There are several errors in your code. Consider this (I put comments where corrections were needed)

```
n=0;
eps=1;
a=0.1; %You need a way smaller parameter to converge!
x=[1;1];
A = [6 -3/2 ; -3/2 8]; %You have a bilinear positive definite form,
%you may use matrix form for convenience
while eps>1e-12 && n<100 %You had wrong termination conditions!!
gradf=2*A*x; %(gradf in terms of matrix)
f=x'*A*x; %you need to update f every iteration!!
eps=(norm(gradf)/(1+abs(f)))
disp(eps > 1e-12)
x=x-a*gradf;
%Now you can see the orbit towards minimum
plot(x(1),x(2),'o'); hold on
n=n+1;
end
n
x
eps
```

for instance with the current value `a=.1`

I get

```
n = 100
eps = 1.2308e-011
x =
1.0e-012 *
-0.2509
0.4688
```

That is I had to perform 100 iteration because my epsilon is still above the threshold. If I allow 200 iterations I get

```
n = 110
eps =
7.9705e-013
x =
1.0e-013 *
-0.1625
0.3036
```

I.e. 110 iterations are sufficient.

Case of a general `f`

(i.e. not a quadratic form).

You can use, for instance, function handles, i.e. you define (before the `while`

)

```
foo = @(x) 6*x(1)^2+8*x(2)^2-3*x(1)*x(2);
foo_x = @(x) 12*x(1)-3*x(2);
foo_y = @(x) 16*x(2)-3*x(1);
```

then, in the `while`

you substitute

```
gradf = [foo_x(x);foo_y(x)];
f = foo(x);
```

P.S. for what concerns the `while`

cycle, please keep in mind that you keep on iterating **while** you are not satisfied with your precision (`eps>1e-12`

) **AND** your total number of iteration is below a given threshold (`n<100`

).

Consider also that you are working in **finite precision**: a numerical algorithm can never reach the analytic solution (i.e. what you have with infinite precision and infinite iterations), therefore, you always have to **set a threshold** (`eps`

, which should be above the machine precision \approx`1e-16`

) and that **is** your `0`

.