* Problem*: Draw the region of points \({\displaystyle{(x,y)}}\) in the plane, which satisfy \({\displaystyle{|y| {\le} |x| {\le} 1}}\).

* Solution*: \({\displaystyle{|y| {\le} |x| {\le} 1}}\) region will bounded by lines \({\displaystyle{x = y}}\), \({\displaystyle{x = -y}}\), \({\displaystyle{x = -1}}\) & \({\displaystyle{x = 1}}\). Why is that?

First note that \( |x| \le 1 \) implies:

Similarly, if we demand \( |y| \le 1 \) (the double shaded zone).

Now if we want \( |y| \le |x| \) . This can be achieved by

- \( y \le x \) when x and y are both positive (in the first quadrant); that is the region below the line x = y
- \( y \le -x\) when x is negative and y positive (in the second quadrant); hence the region below the line y = -x
- \(-y \le -x \) when (x, y) is in the third quadrant.
- \( -y \le x \) when (x, y) is in fourth quadrant.

Therefore the final region is the following shaded region: