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Details for: "2D heat flow example, rectangular domain thermal properties of platinum"

Name: 2D heat flow example, rectangular domain thermal properties of platinum (Key: CO104)
Path: ackrep_data/system_models/compleib_models/HF2D13 View on GitHub
Type: system_model
Short Description: HF2D13 reduced version of HF2D4
Created: 2022-10-10 15:54:05
Compatible Environment: default_conda_environment (Key: CDAMA)
Source Code [ / ] simulation.py
# This file was autogenerated from the template: simulation.py.template (2022-10-10 15:54:06).

import numpy as np
import system_model
from scipy.integrate import solve_ivp, odeint

from ackrep_core import ResultContainer
from ackrep_core.system_model_management import save_plot_in_dir
import matplotlib.pyplot as plt
import os
from ipydex import Container

# link to documentation with examples: https://ackrep-doc.readthedocs.io/en/latest/devdoc/contributing_data.html


def simulate():
    """
    simulate the system model with scipy.integrate.solve_ivp

    :return: result of solve_ivp, might contains input function
    """

    model = system_model.Model()

    rhs_xx_pp_symb = model.get_rhs_symbolic()
    rhs = model.get_rhs_func()

    # initial state values
    xx0 = np.ones(model.sys_dim)

    t_end = 10
    tt = np.linspace(0, t_end, 1000)

    simulation_data = solve_ivp(rhs, (0, t_end), xx0, t_eval=tt)

    # using odeint for models with large state vectors
    # res = odeint(rhs, y0=xx0, t=tt, tfirst=True)
    # simulation_data = Container()
    # simulation_data.y = res.transpose()
    # simulation_data.t = tt

    # postprocessing: calc output
    ny = 4
    C = model.get_parameter_value("C")
    D21 = model.get_parameter_value("D21")
    output = np.zeros((ny, len(tt)))
    for i in range(len(tt)):
        output[:,i] = np.matmul(C, simulation_data.y[:,i]) # + np.matmul(D21, w)
    simulation_data.output = output

    save_plot(simulation_data)

    return simulation_data


def save_plot(simulation_data):
    """
    plot your data and save the plot
    access to data via: simulation_data.t   array of time values
                        simulation_data.y   array of data components
                        simulation_data.uu  array of input values

    :param simulation_data: simulation_data of system_model
    :return: None
    """

    for i in range(simulation_data.output.shape[0]):
        plt.plot(simulation_data.t, simulation_data.output[i], label=f"$y_{i}$")

    plt.legend()
    plt.tight_layout()

    save_plot_in_dir()


def evaluate_simulation(simulation_data):
    """
    assert that the simulation results are as expected

    :param simulation_data: simulation_data of system_model
    :return:
    """
    expected_final_state = np.array([ 0.07551134, -0.00220095, -0.00773686, -0.00407902,  0.00055405])

    rc = ResultContainer(score=1.0)
    simulated_final_state = simulation_data.y[:, -1]
    rc.final_state_errors = [
        simulated_final_state[i] - expected_final_state[i] for i in np.arange(0, len(simulated_final_state))
    ]
    rc.success = np.allclose(expected_final_state, simulated_final_state, rtol=0, atol=1e-2)

    return rc
system_model.py
# This file was autogenerated from the template: system_model.py.template (2022-10-10 15:54:06).

import sympy as sp
import numpy as np
import symbtools as st
import importlib
import sys, os
#from ipydex import IPS, activate_ips_on_exception  

from ackrep_core.system_model_management import GenericModel, import_parameters

# Import parameter_file
params = import_parameters()


#link to documentation with examples: https://ackrep-doc.readthedocs.io/en/latest/devdoc/contributing_data.html


class Model(GenericModel): 

    def initialize(self):
        """
        this function is called by the constructor of GenericModel

        :return: None
        """

        # Define number of inputs -- MODEL DEPENDENT
        self.u_dim = 2

        # Set "sys_dim" to constant value, if system dimension is constant 
        self.sys_dim = 5

        # check existence of params file
        self.has_params = True
        self.params = params
        

    # ----------- SET DEFAULT INPUT FUNCTION ---------- # 
    def uu_default_func(self):
        """
        define input function
    
        :return:(function with 2 args - t, xx_nv) default input function 
        """ 
        
        def uu_rhs(t, xx_nv):
            """
            sequence of numerical input values

            :param t:(scalar or vector) time
            :param xx_nv:(vector or array of vectors) numeric state vector
            :return:(list) numeric inputs 
            """ 
            u = np.zeros(self.u_dim)
            return u

        return uu_rhs


    # ----------- SYMBOLIC RHS FUNCTION ---------- # 

    def get_rhs_symbolic(self):
        """
        define symbolic rhs function

        :return: matrix of symbolic rhs-functions
        """
        if self.dxx_dt_symb is not None:
            return self.dxx_dt_symb

        x = self.xx_symb  
        A, B, B1, C1, C, D11, D12, D21 = self.pp_symb   # parameters
        w = np.zeros(5) # noise
        u = self.uu_symb   # inputs

        # define symbolic rhs functions
        self.dxx_dt_symb = np.matmul(A,x) + np.matmul(B1,w) + np.matmul(B,u)
        



        return self.dxx_dt_symb
    
parameters.py
# This file was autogenerated from the template: parameters.py.template (2022-10-10 15:54:06).

import sys
import os
import numpy as np
import sympy as sp

import tabulate as tab


#link to documentation with examples: https://ackrep-doc.readthedocs.io/en/latest/devdoc/contributing_data.html


# set model name
model_name = '2D heat flow example, rectangular domain thermal properties of platinum'


# ---------- create symbolic parameters
A = sp.MatrixSymbol('A', 5, 5)
B = sp.MatrixSymbol('B', 5, 2)
B1 = sp.MatrixSymbol('B1', 5, 5)
C1 = sp.MatrixSymbol('C1', 7, 5)
C = sp.MatrixSymbol('C', 4, 5)
D11 = sp.MatrixSymbol('D11', 7, 5)
D12 = sp.MatrixSymbol('D12', 7, 2)
D21 = sp.MatrixSymbol('D21', 4, 5)

pp_symb = [A, B, B1, C1, C, D11, D12, D21]


# ---------- create auxiliary symbolic parameters 

# set numerical values of auxiliary parameters
# trailing "_nv" stands for "numerical value"
A_nv = sp.Matrix(np.array([[ -0.37772709,   1.36791281,  -2.87290612,   3.32321037,
          7.55690538],
       [  0.16680559,  -8.47040985,   7.94440351,  -9.88353118,
        -17.26830167],
       [ -0.6881459 ,   6.1112684 , -13.17531471,  11.52374267,
         22.4291518 ],
       [  0.08458209,  -6.42148117,  10.27843945, -19.09497138,
        -32.3377245 ],
       [  0.53354038,  -8.75641894,  18.24166763, -30.41964517,
        -77.12755156]]))
B_nv = sp.Matrix(np.array([[-10.18812488,  -6.67824043],
       [  0.39098466,  10.32501005],
       [-20.28873116,  -8.80554396],
       [  1.43281767,   3.19065572],
       [ 10.96217705,  15.00621302]]))
B1_nv = sp.Matrix(np.array([[-10.18812488,  -6.67824043],
       [  0.39098466,  10.32501005],
       [-20.28873116,  -8.80554396],
       [  1.43281767,   3.19065572],
       [ 10.96217705,  15.00621302]]))
C1_nv = sp.Matrix(np.array([[0.70710678, 0.        , 0.        , 0.        , 0.        ],
       [0.        , 0.70710678, 0.        , 0.        , 0.        ],
       [0.        , 0.        , 0.70710678, 0.        , 0.        ],
       [0.        , 0.        , 0.        , 0.70710678, 0.        ],
       [0.        , 0.        , 0.        , 0.        , 0.70710678],
       [0.        , 0.        , 0.        , 0.        , 0.        ],
       [0.        , 0.        , 0.        , 0.        , 0.        ]]))
C_nv = sp.Matrix(np.array([[ 0.54545081, -0.49130643, -0.48635888, -0.3216928 , -0.5149806 ],
       [ 0.58508721,  0.83053574,  0.8274487 , -0.29234346,  0.19977664],
       [ 0.55827828, -1.047228  ,  1.82165967, -0.24032092, -0.85288395],
       [ 0.52652973, -1.3760178 ,  0.47930376, -0.72656476, -1.26853689]]))
D11_nv = sp.Matrix(np.array([[0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.]]))
D12_nv = sp.Matrix(np.array([[0.        , 0.        ],
       [0.        , 0.        ],
       [0.        , 0.        ],
       [0.        , 0.        ],
       [0.        , 0.        ],
       [7.07106781, 0.        ],
       [0.        , 7.07106781]]))
D21_nv = sp.Matrix(np.array([[0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0.]]))


# ---------- create symbolic parameter functions
# parameter values can be constant/fixed values OR set in relation to other parameters (for example: a = 2*b)  


# list of symbolic parameter functions
# tailing "_sf" stands for "symbolic parameter function"
pp_sf = [A_nv, B_nv, B1_nv, C1_nv, C_nv, D11_nv, D12_nv, D21_nv]


#  ---------- list for substitution
# -- entries are tuples like: (independent symbolic parameter, numerical value)
pp_subs_list = []


# OPTONAL: Dictionary which defines how certain variables shall be written
# in the table - key: Symbolic Variable, Value: LaTeX Representation/Code
# useful for example for complex variables: {Z: r"\underline{Z}"}
latex_names = {}


# ---------- Define LaTeX table

# Define table header 
# DON'T CHANGE FOLLOWING ENTRIES: "Symbol", "Value"
tabular_header = ["Symbol", "Value"]

# Define column text alignments
col_alignment = ["center", "left"]


# Define Entries of all columns before the Symbol-Column
# --- Entries need to be latex code
col_1 = [] 

# contains all lists of the columns before the "Symbol" Column
# --- Empty list, if there are no columns before the "Symbol" Column
start_columns_list = []


# Define Entries of the columns after the Value-Column
# --- Entries need to be latex code
col_4 = []

# contains all lists of columns after the FIX ENTRIES
# --- Empty list, if there are no columns after the "Value" column
end_columns_list = []

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