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)
```

Then `C1`

has to be determined from a boundary condition:

```
T(+L/2)=0
T(-L/2)=0
```

Then I found `C1`

as a function of `g`

(because `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:

```
1/L*int(T(x)dx,-L/2,L/2)=Tw-Tam
```

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.

`cosh{}`

is invalid Matlab) which makes your question hard to read/understand. Please edit it. StackOverflow doesn't support TeX so try to just post your actual code. Also, inserting numeric values into a formula too early can make solving it harder in some cases(especially for floating point values). Finally, "I could not perform it" means nothing. Why? Was there an error? Did you not understand something? – horchler Feb 3 '14 at 19:39`.../3.73*10^-9`

should be`.../3.73e-9`

. And your equation for T(x) at top doesn't match with the others in terms of`g`

and`q`

. If you're going to plug in a bunch of numeric values there's probably no sense in using symbolic math. You might better use`fzero`

. – horchler Feb 3 '14 at 22:34