Let x, y be the coordinates of the object in the non-rotated coordinate system translated so that the eye lies at the origin. You can take advantage of basic properties of two linear functions whose charts partition your simulated space into the four quadrants you drew ("left", "up", "right" and "down").
The tilted line going from left bottom to top right is given by y=x. This means that (assuming y grows upwards and x grows rightwards) the points lying in quadrants "down" and "right" have coordinates satisfying y < x. Similarly points in quadrants "up" and "left" have coordinates satisfying y > x.
In order to differentiate between "down" and "right" and between "up" and "left" quadrants we can use the other line (from top left to bottom right) whose formula is y=-x. This time we see that points belonging to the "left" and "down" quadrants have coordinates obeying y < -x. Similarly, points belonging to the "right" and "up" quadrants have coordinates satisfying y > -x.
Combining these conditions we see that the object with coordinates x, y lies in:
- "left" quadrant iff y > x and y < -x
- "down" quadrant iff y < x and y < -x
- "right" quadrant iff y < x and y > -x
- "up" quadrant iff y > x and y > -x
These conditions assume that the point where all four quadrants meet is the origin of the coordinate system used to express x and y. You should perform the necessary translation using the known position of the eye before using these conditions.
Note that if you want to perform this process relative to a few eyes with different positions, you must use different translation each time. One unwanted consequence of this is that you may arrive at different quadrants for the same objects from two different eyes. This is a consequence of the problem and is independent of how you solve it.
You also need to make a choice regarding the classification of objects lying exactly on quadrants boundary. The choice will require you to change some of the strict inequalities above so that they allow for equality.