y=xy = \sqrt{|x|}

Graph of the Function y=xy = \sqrt{|x|}

y=xy = \sqrt{|x|} is the square root of the absolute value of xx. Since x|x| is always non-negative, the radicand is never negative, so the domain is all real numbers and the range is y0y \geq 0. It splits into y=xy = \sqrt{x} for x0x \geq 0 and y=xy = \sqrt{-x} for x<0x < 0.

Because x=x|-x| = |x|, we have x=x\sqrt{|-x|} = \sqrt{|x|}, so it is an even function, symmetric about the yy-axis. Its right half is exactly x\sqrt{x}, reflected across the yy-axis and spread to the left.

For x>0x > 0, y=12xy' = \dfrac{1}{2\sqrt{x}}; for x<0x < 0, y=12xy' = -\dfrac{1}{2\sqrt{-x}}. As x0+x \to 0^{+}, y+y' \to +\infty, and as x0x \to 0^{-}, yy' \to -\infty, so both tangents at the origin stand vertical. The origin is therefore a sharp cusp where the function is not differentiable.

It decreases for x<0x < 0 and increases for x>0x > 0, with minimum value 00 at the origin (0,0)(0, 0). Overall it resembles a bird spreading its wings, both sides rising gently. Concretely, y=1y = 1 at x=±1x = \pm 1, y=2y = 2 at x=±4x = \pm 4, and y=3y = 3 at x=±9x = \pm 9: each time x|x| quadruples, yy doubles.

It resembles y=x2/3y = x^{2/3}, which also has a cusp at the origin, but near the origin x\sqrt{|x|} approaches 00 more slowly. For instance, at x=0.01x = 0.01, x=0.1\sqrt{|x|} = 0.1 whereas x2/30.046x^{2/3} \approx 0.046.

As a basic composition of the square root and the absolute value, it is a favorite example for studying how to make a function even and how singular behavior (a cusp) arises at the origin. It also appears when handling quantities related to distance or spread.