```
clc;
clear all;
syms y a2 a3
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% [ 0.5 0.25 0.125 ] [ a2 ] [ y ]
% [ 1 1 1 ] [ a3 ] = [ 3 ]
% [ 2 4 8 ] [ 6 ] [ 2 ]
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
M = [0.5 0.25 0.125; 1 1 1; 2 4 8];
t = [a2 a3 6];
r = [y 3 2];
sol = M * t'
s1 = solve(sol(1), a2) % solve for a2
s2 = solve(sol(2), a3) % solve for a3
```

This is what I have so far. These are my output

```
sol =
conj(a2)/2 + conj(a3)/4 + 3/4
conj(a2) + conj(a3) + 6
2*conj(a2) + 4*conj(a3) + 48
s1 =
- conj(a3)/2 - 3/2 - Im(a3)*i
s2 =
- conj(a2) - 6 - 2*Im(a2)*i
```

`sol`

looks like what we would have if we put them back into equation form:

0.5 * a2 + 0.25 * a3 + 0.125 * a4

a2 + a3 + a4 = 3

2*a2 + 4*a3 + 8*a4 = 2

where a4 is known == 6.

My problem is, I am stuck with how to use `solve`

to actually solve these equations to get the values of `a2`

and `a3`

.

`s2`

solve for a3 but it doesn't match what we have on paper (not quite).
a2 + a3 + 6 = 3 should yield a3 = -3 - a2.

because of the imaginary. Somehow I need to equate the vector solution `sol`

to the values `[y 3 2]`

for each row.