Difference between revisions of "Convection Reaction"

Latest revision as of 11:28, 30 November 2023

Convection Reaction
Background
Benchmark ID	convectionReaction_n84m1q1
Category	slicot
System-Class	LTI-FOS
Parameters
nstates	84
ninputs	1
noutputs	1
nparameters	0
components	A, B, C
Copyright
License	NA
Creator	Christian Himpe
Editor	Christian Himpe Petar Mlinarić
Location
NA

Description

This benchmark models a chemical reaction by a convection-reaction partial differential equation on the unit square, given by:

\frac{\partial x}{\partial t} = \frac{\partial^2 x}{\partial y^2} + \frac{\partial^2 x}{\partial z^2} + 20 \frac{\partial x}{\partial z} - 180 x + f(y,z) x(t),

with Dirichlet boundary conditions and discretized with centered difference approximation.

The input vector $B$ is composed of random elements and the output vector equals the input vector $C = B^T$ .

More details can be found in ^[1], ^[2], ^[3] and ^[4], ^[5].

Origin

This benchmark is part of the SLICOT Benchmark Examples for Model Reduction^[5].

Data

The system matrices $A$ , $B$ , $C$ are available from the SLICOT benchmarks page: pde.zip and are stored as MATLAB .mat file.

Here is Python code for loading the matrices ( $A$ is a sparse matrix of 16-bit integers and $B$ and $C$ are full matrices stored as sparse matrices):

import numpy as np
from scipy.io import loadmat

mat = loadmat('build.mat')
A = mat['A'].astype(np.float64)
B = mat['B'].toarray()
C = mat['C'].toarray()

Dimensions

System structure:

\begin{align} \dot{x}(t) &= A x(t) + B u(t) \\ y(t) &= C x(t) \end{align}

System dimensions:

$A \in \mathbb{R}^{84 \times 84}$ , $B \in \mathbb{R}^{84 \times 1}$ , $C \in \mathbb{R}^{1 \times 84}$ .

Citation

To cite this benchmark, use the following references:

For the benchmark itself and its data:

Niconet e.V., SLICOT - Subroutine Library in Systems and Control Theory, http://www.slicot.org

@MANUAL{slicot_pde,
 title =        {{SLICOT} - Subroutine Library in Systems and Control Theory},
 organization = {Niconet e.V.},
 address =      {\url{http://www.slicot.org}},
 key =          {SLICOT}
}

For the background on the benchmark:

@ARTICLE{Saa88,
 author =       {Y. Saad},
 title =        {Projection and deflation method for partial pole assignment in linear state feedback},
 journal =      {IEEE Transactions on Automatic Control},
 volume =       {33},
 number =       {3},
 pages =        {290--297},
 year =         {1988},
 doi =          {10.1109/9.406}
}

References

↑ P. Raschman, M. Kuhicek, M. Maros. Waves in distributed chemical systems: Experiments and computations. In: New Approaches to Nonlinear Problems in Dynamics - Proceedings of the Asilomar Conference Ground: 271--288, SIAM, 1980.
↑ Y. Saad. Projection and deflation method for partial pole assignment in linear state feedback, IEEE Transactions on Automatic Control, 33(3): 290--297, 1988.
↑ E.J. Grimme. Krylov Projection Methods for Model Reduction. PhD Thesis, University of Illinois at Urbana-Champaign, 1998.
↑ Y. Chahlaoui, P. Van Dooren, A collection of Benchmark examples for model reduction of linear time invariant dynamical systems, Working Note 2002-2: 2002.
↑ ^5.0 ^5.1 Y. Chahlaoui, P. Van Dooren, Benchmark Examples for Model Reduction of Linear Time-Invariant Dynamical Systems, Dimension Reduction of Large-Scale Systems, Lecture Notes in Computational Science and Engineering, vol 45: 379--392, 2005.

[raschman80-1] P. Raschman, M. Kuhicek, M. Maros. Waves in distributed chemical systems: Experiments and computations. In: New Approaches to Nonlinear Problems in Dynamics - Proceedings of the Asilomar Conference Ground: 271--288, SIAM, 1980.

[saad88-2] Y. Saad. Projection and deflation method for partial pole assignment in linear state feedback, IEEE Transactions on Automatic Control, 33(3): 290--297, 1988.

[grimme97-3] E.J. Grimme. Krylov Projection Methods for Model Reduction. PhD Thesis, University of Illinois at Urbana-Champaign, 1998.

[chahlaoui02-4] Y. Chahlaoui, P. Van Dooren, A collection of Benchmark examples for model reduction of linear time invariant dynamical systems, Working Note 2002-2: 2002.

[chahlaoui05-5] 5.0 ^5.1 Y. Chahlaoui, P. Van Dooren, Benchmark Examples for Model Reduction of Linear Time-Invariant Dynamical Systems, Dimension Reduction of Large-Scale Systems, Lecture Notes in Computational Science and Engineering, vol 45: 379--392, 2005.

[1]

[2]

[3]

[4]

[5]

@@ Line 1: / Line 1: @@
 [[Category:benchmark]]
 [[Category:SLICOT]]
+[[Category:linear]]
+[[Category:time invariant]]
+[[Category:first differential order]]
 [[Category:Sparse]]
 [[Category:SISO]]
+{{Infobox
+|Title           = Convection Reaction
+|Benchmark ID    = convectionReaction_n84m1q1
+|Category        = slicot
+|System-Class    = LTI-FOS
+|nstates         = 84
+|ninputs         = 1
+|noutputs        = 1
+|nparameters     = 0
+|components      = A, B, C
+|License         = NA
+|Creator         = [[User:Himpe]]
+|Editor          =
+* [[User:Himpe]]
+* [[User:Mlinaric]]
+|Zenodo-link     = NA
+}}
 ==Description==
@@ Line 18: / Line 39: @@
 More details can be found in <ref name="raschman80"/>, <ref name="saad88"/>, <ref name="grimme97"/> and <ref name="chahlaoui02"/>, <ref name="chahlaoui05"/>.
 ==Origin==
 This benchmark is part of the '''SLICOT Benchmark Examples for Model Reduction'''<ref name="chahlaoui05"/>.
 ==Data==
-The system matrices <math>A</math>, <math>B</math>, <math>C</math> are available from the [http://slicot.org/20-site/126-benchmark-examples-for-model-reduction SLICOT benchmarks] page: [http://slicot.org/objects/software/shared/bench-data/pde.zip pde.zip] and are stored as MATLAB [https://www.mathworks.com/help/matlab/import_export/mat-file-versions.html .mat] file.
+The system matrices <math>A</math>, <math>B</math>, <math>C</math> are available from the [https://www.slicot.org/20-site/126-benchmark-examples-for-model-reduction SLICOT benchmarks] page: [https://www.slicot.org/objects/software/shared/bench-data/pde.zip pde.zip] and are stored as MATLAB [https://www.mathworks.com/help/matlab/import_export/mat-file-versions.html .mat] file.
+Here is [https://www.python.org Python] code for loading the matrices (<math>A</math> is a sparse matrix of 16-bit integers and <math>B</math> and <math>C</math> are full matrices stored as sparse matrices):
+:<syntaxhighlight lang="python">
+import numpy as np
+from scipy.io import loadmat
+mat = loadmat('build.mat')
+A = mat['A'].astype(np.float64)
+B = mat['B'].toarray()
+C = mat['C'].toarray()
+</syntaxhighlight>
 ==Dimensions==
@@ Line 35: / Line 65: @@
 :<math>
-\begin{array}{rcl}
+\begin{align}
-\dot{x}(t) &=& Ax(t) + Bu(t) \\
+  \dot{x}(t) &= A x(t) + B u(t) \\
-y(t) &=& Cx(t)
+  y(t) &= C x(t)
-\end{array}
+\end{align}
 </math>
@@ Line 46: / Line 76: @@
 <math>B \in \mathbb{R}^{84 \times 1}</math>,
 <math>C \in \mathbb{R}^{1 \times 84}</math>.
 ==Citation==