Modelica.UsersGuide Modelica.UsersGuide




Package Modelica is a standardized and pre-defined package
that is developed together with the Modelica language from the
Modelica Association, see
http://www.Modelica.org.
It is also called Modelica Standard Library.
It provides constants, types, connectors, partial models and model
components in various disciplines.




This is a short User's Guide for
the overall library. Some of the main sublibraries have their own
User's Guides that can be accessed by the following links:






Digital
   
   Library for digital electrical components based on the VHDL standard
   (2-,3-,4-,9-valued logic)




FluxTubes
    
   Library for modelling of electromagnetic devices with lumped magnetic networks




MultiBody
    
   Library to model 3-dimensional mechanical systems




Rotational
    
   Library to model 1-dimensional mechanical systems




Fluid
    Library of 1-dim. thermo-fluid flow models using the Modelica.Media media description


Media
    
   Library of media property models



SIunits 
   Library of type definitions based on SI units according to ISO 31-1992




StateGraph
    
   Library to model discrete event and reactive systems by hierarchical state machines




Utilities
    
   Library of utility functions especially for scripting (Files, Streams, Strings, System)







Extends from Modelica.Icons.Information (Icon for general information packages).

Package Content




NameDescription


Modelica.UsersGuide.Overview Overview
Overview of Modelica Library


Modelica.UsersGuide.Connectors Connectors
Connectors


Modelica.UsersGuide.Conventions Conventions
Conventions


Modelica.UsersGuide.ParameterDefaults ParameterDefaults
Parameter defaults


Modelica.UsersGuide.ModelicaLicense2 ModelicaLicense2
Modelica License 2


Modelica.UsersGuide.ReleaseNotes ReleaseNotes
Release notes


Modelica.UsersGuide.Contact Contact
Contact








Modelica.UsersGuide.Overview
Modelica.UsersGuide.Overview





The Modelica Standard Library consists of the following
main sub-libraries:






Library Components Description




 
 
 
 Analog

 Analog electric and electronic components, such as
 resistor, capacitor, transformers, diodes, transistors,
 transmission lines, switches, sources, sensors.
 		





 
 
 
 Digital

 Digital electrical components based on the VHDL standard,
 like basic logic blocks with 9-value logic, delays, gates,
 sources, converters between 2-, 3-, 4-, and 9-valued logic.
 		





 
 
 
 Machines

            Electrical asynchronous-, synchronous-, and DC-machines
 (motors and generators) as well as 3-phase transformers.
 		





 
 
 
 FluxTubes

Based on magnetic flux tubes concepts. Especially to model electro-magnetic actuators. Nonlinear shape, force, leackage, and material models. Material data for steel, electric sheet, pure iron, Cobalt iron, Nickel iron, NdFeB, Sm2Co17, and more.
 		





 
 
 
 Translational

 1-dim. mechanical, translational systems, e.g.,
 sliding mass, mass with stops, spring, damper.
 		





 
 
 
 Rotational

 1-dim. mechanical, rotational systems, e.g., inertias, gears,
 planetary gears, convenient definition of speed/torque dependent friction
 (clutches, brakes, bearings, ..)
 		





 

 
 		
 
 MultiBody
 3-dim. mechanical systems consisting of joints, bodies, force and
 sensor elements. Joints can be driven by drive trains defined by
 1-dim. mechanical system library (Rotational).
 Every component has a default animation.
 Components can be arbitrarily connected together.
 





 
 
 
 Fluid

        1-dim. thermo-fluid flow in networks of vessels, pipes,
        fluid machines, valves and fittings. All media from the
        Modelica.Media library can be used (so incompressible or compressible,
        single or multiple substance, one or two phase medium).
 		





 
 
 
 Media

 Large media library providing models and functions
 to compute media properties, such as h = h(p,T), d = d(p,T),
 for the following media:
 
    
 
  •  1240 gases and mixtures between these gases.
    • 
 
  •  incompressible, table based liquids (h = h(T), etc.).
    • 
 
  •  compressible liquids
    • 
 
  •  dry and moist air
    • 
 
  •  high precision model for water (IF97).
    • 
 

 		





 
 
 
 FluidHeatFlow,
 HeatTransfer
 Simple thermo-fluid pipe flow, especially to model cooling of machines
 with air or water (pipes, pumps, valves, ambient, sensors, sources) and
 lumped heat transfer with heat capacitors, thermal conductors, convection,
 body radiation, sources and sensors.
 





 

 
 		
 
 Blocks

 Input/output blocks to model block diagrams and logical networks, e.g.,
 integerator, PI, PID, transfer function, linear state space system,
 sampler, unit delay, discrete transfer function, and/or blocks,
 timer, hysteresis, nonlinear and routing blocks, sources, tables.
 		





 
 
 
 StateGraph

 Hierarchical state machines with a similar modeling power as Statecharts.
 Modelica is used as synchronous action language, i.e., deterministic
 behavior is guaranteed
 		





 
 A = [1,2,3;
   3,4,5;
   2,1,4];
 b = {10,22,12};
 x = Matrices.solve(A,b);
 Matrices.eigenValues(A);
 

 		
 
 Math,
 Utilities

 Functions operating on vectors and matrices, such as for solving
 linear systems, eigen and singular values etc.,  and
 functions operating on strings, streams, files, e.g.,
 to copy and remove a file or sort a vector of strings.
 		








Extends from Modelica.Icons.Information (Icon for general information packages).





Modelica.UsersGuide.Connectors
Modelica.UsersGuide.Connectors






The Modelica standard library defines the most important
elementary connectors in various domains. If any possible,
a user should utilize these connectors in order that components
from the Modelica Standard Library and from other libraries
can be combined without problems.
The following elementary connectors are defined
(the meaning of potential, flow, and stream
variables is explained in section "Connector Equations" below):






domain
   potential
variables		
   flow
variables		
   stream
variables		
   connector definition
   icons



electrical
analog		
   electrical potential
   electrical current
   
   Modelica.Electrical.Analog.Interfaces
     
Pin, PositivePin, NegativePin		
   



electrical
multi-phase		
   vector of electrical pins
   Modelica.Electrical.MultiPhase.Interfaces
     
Plug, PositivePlug, NegativePlug		
   



electrical 
sphace phasor		
   2 electrical potentials
   2 electrical currents
   
   Modelica.Electrical.Machines.Interfaces
     
SpacePhasor		
   



electrical 
digital		
   Integer (1..9)
   
   
   Modelica.Electrical.Digital.Interfaces
     
DigitalSignal, DigitalInput, DigitalOutput		
   



magnetic
   magnetic potential
   magnetic flux
   
   
Modelica.Magnetic.FluxTubes.Interfaces
     
MagneticPort, PositiveMagneticPort, 
NegativeMagneticPort		
   



translational
   distance
   cut-force
   
   Modelica.Mechanics.Translational.Interfaces
     
Flange_a, Flange_b		
   



rotational
   angle
   cut-torque
   
   Modelica.Mechanics.Rotational.Interfaces
     
Flange_a, Flange_b		
   



3-dim.
mechanics		
   position vector

    orientation object		
   cut-force vector

    cut-torque vector		
   
   Modelica.Mechanics.MultiBody.Interfaces
     
Frame, Frame_a, Frame_b, Frame_resolve		
   



simple
fluid flow		
   pressure

    specific enthalpy		
   mass flow rate

    enthalpy flow rate		
   
   Modelica.Thermal.FluidHeatFlow.Interfaces
     
FlowPort, FlowPort_a, FlowPort_b		
   



thermo
fluid flow		
   pressure
   mass flow rate
   specific enthalpy
mass fractions		
   
Modelica.Fluid.Interfaces
     
FluidPort, FluidPort_a, FluidPort_b		
   



heat
transfer		
   temperature
   heat flow rate
   
   Modelica.Thermal.HeatTransfer.Interfaces
     
HeatPort, HeatPort_a, HeatPort_b		
   



block
diagram		
   Real variable

    Integer variable

    Boolean variable		
   
   
   Modelica.Blocks.Interfaces
     
RealSignal, RealInput, RealOutput

      IntegerSignal, IntegerInput, IntegerOutput

      BooleanSignal, BooleanInput, BooleanOutput		
   



state
machine		
   Boolean variables

    (occupied, set, 

     available, reset)		
   
   
   Modelica.StateGraph.Interfaces
     
Step_in, Step_out, Transition_in, Transition_out		
   



 
Connectors from other libraries



hydraulic
   pressure
   volume flow rate
   
   HyLibLight.Interfaces
     
Port_A, Port_b		
   



pneumatic
   pressure
   mass flow rate
   
   PneuLibLight.Interfaces
     
Port_1, Port_2		
   






In all domains, usually 2 connectors are defined. The variable declarations
are identical, only the icons are different in order that it is easy
to distinguish connectors of the same domain that are attached at the same
component.




Hierarchical Connectors 



Modelica supports also hierarchical connectors, in a similar way as hierarchical models.
As a result, it is, e.g., possible, to collect elementary connectors together.
For example, an electrical plug consisting of two electrical pins can be defined as:






connector Plug
   import Modelica.Electrical.Analog.Interfaces;
   Interfaces.PositivePin phase;
   Interfaces.NegativePin ground;
end Plug;







With one connect(..) equation, either two plugs can be connected
(and therefore implicitly also the phase and ground pins) or a
Pin connector can be directly connected to the phase or ground of
a Plug connector, such as "connect(resistor.p, plug.phase)".




Connector Equations




The connector variables listed above have been basically determined
with the following strategy:




    

  1.  State the relevant balance equations and boundary
     conditions of a volume for the particular physical domain.
    2. 

  2.  Simplify the balance equations and boundary conditions
     of (1) by taking the
     limit of an infinitesimal small volume
     (e.g., thermal domain:
      temperatures are identical and heat flow rates
      sum up to zero).

    3. 

  3.  Use the variables needed for the balance equations
     and boundary conditions of (2)
     in the connector and select appropriate Modelica
     prefixes, so that these equations
     are generated by the Modelica connection semantics.





The Modelica connection semantics is sketched at hand
of an example: Three connectors c1, c2, c3 with the definition




connector Demo
  Real        p;  // potential variable
  flow   Real f;  // flow variable
  stream Real s;  // stream variable
end Demo;





are connected together with




   connect(c1,c2);
   connect(c1,c3);





then this leads to the following equations:




  // Potential variables are identical
  c1.p = c2.p;
  c1.p = c3.p;

  // The sum of the flow variables is zero
  0 = c1.f + c2.f + c3.f;

  /* The sum of the product of flow variables and upstream stream variables is zero
     (this implicit set of equations is explicitly solved when generating code;
     the "<undefined>" parts are defined in such a way that
     inStream(..) is continuous).
  */
  0 = c1.f*(if c1.f > 0 then s_mix else c1.s) +
      c2.f*(if c2.f > 0 then s_mix else c2.s) +
      c3.f*(if c3.f > 0 then s_mix else c3.s);

  inStream(c1.s) = if c1.f > 0 then s_mix else <undefined>;
  inStream(c2.s) = if c2.f > 0 then s_mix else <undefined>;
  inStream(c3.s) = if c3.f > 0 then s_mix else <undefined>;





Extends from Modelica.Icons.Information (Icon for general information packages).





Modelica.UsersGuide.ParameterDefaults
Modelica.UsersGuide.ParameterDefaults






In this section the convention is summarized how default parameters are
handled in the Modelica Standard Library (since version 3.0).





Many models in this library have parameter declarations to define
constants of a model that might be changed before simulation starts.
Example:






model SpringDamper
parameter Real c(final unit="N.m/rad")    = 1e5 "Spring constant";
parameter Real d(final unit="N.m.s/rad")  = 0   "Damping constant";
parameter Modelica.SIunits.Angle phi_rel0 = 0   "Unstretched spring angle";
...
end SpringDamper;







In Modelica it is possible to define a default value of a parameter in
the parameter declaration. In the example above, this is performed for
all parameters. Providing default values for all parameters can lead to
errors that are difficult to detect, since a modeler may have forgotten
to provide a meaningful value (the model simulates but gives wrong
results due to wrong parameter values). In general the following basic
situations are present:




    

  1.  The parameter value could be anything (e.g., a spring constant or
  a resistance value) and therefore the user should provide a value in
  all cases. A Modelica translator should warn, if no value is provided.

    2. 


  2.  The parameter value is not changed in > 95 % of the cases
  (e.g., initialization or visualization parameters, or parameter phi_rel0
  in the example above). In this case a default parameter value should be
  provided, in order that the model or function can be conveniently
  used by a modeler.

    3. 


  3.  A modeler would like to quickly utilize a model, e.g.,
  
  In all these cases, it would be not practical, if the modeler would
  have to provide explicit values for all parameters first.
  
    4. 





To handle the conflicting goals of (1) and (3), the Modelica Standard Library
uses two approaches to define default parameters, as demonstrated with the
following example:






model SpringDamper
parameter Real c(final unit="N.m/rad"  , start=1e5) "Spring constant";
parameter Real d(final unit="N.m.s/rad", start=  0) "Damping constant";
parameter Modelica.SIunits.Angle phi_rel0 = 0       "Unstretched spring angle";
...
end SpringDamper;

SpringDamper sp1;              // warning for "c" and "d"
SpringDamper sp2(c=1e4, d=0);  // fine, no warning







Both definition forms, using a "start" value (for "c" and "d") and providing
a declaration equation (for "phi_rel0"), are valid Modelica and define the value
of the parameter. By convention, it is expected that Modelica translators will
trigger a warning message for parameters that are not defined by a declaration
equation, by a modifier equation or in an initial equation/algorithm section.
A Modelica translator might have options to change this behavior, especially,
that no messages are printed in such cases and/or that an error is triggered
instead of a warning.





Extends from Modelica.Icons.Information (Icon for general information packages).





Modelica.UsersGuide.ModelicaLicense2
Modelica.UsersGuide.ModelicaLicense2




	The Modelica License 2





All files in this directory (Modelica) and in all
subdirectories, especially all files that build package "Modelica" and all
files in "Modelica/Resources/*" and "Modelica/help" are licensed by the Modelica Association under the Modelica License 2 (with exception of files
"Modelica/Resources/C-Sources/win32_dirent.*").



Licensor:

Modelica Association

(Ideella Föreningar 822003-8858 in Linköping) 

c/o PELAB, IDA, Linköpings Universitet 

S-58183 Linköping 

Sweden

email: Board@Modelica.org

web: http://www.Modelica.org



Copyright notices of the files:

Copyright © 1998-2010,
ABB, Austrian Institue of Technology, T. Bödrich, DLR, Dassault Systèmes AB, Fraunhofer, A. Haumer, Modelon,
TU Hamburg-Harburg, Politecnico di Milano, XRG Simulation.





The Modelica License 2

Frequently Asked Questions








The Modelica License 2




Preamble. The goal of this license is that Modelica related
model libraries, software, images, documents, data files etc. can be
used freely in the original or a modified form, in open source and in
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Developers of free Modelica packages are encouraged to utilize this
license for their work.




The Modelica License applies to any Original Work that contains the
following licensing notice adjacent to the copyright notice(s) for
this Original Work:



Licensed by the Modelica Association under the Modelica License 2



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  8. “Modelica package” means any Modelica library that is
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2. Grant of Copyright License. Licensor grants You a
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Frequently Asked Questions


This
section contains questions/answer to users and/or distributors of
Modelica packages and/or documents under Modelica License 2. Note,
the answers to the questions below are not a legal interpretation of
the Modelica License 2. In case of a conflict, the language of the
license shall prevail.



Using or Distributing a Modelica Package under the Modelica License 2



What are the main
differences to the previous version of the Modelica License?


    
	
  1. 
	Modelica License 1 is unclear whether the licensed Modelica package
	can be distributed under a different license. Version 2 explicitly
	allows that “Derivative Work” can be distributed under
	any license of Your choice, see examples in Section 1d) as to what
	qualifies as Derivative Work (so, version 2 is clearer).
    
	
  2. 
	If You modify a Modelica package under Modelica License 2 (besides
	fixing of errors, adding vendor specific Modelica annotations, using
	a subset of the classes of a Modelica package, or using another
	representation, e.g., a binary representation), you must rename the
	root-level name of the package for your distribution. In version 1
	you could keep the name (so, version 2 is more restrictive). The
	reason of this restriction is to reduce the risk that Modelica
	packages are available that have identical names, but different
	functionality.
    
	
  3. 
	Modelica License 1 states that “It is not allowed to charge a
	fee for the original version or a modified version of the software,
	besides a reasonable fee for distribution and support”.
	Version 2 has a similar intention for all Original Work under
	Modelica License 2 (to remain free of charge and open source)
	but states this more clearly as “No fee, neither as a
	copyright-license fee, nor as a selling fee for the copy as such may
	be charged”. Contrary to version 1, Modelica License 2 has no
	restrictions on fees for Derivative Work that is provided under a
	different license (so, version 2 is clearer and has fewer
	restrictions).
    
	
  4. 
	Modelica License 2 introduces several useful provisions for the
	licensee (articles 5, 6, 12), and for the licensor (articles 7, 12,
	13, 14) that have no counter part in version 1.
    
	
  5. 
	Modelica License 2 can be applied to all type of work, including
	documents, images and data files, contrary to version 1 that was
	dedicated for software only (so, version 2 is more general).
    




Can I distribute a
Modelica package (under Modelica License 2) as part of my commercial
Modelica modeling and simulation environment?


Yes,
according to Section 2c). However, you are not allowed to charge a
fee for this part of your environment. Of course, you can charge for
your part of the environment.




Can I distribute a
Modelica package (under Modelica License 2) under a different
license?


No.
The license of an unmodified Modelica package cannot be changed
according to Sections 2c) and 2d). This means that you cannot sell
copies of it, any distribution has to be free of charge.



Can I distribute a
Modelica package (under Modelica License 2) under a different license
when I first encrypt the package?


No.
Merely encrypting a package does not qualify for Derivative Work and
therefore the encrypted package has to stay under Modelica License 2.



Can I distribute a
Modelica package (under Modelica License 2) under a different license
when I first add classes to the package?


No.
The package itself remains unmodified, i.e., it is Original Work, and
therefore the license for this part must remain under Modelica
License 2. The newly added classes can be, however, under a different
license.




Can
I copy a class out of a Modelica package (under Modelica License 2)
and include it unmodified in a Modelica package
under a commercial/proprietary license?


No,
according to article 2c). However, you can include model, block,
function, package, record and connector classes in your Modelica
package under Modelica License 2. This means that your
Modelica package could be under a commercial/proprietary license, but
one or more classes of it are under Modelica License 2.
Note, a
“type” class (e.g., type Angle = Real(unit=”rad”))
can be copied and included unmodified under a commercial/proprietary
license (for details, see the next question).



Can
I copy a type class or part of a model, block,
function, record, connector class, out of a Modelica package (under
Modelica License 2) and include it modified or unmodified in a
Modelica package under a commercial/proprietary
license


Yes,
according to article 2d), since this will in the end usually qualify
as Derivative Work. The reasoning is the following: A type class or
part of another class (e.g., an equation, a declaration, part of a
class description) cannot be utilized “by its own”. In
order to make this “usable”, you have to add additional
code in order that the class can be utilized. This is therefore
usually Derivative Work and Derivative Work can be provided under a
different license. Note, this only holds, if the additional code
introduced is sufficient to qualify for Derivative Work. Merely, just
copying a class and changing, say, one character in the documentation
of this class would be no Derivative Work and therefore the copied
code would have to stay under Modelica License 2.



Can
I copy a class out of a Modelica package (under Modelica License 2)
and include it in modified form in a
commercial/proprietary Modelica package?


Yes.
If the modification can be seen as a “Derivative Work”,
you can place it under your commercial/proprietary license. If the
modification does not qualify as “Derivative Work” (e.g.,
bug fixes, vendor specific annotations), it must remain under
Modelica License 2. This means that your Modelica package could be
under a commercial/proprietary license, but one or more parts of it
are under Modelica License 2.



Can I distribute a
“save total model” under my commercial/proprietary
license, even if classes under Modelica License 2 are included?


Your
classes of the “save total model” can be distributed
under your commercial/proprietary license, but the classes under
Modelica License 2 must remain under Modelica License 2. This means
you can distribute a “save total model”, but some parts
might be under Modelica License 2.



Can I distribute a
Modelica package (under Modelica License 2) in encrypted form?


Yes.
Note, if the encryption does not allow “copying” of
classes (in to unencrypted Modelica source code), you have to send
the Modelica source code of this package to your customer, if he/she
wishes it, according to article 6.



Can I distribute an
executable under my commercial/proprietary license, if the model from
which the executable is generated uses models from a Modelica package
under Modelica License 2?


Yes,
according to article 2d), since this is seen as Derivative Work. The
reasoning is the following: An executable allows the simulation of a
concrete model, whereas models from a Modelica package (without
pre-processing, translation, tool run-time library) are not able to
be simulated without tool support. By the processing of the tool and
by its run-time libraries, significant new functionality is added (a
model can be simulated whereas previously it could not be simulated)
and functionality available in the package is removed (e.g., to build
up a new model by dragging components of the package is no longer
possible with the executable).



Is my modification to
a Modelica package (under Modelica License 2) a Derivative Work?


It
is not possible to give a general answer to it. To be regarded as "an
original work of authorship", a derivative work must be
different enough from the original or must contain a substantial
amount of new material. Making minor changes or additions of little
substance to a preexisting work will not qualify the work as a new
version for such purposes.




Using or Distributing a Modelica Document under the Modelica License 2



This
section is devoted especially for the following applications:


    
	
  1. 
	A Modelica tool extracts information out of a Modelica package and
	presents the result in form of a “manual” for this
	package in, e.g., html, doc, or pdf format.
    
	
  2. 
	The Modelica language specification is a document defining the
	Modelica language. It will be licensed under Modelica License 2.
    
	
  3. 
	Someone writes a book about the Modelica language and/or Modelica
	packages and uses information which is available in the Modelica
	language specification and/or the corresponding Modelica package.
    




Can I sell a manual
that was basically derived by extracting information automatically
from a Modelica package under Modelica License 2 (e.g., a “reference
guide” of the Modelica Standard Library):


Yes.
Extracting information from a Modelica package, and providing it in a
human readable, suitable format, like html, doc or pdf format, where
the content is significantly modified (e.g. tables with interface
information are constructed from the declarations of the public
variables) qualifies as Derivative Work and there are no restrictions
to charge a fee for Derivative Work under alternative 2d).



Can
I copy a text passage out of a Modelica document (under Modelica
License 2) and use it unmodified in my document
(e.g. the Modelica syntax description in the Modelica Specification)?


Yes.
In case you distribute your document, the copied parts are still
under Modelica License 2 and you are not allowed to charge a license
fee for this part. You can, of course, charge a fee for the rest of
your document.



Can
I copy a text passage out of a Modelica document (under Modelica
License 2) and use it in modified form in my
document?


Yes,
the creation of Derivative Works is allowed. In case the content is
significantly modified this qualifies as Derivative Work and there
are no restrictions to charge a fee for Derivative Work under
alternative 2d).



Can I sell a printed
version of a Modelica document (under Modelica License 2), e.g., the
Modelica Language Specification?


No,
if you are not the copyright-holder, since article 2c) does not allow
a selling fee for a (in this case physical) copy. However, mere
printing and shipping costs may be recovered.




Extends from Modelica.Icons.Information (Icon for general information packages).





Modelica.UsersGuide.Contact
Modelica.UsersGuide.Contact




The Modelica Standard Library (this Modelica package) is developed by many people from different organizations (see list below). It is licensed under the Modelica License 2 by:


 


Modelica Association


(Ideella Föreningar 822003-8858 in Linköping)


c/o PELAB, IDA, Linköpings Universitet


S-58183 Linköping


Sweden


email: Board@Modelica.org


web: http://www.Modelica.org


  


The development of this Modelica package is organized by:


Martin Otter


Deutsches Zentrum für Luft und Raumfahrt e.V. (DLR)


Institut für Robotik und Mechatronik


Abteilung für Systemdynamik und Regelungstechnik


Postfach 1116


D-82230 Wessling


Germany


email: Martin.Otter@dlr.de




Since end of 2007, the development of the sublibraries of package Modelica is organized by personal and/or organizational library officers assigned by the Modelica Association. They are responsible for the maintenance and for the further organization of the development. Other persons may also contribute, but the final decision for library improvements and/or changes is performed by the responsible library officer(s). In order that a new sublibrary or a new version of a sublibrary is ready to be released, the responsible library officers report the changes to the members of the Modelica Association and the library is made available for beta testing to interested parties before a final decision. A new release of a sublibrary is formally decided by voting of the Modelica Association members.


The following library officers are currently assigned:





Sublibraries 
   Library officers




 Complex 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

        (Martin Otter)

        Anton Haumer, Consultant, St.Andrae-Woerdern, Austria, 

        Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral)






 Modelica.Blocks 

                      Modelica.Constants 		
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

        (Martin Otter)		




 Modelica.Electrical.Analog

                      Modelica.Electrical.Digital

                      Modelica.Electrical.Spice3 		
    Fraunhofer Institute for Integrated Circuits, Dresden, Germany

      (Christoph Clauss)		




 Modelica.ComplexBlocks

                      Modelica.Electrical.Machines

                      Modelica.Electrical.MultiPhase

                      Modelica.Electrical.QuasiStationary 		
    Anton Haumer, Consultant, St.Andrae-Woerdern, Austria, and

      Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral)		




 Modelica.Magnetic.FluxTubes 
    Thomas Bödrich, Dresden, Germany

                               (Dresden University of Technology,

                               Institute of Electromechanical and Electronic Design)





 Modelica.Magnetic.FundamentalWave 
    Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral),

                     Anton Haumer, Consultant, St.Andrae-Woerdern, Austria





 Modelica.Fluid 
    Politecnico di Milano (Francesco Casella), and

                            Rüdiger Franke (ABB)		




 Modelica.Fluid.Dissipation 
    XRG Simulation, Hamburg, Germany (Stefan Wischhusen)




 Modelica.Icons 
    Modelon AB, Lund, Sweden (Johan Andreasson) 




 Modelica.Math 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)		




 Modelica.ComplexMath 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)

      Anton Haumer, Consultant, St.Andrae-Woerdern, Austria,

      Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral)
   		




 Modelica.Mechanics.MultiBody 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter),

       Modelon AB, Lund, Sweden (Johan Andreasson) 		




 Modelica.Mechanics.Rotational 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)

      Anton Haumer, Consultant, St.Andrae-Woerdern, Austria,

      Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral),

      Modelon AB, Lund, Sweden (Johan Andreasson)		




 Modelica.Mechanics.Translational 
    Anton Haumer, Consultant, St.Andrae-Woerdern, Austria,

      Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral), 

      DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)

       Modelon AB, Lund, Sweden (Johan Andreasson)		




 Modelica.Media 
    Modelon AB, Lund, Sweden (Hubertus Tummescheit) 




 Modelica.SIunits 

      Modelica.StateGraph 		
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)		




 Modelica.Thermal.FluidHeatFlow 

      Modelica.Thermal.HeatTransfer 		
    Anton Haumer, Consultant, St.Andrae-Woerdern, Austria, and

      Austrian Institute of Technology (AIT), Vienna, Austria (Christian Kral)		


 Modelica.Utilities 
    DLR Institute of Robotics and Mechatronics, Oberpfaffenhofen, Germany

      (Martin Otter)

      Dassault Systèmes AB, Lund, Sweden (Hans Olsson)		







The following people have directly contributed to the implementation
of the Modelica package (many more people have contributed to the design):






Marcus Baur 
    Institute of Robotics and Mechatronics

     DLR, German Aerospace Center, 

     Oberpfaffenhofen, Germany		
    Complex

                     Modelica.Math.Vectors

                     Modelica.Math.Matrices		




Peter Beater 
    University of Paderborn, Germany
    Modelica.Mechanics.Translational 




Thomas Bödrich 
    Dresden University of Technology, Germany
    Modelica.Magnetic.FluxTubes 


Dag Brück 
    Dassault Systèmes AB, Lund, Sweden
    Modelica.Utilities




Francesco Casella 
    Politecnico di Milano, Milano, Italy
    Modelica.Fluid

                            Modelica.Media		




Christoph Clauss 
    Fraunhofer Institute for Integrated Circuits,
 Dresden, Germany		
    Modelica.Electrical.Analog

     Modelica.Electrical.Digital

     Modelica.Electrical.Spice3		




Jonas Eborn 
    Modelon AB, Lund, Sweden
    Modelica.Media




Hilding Elmqvist 
    Dassault Systèmes AB, Lund, Sweden
    Modelica.Mechanics.MultiBody

                   Modelica.Fluid

     Modelica.Media

     Modelica.StateGraph

     Modelica.Utilities

     Conversion from 1.6 to 2.0		




Rüdiger Franke 
    ABB Corporate Research,
Ladenburg, German		
    Modelica.Fluid

                            Modelica.Media		




Manuel Gräber 
    Institut für Thermodynamik, 

     Technische Universität Braunschweig, 

     Germany		
    Modelica.Fluid




Anton Haumer 
    Consultant, St.Andrae-Woerdern,
Austria		
    Modelica.ComplexBlocks

     Modelica.Electrical.Machines

     Modelica.Electrical.Multiphase

     Modelica.Electrical.QuasiStationary

     Modelica.Magnetics.FundamentalWave

     Modelica.Mechanics.Rotational

     Modelica.Mechanics.Translational

     Modelica.Thermal.FluidHeatFlow

     Modelica.Thermal.HeatTransfer

     Modelica.ComplexMath

     Conversion from 1.6 to 2.0

     Conversion from 2.2 to 3.0		




Hans-Dieter Joos 
    Institute of Robotics and Mechatronics

     DLR, German Aerospace Center, 

     Oberpfaffenhofen, Germany		
    Modelica.Math.Matrices




Christian Kral 
    Austrian Institute of Technology (AIT), Vienna, Austria
    Modelica.ComplexBlocks

     Modelica.Electrical.Machines

     Modelica.Electrical.MultiPhase

     Modelica.Electrical.QuasiStationary

     Modelica.Magnetics.FundamentalWave

     Modelica.Mechanics.Rotational

     Modelica.Mechanics.Translational

     Modelica.Thermal.FluidHeatFlow

     Modelica.Thermal.HeatTransfer

     Modelica.ComplexMath
     		




Sven Erik Mattsson 
    Dassault Systèmes AB, Lund, Sweden
    Modelica.Mechanics.MultiBody



Hans Olsson 
    Dassault Systèmes AB, Lund, Sweden
    Modelica.Blocks

     Modelica.Math.Matrices

     Modelica.Utilities

     Conversion from 1.6 to 2.0

     Conversion from 2.2 to 3.0		




Martin Otter 
    Institute of Robotics and Mechatronics

     DLR, German Aerospace Center, 

     Oberpfaffenhofen, Germany		
    Complex

     Modelica.Blocks

     Modelica.Fluid

     Modelica.Mechanics.MultiBody

     Modelica.Mechanics.Rotational

     Modelica.Mechanics.Translational

     Modelica.Math

     Modelica.ComplexMath

     Modelica.Media

     Modelica.SIunits

     Modelica.StateGraph

     Modelica.Thermal.HeatTransfer

     Modelica.Utilities

     ModelicaReference

     Conversion from 1.6 to 2.0

     Conversion from 2.2 to 3.0		




Katrin Prölß 
    Modelon AB, Lund, Sweden

                            until 2008:

                            Department of Technical Thermodynamics,

     Technical University Hamburg-Harburg,
Germany		
    Modelica.Fluid

                            Modelica.Media		




Christoph C. Richter 
    until 2009:

     Institut für Thermodynamik, 

     Technische Universität Braunschweig, 

     Germany		
    Modelica.Fluid

                            Modelica.Media		




André Schneider 
    Fraunhofer Institute for Integrated Circuits,
 Dresden, Germany		
    Modelica.Electrical.Analog

     Modelica.Electrical.Digital		



Christian Schweiger 
    Until 2006:

     Institute of Robotics and Mechatronics,

     DLR, German Aerospace Center,

     Oberpfaffenhofen, Germany		
    Modelica.Mechanics.Rotational

     ModelicaReference

     Conversion from 1.6 to 2.0		




Michael Sielemann 
    Institute of Robotics and Mechatronics

     DLR, German Aerospace Center, 

     Oberpfaffenhofen, Germany		
    Modelica.Fluid




Michael Tiller 
    Emmeskay, Inc., Dearborn, MI, U.S.A, 

     (previously Ford Motor Company, Dearborn) 		
    Modelica.Media

     Modelica.Thermal.HeatTransfer		



Hubertus Tummescheit 
    Modelon AB, Lund, Sweden 
    Modelica.Media

     Modelica.Thermal.HeatTransfer		




Thorsten Vahlenkamp 
    until 2010:

                     XRG Simulation GmbH, Hamburg, Germany		
    Modelica.Fluid.Dissipation




Nico Walter 
    Master thesis at HTWK Leipzig

     (Prof. R. Müller) and

     DLR Oberpfaffenhofen, Germany		
    Modelica.Math.Matrices




Manuel Wetter 
    Lawrence Berkeley National Laboratory; U.S.A
    Modelica.Fluid




Hans-Jürg Wiesmann 
    Switzerland
    Modelica.ComplexMath




Stefan Wischhusen 
    XRG Simulation GmbH, Hamburg, Germany
    Modelica.Fluid.Dissipation







Extends from Modelica.Icons.Contact (Icon for contact information).



Automatically generated Fri Nov 12 16:27:29 2010.