A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Some Techniques for Solving “Stiff” Equations
The Structural Dynamics involves a large amount of computational effort. Most dynamic structural models require the solution of a set of 2nd order differential equations. There are developed integration techniques for the 1st order and 2nd order differential equation. The 2nd order set of equations is submitted to a transformation [12] in order to obtain the first order system. This paper deals with the “stiff” systems of 1st order differential equations. From the physical point of view the stiff system consists of two components – one with a fast dynamic behavior and other one, slow. The ignoring of high frequency component may lead the wrong results. There are presented some advanced solution methods, criteria for choosing the appropriate techniques and a case study.
Some Techniques for Solving “Stiff” Equations
The Structural Dynamics involves a large amount of computational effort. Most dynamic structural models require the solution of a set of 2nd order differential equations. There are developed integration techniques for the 1st order and 2nd order differential equation. The 2nd order set of equations is submitted to a transformation [12] in order to obtain the first order system. This paper deals with the “stiff” systems of 1st order differential equations. From the physical point of view the stiff system consists of two components – one with a fast dynamic behavior and other one, slow. The ignoring of high frequency component may lead the wrong results. There are presented some advanced solution methods, criteria for choosing the appropriate techniques and a case study.
Some Techniques for Solving “Stiff” Equations
Victor-Octavian Roşca (author)
2005
Article (Journal)
Electronic Resource
Unknown
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