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Nonlinear Model Predictive Control for Batch Crystallization

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.ipynb_checkpoints
 
 
Thesis_Report
Thesis_Report
 
 
example
example
 
 
paper
paper
 
 
results
results
 
 
.gitignore
.gitignore
 
 
DH_dy.py
DH_dy.py
 
 
DH_dy.pyc
DH_dy.pyc
 
 
DH_dz.py
DH_dz.py
 
 
DH_dz.pyc
DH_dz.pyc
 
 
MTP_PPT.pdf
MTP_PPT.pdf
 
 
MTP_PPT_final.pdf
MTP_PPT_final.pdf
 
 
PC_expand.ipynb
PC_expand.ipynb
 
 
README.md
README.md
 
 
Thesis.pdf
Thesis.pdf
 
 
Thesis_Final.pdf
Thesis_Final.pdf
 
 
Tvalues.txt
Tvalues.txt
 
 
__init__.py
__init__.py
 
 
check_constraint.m
check_constraint.m
 
 
check_constraint.py
check_constraint.py
 
 
check_constraint.pyc
check_constraint.pyc
 
 
conc_values.txt
conc_values.txt
 
 
deterministic_model.py
deterministic_model.py
 
 
deterministic_model.pyc
deterministic_model.pyc
 
 
fi_ODE.py
fi_ODE.py
 
 
fi_ODE.pyc
fi_ODE.pyc
 
 
growth_rate.py
growth_rate.py
 
 
hamiltonian_main.py
hamiltonian_main.py
 
 
main1.py
main1.py
 
 
main2.py
main2.py
 
 
main3.py
main3.py
 
 
mean_values.txt
mean_values.txt
 
 
pyPCE.ipynb
pyPCE.ipynb
 
 
test_file.ipynb
test_file.ipynb
 
 
texput.log
texput.log
 
 
theta_ODE.py
theta_ODE.py
 
 
theta_ODE.pyc
theta_ODE.pyc
 
 
utilities.py
utilities.py
 
 
utilities.pyc
utilities.pyc
 
 
utilities_test.py
utilities_test.py
 
 
values.txt
values.txt
 
 
y_ODE.py
y_ODE.py
 
 
y_ODE.pyc
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z_ODE.py
z_ODE.py
 
 
z_ODE.pyc
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Deterministic and Stochastic Optimal Control of a Batch Cooling Crystallizer

The work done here deals with 2 methods for determining Optimal Temperature Control profile for batch Cyrstallization process.

  1. Deterministic Optimal Control aims at finding the an optimum temperature profile to maximise an objective function selected to achieve a desired volume of the product. Herein, the experimental kinetic parameters are employed to simulate a batch crystalllization process.
  2. Stochastic Optimal Control undertakes the task of quantifying the uncertainites which creep in due to experimentation. It aims to achive a maximum expected value for the desired product, simultaneously incorporating randomness in the process parameters into the model. Namely, Two methods Ito Process and Polynomial Chaos Expansions are used.

Deterministic Optimal Control

This undertakes the use of Maximum Principle using the Hamiltonian Derivative to move towards the optimum value of Temperature at each time step.

Stochastic Optimal Control

  1. Ito Processes are used to incorporate the uncertainities which are present in the kinetic parameters. This is used in conjuction with the Hamiltonian method employed above.
  2. Polynomial Chaos Expansions is a novel technique and has been rarely used in Batch Crystallization which is the main focus here.

Polynomial Chaos Expansions

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Nonlinear Model Predictive Control for Batch Crystallization

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non-linear-optimization polynomial-chaos-expansions batch-crystallization

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