Difference between revisions of "User:Arc32"
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===Grand Challenges of Engineering=== | ===Grand Challenges of Engineering=== | ||
− | [http://news.bbc.co.uk/2/hi/7512672.stm UN in | + | [http://news.bbc.co.uk/2/hi/7512672.stm UN in call for basic sanitation] , BBC Mobile News, updated July 17, 2008, accessed September 17, 2011 (Provide access to clean water) |
+ | |||
+ | =='''Favorite Demonstration'''== | ||
+ | My favorite demo is "Viewing a Penny". I think it's really cool that you can use MATLAB to graph different curves and create a complicated graphic that is so accurate. | ||
+ | |||
+ | |||
+ | tester code by Behringer for physics 61 | ||
+ | |||
+ | |||
+ | function drag(v,tf,muin) | ||
+ | global m g mu | ||
+ | h0 = 0; % initial height in m | ||
+ | v0 = v; % initial velocity up in m/s | ||
+ | m = 1; % mass in kg | ||
+ | g = 9.81; % acceleration due to gravity in m/s/s | ||
+ | |||
+ | mu = muin; % set global drag coefficient from input | ||
+ | |||
+ | tspan = [0 tf]; % time span in seconds | ||
+ | y0=[h0;v0]; | ||
+ | |||
+ | % Controls for ODE solver. Use ode45 for matlab, ode54 for octave with | ||
+ | % odepkg installed. | ||
+ | options = odeset('RelTol',1e-6,'AbsTol',1e-6,'InitialStep',0.1,'MaxStep',0.1); | ||
+ | % [t,y]=ode54(@eom,tspan,y0,options); | ||
+ | [t,y]=ode45(@eom,tspan,y0,options); | ||
+ | |||
+ | figure(1); | ||
+ | clf; | ||
+ | hold on; | ||
+ | % draw x-axis for reference. | ||
+ | plot(t,zeros(length(t)),'k'); | ||
+ | % plot y(t) | ||
+ | plot(t,y(:,1),'g'); | ||
+ | % Mark at t = 4 as "target". | ||
+ | tt = 4.*ones(2); | ||
+ | ty = [0 1]; | ||
+ | plot(tt,ty,'-k'); | ||
+ | % labels, legend. | ||
+ | xlabel('Time (s)'); | ||
+ | ylabel('Height (m)'); | ||
+ | legend('Ball','(Surface of Earth)',0); | ||
+ | title('Height of Ball vs. Time'); | ||
+ | hold off; | ||
+ | |||
+ | % This equation of motion is appropriate for a turbulent drag force of | ||
+ | % F = - mu v^2, formulated in such a way that it always opposes the | ||
+ | % direction of v. | ||
+ | function dydt=eom(t,y) | ||
+ | global m g mu | ||
+ | |||
+ | dydt=[y(2) | ||
+ | -g - mu*y(2)*abs(y(2))]; |
Latest revision as of 04:01, 29 February 2012
Contents
Abby Carignan
Name Pronunciation
Abby Carignan. Abby is pronounced "Ah-bee"--as if you combined the words apple and bee. My last name is pronounced rather phenetically--"Cuh-rig-nin" with the stress on the rig (but not too strongly...)
Grand Challenges of Engineering
UN in call for basic sanitation , BBC Mobile News, updated July 17, 2008, accessed September 17, 2011 (Provide access to clean water)
Favorite Demonstration
My favorite demo is "Viewing a Penny". I think it's really cool that you can use MATLAB to graph different curves and create a complicated graphic that is so accurate.
tester code by Behringer for physics 61
function drag(v,tf,muin)
global m g mu
h0 = 0; % initial height in m v0 = v; % initial velocity up in m/s m = 1; % mass in kg g = 9.81; % acceleration due to gravity in m/s/s
mu = muin; % set global drag coefficient from input
tspan = [0 tf]; % time span in seconds y0=[h0;v0];
% Controls for ODE solver. Use ode45 for matlab, ode54 for octave with % odepkg installed. options = odeset('RelTol',1e-6,'AbsTol',1e-6,'InitialStep',0.1,'MaxStep',0.1); % [t,y]=ode54(@eom,tspan,y0,options); [t,y]=ode45(@eom,tspan,y0,options); figure(1); clf; hold on; % draw x-axis for reference. plot(t,zeros(length(t)),'k'); % plot y(t) plot(t,y(:,1),'g'); % Mark at t = 4 as "target". tt = 4.*ones(2); ty = [0 1]; plot(tt,ty,'-k'); % labels, legend. xlabel('Time (s)'); ylabel('Height (m)'); legend('Ball','(Surface of Earth)',0); title('Height of Ball vs. Time'); hold off;
% This equation of motion is appropriate for a turbulent drag force of % F = - mu v^2, formulated in such a way that it always opposes the % direction of v. function dydt=eom(t,y) global m g mu
dydt=[y(2)
-g - mu*y(2)*abs(y(2))];