Can't stand aside,

So we have linear system:

A_{1} * x + B_{1} * y = C_{1}

A_{2} * x + B_{2} * y = C_{2}

let's do it with Cramer's rule, so solution can be found in determinants:

x = D_{x}/D

y = D_{y}/D

where *D* is main determinant of the system:

A_{1} B_{1}

A_{2} B_{2}

and *D*_{x} and *D*_{y} can be found from matricies:

C_{1} B_{1}

C_{2} B_{2}

and

A_{1} C_{1}

A_{2} C_{2}

(notice, as *C* column consequently substitues the coef. columns of *x* and *y*)

So now the python, for clarity for us, to not mess things up let's do mapping between math and python. We will use array `L`

for storing our coefs *A*, *B*, *C* of the line equations and intestead of pretty `x`

, `y`

we'll have `[0]`

, `[1]`

, but anyway. Thus, what I wrote above will have the following form further in the code:

for *D*

L1[0] L1[1]

L2[0] L2[1]

for *D*_{x}

L1[2] L1[1]

L2[2] L2[1]

for *D*_{y}

L1[0] L1[2]

L2[0] L2[2]

Now go for coding:

`line`

- produces coefs *A*, *B*, *C* of line equation by two points provided,

`intersection`

- finds intersection point (if any) of two lines provided by coefs.

```
from __future__ import division
def line(p1, p2):
A = (p1[1] - p2[1])
B = (p2[0] - p1[0])
C = (p1[0]*p2[1] - p2[0]*p1[1])
return A, B, -C
def intersection(L1, L2):
D = L1[0] * L2[1] - L1[1] * L2[0]
Dx = L1[2] * L2[1] - L1[1] * L2[2]
Dy = L1[0] * L2[2] - L1[2] * L2[0]
if D != 0:
x = Dx / D
y = Dy / D
return x,y
else:
return False
```

Usage example:

```
L1 = line([0,1], [2,3])
L2 = line([2,3], [0,4])
R = intersection(L1, L2)
if R:
print "Intersection detected:", R
else:
print "No single intersection point detected"
```

“I know how to do this on paper”— Then what exactly is your problem? It’s pure math which you need to apply here. And Python is your calculator. What have you tried? – poke Dec 19 '13 at 9:34