Digital Control Systems: Difference between revisions
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* Also check Chapter 7.3 of [http://www.me.unm.edu/~starr/teaching/me581/textbook.pdf Greg Starr's book]. |
* Also check Chapter 7.3 of [http://www.me.unm.edu/~starr/teaching/me581/textbook.pdf Greg Starr's book]. |
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===Scilab=== |
===Scilab/Xcos=== |
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*[https://www.scilab.org/content/download/1107/10095/file/Xcos_beginners.pdf Xcos Beginners Guide] |
*[https://www.scilab.org/content/download/1107/10095/file/Xcos_beginners.pdf Xcos Beginners Guide] |
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*[http://www.iitg.ernet.in/trivedi/Downloads/scilab/book.pdf Scilab/Scicos Book] |
Revision as of 09:50, 23 April 2014
Links
- Textbooks
- Introduction to Applied Digital Control, Greg Starr, University of New Mexico
- Greg's ME481/ME581 web pages contain solutions to the book problems and other things.
- Optimal Sampled-Data Control Systems, Chen & Francis
- Digital Control System Analysis and Design, 3rd Ed., Philips
- Control Systems and Control Engineering
- Introduction to Applied Digital Control, Greg Starr, University of New Mexico
MATLAB/Octave
- Octave Control Systems Toolbox This is not the same thing that is on Octave Forge here.
Z Transforms
- Relationship between the Laplace and Z transforms
- Convolution and Z Transforms
- Z Transforms and Convolution
- Here is an animation of convolution with continuous signals. Look at it so you understand what is happening with the mechanics of convolution. To convolve with , you flip shift into on the axis, then you multiply it by to get , then you integrate with respect to , so that the convolution is: . The first animation shows this happening with sampled waveforms: and .
- Notice that this is really the same as Polynomial Multiplication.
Discretization
- This is how the c2d zero order hold works in MATLAB/octave. It uses the "exact" solution to the discretization problem.
- Also check Chapter 7.3 of Greg Starr's book.