@inproceedings {INPROC-1995-12,
   author = {Hans-Joachim Bungartz},
   title = {{Applications of computer algebra in scientific computing}},
   booktitle = {Electronic Proceedings of the 1. IMACS Conference on Applications of Computer Algebra},
   editor = {M. Jahn and S. Steinberg and M. Wester},
   publisher = {IMACS/UNM},
   institution = {University of Stuttgart, Faculty of Computer Science, Electrical Engineering, and Information Technology, Germany},
   type = {Conference Paper},
   month = {May},
   year = {1995},
   language = {English},
   cr-category = {G.0 Mathematics of Computing General},
   contact = {Hans-Joachim Bungartz bungartz@ipvs.uni-stuttgart.de},
   department = {University of Stuttgart, Institute of Parallel and Distributed Systems, Simulation of Large Systems},
   abstract = {no abstract available},
   url = {http://www2.informatik.uni-stuttgart.de/cgi-bin/NCSTRL/NCSTRL_view.pl?id=INPROC-1995-12&amp;engl=1}
}

@inproceedings {INPROC-1995-11,
   author = {H.-J. Bungartz and W. Huber},
   title = {{First experiments with turbulence simulation on workstation networks using sparse grid methods}},
   booktitle = {Computational Fluid Dynamics on Parallel Systems},
   editor = {S. Wagner},
   publisher = {Vieweg},
   institution = {University of Stuttgart, Faculty of Computer Science, Electrical Engineering, and Information Technology, Germany},
   series = {Notes on Numerical Fluid Mechanics},
   volume = {50},
   type = {Conference Paper},
   month = {January},
   year = {1995},
   language = {English},
   cr-category = {I.6 Simulation and Modeling},
   contact = {Hans-Joachim Bungartz bungartz@ipvs.uni-stuttgart.de},
   department = {University of Stuttgart, Institute of Parallel and Distributed Systems, Simulation of Large Systems},
   abstract = {no abstract available},
   url = {http://www2.informatik.uni-stuttgart.de/cgi-bin/NCSTRL/NCSTRL_view.pl?id=INPROC-1995-11&amp;engl=1}
}

@inproceedings {INPROC-1995-10,
   author = {H.-J. Bungartz and S. Schulte},
   title = {{Coupled problems in microsystem technology}},
   booktitle = {Numerical Treatment of Coupled Systems},
   address = {Braunschweig, Wiesbaden},
   publisher = {Vieweg},
   institution = {University of Stuttgart, Faculty of Computer Science, Electrical Engineering, and Information Technology, Germany},
   series = {Notes on Numerical Fluid Mechanics},
   volume = {51},
   pages = {11--24},
   type = {Conference Paper},
   month = {January},
   year = {1995},
   isbn = {3-528-07651-8},
   language = {German},
   cr-category = {I.6 Simulation and Modeling},
   contact = {Hans-Joachim Bungartz bungartz@ipvs.uni-stuttgart.de},
   department = {University of Stuttgart, Institute of Parallel and Distributed Systems, Simulation of Large Systems},
   abstract = {In microsystem technology, the numerical simulation of coupled problems is one
      of the principal challenges. There are three main reasons for the fact that,
      here, the coupling of different physical effects (structural dynamics, fluid
      dynamics, heat transfer, or electromagnetics, e.g.) is more frequently
      encountered than in the macro world: First, aspects of scaling often lead to a
      dominance of surface effects on volume dependent effects. Second, especially in
      sensors a lot of different physical phenomena are used for signal conversion,
      and, finally, in some microsystems different physical effects have an influence
      on each other.
      
      We present a classification of the most important couplings in the microsystem
      world, and we give a survey on existing solution techniques with emphasis on
      methods based on the so-called partitioned solution. Here, there is no joint
      model, neither continuous nor discrete, but the coupled problem is solved by an
      outer iteration realizing the coupling and by arbitrary inner solution
      processes for each single problem. The coupling is done via changed boundary
      conditions, geometries, or parameters after each step of iteration. This
      approach seems to be advantageous, since its modularity allows the use of
      existing and efficient codes for each sub-problem. Therefore, only the outer
      iteration has to be organized with some kind of interface for the coupling.
      Furthermore, this technique seems to be perfectly suited for parallelization,
      especially for the use of (heterogeneous) workstation clusters.
      
      Finally, some first numerical results concerning the simulation of a
      micro-miniaturized two-valve membrane pump are presented.},
   url = {http://www2.informatik.uni-stuttgart.de/cgi-bin/NCSTRL/NCSTRL_view.pl?id=INPROC-1995-10&amp;engl=1}
}

@inbook {INBOOK-1995-01,
   author = {S. Schulte and A. Maurer and H.-J. Bungartz},
   title = {{Modular solution approach for simulation of coupled physical phenomena}},
   series = {Simulation and Design of Microsystems and Microstructures},
   address = {Southhampton},
   publisher = {Computational Mechanics Publications},
   pages = {201--210},
   type = {Article in Book},
   month = {December},
   year = {1995},
   isbn = {1-85312-390-0},
   language = {English},
   cr-category = {I.6 Simulation and Modeling},
   contact = {Hans-Joachim Bungartz bungartz@ipvs.uni-stuttgart.de},
   department = {University of Stuttgart, Institute of Parallel and Distributed Systems, Simulation of Large Systems},
   abstract = {no abstract available},
   url = {http://www2.informatik.uni-stuttgart.de/cgi-bin/NCSTRL/NCSTRL_view.pl?id=INBOOK-1995-01&amp;engl=1}
}