**\(\mathbf{ A= {(x, y), x^2 + y^2 \le 144 , \sin(2x+3y) le 0 } } \) . Find the area of A.**

**Discussion:**

\(\mathbf{ x^2 + y^2 \le 144 }\) is a disc of radius 12 with center (0, 0).

Now notice that \(\mathbf{ \sin(2x + 3y) \le 0 \implies \sin ( 2(-x) + 3(-y) ) = \sin(-(2x+3y)) = -\sin(2x+3y) \ge 0 }\)

Hence if a point (x, y) is in A then (-x, -y) is not in A.

Similarly if there is a point (x, y) not in A then we get a corresponding point (-x, -y) in A.

Therefore we have a bijection between points in A and not in A.

Thus area of A is exactly half the area of the disc = \(\mathbf{ \frac{\pi (12)^2 }{2} = 72 \pi }\)

This can in fact be generalised to any odd function f(x). f(ax+by) divides the area of the disc in half if f is odd.