MSP Simulation Example - Resistive Companion - Exercise 3 - Task 1¶
Sample Circuit¶
$R_1$ $=0.2 \Omega$
$L_1$ $=1mH$
$I_1$$=10A$
$i_L(0)=0 $
Circuit and Simulation Setup¶
In [1]:
import numpy as np
import ipywidgets as widget
import matplotlib.pyplot as plt
np.set_printoptions(sign=' ')
# Circuit parameters
R1 = 0.2
L1 = 1e-3
I_src= 10
G1 = 1/R1
DC equivalent of Inductor¶
Equation of the inductor:¶
$v_L(t) =L\cdot\frac{di_L}{dt}$
Integration:¶
$i_L(t+\Delta{t}) =i_L(t) + \frac{1}{L} \int_{t}^{t+\Delta{t}} \ v_L(\tau) d\tau$
Discretization:¶
$i_L(k+1)= i_L(k) + \frac{1}{L} \int_{t_k}^{t_k+\Delta{t}} \ v_L(\tau) d\tau$
Application of trapezoidal rule:¶
$i_L(k)= i_L(k) + \frac{1}{L} \frac{v_L(k)+v_L(k+1)}{2} \Delta{t} $
$i_L(k+1)=\frac{\Delta{t}}{2L} v_L(k+1) + (i_L(k) + \frac{\Delta{t}}{2L} v_L(k)) $
The inductor in the calculation step (k + 1) can be substituted with an inductance $G_L = \frac{\Delta{t}}{2L}$ in parallel with a current source $A_L(k) = i_L(k) + \frac{\Delta{t}}{2L} v_L(k) $
Run Simulation¶
In [2]:
# Perform simulation with dpsim
import dpsim
# Simulation parameters
model_name = 'CS_R1L1'
time_step = 1e-4
final_time = 1e-2
npoint = int(np.round(final_time/time_step))
# Nodes
gnd = dpsim.emt.Node.GND()
n1 = dpsim.emt.Node('n1')
n1.set_initial_voltage(voltage=complex(2,0),index=0)
# Components
r1 = dpsim.emt.ph1.Resistor('r1')
r1.R = 0.2
l1 = dpsim.emt.ph1.Inductor('l1')
l1.L = 1e-3
cs = dpsim.emt.ph1.CurrentSource('cs')
cs.I_ref = complex(10,0)
cs.f_src = 0
cs.connect([gnd, n1])
r1.connect([n1, gnd])
l1.connect([n1, gnd])
system = dpsim.SystemTopology(50, [gnd, n1], [cs, r1, l1])
logger = dpsim.Logger(model_name)
logger.log_attribute(n1, 'v');
logger.log_attribute(r1, 'i_intf');
logger.log_attribute(l1, 'i_intf');
sim = dpsim.Simulation(model_name, system, timestep=time_step, duration=final_time, pbar=True, sim_type=1, log_level=1)
sim.add_logger(logger)
sim.start()
Read log¶
In [3]:
from villas.dataprocessing.readtools import *
from villas.dataprocessing.timeseries import *
import re
work_dir = 'logs/'
log_path = work_dir + model_name + '_Solver.log'
log_lines, log_sections = read_dpsim_log(log_path)
Show node detection log¶
In [4]:
for line_pos in log_sections['nodenumbers']:
print(log_lines[line_pos])
Show matrix stamping log¶
In [5]:
for line_pos in log_sections['sysmat_stamp']:
print(log_lines[line_pos])
Show source vector log¶
In [6]:
for line_pos in log_sections['sourcevec_stamp']:
print(log_lines[line_pos])
Read solution log¶
In [7]:
log_path = work_dir + model_name + '.csv'
ts_dpsim_emt = read_timeseries_dpsim(log_path, print_status=False)
# for key, val in ts_dpsim_emt.items():
# print(key + ': ' + str(val.values))
Plot results¶
In [8]:
import matplotlib.pyplot as plt
#Extract plot data
plot_data=ts_dpsim_emt["n1.v"]
y_values= np.asarray(plot_data.values)
#Add initial value
y_values= np.insert(y_values, 0, I_src*R1)
t = np.arange(npoint+2)*time_step
plt.figure(figsize=(10,8))
plt.xlabel('Time [s]')
plt.ylabel('Voltage [V]')
plt.axis([0, final_time+time_step , 0, 2.05])
plt.scatter(t,y_values, label='$e_{1}$(t)')
#show corresponding values on the plot
for i in np.arange(3):
plt.annotate(' ' + str(np.round(y_values[i], 2)), (t[i], y_values[i]))
plt.legend(loc='upper right')
plt.show()
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