There i am assuming the velocity vector is FROM 0,0 TO 0,5. And 0,0 is i and 0,5 is j.

In that case the velocity vector is only along y and the y component should be 5 and x component 0. It is coming as opposite because,

`cos(radian)`

whould be x velocity component and `sin(radian)`

the y compunent.

And the number 6.123031769111886E-17 is actually returned in place of 0.

Look at the following figure:

Also as can be seen from the figure you do not need the trigonometric computations at all.

You can simply get the x and y components as follows:

```
// y2 - y1
var vy = listOfNodes[j].y - listOfNodes[i].y;
// x2 - x1
var vx = listOfNodes[j].x - listOfNodes[i].x;
```

This will avoid the floating point inaccuracy caused by the trig finctions due to which you are seeing 6.123031769111886E-17 instead of 0.

You only need to use `atan2`

if you actually need the angle θ in your code.

**Update:**
Well if you need only unit (normalized) vector's components you can divide the vx and vy with the length of the original vector. Like this:

```
// y2 - y1
var vy = listOfNodes[j].y - listOfNodes[i].y;
// x2 - x1
var vx = listOfNodes[j].x - listOfNodes[i].x;
// vector magnitude
var mag = Math.sqrt(vx * vx + vy * vy);
// get unit vector components
vy /= mag;
vx /= mag;
```

Using the above you will get the exactly the same results as you are getting from trig `sin`

and `cos`

functions.

But if you still need to use the original code and want to make 6.12...E-17 compare to 0, you can use the epsilon technique for comparing floats. So you can compare any value within epsilon's range from 0, using flllowing code:

```
function floatCompare(a:Number, b:Number, epsilon:Number):Boolean{
return (a >= (b - epsilon) && a <= (b + epsilon));
}
// To check for zero use this code, here i'm using 0.0001 as epsilon
if(floatCompare(vx, 0, 0.0001)){
// code here
}
```

So any deviation in the range of `[b-epsilon, b+epsilon]`

would successfully compare to b. This is essential in case of floating point arithmetic.