Difference between revisions of "MAP:Cantilever Beam"
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| Line 11: | Line 11: | ||
%% Load and manipulate the data | %% Load and manipulate the data | ||
% Load data from Cantilever.dat | % Load data from Cantilever.dat | ||
| − | load Cantilever.dat | + | beam_data = load('Cantilever.dat') |
% Copy data from each column into new variables | % Copy data from each column into new variables | ||
| − | + | mass = beam_data(:,1); | |
| − | + | displ = beam_data(:,2); | |
| − | % Convert | + | % Convert mass to a force measurement |
| − | + | force = mass*9.81; | |
| − | % Convert | + | % Convert displacement in inches to meters |
| − | + | displ = (displ*2.54)/100; | |
%% Perform calculations | %% Perform calculations | ||
% Use polyfit to find first-order fit polynomials | % Use polyfit to find first-order fit polynomials | ||
| − | P = polyfit( | + | P = polyfit(force, displ, 1) |
%% Generate predictions | %% Generate predictions | ||
| − | % Create 100 representational | + | % Create 100 representational force values |
| − | + | force_model = linspace(min(force),max(force),100); | |
% Calculate Displacement predictions | % Calculate Displacement predictions | ||
| − | + | disp_model = polyval(P, force_model); | |
%% Generate and save plots | %% Generate and save plots | ||
| Line 36: | Line 36: | ||
clf | clf | ||
% Plot Displacement as a function of Force | % Plot Displacement as a function of Force | ||
| − | plot( | + | plot(force, displ, 'ko') |
% Turn hold on, plot the model values, and turn hold off | % Turn hold on, plot the model values, and turn hold off | ||
hold on | hold on | ||
| − | plot( | + | plot(force_model, disp_model, 'k-') |
hold off | hold off | ||
% Turn the grid on | % Turn the grid on | ||
| Line 47: | Line 47: | ||
ylabel('Displacement (meters)') | ylabel('Displacement (meters)') | ||
title('Displacement vs. Force for Cantilever.dat (NetID)') | title('Displacement vs. Force for Cantilever.dat (NetID)') | ||
| − | % Save the graph to PostScript | + | % Save the graph to PostScript and PDF |
print -deps RunCanPlot | print -deps RunCanPlot | ||
| + | print -dpdf RunCanPlot | ||
</source> | </source> | ||
| Line 61: | Line 62: | ||
beam_data = np.loadtxt('Cantilever.dat') | beam_data = np.loadtxt('Cantilever.dat') | ||
# Copy data from each column into new variables | # Copy data from each column into new variables | ||
| − | mass = beam_data[:, 0].copy() | + | mass = beam_data[:, 0].copy() |
| − | + | displ = beam_data[:, 1].copy() | |
| − | # Convert | + | # Convert mass to a force measurement |
force = mass * 9.81 | force = mass * 9.81 | ||
| − | # Convert | + | # Convert displace in inches to meters |
| − | + | displ = (displ * 2.54) / 100.0 | |
# %% Perform calculations | # %% Perform calculations | ||
# Use polyfit to find first-order fit polynomials | # Use polyfit to find first-order fit polynomials | ||
| − | p = np.polyfit(force, | + | p = np.polyfit(force, displ, 1) |
# %% Generate predictions | # %% Generate predictions | ||
| Line 84: | Line 85: | ||
plt.clf() | plt.clf() | ||
# Plot Displacement as a function of Force | # Plot Displacement as a function of Force | ||
| − | plt.plot(force, | + | plt.plot(force, displ, 'ko') |
# Plot the model values | # Plot the model values | ||
plt.plot(force_model, disp_model, 'k-') | plt.plot(force_model, disp_model, 'k-') | ||
| Line 93: | Line 94: | ||
plt.ylabel('Displacement (meters)') | plt.ylabel('Displacement (meters)') | ||
plt.title('Displacement vs. Force for Cantilever.dat (NetID)') | plt.title('Displacement vs. Force for Cantilever.dat (NetID)') | ||
| − | # Save the graph to PostScript | + | # Save the graph to PostScript and PDF |
plt.savefig('RunCanPlot.eps') | plt.savefig('RunCanPlot.eps') | ||
plt.savefig('RunCanPlot.pdf') | plt.savefig('RunCanPlot.pdf') | ||
</source> | </source> | ||
Revision as of 17:50, 26 November 2018
The Cantilever Beam lab has been a foundation of EGR 103 for several years. It demonstrates how to initialize the workspace, load and manipulate data, perform calculations, generate values of a model equation, plot data and model values, and save plots. Not bad for the second week of an introductory course in computational methods! For at least the short-term, the Cantilever Beam lab will live on in MATLAB and in Python. Since the lab itself actually develops the final code, it is acceptable to post it here. Here's what the lab's solution looks like in MATLAB and in Python 3:
MATLAB
%% Initialize the workspace
% Clear all variables
clear
% Change display to short exponential format
format short e
%% Load and manipulate the data
% Load data from Cantilever.dat
beam_data = load('Cantilever.dat')
% Copy data from each column into new variables
mass = beam_data(:,1);
displ = beam_data(:,2);
% Convert mass to a force measurement
force = mass*9.81;
% Convert displacement in inches to meters
displ = (displ*2.54)/100;
%% Perform calculations
% Use polyfit to find first-order fit polynomials
P = polyfit(force, displ, 1)
%% Generate predictions
% Create 100 representational force values
force_model = linspace(min(force),max(force),100);
% Calculate Displacement predictions
disp_model = polyval(P, force_model);
%% Generate and save plots
% Bring up a figure window
figure(1)
% Clear the figure window
clf
% Plot Displacement as a function of Force
plot(force, displ, 'ko')
% Turn hold on, plot the model values, and turn hold off
hold on
plot(force_model, disp_model, 'k-')
hold off
% Turn the grid on
grid on
% Label and title the graph
xlabel('Force (Newtons)')
ylabel('Displacement (meters)')
title('Displacement vs. Force for Cantilever.dat (NetID)')
% Save the graph to PostScript and PDF
print -deps RunCanPlot
print -dpdf RunCanPlot
Python
# %% Import modules
import numpy as np
import matplotlib.pyplot as plt
# %% Load and manipulate the data
# Load data from Cantilever.dat
beam_data = np.loadtxt('Cantilever.dat')
# Copy data from each column into new variables
mass = beam_data[:, 0].copy()
displ = beam_data[:, 1].copy()
# Convert mass to a force measurement
force = mass * 9.81
# Convert displace in inches to meters
displ = (displ * 2.54) / 100.0
# %% Perform calculations
# Use polyfit to find first-order fit polynomials
p = np.polyfit(force, displ, 1)
# %% Generate predictions
# Create 100 representational Force values
force_model = np.linspace(min(force), max(force), 100)
# Calculate Displacement predictions
disp_model = np.polyval(p, force_model)
# %% Generate and save plots
# Bring up a figure window
plt.figure(1)
# Clear the figure window
plt.clf()
# Plot Displacement as a function of Force
plt.plot(force, displ, 'ko')
# Plot the model values
plt.plot(force_model, disp_model, 'k-')
# Turn the grid on
plt.grid()
# Label and title the graph
plt.xlabel('Force (Newtons)')
plt.ylabel('Displacement (meters)')
plt.title('Displacement vs. Force for Cantilever.dat (NetID)')
# Save the graph to PostScript and PDF
plt.savefig('RunCanPlot.eps')
plt.savefig('RunCanPlot.pdf')
