Borrar filtros
Borrar filtros

Using ode45 for high altitude balloon trajectory: need some variables to update every iteration and need to plot altitude vs time.

4 visualizaciones (últimos 30 días)
Kellie Matthews
Kellie Matthews el 28 de Jul. de 2017
Editada: Torsten el 31 de Jul. de 2017
I'm trying to predict the trajectory of a high altitude balloon. This is the second order ODE I am using: (mass+cb*rho*vol)*z"=g(rho*vol-mass)-.5*rho*Cd*z'*|z'|*Ca
cb, Cd, g, and mass are constants. density[rho],volume, (approximate) surface area of a circle [Ca] all change with altitude.
I used this link to help me set up my second order ODE as a function: http://www.math.purdue.edu/~shen/cs614/projects/ode45.pdf
function xp=F(t,x) %xp = x prime or x'
xp=zeros(2,1); %output must be column vector
xp(1)=x(2);
xp(2)=(g*(RhoA*vol-mass)-.5*RhoA*realCD*x(2)*abs(x(2))*Ca)/(mass+cb*RhoA*vol);
end
This is what I need for my atmospheric properties that rely on altitude:
if (z <= 11000) %Meters (Troposhpere)
temp = 15.04 - 0.00649*z;
tempK = temp + 273.15;
p = 101.29*((temp+273.1)/(288.08)).^5.256; %kPa
elseif (z > 11000 && z < 25000) %Meters (Lower Stratosphere)
temp = -56.46;
tempK = temp + 273.15;
p = 22.65*exp(1.73-0.000157*z); %kPa
else %Upper Stratosphere
temp = -131.21 + 0.00299*z;
tempK = temp + 273.15;
p = 2.488 * ((temp+273.1)/216.6).^-11.388; %kPa
end
dTempK = abs(tempK - oldTempK);
RhoA = (p/(.2869*tempK));
Wg = Mb.*(1000*p).*vol/(r.*tempK);
radius = ((3/(4*pi))*vol).^(1/3);
Ca = pi*radius.^2;
old_z = z;
[t,x]=ode45('F',[0,tf],[0,0]);
hold on
plot(t,x(:,1))
z=x(i,1);
dz = z - old_z; %this is the change in altitude from the last second
dVol = (r/(p*Mb))*(Wg*dTempK/dt)*dt + (RhoA/p)*(vol)*dz;
vol = vol + dVol;

Iniciar sesión para responder a esta pregunta.

Respuesta aceptada

Ari
Ari el 28 de Jul. de 2017
Editada: Ari el 28 de Jul. de 2017
or variables that change with time or state you should put their calculations inside the function xp. In your case, your states x seem to be [z;z']. Set z = x(1) in the beginning of the function and calculate the variable parameters before you calculate xp(2). It seems you will run into a problem trying to access the z value of the previous timestep (old_z) unless you use a persistent variable. You can try the following.
function xp = F(t,x)
persistent old_z;
z = x(1);
dz = z - old_z;
old_z = z; % set the value of old_z for next timestep
% calculate variable parameters
...
xp = zeros(2,1);
xp(1) = x(2);
xp(2) = (g*(RhoA*vol-mass)-.5*RhoA*realCD*x(2)*abs(x(2))*Ca)/(mass+cb*RhoA*vol);
end
The persisent variable will remain in memory between calls to the function.
  4 comentarios
Mostrar 2 comentarios más antiguos
Kellie Matthews
Kellie Matthews el 31 de Jul. de 2017
I'm sorry, but this didn't work for me. After xp(2)=%ascent eq.% I have
dz = z - old_z; %this is the change in altitude from the last second
dVol = (r/(p*Mb))*(Wg*dTempK/dt)*dt + (RhoA/p)*(vol)*dz;
vol = vol + dVol;
However, dVol and vol are underlined in red and matlab says "The value assigned to variable '..' might be unused" Does this mean that the volume is not updated throughout the code? I tried the if statement you suggested and my graph came out exactly the same as before, with no apparent decrease in altitude caused by a decrease in volume.
This is what I tried with an if statement:
dz = z - old_z; %this is the change in altitude from the last second
if t <= 10800
dVol = (r/(p*Mb))*(Wg*dTempK/dt)*dt + (RhoA/p)*(vol)*dz;
vol = vol + dVol;
else
vol = vol - 10;
end
The variables dVol and vol are still underlined in red when I try this.
Torsten
Torsten el 31 de Jul. de 2017
Editada: Torsten el 31 de Jul. de 2017
I wonder why you don't solve an additional (third) ODE for "vol" together with the two ODEs for height and velocity:
dVol/dt = (r/(p*Mb))*(Wg*dTempK/dt) + (RhoA/p)*(Vol)*dz/dt ;
This way, you overcome all the problems from above.
Best wishes
Torsten.

Iniciar sesión para comentar.

Más respuestas (0)

Categorías

Más información sobre Ordinary Differential Equations en Help Center y File Exchange.

Etiquetas

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by