Thinking Like an Engineer: An Active Learning Approach (4th Edition)
4th Edition
ISBN: 9780134639673
Author: Elizabeth A. Stephan, David R. Bowman, William J. Park, Benjamin L. Sill, Matthew W. Ohland
Publisher: PEARSON
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Textbook Question
Chapter 13, Problem 15ICA
The following instructions will apply to ICA 13-10 to 13-21 for the preceding graph, identify:
- whether this model is linear, power, exponential, or none of those options,
- what is the equation of the line shown in the graph, and
- the units of each value represented in the equation of the line
ICA 13-15
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MULTIPLE CHOICE -The answer is one of the options below please solve carefully and circle the correct option Please write clear .
Hello I’m trying to make the graph that you see in the picture, I’m trying the exact copy of that graph using this code but I’m having a hard time doing that. Could you change the code so that it looks like the graph that you see on the picture using MATLAB, please send the code when you are finished.
% Sample data for Diesel and Petrol cars
carPosition = linspace(1, 60, 50); % Assumed positions of cars
% Fix the random seed for reproducibility
rng(45);
% Assumed positions of cars
CO2Diesel = 25 + 5*cos(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Diesel
CO2Petrol = 20 + 5*sin(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Petrol
% Fit polynomial curves
pDiesel = polyfit(carPosition, CO2Diesel, 3);
pPetrol = polyfit(carPosition, CO2Petrol, 3);
% Generate points for best fit lines
fitDiesel = polyval(pDiesel, carPosition);
fitPetrol = polyval(pPetrol, carPosition);
% Plotting the data
figure; hold on;
scatter(carPosition, CO2Diesel, 'o', 'MarkerEdgeColor', [1 0.5…
I’m making the graph that you see in the picture but the code that I’m using makes the line with to many curves. Could you make the lines look like the one that you see on the graph. Don’t change the color just make it with a little bit less curves like you see in the picture.
Use this code on MATLAB and fix it.
% Sample data for Diesel and Petrol cars
carPosition = linspace(1, 60, 50); % Assumed positions of cars
% Fix the random seed for reproducibility
rng(50);
% Assumed CO2 emissions for Diesel and Petrol
CO2Diesel = 25 + 5*cos(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Diesel
CO2Petrol = 20 + 5*sin(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Petrol
% Fit polynomial curves
pDiesel = polyfit(carPosition, CO2Diesel, 3);
pPetrol = polyfit(carPosition, CO2Petrol, 3);
% Generate points for best fit lines
fitDiesel = polyval(pDiesel, carPosition);
fitPetrol = polyval(pPetrol, carPosition);
% Combined best fit
combinedFit = (fitDiesel + fitPetrol) / 2;…
Chapter 13 Solutions
Thinking Like an Engineer: An Active Learning Approach (4th Edition)
Ch. 13.2 - An unknown amount of oxygen, kept in 8 piston-type...Ch. 13.2 - The data shown graphically in the figure describe...Ch. 13.5 - Prob. 3CCCh. 13.5 - Prob. 4CCCh. 13 - Capillary action draws liquid up a narrow tube...Ch. 13 - Several reactions are carried out in a closed...Ch. 13 - An environmental engineer has obtained a bacteria...Ch. 13 - In a turbine a device used for mixing the power...Ch. 13 - Being quite interested in obsolete electronics,...Ch. 13 - Referring to the previous ICA 13-5, Angus is also...
Ch. 13 - Prob. 7ICACh. 13 - The following instructions apply to ICA 13-7 to...Ch. 13 - The following instructions apply to ICA 13-7 to...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - The following instructions will apply to ICA 13-10...Ch. 13 - Prob. 21ICACh. 13 - As a reminder, the Reynolds number is discussed in...Ch. 13 - As a reminder, the Reynolds number is discussed in...Ch. 13 - An environmental engineer has obtained a bacteria...Ch. 13 - An environmental engineer has obtained a bacteria...Ch. 13 - An environmental engineer has obtained a bacteria...Ch. 13 - A growing field of inquiry that poses both great...Ch. 13 - If an object is heated, the temperature of the...Ch. 13 - The Volcanic Explosivity Index (VEI) is based...Ch. 13 - You are an engineer for a plastics manufacturing...Ch. 13 - A Pitot tube is a device used to measure the...Ch. 13 - As part of an electronic music synthesizer you...Ch. 13 - The following data were collected during testing...Ch. 13 - The relationship of the power required by a...Ch. 13 - When a fluid flows around an object, it creates a...
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- Could you please fix my code it’s supposed to look like the graph that’s on the picture. But the lines do not cross eachother at the beginning. Could you make the lines look like the lines on the graph? Use this code in MATLAB and fix it. % Sample data for Diesel and Petrol cars carPosition = linspace(1, 60, 50); % Assumed positions of cars % Define your seed here seed = 50; rand('seed',seed); % Set the seed for reproducibility % Assumed CO2 emissions for Diesel and Petrol CO2Diesel = 25 + 5*cos(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Diesel CO2Petrol = 20 + 5*sin(carPosition/60*2*pi) + randn(1, 50)*5; % Random data for Petrol % Fit polynomial curves with a reduced degree of 2 pDiesel = polyfit(carPosition, CO2Diesel, 2); pPetrol = polyfit(carPosition, CO2Petrol, 2); % Generate points for best fit lines fitDiesel = polyval(pDiesel, carPosition); fitPetrol = polyval(pPetrol, carPosition); % Plotting the data figure; hold on; % Plot Diesel best fit line…arrow_forwardUse MATLAB, please make sure you use the numbers on the picture to make the graph that is also on the pictures. Make an exact copy of that graph and make sure that it runs on MATLAB, please send the code and a screenshot of the graph to show that it works. I need help with this.arrow_forwardFor the position-time graph shown, pick the corresponding velocity-time graph. Velocity Position Time (s) Black dot line (right): Red dot line (left); Yellow solid line (right): Cyan dash line (left); Blue solid line (left): Time (s) Velocity Time (s)arrow_forward
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