Difference between revisions of "Figure 3.2: Illustration of a state model"
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|Chapter=System Modeling | |Chapter=System Modeling | ||
|Figure number=3.2 | |Figure number=3.2 | ||
+ | |Sort key=302 | ||
|Figure title=Illustration of a state model | |Figure title=Illustration of a state model | ||
|GitHub URL=https://github.com/murrayrm/fbs2e-python/blob/main/figure-3.2-state_model.py | |GitHub URL=https://github.com/murrayrm/fbs2e-python/blob/main/figure-3.2-state_model.py | ||
}} | }} | ||
− | [[Image:figure-3.2-state_model.png| | + | [[Image:figure-3.2-state_model.png|640px]] |
'''Figure 3.2''': Illustration of a state model. A state model gives the rate of change of the state as a function of the state. The plot on the left shows the evolution of the state as a function of time. The plot on the right, called a phase portrait, shows the evolution of the states relative to each other, with the velocity of the state denoted by arrows. | '''Figure 3.2''': Illustration of a state model. A state model gives the rate of change of the state as a function of the state. The plot on the left shows the evolution of the state as a function of time. The plot on the right, called a phase portrait, shows the evolution of the states relative to each other, with the velocity of the state denoted by arrows. | ||
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# | # | ||
# The nonlinear damping is implemented as a change in the linear damping | # The nonlinear damping is implemented as a change in the linear damping | ||
− | # coefficient at a small velocity. This is intended to roughly correspond | + | # coefficient at a small velocity. This is intended to roughly correspond |
− | # to some sort of stiction (and give an interesting phase portrait). The | + | # to some sort of stiction (and give an interesting phase portrait). The |
# default parameters for the system are given by | # default parameters for the system are given by | ||
# | # | ||
Line 47: | Line 48: | ||
# This corresponds to a fairly lightly damped oscillator away from the origin. | # This corresponds to a fairly lightly damped oscillator away from the origin. | ||
− | def | + | def _nlspringmass(t, x, u, params): |
+ | m = params.get('m', 1) | ||
+ | k = params.get('k', 1) | ||
+ | b1 = params.get('b1', 2) | ||
+ | b2 = params.get('b2', 0.01) | ||
+ | dth = params.get('dth', 0.2) | ||
+ | |||
# Compute the friction force | # Compute the friction force | ||
if abs(x[1]) < dth: | if abs(x[1]) < dth: | ||
Line 60: | Line 67: | ||
# Return the time derivative of the state | # Return the time derivative of the state | ||
return np.array([x[1], -k/m * x[0] - Fb/m]) | return np.array([x[1], -k/m * x[0] - Fb/m]) | ||
+ | nlspringmass = ct.nlsys(_nlspringmass, None, states=2, inputs=0, outputs=2) | ||
# | # | ||
Line 67: | Line 75: | ||
t = np.linspace(0, 16, 100) | t = np.linspace(0, 16, 100) | ||
− | + | resp = ct.input_output_response(nlspringmass, t, 0, [2, 0]) | |
+ | y = resp.outputs | ||
− | plt.plot(t, y[ | + | plt.plot(t, y[0], '-', t, y[1], '--') |
plt.xlabel('Time $t$ [s]') | plt.xlabel('Time $t$ [s]') | ||
− | plt.ylabel('Position $q$ [m], velocity $\dot q$̇ [m/s]') | + | plt.ylabel(r'Position $q$ [m], velocity $\dot q$̇ [m/s]') |
plt.title('Time plot') | plt.title('Time plot') | ||
plt.legend(['Position $q$', 'Velocity $v$']) | plt.legend(['Position $q$', 'Velocity $v$']) | ||
Line 78: | Line 87: | ||
# (b) Generate a phase plot for the damped oscillator | # (b) Generate a phase plot for the damped oscillator | ||
# | # | ||
− | plt.subplot(2, 2, 2) | + | ax = plt.subplot(2, 2, 2) |
− | ct. | + | cplt = ct.phase_plane_plot( |
nlspringmass, # dynamics | nlspringmass, # dynamics | ||
− | + | [-1, 1, -1, 1], # bounds of the plot | |
− | + | gridspec=[8, 8], # number of points for vectorfield | |
− | + | plot_vectorfield=True, # plot vectorfield | |
+ | plot_streamlines=False, # plot streamlines separately | ||
+ | plot_separatrices=False, # leave off separatrices | ||
+ | ax=ax | ||
+ | ) | ||
+ | ct.phaseplot.streamlines( # Plot streamlines from selected points | ||
+ | nlspringmass, | ||
+ | np.array([[-1, 0.4], [0.1, 1], [1, -0.4], [-0.1, -1]]), | ||
+ | 10, ax=ax | ||
+ | ) | ||
plt.xlabel('Position $q$ [m]') | plt.xlabel('Position $q$ [m]') | ||
− | plt.ylabel('Velocity $\dot q$ [m/s]') | + | plt.ylabel(r'Velocity $\dot q$ [m/s]') |
plt.title('Phase portrait') | plt.title('Phase portrait') | ||
plt.axis([-1, 1, -1, 1]) | plt.axis([-1, 1, -1, 1]) |
Latest revision as of 18:34, 16 November 2024
Chapter | System Modeling |
---|---|
Figure number | 3.2 |
Figure title | Illustration of a state model |
GitHub URL | https://github.com/murrayrm/fbs2e-python/blob/main/figure-3.2-state model.py |
Requires | python-control |
Figure 3.2: Illustration of a state model. A state model gives the rate of change of the state as a function of the state. The plot on the left shows the evolution of the state as a function of time. The plot on the right, called a phase portrait, shows the evolution of the states relative to each other, with the velocity of the state denoted by arrows.
# figure-3.2-state_mode.py - illustration of a state model # RMM, 2 Jul 2021 # # Figure 3.2: Illustration of a state model. A state model gives the rate of # change of the state as a function of the state. The plot on the left shows # the evolution of the state as a function of time. The plot on the right, # called a phase portrait, shows the evolution of the states relative to # each other, with the velocity of the state denoted by arrows. # import numpy as np import scipy as sp import matplotlib.pyplot as plt import control as ct # # Spring mass system with nonlinear dampling # # This function gives the dynamics for a dampled oscillator with nonlinear # damping. The states of the system are # # x[0] position # x[1] velocity # # The nonlinear damping is implemented as a change in the linear damping # coefficient at a small velocity. This is intended to roughly correspond # to some sort of stiction (and give an interesting phase portrait). The # default parameters for the system are given by # # m = 1 mass, kg # k = 1 spring constant, N/m # b1 = 1 damping constant near origin, N-sec/m # b2 = 0.01 damping constant away from origin, N-sec/m # dth = 0.5 threshold for switching between damping # # This corresponds to a fairly lightly damped oscillator away from the origin. def _nlspringmass(t, x, u, params): m = params.get('m', 1) k = params.get('k', 1) b1 = params.get('b1', 2) b2 = params.get('b2', 0.01) dth = params.get('dth', 0.2) # Compute the friction force if abs(x[1]) < dth: Fb = b1 * x[1]; elif x[1] < 0: Fb = -b1 * dth \ + b2 * (x[1] + dth); else: Fb = b1 * dth \ + b2 * (x[1] - dth); # Return the time derivative of the state return np.array([x[1], -k/m * x[0] - Fb/m]) nlspringmass = ct.nlsys(_nlspringmass, None, states=2, inputs=0, outputs=2) # # (a) Simulation of the nonlinear spring mass system # plt.subplot(2, 2, 1) t = np.linspace(0, 16, 100) resp = ct.input_output_response(nlspringmass, t, 0, [2, 0]) y = resp.outputs plt.plot(t, y[0], '-', t, y[1], '--') plt.xlabel('Time $t$ [s]') plt.ylabel(r'Position $q$ [m], velocity $\dot q$̇ [m/s]') plt.title('Time plot') plt.legend(['Position $q$', 'Velocity $v$']) # # (b) Generate a phase plot for the damped oscillator # ax = plt.subplot(2, 2, 2) cplt = ct.phase_plane_plot( nlspringmass, # dynamics [-1, 1, -1, 1], # bounds of the plot gridspec=[8, 8], # number of points for vectorfield plot_vectorfield=True, # plot vectorfield plot_streamlines=False, # plot streamlines separately plot_separatrices=False, # leave off separatrices ax=ax ) ct.phaseplot.streamlines( # Plot streamlines from selected points nlspringmass, np.array([[-1, 0.4], [0.1, 1], [1, -0.4], [-0.1, -1]]), 10, ax=ax ) plt.xlabel('Position $q$ [m]') plt.ylabel(r'Velocity $\dot q$ [m/s]') plt.title('Phase portrait') plt.axis([-1, 1, -1, 1]) plt.tight_layout()