y=arsinhxy = \operatorname{arsinh} x

Inverse Hyperbolic Sine y=arsinhxy = \operatorname{arsinh} x

arsinhx\operatorname{arsinh} x (the inverse hyperbolic sine, or area hyperbolic sine) is the inverse of the hyperbolic sine sinhx=exex2\sinh x = \dfrac{e^x - e^{-x}}{2}. Because sinh\sinh is strictly increasing over all real numbers, its inverse is uniquely defined without any restriction.

Definition and closed form

y=arsinhxy = \operatorname{arsinh} x is defined as the value yy satisfying x=sinhyx = \sinh y. Solving with exponentials gives the closed logarithmic form

arsinhx=ln ⁣(x+x2+1)\operatorname{arsinh} x = \ln\!\left(x + \sqrt{x^2 + 1}\right)

The quantity x2+1x^2 + 1 under the square root is always positive, so this expression is valid for every real xx.

Domain and range

The domain is all real numbers (,)(-\infty, \infty), and the range is also all real numbers (,)(-\infty, \infty), since sinh\sinh maps the whole real line one-to-one onto itself.

Symmetry and monotonicity

arsinh\operatorname{arsinh} is an odd function: arsinh(x)=arsinhx\operatorname{arsinh}(-x) = -\operatorname{arsinh} x, so its graph is symmetric about the origin. Its derivative

ddxarsinhx=1x2+1\frac{d}{dx}\operatorname{arsinh} x = \frac{1}{\sqrt{x^2 + 1}}

is always positive, so the function is strictly increasing everywhere.

Limits and growth rate

Near the origin arsinhxx\operatorname{arsinh} x \approx x, so the curve is tangent to the line y=xy = x. For large xx, since x2+1x\sqrt{x^2 + 1} \approx x, we have arsinhxln(2x)\operatorname{arsinh} x \approx \ln(2x), meaning it grows logarithmically and very slowly. It has no vertical or horizontal asymptote.

Notable points

The graph passes through the origin (0,0)(0, 0). For example, arsinh1=ln(1+2)0.8814\operatorname{arsinh} 1 = \ln(1 + \sqrt{2}) \approx 0.8814.

Relations and applications

It belongs to the family of inverse hyperbolic functions alongside arcosh\operatorname{arcosh} and artanh\operatorname{artanh}. It arises as the value of the integral dxx2+1\displaystyle\int \frac{dx}{\sqrt{x^2 + 1}}, appearing in arc-length calculations for the catenary and in computations in special relativity and geodesics.