Reading Godot Game Engine documentation about unit vector, normalization, and dot product really makes a lot of sense. Here is the article:

**Unit vectors**

Ok, so we know what a vector is. It has a direction and a magnitude. We also know how to use them in Godot. The next step is learning about unit vectors. Any vector with magnitude of length 1 is considered a unit vector. In 2D, imagine drawing a circle of radius one. That circle contains all unit vectors in existence for 2 dimensions:

So, what is so special about unit vectors? Unit vectors are amazing. In other words, unit vectors have several, very useful properties.

Can’t wait to know more about the fantastic properties of unit vectors, but one step at a time. So, how is a unit vector created from a regular vector?

**Normalization**

Taking any vector and reducing its magnitude to 1.0 while keeping its direction is called normalization. Normalization is performed by dividing the x and y (and z in 3D) components of a vector by its magnitude:

```
var a = Vector2(2,4)
var m = sqrt(a.x*a.x + a.y*a.y)
a.x /= m
a.y /= m
```

As you might have guessed, if the vector has magnitude 0 (meaning, it’s not a vector but the origin also called null vector), a division by zero occurs and the universe goes through a second big bang, except in reverse polarity and then back. As a result, humanity is safe but Godot will print an error. Remember! Vector(0,0) can’t be normalized!.

Of course, Vector2 and Vector3 already provide a method to do this:

```
a = a.normalized()
```

**Dot product**

OK, the dot product is the most important part of vector math. Without the dot product, Quake would have never been made. This is the most important section of the tutorial, so make sure to grasp it properly. Most people trying to understand vector math give up here because, despite how simple it is, they can’t make head or tails from it. Why? Here’s why, it’s because...

The dot product takes two vectors and returns a scalar:

```
var s = a.x*b.x + a.y*b.y
```

Yes, pretty much that. Multiply x from vector a by x from vector b. Do the same with y and add it together. In 3D it’s pretty much the same:

```
var s = a.x*b.x + a.y*b.y + a.z*b.z
```

I know, it’s totally meaningless! You can even do it with a built-in function:

```
var s = a.dot(b)
```

The order of two vectors does not matter, `a.dot(b)`

returns the same value as `b.dot(a)`

.

This is where despair begins and books and tutorials show you this formula:

`A ⋅ B = ∥A∥ ∥B∥ cos(θ)`

And you realize it’s time to give up making 3D games or complex 2D games. How can something so simple be so complex? Someone else will have to make the next Zelda or Call of Duty. Top down RPGs don’t look so bad after all. Yeah I hear someone did pretty will with one of those on Steam...

So this is your moment, this is your time to shine. DO NOT GIVE UP! At this point, this tutorial will take a sharp turn and focus on what makes the dot product useful. This is, why it is useful. We will focus one by one in the use cases for the dot product, with real-life applications. No more formulas that don’t make any sense. Formulas will make sense once you learn what they are useful for.

Siding
The first useful and most important property of the dot product is to check what side stuff is looking at. Let’s imagine we have any two vectors, a and b. Any direction or magnitude (neither origin). Does not matter what they are, but let’s imagine we compute the dot product between them.

```
var s = a.dot(b)
```

The operation will return a single floating point number (but since we are in vector world, we call them scalar, will keep using that term from now on). This number will tell us the following:

If the number is greater than zero, both are looking towards the same direction (the angle between them is < 90° degrees).
If the number is less than zero, both are looking towards opposite direction (the angle between them is > 90° degrees).
If the number is zero, vectors are shaped in L (the angle between them is 90° degrees).

So let’s think of a real use-case scenario. Imagine Snake is going through a forest, and then there is an enemy nearby. How can we quickly tell if the enemy has seen discovered Snake? In order to discover him, the enemy must be able to see Snake. Let’s say, then that:

Snake is in position A.
The enemy is in position B.
The enemy is facing towards direction vector F.

So, let’s create a new vector BA that goes from the guard (B) to Snake (A), by subtracting the two:

```
var BA = A - B
```

Ideally, if the guard was looking straight towards snake, to make eye to eye contact, it would do it in the same direction as vector BA.

If the dot product between F and BA is greater than 0, then Snake will be discovered. This happens because we will be able to tell that the guard is facing towards him:

```
if (BA.dot(F) > 0):
print("!")
```

Seems Snake is safe so far.

Siding with unit vectors
Ok, so now we know that dot product between two vectors will let us know if they are looking towards the same side, opposite sides or are just perpendicular to each other.

This works the same with all vectors, no matter the magnitude so unit vectors are not the exception. However, using the same property with unit vectors yields an even more interesting result, as an extra property is added:

If both vectors are facing towards the exact same direction (parallel to each other, angle between them is 0°), the resulting scalar is 1.
If both vectors are facing towards the exact opposite direction (parallel to each other, but angle between them is 180°), the resulting scalar is -1.
This means that dot product between unit vectors is always between the range of 1 and -1. So Again...

If their angle is 0° dot product is 1.
If their angle is 90°, then dot product is 0.
If their angle is 180°, then dot product is -1.
Uh.. this is oddly familiar... seen this before... where?

Let’s take two unit vectors. The first one is pointing up, the second too but we will rotate it all the way from up (0°) to down (180° degrees)...

While plotting the resulting scalar!

Aha! It all makes sense now, this is a Cosine function!

We can say that, then, as a rule...

The dot product between two unit vectors is the cosine of the angle between those two vectors. So, to obtain the angle between two vectors, we must do:

```
var angle_in_radians = acos( a.dot(b) )
```

What is this useful for? Well obtaining the angle directly is probably not as useful, but just being able to tell the angle is useful for reference. One example is in the Kinematic Character demo, when the character moves in a certain direction then we hit an object. How to tell if what we hit is the floor?

By comparing the normal of the collision point with a previously computed angle.

The beauty of this is that the same code works exactly the same and without modification in 3D. Vector math is, in a great deal, dimension-amount-independent, so adding or removing an axis only adds very little complexity.