Areatangens hyperbolicus and areakotangens hyperbolicus

Areatangens hyperbolicus and areakotangens hyperbolicus are the inverse functions of the tangent hyperbolicus and cotangent hyperbolicus and thus area functions .

Spellings:

${\ displaystyle y = \ operatorname {artanh} (x) = \ tanh ^ {- 1} (x)}$

${\ displaystyle y = \ operatorname {arcoth} (x) = \ coth ^ {- 1} (x)}$

The latter is used less often to avoid confusion with the reciprocal of the hyperbolic (co-) tangent. It is . ${\ displaystyle \ operatorname {artanh} (x) = \ tanh ^ {- 1} (x) \ not = \ tanh (x) ^ {- 1} = {\ tfrac {1} {\ tanh (x)}} }$

Definitions

Hyperbolic areatangens:

${\ displaystyle \ operatorname {artanh} (x): = {\ frac {1} {2}} \ ln \ left ({\ frac {1 + x} {1-x}} \ right) \ quad \ mathrm { f {\ ddot {u}} r} \ quad | x | <1}$

Hyperbolic areakotangent:

${\ displaystyle \ operatorname {arcoth} (x): = {\ frac {1} {2}} \ ln \ left ({\ frac {x + 1} {x-1}} \ right) \ quad \ mathrm { f {\ ddot {u}} r} \ quad | x |> 1}$

Geometric definitions

Geometric can be the Area hyperbolic tangent represented by the area in the plane containing the connection line between the coordinate origin and the hyperbola sweeps: Let and start and end point on the hyperbola, the surface of the link overlined. ${\ displaystyle (x, y) = (0,0)}$${\ displaystyle x ^ {2} -y ^ {2} = 1}$${\ displaystyle (x, -y) = \ left (x, - {\ sqrt {x ^ {2} -1}} \ right)}$${\ displaystyle (x, y) = \ left (x, + {\ sqrt {x ^ {2} -1}} \ right)}$${\ displaystyle A = \ operatorname {artanh} \ left ({\ frac {y} {x}} \ right)}$

properties

Graph of the function artanh (x)

Graph of the function arcoth (x)

	Hyperbolic areatangens	Hyperbolic areakotangent
Domain of definition	${\ displaystyle -1 <x <1}$	${\ displaystyle - \ infty <x <-1}$ ${\ displaystyle 1 <x <\ infty}$
Range of values	${\ displaystyle - \ infty <f (x) <\ infty}$	${\ displaystyle - \ infty <f (x) <\ infty; \; f (x) \ neq 0}$
periodicity	no	no
monotony	strictly monotonously increasing	no
Symmetries	odd function: ${\ displaystyle f (-x) = - f (x)}$	odd function: ${\ displaystyle f (-x) = - f (x)}$
Asymptotes	${\ displaystyle x = 1 \ colon \, f (x) \ to \ infty {\ text {for}} x \ to 1}$ ${\ displaystyle x = -1 \ colon \, f (x) \ to - \ infty {\ text {for}} x \ to -1}$	${\ displaystyle y = 0 \ colon \, f (x) \ to 0 {\ text {for}} x \ to \ pm \ infty}$
zeropoint	${\ displaystyle x = 0}$	no
Jump points	no	no
Poles	${\ displaystyle x = \ pm 1}$	${\ displaystyle x = \ pm 1}$
Extremes	no	no
Turning points	${\ displaystyle x = 0}$	no

Series developments

Taylor and Laurent series of the two functions are

${\ displaystyle {\ begin {alignedat} {2} \ operatorname {artanh} (x) & = \ sum _ {k = 0} ^ {\ infty} {\ frac {x ^ {2k + 1}} {2k + 1}} & = x + {\ frac {1} {3}} x ^ {3} + {\ frac {1} {5}} x ^ {5} + {\ frac {1} {7}} x ^ {7} + \ ldots & {} \\\ operatorname {arcoth} (x) & = \ sum _ {k = 1} ^ {\ infty} {\ frac {x ^ {- (2k-1)}} { 2k-1}} & = x ^ {- 1} + {\ frac {1} {3}} x ^ {- 3} + {\ frac {1} {5}} x ^ {- 5} + {\ frac {1} {7}} x ^ {- 7} + \ ldots & {} \\ & = \ sum _ {k = 0} ^ {\ infty} {\ frac {1} {(2k + 1) \ cdot x ^ {2k + 1}}} & = {\ frac {1} {x}} + {\ frac {1} {3x ^ {3}}} + {\ frac {1} {5x ^ {5} }} + {\ frac {1} {7x ^ {7}}} + \ ldots & {} \ end {alignedat}}}$

Derivatives

${\ displaystyle {\ frac {\ mathrm {d}} {\ mathrm {d} x}} \ operatorname {artanh} (x) = {\ frac {1} {1-x ^ {2}}} \ ,; \ quad | x | <1}$

${\ displaystyle {\ frac {\ mathrm {d}} {\ mathrm {d} x}} \ operatorname {arcoth} (x) = {\ frac {1} {1-x ^ {2}}} \ ,; \ quad | x |> 1}$

Integrals

The antiderivatives are:

${\ displaystyle \ int \ operatorname {artanh} (x) \, \ mathrm {d} x = x \ cdot \ operatorname {artanh} (x) + {\ frac {1} {2}} \ ln \ left (1 -x ^ {2} \ right) + C}$

${\ displaystyle \ int \ operatorname {arcoth} (x) \, \ mathrm {d} x = x \ cdot \ operatorname {arcoth} (x) + {\ frac {1} {2}} \ ln \ left (x ^ {2} -1 \ right) + C}$

Addition theorems

${\ displaystyle \ operatorname {artanh} (x) \ pm \ operatorname {artanh} (y) = \ operatorname {artanh} \ left ({\ frac {x \ pm y} {1 \ pm xy}} \ \ right) }$

${\ displaystyle \ operatorname {arcoth} (x) \ pm \ operatorname {arcoth} (y) = \ operatorname {arcoth} \ left ({\ frac {1 \ pm xy} {x \ pm y}} \ \ right) }$

See also

• Trigonometric functions
• Circle and hyperbolic functions

Web links

• Eric W. Weisstein : Inverse Hyperbolic Tangent and Inverse Hyperbolic Cotangent on MathWorld