Ejemplo n.º 1
0
    def test_response1(
            self):  # The first test case is that when both ESR of both
        t = numpy.array(range(
            0, 30000, 1))  # inductor and capacitor is 0 the gain must be
        t = t / 1000  # perfectly zero at anti-resonating frequency.
        A = 1
        i1, V1, t1, gain1 = response(
            A, 1, 1, 0, 0, 1,
            t)  # When L = 1 Henry. C = 1 Farad. Wr = 1 rad/sec
        # Checking the gain at Wr is zero or not.
        i2, V2, t2, gain2 = response(
            A, 2, 0.5, 0, 0, 0.5,
            t)  # When L = 0.5 Henry. C = 0.5 Farad. Wr = 2 rad/sec

        i3, V3, t3, gain3 = response(
            A, 2, 0.25, 0, 0, 1,
            t)  # When L = 0.25 Henry. C = 1 Farad. Wr = 2 rad/sec

        i4, V4, t4, gain4 = response(
            A, 2, 1, 0, 0, 0.25,
            t)  # When L = 1 Henry. C = 0.25 Farad. Wr = 2 rad/sec
        self.assertEqual(round(gain1, 3), 0)
        self.assertEqual(round(gain2, 3), 0)
        self.assertEqual(round(gain3, 3), 0)
        self.assertEqual(round(gain4, 3), 0)
Ejemplo n.º 2
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def current_vs_voltage_plot(A, w, L, R1, R2, C, t, figure_index):
    i, V, t, gain = response(A, w, L, R1, R2, C, t)
    plt.figure(figure_index)
    plt.plot(t, V, '-', linewidth=1)
    plt.plot(t, i, '.', linewidth=1)
    plt.xlabel('Time in seconds')
    plt.ylabel('Current in Ampere and Voltage in Volts')
    plt.legend(['Voltage', 'Current'])
    plt.savefig('Voltage_and_Current_vs_time_at_frequency_omega_' + str(w) +
                '_with_both_resistance_' + str(R1) + '.png')
    return
Ejemplo n.º 3
0
 def test_response2(self):
     t = numpy.array(
         range(0, 30000,
               1))  # The second test case tests when the magnitude of both
     t = t / 1000  # L and C are same, then if the ESRs of both L and C are
     A = 1  # 1 ohm then the gain must be perfectly 1 for angular
     w = 1  # frequencies w = 1,2,5 rad/sec.
     i1, V1, t1, gain1 = response(A, w, 1, 1, 1, 1, t)
     i2, V2, t2, gain2 = response(A, w, 0.5, 1, 1, 0.5, t)
     w = 2
     i3, V3, t3, gain3 = response(A, w, 1, 1, 1, 1, t)
     i4, V4, t4, gain4 = response(A, w, 0.5, 1, 1, 0.5, t)
     w = 5
     i5, V5, t5, gain5 = response(A, w, 1, 1, 1, 1, t)
     i6, V6, t6, gain6 = response(A, w, 0.5, 1, 1, 0.5, t)
     os.remove("source/LC_tank_both.pyc")
     self.assertEqual(round(gain1, 3), 1)
     self.assertEqual(round(gain2, 3), 1)
     self.assertEqual(round(gain3, 3), 1)
     self.assertEqual(round(gain4, 3), 1)
     self.assertEqual(round(gain5, 3), 1)
     self.assertEqual(round(gain6, 3), 1)
Ejemplo n.º 4
0
t = numpy.array(range(0, 3000, 1))
t = t / 100

# Initilizing different component values for the first case. L in Henry. C in Farad. R11 (ESR of inductor) in ohm. R12 (ESR of capacitor) in ohm.
L = 0.5
R11 = 0
R12 = 0
C = 0.5
A = 1

frequency = numpy.array(range(1, 100))
frequency = frequency / 10
Gain1 = []
for w in frequency:
    i, V, t, gain = response(A, w, L, R11, R12, C, t)
    Gain1.append(gain)

plt.figure(1)
plt.plot(frequency, Gain1)
plt.xlabel('Frequency in rad/sec')
plt.ylabel('Gain')
plt.savefig('Frequency_response_without_any_resistance.png')

R21 = 1  # The ESR values for the second case. L and C are smae as above.
R22 = 0

Gain2 = []
for w in frequency:
    i, V, t, gain = response(A, w, L, R21, R22, C, t)
    Gain2.append(gain)
Ejemplo n.º 5
0
# initialization function: plot the background of each frame
def init():
    line.set_data([], [])
    line2.set_data([], [])
    return line, line2,

A = 1
w_dash = 1
L_dash = 0.5
R1 = 0
R2 = 0
C_dash = 0.5

t = numpy.array(range(0,300,1))
t = t/10
i1,V,t,gain = response(A,w_dash,L_dash,R1,R2,C_dash,t)
# animation function.  This is called sequentially
def animate(i):
    line.set_data(t-0.1*i,V)
    line2.set_data(t-0.1*i,i1)
    return line,line2

# call the animator.  blit=True means only re-draw the parts that have changed.
ani = animation.FuncAnimation(fig, animate, init_func=init,
                               frames=200, interval=20, blit= False)

ani.save('movie1.mp4', fps=10, extra_args=['-vcodec', 'libx264'])

A = 1
w_dash = 1
L_dash = 0.5