I have the following code to compute the orthogonal vectors of each vector coming as input from an i,j dimension matrix. So each row in the matrix is a vector. Here is the code:

```
for i in range(data.shape[0]):
for j in range(data.shape[1]):
s=0 #row counter set to 0
if j == data.shape[1]-1: #check if last row element has been reached
for k in range(j): #compute the sum of all previous values.
s=s+data2[i][k]*data[i][k]
data2[i][j] = -s/data[i][k]
else:
data2[i][j] = random.uniform(1,random.getrandbits(10))
dot(data[i],data2[i])
```

But it doesn't work as the dot function very rarely returns 0 which should be in case the vectors are orthogonal. I can't see a flow at the logic of my code. I simply fix j-1 random elements for the coefficients of the orthogonal vector and then in order to find the last coefficient i solve a simple equation which is the dot product of the previous coefficients of the random elements with the coefficients of the vector divided by the last coeffient. a1r1+a2r3+...+anrn=0. I know ai's. I fix random i-1 ri and then i solve the 1 var equation linear problem to find rn suth than ri vector would be orthogonal to a1 vector. The results from the last dot product computation i am getting are in this form:

```
===================================================
8.90285882653
===================================================
15.1275777619
===================================================
25.0847305913
===================================================
30.8608285102
===================================================
35.2496752739
===================================================
-53.3796252747
===================================================
16.302777
===================================================
29.3607765359
===================================================
-39.8982101139
===================================================
42.97222625
```

`dot`

? It's unlikely that with floating point numbers you'll get a result ofexactlyzero -- Usually you get numbers on the order of epsilon for your data type (`1e-16`

for double precision). – mgilson Jun 25 '13 at 12:37