfy (4.4). See  for details. For a similar approach concerning fully computable a posteriori error estimators for stabilized FEM (even in 3D) see .
One can also use a discontinuous numerical approximation as typical for dG methods. Than an additional reconstruction of the potential by a function in is introduced, see [149, 150]. For the separation of the error into an element residual error and flux errors with respect to goal-oriented a posteriori error estimates (DWR method), see . Nonlinear unsteady problems are discussed in .
There exist some attempts to derive pointwise a posteriori error estimates in the singularly-perturbed case. Using the Green's function of the continuous problem the starting point is, in general, the representation or (in the strong form using distributions) In  the author studies in 1D higher order FEM based on (4.7) and gets estimates using information on . The estimator contains discrete derivatives of the numerical solution . Kopteva  studied the finite difference method in 2D based on (4.8).
It is open to use the information on the Green's function provided in [155, 156] to derive pointwise a posteriori error estimates for finite elements in 2D. For time-dependent problems, but one-dimensional in space, see .
An error estimator provides the information where the mesh should be refined. But, in general, we do not have additional information on the directional behavior of the error in order to know how the mesh should be refined. An exception is , where the author tries to detect anisotropies, see also the recent . There seems to be no new theoretical perception concerning metric-based algorithms for mesh generation in the singularly perturbed case.
It is still mostly standard to derive error estimators based on the assumption that the mesh is shape-regular and locally uniform. For anisotropic meshes, there seems to be so far nothing better than the theory developed by Kunert  ten years ago. For some survey on anisotropic refinement methods in FEM, see .
5. Singularly Perturbed Systems
In 2009, Linss and Stynes  presented a survey on the numerical solution of singularly perturbed systems. In this Section we only comment on some recent results not contained in  which sparkle that survey.
First we study systems of reaction-diffusion equations of the form where with . If the matrix satisfies certain conditions, the asymptotic behavior of such a system is well understood. Assume that has positive diagonal entries, moreover the matrix defined by satisfies . Then, in  the existence of a solution decomposition is proved. Other authors assume that is an -matrix or that is point-wise positive definite. See [162, Theorem 2.2] for establishing a connection between positive definiteness and the property . In  a full asymptotic expansion is derived for positive definite in the case of two equations, including information on analytic regularity.
Systems of convection-diffusion problems are more delicate to handle. Consider first weakly coupled systems of the form assuming Then it was shown in  for When only first order derivatives are considered, there is no strong interaction between the layers of different components unlike the reaction-diffusion case.
But, consider for example a set of two equations with and for . Then the layer at in the first component generates a weak layer at in the second component; the situation at is analogous. Under certain conditions , one can prove the existence of the following solution decomposition for : with Here is some positive parameter. This observation is important for control problems governed by convection-diffusion equations: subject to For strongly coupled systems of convection-diffusion equations full layer-interaction takes place. Consider the system of two equations assuming is symmetric. is positive semidefinite. The eigenvalues of satisfy for all .
If both eigenvalues of are positive, both solution components do have overlapping layers at , the reduced solution solves an initial value problem . But if the eigenvalues do have a different sign, both solution components do have layers at and ; we have full layer interaction. It is remarkable that the reduced solution, in general, does not satisfy any of the given boundary conditions .
The author would like to thank Katharina Höhne and Sebastian Franz for the help in preparing this paper.
- H.-G. Roos, M. Stynes, and L. Tobiska, Robust Numerical Methods for Singularly Perturbed Differential Equations, vol. 24 of Springer Series in Computational Mathematics, Springer, Berlin, Germany, 2nd edition, 2008, Convection-diffusion-reaction and flow problems.
- T. Linß, Layer-Adapted Meshes for Reaction-Convection-Diffusion Problems, vol. 1985 of Lecture Notes in Mathematics, Springer, Berlin, Germany, 2010.
- M. K. Kadalbajoo and V. Gupta, “A brief survey on numerical methods for solving singularly perturbed problems,” Applied Mathematics and Computation, vol. 217, no. 8, pp. 3641–3716, 2010.
- L. P. Franca, G. Hauke, and A. Masud, “Revisiting stabilized finite element methods for the advective-diffusive equation,” Computer Methods in Applied Mechanics and Engineering, vol. 195, no. 13–16, pp. 1560–1572, 2006.
- G. Lube, “Stabilized fem for incompressible ow. critical review and new trends,” in European Conference on Computational Fluid Dynamics (ECCOMAS CFD '06), P. Wesseling, E. Onate, and J. Periaux, Eds., pp. 1–20, TU Delft, Dordrecht, The Netherlands, 2006.
- F. Brezzi and A. Russo, “Choosing bubbles for advection-diffusion problems,” Mathematical Models & Methods in Applied Sciences, vol. 4, no. 4, pp. 571–587, 1994.
- J.-L. Guermond, “Stabilization of Galerkin approximations of transport equations by subgrid modeling,” Mathematical Modelling and Numerical Analysis, vol. 33, no. 6, pp. 1293–1316, 1999.
- T. J. R. Hughes, “Multiscale phenomena: green's functions, the Dirichlet-to-Neumann formulation, subgrid scale models, bubbles and the origins of stabilized methods,” Computer Methods in Applied Mechanics and Engineering, vol. 127, no. 1–4, pp. 387–401, 1995.
- V. John, S. Kaya, and W. Layton, “A two-level variational multiscale method for convection-dominated convection-diffusion equations,” Computer Methods in Applied Mechanics and Engineering, vol. 195, no. 33–36, pp. 4594–4603, 2006.
- H. C. Elman, D. J. Silvester, and A. J. Wathen, Finite Elements and Fast Iterative Solvers: With Applications in Incompressible Fluid Dynamics, Numerical Mathematics and Scientific Computation, Oxford University Press, New York, NY, USA, 2005.
- A. Serghini Mounim, “A stabilized finite element method for convection-diffusion problems,” Numerical Methods for Partial Differential Equations, vol. 28, no. 6, pp. 1916–1943, 2012.
- P. Knobloch, “On the definition of the SUPG parameter,” Electronic Transactions on Numerical Analysis, vol. 32, pp. 76–89, 2008.
- P. Knobloch, “On the choice of the SUPG parameter at outflow boundary layers,” Advances in Computational Mathematics, vol. 31, no. 4, pp. 369–389, 2009.
- V. John, P. Knobloch, and S. B. Savescu, “A posteriori optimization of parameters in stabilized methods for convection-diffusion problems—part I,” Computer Methods in Applied Mechanics and Engineering, vol. 200, no. 41–44, pp. 2916–2929, 2011.
- V. John and P. Knobloch, “On spurious oscillations at layers diminishing (SOLD) methods for convection-diffusion equations. I. A review,” Computer Methods in Applied Mechanics and Engineering, vol. 196, no. 17–20, pp. 2197–2215, 2007.
- V. John and P. Knobloch, “On the performance of SOLD methods for convection-diffusion problems with interior layers,” International Journal of Computing Science and Mathematics, vol. 1, no. 2–4, pp. 245–258, 2007.
- V. John and P. Knobloch, “On spurious oscillations at layers diminishing (SOLD) methods for convection-diffusion equations. II. Analysis for and finite elements,” Computer Methods in Applied Mechanics and Engineering, vol. 197, no. 21–24, pp. 1997–2014, 2008.
- M. Augustin, A. Caiazzo, A. Fiebach et al., “An assessment of discretizations for convection-dominated convection-diffusion equations,” Computer Methods in Applied Mechanics and Engineering, vol. 200, no. 47-48, pp. 3395–3409, 2011.
- E. Burman and P. Hansbo, “Edge stabilization for Galerkin approximations of convection-diffusion-reaction problems,” Computer Methods in Applied Mechanics and Engineering, vol. 193, no. 15-16, pp. 1437–1453, 2004.
- F. Schieweck, “On the role of boundary conditions for CIP stabilization of higher order finite elements,” Electronic Transactions on Numerical Analysis, vol. 32, pp. 1–16, 2008.
- E. Burman and A. Ern, “Stabilized Galerkin approximation of convection-diffusion-reaction equations: discrete maximum principle and convergence,” Mathematics of Computation, vol. 74, no. 252, pp. 1637–1652, 2005.
- P. Knobloch, “A generalization of the local projection stabilization for convection-diffusion-reaction equations,” SIAM Journal on Numerical Analysis, vol. 48, no. 2, pp. 659–680, 2010.
- R. Codina, “Stabilization of incompressibility and convection through orthogonal sub-scales in finite element methods,” Computer Methods in Applied Mechanics and Engineering, vol. 190, no. 13-14, pp. 1579–1599, 2000.
- R. Becker and M. Braack, “A finite element pressure gradient stabilization for the Stokes equations based on local projections,” Calcolo, vol. 38, no. 4, pp. 173–199, 2001.
- G. Matthies, P. Skrzypacz, and L. Tobiska, “A unified convergence analysis for local projection stabilisations applied to the Oseen problem,” Mathematical Modelling and Numerical Analysis, vol. 41, no. 4, pp. 713–742, 2007.
- R. Codina, “Analysis of a stabilized finite element approximation of the Oseen equations using orthogonal subscales,” Applied Numerical Mathematics, vol. 58, no. 3, pp. 264–283, 2008.
- P. Knobloch and L. Tobiska, “On the stability of finite-element discretizations of convection-diffusion-reaction equations,” IMA Journal of Numerical Analysis, vol. 31, no. 1, pp. 147–164, 2011.
- P. Knobloch and G. Lube, “Local projection stabilization for advection-diffusion-reaction problems: one-level vs. two-level approach,” Applied Numerical Mathematics, vol. 59, no. 12, pp. 2891–2907, 2009.
- L. He and L. Tobiska, “The two-level local projection stabilization as an enriched one-level approach,” Advances in Computational Mathematics, vol. 36, no. 4, pp. 503–523, 2012.
- D. Juhnke and L. Tobiska, “A local projection type stabilization with exponential enrichments applied to one-dimensional advection-diffusion equations,” Computer Methods in Applied Mechanics and Engineering, vol. 201–204, pp. 179–190, 2012.
- G. R. Barrenechea and F. Valentin, “A residual local projection method for the Oseen equation,” Computer Methods in Applied Mechanics and Engineering, vol. 199, no. 29–32, pp. 1906–1921, 2010.
- G. R. Barrenechea, V. John, and P. Knobloch, A Local Projection Stabilisation Finite Element Method Wiith Nonlinear Crosswind Diffusion for Convection-Diffusion-Reaction Equations, WIAS, Berlin, Germany, 2012.
- B. Rivière, Discontinuous Galerkin Methods for Solving Elliptic and Parabolic Equations: Theory and Implementation, vol. 35 of Frontiers in Applied Mathematics, Society for Industrial and Applied Mathematics (SIAM), Philadelphia, Pa, USA, 2008.
- J. S. Hesthaven and T. Warburton, Nodal Discontinuous Galerkin Methods: Algorithms, Analysis, and Applications, vol. 54 of Texts in Applied Mathematics, Springer, New York, NY, USA, 2008.
- G. Kanschat, Discontinuous Galerkin Methods for Viscous Incompressible Flow, Advances in Numerical Mathematics. Vieweg, 2008.
- D. A. Di Pietro and A. Ern, Mathematical Aspects of Discontinuous Galerkin Methods, vol. 69 of Mathématiques & Applications, Springer, Berlin, 2012.
- Y. Bazilevs and T. J. R. Hughes, “Weak imposition of Dirichlet boundary conditions in fluid mechanics,” Computers & Fluids, vol. 36, no. 1, pp. 12–26, 2007.
- Y. Bazilevs, C. Michler, V. M. Calo, and T. J. R. Hughes, “Weak Dirichlet boundary conditions for wall-bounded turbulent flows,” Computer Methods in Applied Mechanics and Engineering, vol. 196, no. 49–52, pp. 4853–4862, 2007.
- E. Burman, “A penalty-free nonsymmetric nitsche-type method for the weak imposition of boundary conditions,” SIAM Journal on Numerical Analysis, vol. 50, no. 4, pp. 1959–1981, 2012.
- R. E. Ewing, J. Wang, and Y. Yang, “A stabilized discontinuous finite element method for elliptic problems,” Numerical Linear Algebra with Applications, vol. 10, no. 1-2, pp. 83–104, 2003.
- B. Cockburn, J. Gopalakrishnan, and R. Lazarov, “Unified hybridization of discontinuous Galerkin, mixed, and continuous Galerkin methods for second order elliptic problems,” SIAM Journal on Numerical Analysis, vol. 47, no. 2, pp. 1319–1365, 2009.
- P. Causin and R. Sacco, “A discontinuous Petrov-Galerkin method with Lagrangian multipliers for second order elliptic problems,” SIAM Journal on Numerical Analysis, vol. 43, no. 1, pp. 280–302, 2005.
- B. Cockburn, B. Dong, J. Guzmán, M. Restelli, and R. Sacco, “A hybridizable discontinuous Galerkin method for steady-state convection-diffusion-reaction problems,” SIAM Journal on Scientific Computing, vol. 31, no. 5, pp. 3827–3846, 2009.
- H. Egger and J. Schöberl, “A hybrid mixed discontinuous Galerkin finite-element method for convection-diffusion problems,” IMA Journal of Numerical Analysis, vol. 30, no. 4, pp. 1206–1234, 2010.
- C. L. Bottasso, S. Micheletti, and R. Sacco, “A multiscale formulation of the discontinuous Petrov-Galerkin method for advective-diffusive problems,” Computer Methods in Applied Mechanics and Engineering, vol. 194, no. 25-26, pp. 2819–2838, 2005.
- P. Causin, R. Sacco, and C. L. Bottasso, “Flux-upwind stabilization of the discontinuous Petrov-Galerkin formulation with Lagrange multipliers for advection-diffusion problems,” Mathematical Modelling and Numerical Analysis, vol. 39, no. 6, pp. 1087–1114, 2005.
- L. Demkowicz and J. Gopalakrishnan, “A class of discontinuous Petrov-Galerkin methods. II. Optimal test functions,” Numerical Methods for Partial Differential Equations, vol. 27, no. 1, pp. 70–105, 2011.
- N. Heuer and L. Demkowicz, Robust Dpg Method for Convection-Dominated Diffusion Problems, University of Texas at Austin, ICES.
- J. Chan, N. Heuer, T. Bui-Thanh, and D. Demkowicz, “Robust dpg method for convection-dominated diffusion problems ii: a natural in flow condition,” submitted.
- R. J. Labeur and G. N. Wells, “A Galerkin interface stabilisation method for the advection-diffusion and incompressible Navier-Stokes equations,” Computer Methods in Applied Mechanics and Engineering, vol. 196, no. 49–52, pp. 4985–5000, 2007.
- G. N. Wells, “Analysis of an interface stabilized finite element method: the advection-diffusion-reaction equation,” SIAM Journal on Numerical Analysis, vol. 49, no. 1, pp. 87–109, 2011.
- D. Kuzmin and S. Turek, “Flux correction tools for finite elements,” Journal of Computational Physics, vol. 175, no. 2, pp. 525–558, 2002.
- D. Kuzmin, Free Cfd Book: A Guide to Numerical Methods for Transport Equations, University Erlangen-Nürnberg, 2010.
- E. Burman and M. A. Fernández, “Finite element methods with symmetric stabilization for the transient convection-diffusion-reaction equation,” Computer Methods in Applied Mechanics and Engineering, vol. 198, no. 33–36, pp. 2508–2519, 2009.
- N. Ahmed, G. Matthies, L. Tobiska, and H. Xie, “Discontinuous Galerkin time stepping with local projection stabilization for transient convection-diffusion-reaction problems,” Computer Methods in Applied Mechanics and Engineering, vol. 200, no. 21-22, pp. 1747–1756, 2011.
- M. Feistauer, J. Hájek, and K. Svadlenka, “Space-time discontinuous Galerkin method for solving nonstationary convection-diffusion-reaction problems,” Applications of Mathematics, vol. 52, no. 3, pp. 197–233, 2007.
- E. Burman and A. Ern, “Implicit-explicit Runge-Kutta schemes and finite elements with symmetric stabilization for advection-diffusion equations,” Mathematical Modelling and Numerical Analysis, vol. 46, no. 4, pp. 681–707, 2012.
- V. Dolejší, M. Feistauer, V. Kučera, and V. Sobotíková, “An optimal -error estimate for the discontinuous Galerkin approximation of a nonlinear non-stationary convection-diffusion problem,” IMA Journal of Numerical Analysis, vol. 28, no. 3, pp. 496–521, 2008.
- V. Dolejší and M. Vlasák, “Analysis of a BDF-DGFE scheme for nonlinear convection-diffusion problems,” Numerische Mathematik, vol. 110, no. 4, pp. 405–447, 2008.
- V. John and J. Novo, “Error analysis of the SUPG finite element discretization of evolutionary convection-diffusion-reaction equations,” SIAM Journal on Numerical Analysis, vol. 49, no. 3, pp. 1149–1176, 2011.
- E. Burman and G. Smith, “Analysis of the space semi-discretized SUPG method for transient convection-diffusion equations,” Mathematical Models and Methods in Applied Sciences, vol. 21, no. 10, pp. 2049–2068, 2011.
- E. Burman, “Consistent SUPG-method for transient transport problems: stability and convergence,” Computer Methods in Applied Mechanics and Engineering, vol. 199, no. 17–20, pp. 1114–1123, 2010.
- H.-G. Roos and M. Schopf, “Error estimation in energy norms: is it necessary to fit the mesh to the boundary layer?” submitted.
- R. Lin, “Discontinuous discretization for least-squares formulation of singularly perturbed reaction-diffusion problems in one and two dimensions,” SIAM Journal on Numerical Analysis, vol. 47, no. 1, pp. 89–108, 2008.
- T. K. Nilssen, X.-C. Tai, and R. Winther, “A robust nonconforming -element,” Mathematics of Computation, vol. 70, no. 234, pp. 489–505, 2001.
- J. Guzmán, D. Leykekhman, and M. Neilan, “A family of non-conforming elements and the analysis of Nitsche's method for a singularly perturbed fourth order problem,” Calcolo, vol. 49, no. 2, pp. 95–125, 2012.
- O. Axelsson, E. Glushkov, and N. Glushkova, “The local Green's function method in singularly perturbed convection-diffusion problems,” Mathematics of Computation, vol. 78, no. 265, pp. 153–170, 2009.
- L. Demkowicz and J. Gopalakrishnan, “A class of discontinuous Petrov-Galerkin methods. Part I: the transport equation,” Computer Methods in Applied Mechanics and Engineering, vol. 199, no. 23-24, pp. 1558–1572, 2010.
- L. Demkowicz, J. Gopalakrishnan, and A. H. Niemi, “A class of discontinuous Petrov-Galerkin methods. Part III: adaptivity,” Applied Numerical Mathematics, vol. 62, no. 4, pp. 396–427, 2012.
- H. Han and Z. Huang, “Tailored finite point method based on exponential bases for convection-diffusion-reaction equation,” Mathematics of Computation, vol. 82, no. 281, pp. 213–226, 2013.
- X. Li, X. Yu, and G. Chen, “Error estimates of the finite element method with weighted basis functions for a singularly perturbed convection-diffusion equation,” Journal of Computational Mathematics, vol. 29, no. 2, pp. 227–242, 2011.
- H. Riou and P. Ladevéze, “A new numerical strategy for the resolution of high- péclet advection-diffusion problems,” Computer Methods in Applied Mechanics and Engineering, vol. 241–244, pp. 302–310, 2012.
- A. L. Lombardi and P. Pietra, “Exponentially fitted discontinuous galerkin schemes for singularly perturbed problems,” Numerical Methods for Partial Differential Equations, vol. 28, no. 6, pp. 1747–1777, 2012.
- F. Brezzi, L. D. Marini, and P. Pietra, “Two-dimensional exponential fitting and applications to drift-diffusion models,” SIAM Journal on Numerical Analysis, vol. 26, no. 6, pp. 1342–1355, 1989.
- S. Holst, A. Jüngel, and P. Pietra, “A mixed finite-element discretization of the energy-transport model for semiconductors,” SIAM Journal on Scientific Computing, vol. 24, no. 6, pp. 2058–2075, 2003.
- R. B. Kellogg and M. Stynes, “Corner singularities and boundary layers in a simple convection-diffusion problem,” Journal of Differential Equations, vol. 213, no. 1, pp. 81–120, 2005.
- R. B. Kellogg and M. Stynes, “Sharpened bounds for corner singularities and boundary layers in a simple convection-diffusion problem,” Applied Mathematics Letters, vol. 20, no. 5, pp. 539–544, 2007.
- T. Linß and M. Stynes, “Asymptotic analysis and Shishkin-type decomposition for an elliptic convection-diffusion problem,” Journal of Mathematical Analysis and Applications, vol. 261, no. 2, pp. 604–632, 2001.
- E. O'Riordan and G. I. Shishkin, “A technique to prove parameter-uniform convergence for a singularly perturbed convection-diffusion equation,” Journal of Computational and Applied Mathematics, vol. 206, no. 1, pp. 136–145, 2007.
- N. S. Bakhvalov, “On the optimization of the methods for solving boundary value problems in the presence of a boundary layer,” Zhurnal Vychislitel'noi Matematiki i Matematicheskoi Fiziki, vol. 9, pp. 841–859, 1969.
- T. Linß, “Layer-adapted meshes for convection-diffusion problems,” Computer Methods in Applied Mechanics and Engineering, vol. 192, no. 9-10, pp. 1061–1105, 2003.
- T. Linß, Layer Adapted Meshes for Convection-Diffusion Problems, Habilitation TU Dresden, 2006.
- H.-G. Roos, “Error estimates for linear finite elements on Bakhvalov-type meshes,” Applications of Mathematics, vol. 51, no. 1, pp. 63–72, 2006.
- T. Apel and G. Lube, “Anisotropic mesh refinement in stabilized Galerkin methods,” Numerische Mathematik, vol. 74, no. 3, pp. 261–282, 1996.
- Z. Xie and Z. Zhang, “Uniform superconvergence analysis of the discontinuous Galerkin method for a singularly perturbed problem in 1-D,” Mathematics of Computation, vol. 79, no. 269, pp. 35–45, 2010.
- J. M. Melenk, hp-Finite Element Methods for Singular Perturbations, vol. 1796 of Lecture Notes in Mathematics, Springer, Berlin, Germany, 2002.
- T. Linß, H.-G. Roos, and M. Schopf, “Nitsche-mortaring for singularly perturbed convection-diffusion problems,” Advances in Computational Mathematics, vol. 36, no. 4, pp. 581–603, 2012.
- H.-G. Roos and T. Skalický, “A comparison of the finite element method on Shishkin and Gartland-type meshes for convection-diffusion problems,” CWI Quarterly, vol. 10, no. 3-4, pp. 277–300, 1997, International Workshop on the Numerical Solution of Thin-Layer Phenomena (Amsterdam).
- S.-T. Liu and Y. Xu, “Graded Galerkin methods for the high-order convection-diffusion problem,” Numerical Methods for Partial Differential Equations, vol. 25, no. 6, pp. 1261–1282, 2009.
- M. Stynes and E. O'Riordan, “A uniformly convergent Galerkin method on a Shishkin mesh for a convection-diffusion problem,” Journal of Mathematical Analysis and Applications, vol. 214, no. 1, pp. 36–54, 1997.
- M. Dobrowolski and H.-G. Roos, “A priori estimates for the solution of convection-diffusion problems and interpolation on Shishkin meshes,” Zeitschrift für Analysis und ihre Anwendungen, vol. 16, no. 4, pp. 1001–1012, 1997.
- H.-G. Roos and T. Linß, “Sufficient conditions for uniform convergence on layer-adapted grids,” Computing, vol. 63, no. 1, pp. 27–45, 1999.
- H.-G. Roos and M. Schopf, “Analysis of finite element methods on Bakhvalov-type meshes for linear convection-diffusion problems in 2D,” Applications of Mathematics, vol. 57, no. 2, pp. 97–108, 2012.
- R. G. Durán and A. L. Lombardi, “Finite element approximation of convection diffusion problems using graded meshes,” Applied Numerical Mathematics, vol. 56, no. 10-11, pp. 1314–1325, 2006.
- H.-G. Roos and M. Schopf, “Finite elements on locally uniform meshes for convection-diffusion problems with boundary layers,” Computing, vol. 92, no. 4, pp. 285–296, 2011.
- S. Franz and T. Linß, “Superconvergence analysis of the Galerkin FEM for a singularly perturbed convection-diffusion problem with characteristic layers,” Numerical Methods for Partial Differential Equations, vol. 24, no. 1, pp. 144–164, 2008.
- P. Sun, L. Chen, and J. Xu, “Numerical studies of adaptive finite element methods for two dimensional convection-dominated problems,” Journal of Scientific Computing, vol. 43, no. 1, pp. 24–43, 2010.
- T. Linß and M. Stynes, “Numerical methods on shishkin meshes for linear convection- diffusion problems,” Computer Methods in Applied Mechanics and Engineering, no. 190, pp. 3527–3542, 2001.
- C. Grossmann and H.-G. Roos, Numerical Treatment of Partial Differential Equations, Universitext, Springer, Berlin, Germany, 2007.
- M. Stynes and L. Tobiska, “The SDFEM for a convection-diffusion problem with a boundary layer: optimal error analysis and enhancement of accuracy,” SIAM Journal on Numerical Analysis, vol. 41, no. 5, pp. 1620–1642, 2003.
- J. Zhang and L. Mei, “Pointwise error estimates of the bilinear sdfem on shishkin meshes,” Numerical Methods for Partial Differential Equations. In press.
- N. Kopteva, “How accurate is the streamline-diffusion FEM inside characteristic (boundary and interior) layers?” Computer Methods in Applied Mechanics and Engineering, vol. 193, no. 45–47, pp. 4875–4889, 2004.
- S. Franz, T. Linß, and H.-G. Roos, “Superconvergence analysis of the SDFEM for elliptic problems with characteristic layers,” Applied Numerical Mathematics, vol. 58, no. 12, pp. 1818–1829, 2008.
- Q. Lin and J. Lin, Finite Element Methods: Accuracy and Improvement, Mathematics Monograph Series, Science Press, 2006.
- R. G. Durán, A. L. Lombardi, and M. I. Prieto, “Superconvergence for finite element approximation of a convection-diffusion equation using graded meshes,” IMA Journal of Numerical Analysis, vol. 32, no. 2, pp. 511–533, 2012.
- R. G. Durán, A. L. Lombardi, and M. I. Prieto, “Supercloseness on graded meshes for finite element approximation of a reaction-diffusion equation,” Journal of Computational and Applied Mathematics, vol. 242, pp. 232–242, 2013.
- G. Zhu and S. Chen, “Convergence and superconvergence analysis of an anisotropic nonconforming finite element methods for singularly perturbed reaction-diffusion problems,” Journal of Computational and Applied Mathematics, vol. 234, no. 10, pp. 3048–3063, 2010.
- S. Franz, “Convergence phenomena for -elements for convection-diffusion problems,” Numerical Methods for Partial Differential Equations, vol. 29, pp. 280–296, 2013.
- M. Stynes and L. Tobiska, “Using rectangular elements in the SDFEM for a convection-diffusion problem with a boundary layer,” Applied Numerical Mathematics, vol. 58, no. 12, pp. 1789–1802, 2008.
- S. Franz, “Superconvergence for pointwise interpolation in convection-diffusion problems”.
- S. Franz, T. Linß, H.-G. Roos, and S. Schiller, “Uniform superconvergence of a finite element method with edge stabilization for convection-diffusion problems,” Journal of Computational Mathematics, vol. 28, no. 1, pp. 32–44, 2010.
- S. Franz, “Continuous interior penalty method on a Shishkin mesh for convection-diffusion problems with characteristic boundary layers,” Computer Methods in Applied Mechanics and Engineering, vol. 197, no. 45–48, pp. 3679–3686, 2008.
- G. Matthies, “Local projection stabilisation for higher order discretisations of convection-diffusion problems on Shishkin meshes,” Advances in Computational Mathematics, vol. 30, no. 4, pp. 315–337, 2009.
- G. Matthies, “Local projection methods on layer-adapted meshes for higher order discretisations of convection-diffusion problems,” Applied Numerical Mathematics, vol. 59, no. 10, pp. 2515–2533, 2009.
- S. Franz and G. Matthies, “Local projection stabilisation on S-type meshes for convection-diffusion problems with characteristic layers,” Computing, vol. 87, no. 3-4, pp. 135–167, 2010.
- H.-G. Roos and H. Zarin, “A supercloseness result for the discontinuous Galerkin stabilization of convection-diffusion problems on Shishkin meshes,” Numerical Methods for Partial Differential Equations, vol. 23, no. 6, pp. 1560–1576, 2007.
- Z. Xie and Z. Zhang, “Superconvergence of DG method for one-dimensional singularly perturbed problems,” Journal of Computational Mathematics, vol. 25, no. 2, pp. 185–200, 2007.
- H. Zhu and Z. Zhang, “Convergence analysis of the LDG method applied to singularly perturbed problems,” Numerical Methods for Partial Differential Equations. In press.
- H. Zhu and Z. Zhang, “Uniform convergence of the LDG method for a singularly perturbed problem with the exponential boundary layer”.
- S. Franz, L. Tobiska, and H. Zarin, “A new approach to recovery of discontinuous Galerkin,” Journal of Computational Mathematics, vol. 27, no. 6, pp. 697–712, 2009.
- S. Franz, F. Liu, H.-G. Roos, M. Stynes, and A. Zhou, “The combination technique for a two-dimensional convection-diffusion problem with exponential layers,” Applications of Mathematics, vol. 54, no. 3, pp. 203–223, 2009.
- F. Liu, N. Madden, M. Stynes, and A. Zhou, “A two-scale sparse grid method for a singularly perturbed reaction-diffusion problem in two dimensions,” IMA Journal of Numerical Analysis, vol. 29, no. 4, pp. 986–1007, 2009.
- H.-G. Roos and M. Schopf, “Convergence and stability in balanced norms of finite element methods on shishkin meshes for reaction-diffusion problems”.
- R. Lin and M. Stynes, “A balanced finite element method for singularly perturbed reaction-diffusion problems,” SIAM Journal on Numerical Analysis, vol. 50, pp. 2729–2743, 2012.
- S. Franz and H. G. Roos, “Error estimation in a balanced norm for a convection- diffusion problem with two different boundary layers,” submitted.
- B. Garcia-Archilla, “Shishkin mesh simulation: a new stabilization technique for convection-diffusion problems”.
- V. B. Andreev and N. Kopteva, “Pointwise approximation of corner singularities for a singularly perturbed reaction-diffusion equation in an -shaped domain,” Mathematics of Computation, vol. 77, no. 264, pp. 2125–2139, 2008.
- V. B. Andreev, “Uniform grid approximation of nonsmooth solutions of a mixed boundary value problem for a singularly perturbed reaction-diffusion equation in a rectangle,” Zhurnal Vychislitel'noi Matematiki i Matematicheskoi Fiziki, vol. 48, no. 1, pp. 90–114, 2008.
- S. Franz, R. B. Kellogg, and M. Stynes, “Galerkin and streamline diffusion finite element methods on a Shishkin mesh for a convection-diffusion problem with corner singularities,” Mathematics of Computation, vol. 81, no. 278, pp. 661–685, 2012.
- S. Franz, R. B. Kellogg, and M. Stynes, “On the choice of mesh for a singularly perturbed problem with a corner singularity,” in Proceedings of the Boundary and Interior Layers, Computational and Asymptotic Methods (BAIL '10), vol. 81 of Lecture Notes in Computational Science and Engineering, pp. 119–126, Springer, Heidelberg, Germany, 2011.
- H. G. Roos and L. Ludwig, “Finite element superconvergence on shishkin meshes for convection-diffusion problems with corner singularities,” submitted.
- H.-G. Roos and L. Ludwig, “Superconvergence for convection-diffusion problems with low regularity,” Proceedings in Applied Mathematics and Mechanics, pp. 173–187, 2012.
- V. B. Andreev, “Uniform grid approximation of nonsmooth solutions of a singularly perturbed convection-diffusion equation in a rectangle,” Differentsial'nye Uravneniya, vol. 45, no. 7, pp. 954–964, 2009.
- V. B. Andreev, “Pointwise approximation of corner singularities for singularly perturbed elliptic problems with characteristic layers,” International Journal of Numerical Analysis and Modeling, vol. 7, no. 3, pp. 416–427, 2010.
- C. Clavero, J. L. Gracia, and M. Stynes, “A simpler analysis of a hybrid numerical method for time-dependent convection-diffusion problems,” Journal of Computational and Applied Mathematics, vol. 235, no. 17, pp. 5240–5248, 2011.
- L. Kaland and H.-G. Roos, “Parabolic singularly perturbed problems with exponential layers: robust discretizations using finite elements in space on Shishkin meshes,” International Journal of Numerical Analysis and Modeling, vol. 7, no. 3, pp. 593–606, 2010.
- V. Dolejší and H.-G. Roos, “BDF-FEM for parabolic singularly perturbed problems with exponential layers on layers-adapted meshes in space,” Neural, Parallel & Scientific Computations, vol. 18, no. 2, pp. 221–235, 2010.
- H.-G. Roos and M. Vlasak, “An optimal uniform a priori error estimate for an un- steady singularly perturbed problem,” International Journal of Numerical Analysis and Modeling Computing and Information, vol. 9, no. 1, pp. 56–72, 2012.
- R. Verfürth, “Robust a posteriori error estimates for stationary convection-diffusion equations,” SIAM Journal on Numerical Analysis, vol. 43, no. 4, pp. 1766–1782, 2005.
- L. El Alaoui, A. Ern, and E. Burman, “A priori and a posteriori analysis of non-conforming finite elements with face penalty for advection-diffusion equations,” IMA Journal of Numerical Analysis, vol. 27, no. 1, pp. 151–171, 2007.
- B. Achchab, M. El Fatini, A. Ern, and A. Souissi, “A posteriori error estimates for subgrid viscosity stabilized approximations of convection-diffusion equations,” Applied Mathematics Letters, vol. 22, no. 9, pp. 1418–1424, 2009.
- B. Achchab, M. El Fatini, and A. Souissi, “A posteriori error analysis for multiscale stabilization of convection-diffusion-reaction problems: unsteady state,” International Journal of Mathematics and Statistics, vol. 4, no. S09, pp. 3–11, 2009.
- T. Apel, S. Nicaise, and D. Sirch, “A posteriori error estimation of residual type for anisotropic diffusion-convection-reaction problems,” Journal of Computational and Applied Mathematics, vol. 235, no. 8, pp. 2805–2820, 2011.
- B. Achchab, A. Agouzal, M. El Fatini, and A. Souissi, “Robust hierarchical a posteriori error estimators for stabilized convection-diffusion problems,” Numerical Methods for Partial Differential Equations, vol. 28, no. 5, pp. 1717–1728, 2012.
- B. Achchab, A. Benjouad, M. El Fatini, A. Souissi, and G. Warnecke, “Robust a posteriori error estimates for subgrid stabilization of non-stationary convection dominated diffusive transport,” Applied Mathematics and Computation, vol. 218, no. 9, pp. 5276–5291, 2012.
- I. Cheddadi, R. Fučík, M. I. Prieto, and M. Vohralík, “Guaranteed and robust a posteriori error estimates for singularly perturbed reaction-diffusion problems,” Mathematical Modelling and Numerical Analysis, vol. 43, no. 5, pp. 867–888, 2009.
- M. Vohralík, A Posteriori Error Estimates for Efficiency and Error Control in Numerical Simulations, vol. 6 of Lecture Notes, Université Pierre et Marie Curie, Paris, France, 2012.
- M. Ainsworth, A. Allendes, G. R. Barrenechea, and R. Rankin, Fully Computable a Posteriori Error Bounds for Stabilized Fem Approximations of Convection-Diffusion-Reaction Problems in Three Dimensions, University of Strathclyde.
- L. Zhu and D. Schötzau, “A robust a posteriori error estimate for hp-adaptive DG methods for convection-diffusion equations,” IMA Journal of Numerical Analysis, vol. 31, no. 3, pp. 971–1005, 2011.
- A. Ern, A. F. Stephansen, and M. Vohralík, “Guaranteed and robust discontinuous Galerkin a posteriori error estimates for convection-diffusion-reaction problems,” Journal of Computational and Applied Mathematics, vol. 234, no. 1, pp. 114–130, 2010.
- D. Kuzmin and S. Korotov, “Goal-oriented a posteriori error estimates for transport problems,” Mathematics and Computers in Simulation, vol. 80, no. 8, pp. 1674–1683, 2010.
- V. Dolejší, A. Ern, and M. Vohralík, “A framework for robust a posteriori error control in unsteady nonlinear advection-diffusion problems”.
- T. Linß, “A posteriori error estimation for higher order fem applied to one-dimensional reaction-diffusion problems”.
- N. Kopteva, “Maximum norm a posteriori error estimate for a 2D singularly perturbed semilinear reaction-diffusion problem,” SIAM Journal on Numerical Analysis, vol. 46, no. 3, pp. 1602–1618, 2008.
- S. Franz and N. Kopteva, “Green's function estimates for a singularly perturbed convection-diffusion problem,” Journal of Differential Equations, vol. 252, no. 2, pp. 1521–1545, 2012.
- S. Franz and N. Kopteva, “Green's function estimates for a singularly perturbed convection-diffusion problem in three dimensions,” International Journal of Numerical Analysis and Modeling B, vol. 2, no. 2-3, pp. 124–141, 2011.
- N. Kopteva and T. Linß, “Maximum norm a posteriori error estimation for a time-dependent reaction-diffusion problem,” Computational Methods in Applied Mathematics, vol. 12, pp. 189–205, 2012.
- T. Richter, “A posteriori error estimation and anisotropy detection with the dual-weighted residual method,” International Journal for Numerical Methods in Fluids, vol. 62, no. 1, pp. 90–118, 2010.
- W. Huang, L. Kamenski, and J. Lang, “A new anisotropic mesh adaptation method based upon hierarchical a posteriori error estimates,” Journal of Computational Physics, vol. 229, no. 6, pp. 2179–2198, 2010.
- G. Kunert, “Toward anisotropic mesh construction and error estimation in the finite element method,” Numerical Methods for Partial Differential Equations, vol. 18, no. 5, pp. 625–648, 2002.
- R. Schneider, “A review of anisotropic refinement methods for triangular meshes in FEM,” in Advanced Finite Element Methods and Applications, vol. 66 of Lecture Notes in Applied and Computational Mechanics, pp. 133–152, Springer, Heidelberg, Germany, 2013.
- T. Linss and M. Stynes, “Numerical solution of systems of singularly perturbed differential equations,” Computational Methods in Applied Mathematics, vol. 9, no. 2, pp. 165–191, 2009.
- T. Linß and N. Madden, “Layer-adapted meshes for a linear system of coupled singularly perturbed reaction-diffusion problems,” IMA Journal of Numerical Analysis, vol. 29, no. 1, pp. 109–125, 2009.
- J. M. Melenk, L. Oberbroeckling, and C. Xenophontos, “Analytic regularity for a singularly perturbed system of reaction-diffusion equations with multiple scales: a road map,” submitted.
- T. Linß, “Analysis of an upwind finite-difference scheme for a system of coupled singularly perturbed convection-diffusion equations,” Computing, vol. 79, no. 1, pp. 23–32, 2007.
- H.-G. Roos and C. Reibiger, “Numerical analysis of a system of singularly perturbed convection-diffusion equations related to optimal control,” Numerical Mathematics: Theory, Methods and Applications, vol. 4, no. 4, pp. 562–575, 2011.
- E. O'Riordan and M. Stynes, “Numerical analysis of a strongly coupled system of two singularly perturbed convection-diffusion problems,” Advances in Computational Mathematics, vol. 30, no. 2, pp. 101–121, 2009.
- H.-G. Roos and C. Reibiger, “Analysis of a strongly coupled system of two convection-diffusion equations with full layer interaction,” Zeitschrift für Angewandte Mathematik und Mechanik, vol. 91, no. 7, pp. 537–543, 2011.
- T. Linss, “Analysis of a system of singularly perturbed convection-diffusion equations with strong coupling,” SIAM Journal on Numerical Analysis, vol. 47, no. 3, pp. 1847–1862, 2009.
- H.-G. Roos, “Special features of strongly coupled systems of convection-diffusion equations with two small parameters,” Applied Mathematics Letters, vol. 25, no. 8, pp. 1127–1130, 2012.