# Distance Between 2 Points

### Quick Explanation

When we know the **horizontal** and **vertical** distances between two points we can calculate the straight line distance like this:

distance = √ a^{2} + b^{2}

Imagine you know the location of two points (A and B) like here.

What is the distance between them?

We can run lines down from A, and along from B, to make a Right Angled Triangle.

And with a little help from Pythagoras we know that:

a^{2} + b^{2} = c^{2}

Now label the coordinates of points A and B.

x_{A} means the x-coordinate of point A

y_{A} means the y-coordinate of point A

The horizontal distance **a** is **(x _{A} − x_{B})**

The vertical distance **b** is **(y _{A} − y_{B})**

Now we can solve for c (the distance between the points):

^{2}= a

^{2}+ b

^{2}

^{2}= (x

_{A}− x

_{B})

^{2}+ (y

_{A}− y

_{B})

^{2}

## Examples

### Example 1

Fill in the values: | ||

### Example 2

It doesn't matter what order the points are in, because squaring removes any negatives:

Fill in the values: | ||

### Example 3

And here is another example with some negative coordinates ... it all still works:

Fill in the values: | ||

*(Note √136 can be further simplified to 2√34 if you want)*

## Try It Yourself

Drag the points:

## Three or More Dimensions

It works perfectly well in 3 (or more!) dimensions.

Square the difference for each axis, then sum them up and take the square root:

Distance = √[ (x_{A} − x_{B})^{2} + (y_{A} − y_{B})^{2} + (z_{A} − z_{B})^{2} ]

### Example: the distance between the two points (8,2,6) and (3,5,7) is:

= √[ (8−3)^{2} + (2−5)^{2} + (6−7)^{2} ] |

= √[ 5^{2} + (−3)^{2} + (−1)^{2} ] |

= √( 25 + 9 + 1 ) |

= √35 |

Which is about 5.9 |