I am working on constant temperature hot-wire anemometry in Matlab. So I am using a second order differential equation (conduction equation).
I solved the main equation analytically and found temperature distribution:
f=0.09; b=0.0044; q=3.73E-9; L=1; Tw=250; Tam=27; T(x)= 2*C1*cosh(x*((f-b*g)/q)^0.5)+g/(f-b*g)
C1 has to be determined from a boundary condition:
Then I found
C1 as a function of
g is implicitly unknown):
syms c g solve(2*c*cosh(0.5*(0.09-0.0044*g)/3.73*10^-9)^0.5+g/(0.09-3.73*10^-9*g)==0,c)
g can be determined from constant temperature condition:
All things considered, my all code is:
clc; clear all; f=0.09; b=0.0044; q=3.73*10^-9; L=1; Tw=250; Tam=27; syms c g c=solve(2*c*cosh(L/2*(0.09-0.0044*g)/3.73*10^-9)^0.5+g/(0.09-0.0044*3.73*10^-9)==0,c) syms x z=int(2*c*cosh(x*((f-b*g)/q)^0.5)+g/(f-b*g),x,-L/2,L/2); g=solve(z==L*(Tw-Tam),g)
This condition should give,after performing the integral, an algebraic equation for
g. But the resultant
g is zero. It always returns
g as a zero. Why? My Matlab skills are not enough for this. I then want to plot the temperature distribution T(x).
x can be divided into 100 parts of length
L to plot the temperature distribution.