**tl;dr: Normalized vectors simplify your math. They also reduce the number of very hard to diagnose visual artifacts in your images.**

Normalized vector is in the same direction with just unit length 1? So
I'm unclear when it is necessary?

You almost always want all vectors in a ray tracer to be normalized.

The simplest example is that of the intersection test: where does a bouncing ray hit another object.

Consider a ray where:

```
p(t) = p_0 + v * t
```

In this case, a point anywhere along that ray `p(t)`

is defined as an offset from the original point `p_0`

and an offset along a particular direction `v`

. For every increment of parameter `t`

, the resulting `p(t)`

will move another increment of length equal to the length of the vector `v`

.

Remember, you know `p_0`

and `v`

. When you are trying to find the point where this ray next hits another object, you have to solve for that `t`

. It is obviously more convenient, if not always obviously necessary, to use normalized vector `v`

s in that representation.

However, that same vector `v`

is used in lighting calculations. Imagine that we have another direction vector `u`

that points towards a lighting source. For the purpose of a very simple shading model, we can define the light at a particular point to be the dot product between those two vectors:

```
L(p) = v * u
```

*Admittedly, this is a very uninteresting reflection model but it captures the high points of the discussion. A spot on a surface is bright if reflection points towards the light and dim if not.*

Now, remember that another way of writing this dot product is the product of the magnitudes of the vectors times the cosine of the angle between them:

```
L(p) = ||v|| ||u|| cos(theta)
```

If `u`

and `v`

are of unit length (normalized), then the equation will evaluate to be proportional to the angle between the two vectors. However, if `v`

is not of unit length, say because you didn't bother to normalize after reflecting the vector in the ray model above, now your lighting model has a problem. Spots on the surface using a larger `v`

will be much brighter than spots that do not.