I am posting my response as an answer because I do not have enough points to make a comment.

**My interpretation of the question: How do we normalize the coordinates of a set of points in 2 dimensional space?**

A normalization operation involves a **"shift and scale"** operation. In case of **1 dimensional space** this is fairly easy and intuitive (as pointed out by @Mizipzor).

```
normalizedX=(originalX-minX)/(maxX-minX)
```

In this case we are first **shifing** the value by a distance of **minX** and then **scaling** it by the range which is given by **(maxX-minX)**. The **shift** operation ensures that the minimum moves to 0 and the **scale** operation *squashes* the distribution such that the distribution has an upper limit of 1

**In case of 2d , simply dividing by the largest dimension is not enought. Why?**

Consider the simplified case with just 2 points as shown below.
The maximum value of any dimension is the **Y** value of point **B** and this **10000**.

```
Coordinates of normalized A=>5000/10000,8000/10000 ,i.e 0.5,0.8
Coordinates of normalized A=>7000/10000,10000/10000 ,i.e 0.7,1.0
```

The X and Y values are all with 0 and 1. However, the distribution of the normalized values is far from uniform. The minimum value is just 0.5. Ideally this should be closer to 0.

**Preferred approach for normalizing 2d coordinates**

To get a more even distribution we should do a "shift" operation around the minimum of all X values and minimum of all Y values. This could be done around the mean of X and mean of Y as well. Considering the above example,

- the minimum of all X is 5000
- the minimum of all Y is 8000

**Step 1 - Shift operation**

```
A=>(5000-5000,8000-8000), i.e (0,0)
B=>(7000-5000,10000-8000), i.e. (2000,2000)
```

**Step 2 - Scale operation**

To scale down the values we need some maximum. We could use the diagonal AB whose length is 2000

```
A=>(0/2000,0/2000), i.e. (0,0)
B=>(2000/2000,2000/2000)i.e. (1,1)
```

**What happens when there are more than 2 points?**
The approach remains similar. We find the coordinates of the smallest bounding box which fits all the points.

- We find the minimum value of X (MinX) and minimum value of Y (MinY) from all the points and do a
**shift** operation. This changes the origin to the lower left corner of the bounding box.
- We find the maximum value of X (MaxX) and maximum value of Y (MaxY) from all the points.
- We calculate the length of the diagonal connecting (MinX,MinY) and (MaxX,MaxY) and use this value to do a
**scale** operation.

.

```
length of diagonal=sqrt((maxX-minX)*(maxX-minX) + (maxY-minY)*(maxY-minY))
normalized X = (originalX - minX)/(length of diagonal)
normalized Y = (originalY - minY)/(length of diagonal)
```

**How does this logic change if we have more than 2 dimensions?**

The concept remains the same.
- We find the minimum value in each of the dimensions (X,Y,Z)
- We find the maximum value in each of the dimensions (X,Y,Z)
- Compute the length of the diagonal as a scaling factor
- Use the minimum values to shift the origin.

```
length of diagonal=sqrt((maxX-minX)*(maxX-minX)+(maxY-minY)*(maxY-minY)+(maxZ-minZ)*(maxZ-minZ))
normalized X = (originalX - minX)/(length of diagonal)
normalized Y = (originalY - minY)/(length of diagonal)
normalized Z = (originalZ - minZ)/(length of diagonal)
```