# What is the equation stands for in geometry(intuitively)?

I am writing a bilinear interpolation method.

This method can be abstract by solve the equation A*x = b, A is a 4x4 matrix below:

``````1 x1 y1 x1*y1
1 x2 y2 x2*y2
1 x3 y3 x3*y3
1 x4 y4 x4*y4
``````

Here, (x1, y1), (x2, y2), (x3, y3) and (x4, y4) is four points containing the dst interpolation point.

My problem is when det(A) = 0(then x! = A-1*b), what is the quadrangle looks like?

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The determinant becomes 0 when one of the rows or columns can be expressed as a linear combination of the others. Using columns, this equation must hold for some constants a, b, c for each of the four points:

``````a*1 + b*x + c*y + xy = 0
``````

This is the equation a hyperbola with asymptotes parallel to the axis, so the determinant is zero if and only if the four points fall on the same hyperbola.

For example, if you pick the rectangle (-2, -1), (-1, -2), (1, 2), (2, 1) the determinant will be zero since the points fall on the hyperbola defined by t → (t, 2/t).

Another way to look at it: you are free to pick any 3 points. The three points define a unique hyperbola. The determinant is 0 if and only if you pick the fourth point from that hyperbola.

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Joni's answer above is entirely correct, but here's a physical interpretation that you might like:

Picture a square as a well-behaved quadrilateral defined by the following four points: 1 = (0,0), 2 = (1,0), 3 = (1, 1), and 4 = (0, 1).

If you start skewing it by anchoring points 1 and 2 but tugging point 3 to the right in such a way that the sides remain the same length, but the angle between the x-axis and the line segment between points 2 and 3 changes from 90 degrees to 180 and the angle between the x-axis and the line segment between points 1 and 4 changes from 90 degrees to 0, the determinant will approach zero as the angle increases. When you have points 1 = (0,0), 2 = (1, 0), 3 = (2,0), and 4 = (1,0) the quad will be collapsed to a line segment and the determinant will be zero.

You can run this experiment with your matrix and see if I'm correct.

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