History of Topics in Special Relativity/Lorentz transformation (hyperbolic)

Lorentz transformation via hyperbolic functions[edit | edit source]

Translation in the hyperbolic plane[edit | edit source]

The case of a Lorentz transformation without spatial rotation is called a w:Lorentz boost. The simplest case can be given, for instance, by setting n=1 in the E:most general Lorentz transformation (1a):

${\displaystyle {\begin{matrix}-x_{0}^{2}+x_{1}^{2}=-x_{0}^{\prime 2}+x_{1}^{\prime 2}\\\hline {\begin{aligned}x_{0}^{\prime }&=x_{0}g_{00}+x_{1}g_{01}\\x_{1}^{\prime }&=x_{0}g_{10}+x_{1}g_{11}\\\\x_{0}&=x_{0}^{\prime }g_{00}-x_{1}^{\prime }g_{10}\\x_{1}&=-x_{0}^{\prime }g_{01}+x_{1}^{\prime }g_{11}\end{aligned}}\left|{\begin{aligned}g_{01}^{2}-g_{00}^{2}&=-1\\g_{11}^{2}-g_{10}^{2}&=1\\g_{01}g_{11}-g_{00}g_{10}&=0\\g_{10}^{2}-g_{00}^{2}&=-1\\g_{11}^{2}-g_{01}^{2}&=1\\g_{10}g_{11}-g_{00}g_{01}&=0\end{aligned}}\rightarrow {\begin{aligned}g_{00}^{2}&=g_{11}^{2}\\g_{01}^{2}&=g_{10}^{2}\end{aligned}}\right.\end{matrix}}}$ or in matrix notation ${\displaystyle \left.{\begin{aligned}\mathbf {x} '&={\begin{bmatrix}g_{00}&g_{01}\\g_{10}&g_{11}\end{bmatrix}}\cdot \mathbf {x} \\\mathbf {x} &={\begin{bmatrix}g_{00}&-g_{10}\\-g_{01}&g_{11}\end{bmatrix}}\cdot \mathbf {x} '\end{aligned}}\quad \right|\quad \det {\begin{bmatrix}g_{00}&g_{01}\\g_{10}&g_{11}\end{bmatrix}}=1}$

(3a)

which resembles precisely the relations of w:hyperbolic functions in terms of w:hyperbolic angle ${\displaystyle \eta }$. Thus a Lorentz boost or w:hyperbolic rotation (being the same as a rotation around an imaginary angle ${\displaystyle i\eta =\phi }$ in E:(2b) or a translation in the hyperbolic plane in terms of the hyperboloid model) is given by

${\displaystyle {\begin{matrix}-x_{0}^{2}+x_{1}^{2}=-x_{0}^{\prime 2}+x_{1}^{\prime 2}\\\hline g_{00}=g_{11}=\cosh \eta ,\ g_{01}=g_{10}=-\sinh \eta \\\hline \left.{\begin{aligned}&\quad \quad (A)&&\quad \quad (B)&&\quad \quad (C)\\x_{0}^{\prime }&=x_{0}\cosh \eta -x_{1}\sinh \eta &&={\frac {x_{0}-x_{1}\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}&&={\frac {x_{0}-x_{1}v}{\sqrt {1-v^{2}}}}\\x_{1}^{\prime }&=-x_{0}\sinh \eta +x_{1}\cosh \eta &&={\frac {x_{1}-x_{0}\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}&&={\frac {x_{1}-x_{0}v}{\sqrt {1-v^{2}}}}\\\\x_{0}&=x_{0}^{\prime }\cosh \eta +x_{1}^{\prime }\sinh \eta &&={\frac {x_{0}^{\prime }+x_{1}^{\prime }\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}&&={\frac {x_{0}^{\prime }+x_{1}^{\prime }v}{\sqrt {1-v^{2}}}}\\x_{1}&=x_{0}^{\prime }\sinh \eta +x_{1}^{\prime }\cosh \eta &&={\frac {x_{1}^{\prime }+x_{0}^{\prime }\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}&&={\frac {x_{1}^{\prime }+x_{0}^{\prime }v}{\sqrt {1-v^{2}}}}\end{aligned}}\right|{\scriptstyle {\begin{aligned}\sinh ^{2}\eta -\cosh ^{2}\eta &=-1&(a)\\\cosh ^{2}\eta -\sinh ^{2}\eta &=1&(b)\\{\frac {\sinh \eta }{\cosh \eta }}&=\tanh \eta =v&(c)\\{\frac {1}{\sqrt {1-\tanh ^{2}\eta }}}&=\cosh \eta &(d)\\{\frac {\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}&=\sinh \eta &(e)\\{\frac {\tanh q\pm \tanh \eta }{1\pm \tanh q\tanh \eta }}&=\tanh \left(q\pm \eta \right)&(f)\end{aligned}}}\end{matrix}}}$ or in matrix notation ${\displaystyle \left.{\begin{aligned}\mathbf {x} '&={\begin{bmatrix}\cosh \eta &-\sinh \eta \\-\sinh \eta &\cosh \eta \end{bmatrix}}\cdot \mathbf {x} \\\mathbf {x} &={\begin{bmatrix}\cosh \eta &\sinh \eta \\\sinh \eta &\cosh \eta \end{bmatrix}}\cdot \mathbf {x} '\end{aligned}}\quad \right|\quad \det {\begin{bmatrix}\cosh \eta &-\sinh \eta \\-\sinh \eta &\cosh \eta \end{bmatrix}}=1}$

(3b)

Hyperbolic identities (a,b) on the right of (3b) were given by Riccati (1757), all identities (a,b,c,d,e,f) by Lambert (1768–1770). Lorentz transformations (3b-A) were given by Laisant (1874), Cox (1882), Goursat (1888), Lindemann (1890/91), Gérard (1892), Killing (1893, 1897/98), Whitehead (1897/98), Woods (1903/05), Elliott (1903) and Liebmann (1904/05) in terms of Weierstrass coordinates of the w:hyperboloid model, while transformations similar to (3b-C) have been used by Lipschitz (1885/86). In special relativity, hyperbolic functions were used by Frank (1909) and Varićak (1910).

Using the idendity ${\displaystyle \cosh \eta +\sinh \eta =e^{\eta }}$, Lorentz boost (3b) assumes a simple form by using w:squeeze mappings in analogy to Euler's formula in E:(2c):^[1]

${\displaystyle {\begin{matrix}-x_{0}^{2}+x_{1}^{2}=-x_{0}^{\prime 2}+x_{1}^{\prime 2}\\\hline {\begin{matrix}{\begin{aligned}u'&=ku\\w'&={\frac {1}{k}}w\end{aligned}}&\Rightarrow &{\begin{aligned}x_{1}^{\prime }-x_{0}^{\prime }&=e^{\eta }\left(x_{1}-x_{0}\right)\\x_{1}^{\prime }+x_{0}^{\prime }&=e^{-\eta }\left(x_{1}+x_{0}\right)\end{aligned}}\quad {\begin{aligned}x_{1}-x_{0}&=e^{-\eta }\left(x_{1}^{\prime }-x_{0}^{\prime }\right)\\x_{1}+x_{0}&=e^{\eta }\left(x_{1}^{\prime }+x_{0}^{\prime }\right)\end{aligned}}\end{matrix}}\\\hline k=e^{\eta }=\cosh \eta +\sinh \eta ={\sqrt {\frac {1+\tanh \eta }{1-\tanh \eta }}}={\sqrt {\frac {1+v}{1-v}}}\end{matrix}}}$

(3c)

Lorentz transformations (3c) for arbitrary k were given by many authors (see E:Lorentz transformations via squeeze mappings), while a form similar to ${\displaystyle k={\sqrt {\tfrac {1+v}{1-v}}}}$ was given by Lipschitz (1885/86), and the exponential form was implicitly used by Mercator (1668) and explicitly by Lindemann (1890/91), Elliott (1903), Herglotz (1909).

Rapidity can be composed of arbitrary many rapidities ${\displaystyle \eta _{1},\eta _{2}\dots }$ as per the w:angle sum laws of hyperbolic sines and cosines, so that one hyperbolic rotation can represent the sum of many other hyperbolic rotations, analogous to the relation between w:angle sum laws of circular trigonometry and spatial rotations. Alternatively, the hyperbolic angle sum laws themselves can be interpreted as Lorentz boosts, as demonstrated by using the parameterization of the w:unit hyperbola:

${\displaystyle {\begin{matrix}-x_{0}^{2}+x_{1}^{2}=-x_{0}^{\prime 2}+x_{1}^{\prime 2}=1\\\hline \left[\eta =\eta _{2}-\eta _{1}\right]\\{\begin{aligned}x_{0}^{\prime }&=\sinh \eta _{1}=\sinh \left(\eta _{2}-\eta \right)=\sinh \eta _{2}\cosh \eta -\cosh \eta _{2}\sinh \eta &&=x_{0}\cosh \eta -x_{1}\sinh \eta \\x_{1}^{\prime }&=\cosh \eta _{1}=\cosh \left(\eta _{2}-\eta \right)=-\sinh \eta _{2}\sinh \eta +\cosh \eta _{2}\cosh \eta &&=-x_{0}\sinh \eta +x_{1}\cosh \eta \\\\x_{0}&=\sinh \eta _{2}=\sinh \left(\eta _{1}+\eta \right)=\sinh \eta _{1}\cosh \eta +\cosh \eta _{1}\sinh \eta &&=x_{0}^{\prime }\cosh \eta +x_{1}^{\prime }\sinh \eta \\x_{1}&=\cosh \eta _{2}=\cosh \left(\eta _{1}+\eta \right)=\sinh \eta _{1}\sinh \eta +\cosh \eta _{1}\cosh \eta &&=x_{0}^{\prime }\sinh \eta +x_{1}^{\prime }\cosh \eta \end{aligned}}\end{matrix}}}$ or in matrix notation ${\displaystyle {\scriptstyle {\begin{aligned}{\begin{bmatrix}x_{1}^{\prime }&x_{0}^{\prime }\\x_{0}^{\prime }&x_{1}^{\prime }\end{bmatrix}}&={\begin{bmatrix}\cosh \eta _{1}&\sinh \eta _{1}\\\sinh \eta _{1}&\cosh \eta _{1}\end{bmatrix}}={\begin{bmatrix}\cosh \left(\eta _{2}-\eta \right)&\sinh \left(\eta _{2}-\eta \right)\\\sinh \left(\eta _{2}-\eta \right)&\cosh \left(\eta _{2}-\eta \right)\end{bmatrix}}={\begin{bmatrix}\cosh \eta _{2}&\sinh \eta _{2}\\\sinh \eta _{2}&\cosh \eta _{2}\end{bmatrix}}\cdot {\begin{bmatrix}\cosh \eta &-\sinh \eta \\-\sinh \eta &\cosh \eta \end{bmatrix}}&&={\begin{bmatrix}x_{1}&x_{0}\\x_{0}&x_{1}\end{bmatrix}}\cdot {\begin{bmatrix}\cosh \eta &-\sinh \eta \\-\sinh \eta &\cosh \eta \end{bmatrix}}\\{\begin{bmatrix}x_{1}&x_{0}\\x_{0}&x_{1}\end{bmatrix}}&={\begin{bmatrix}\cosh \eta _{2}&\sinh \eta _{2}\\\sinh \eta _{2}&\cosh \eta _{2}\end{bmatrix}}={\begin{bmatrix}\cosh \left(\eta _{1}+\eta \right)&\sinh \left(\eta _{1}+\eta \right)\\\sinh \left(\eta _{1}+\eta \right)&\cosh \left(\eta _{1}+\eta \right)\end{bmatrix}}={\begin{bmatrix}\cosh \eta _{1}&\sinh \eta _{1}\\\sinh \eta _{1}&\cosh \eta _{1}\end{bmatrix}}\cdot {\begin{bmatrix}\cosh \eta &\sinh \eta \\\sinh \eta &\cosh \eta \end{bmatrix}}&&={\begin{bmatrix}x_{1}^{\prime }&x_{0}^{\prime }\\x_{0}^{\prime }&x_{1}^{\prime }\end{bmatrix}}\cdot {\begin{bmatrix}\cosh \eta &\sinh \eta \\\sinh \eta &\cosh \eta \end{bmatrix}}\end{aligned}}}}$ or in exponential form as squeeze mapping analogous to (3c): ${\displaystyle {\begin{aligned}e^{-\eta _{1}}&=e^{\eta }e^{-\eta _{2}}=e^{\eta -\eta _{2}}&e^{-\eta _{2}}&=e^{-\eta }e^{-\eta _{1}}=e^{-\eta _{1}-\eta }\\e^{\eta _{1}}&=e^{-\eta }e^{\eta _{2}}=e^{\eta _{2}-\eta }&e^{\eta _{2}}&=e^{\eta }e^{\eta _{1}}=e^{\eta _{1}+\eta }\end{aligned}}}$

(3d)

Hyperbolic angle sum laws were given by Riccati (1757) and Lambert (1768–1770) and many others, while matrix representations were given by Glaisher (1878) and Günther (1880/81).

Hyperbolic law of cosines[edit | edit source]

By adding coordinates ${\displaystyle x_{2}^{\prime }=x_{2}}$ and ${\displaystyle x_{3}^{\prime }=x_{3}}$ in Lorentz transformation (3b) and interpreting ${\displaystyle x_{0},x_{1},x_{2},x_{3}}$ as w:homogeneous coordinates, the Lorentz transformation can be rewritten in line with equation E:(1b) by using coordinates ${\displaystyle [u_{1},\ u_{2},\ u_{3}]=\left[{\tfrac {x_{1}}{x_{0}}},\ {\tfrac {x_{2}}{x_{0}}},\ {\tfrac {x_{3}}{x_{0}}}\right]}$ defined by ${\displaystyle u_{1}^{2}+u_{2}^{2}+u_{3}^{2}\leq 1}$ inside the w:unit sphere as follows:

${\displaystyle {\begin{aligned}&\quad \quad (A)&&\quad \quad (B)&&\quad \quad (C)\\\hline \\u_{1}^{\prime }&={\frac {-\sinh \eta +u_{1}\cosh \eta }{\cosh \eta -u_{1}\sinh \eta }}&&={\frac {u_{1}-\tanh \eta }{1-u_{1}\tanh \eta }}&&={\frac {u_{1}-v}{1-u_{1}v}}\\u_{2}^{\prime }&={\frac {u_{2}}{\cosh \eta -u_{1}\sinh \eta }}&&={\frac {u_{2}{\sqrt {1-\tanh ^{2}\eta }}}{1-u_{1}\tanh \eta }}&&={\frac {u_{2}{\sqrt {1-v^{2}}}}{1-u_{1}v}}\\u_{3}^{\prime }&={\frac {u_{3}}{\cosh \eta -u_{1}\sinh \eta }}&&={\frac {u_{3}{\sqrt {1-\tanh ^{2}\eta }}}{1-u_{1}\tanh \eta }}&&={\frac {u_{3}{\sqrt {1-v^{2}}}}{1-u_{1}v}}\\\\\hline \\u_{1}&={\frac {\sinh \eta +u_{1}^{\prime }\cosh \eta }{\cosh \eta +u_{1}^{\prime }\sinh \eta }}&&={\frac {u_{1}^{\prime }+\tanh \eta }{1+u_{1}^{\prime }\tanh \eta }}&&={\frac {u_{1}^{\prime }+v}{1+u_{1}^{\prime }v}}\\u_{2}&={\frac {u_{2}^{\prime }}{\cosh \eta +u_{1}^{\prime }\sinh \eta }}&&={\frac {u_{2}^{\prime }{\sqrt {1-\tanh ^{2}\eta }}}{1+u_{1}^{\prime }\tanh \eta }}&&={\frac {u_{2}^{\prime }{\sqrt {1-v^{2}}}}{1+u_{1}^{\prime }v}}\\u_{3}&={\frac {u_{3}^{\prime }}{\cosh \eta +u_{1}^{\prime }\sinh \eta }}&&={\frac {u_{3}^{\prime }{\sqrt {1-\tanh ^{2}\eta }}}{1+u_{1}^{\prime }\tanh \eta }}&&={\frac {u_{3}^{\prime }{\sqrt {1-v^{2}}}}{1+u_{1}^{\prime }v}}\end{aligned}}}$

(3e)

Transformations (A) were given by Escherich (1874), Goursat (1888), Killing (1898), and transformations (C) by Beltrami (1868), Schur (1885/86, 1900/02) in terms of Beltrami coordinates^[2] of hyperbolic geometry. This transformation becomes equivalent to the w:hyperbolic law of cosines by restriction to coordinates of the ${\displaystyle \left[u_{1},u_{2}\right]}$-plane and ${\displaystyle \left[u'_{1},u'_{2}\right]}$-plane and defining their scalar products in terms of trigonometric and hyperbolic identities:^{[3][R 1][4]}

${\displaystyle {\begin{matrix}&{\begin{matrix}u^{2}=u_{1}^{2}+u_{2}^{2}\\u'^{2}=u_{1}^{\prime 2}+u_{2}^{\prime 2}\end{matrix}}\left|{\begin{aligned}u_{1}=u\cos \alpha &={\frac {u'\cos \alpha '+v}{1+vu'\cos \alpha '}},&u_{1}^{\prime }=u'\cos \alpha '&={\frac {u\cos \alpha -v}{1-vu\cos \alpha }}\\u_{2}=u\sin \alpha &={\frac {u'\sin \alpha '{\sqrt {1-v^{2}}}}{1+vu'\cos \alpha '}},&u_{2}^{\prime }=u'\sin \alpha '&={\frac {u\sin \alpha {\sqrt {1-v^{2}}}}{1-vu\cos \alpha }}\\{\frac {u_{2}}{u_{1}}}=\tan \alpha &={\frac {u'\sin \alpha '{\sqrt {1-v^{2}}}}{u'\cos \alpha '+v}},&{\frac {u_{2}^{\prime }}{u_{1}^{\prime }}}=\tan \alpha '&={\frac {u\sin \alpha {\sqrt {1-v^{2}}}}{u\cos \alpha -v}}\end{aligned}}\right.\\\\\Rightarrow &u={\frac {\sqrt {v^{2}+u^{\prime 2}+2vu'\cos \alpha '-\left(vu'\sin \alpha '\right){}^{2}}}{1+vu'\cos \alpha '}},\quad u'={\frac {\sqrt {-v^{2}-u^{2}+2vu\cos \alpha +\left(vu\sin \alpha \right){}^{2}}}{1-vu\cos \alpha }}\\\Rightarrow &{\frac {1}{\sqrt {1-u^{\prime 2}}}}={\frac {1}{\sqrt {1-v^{2}}}}{\frac {1}{\sqrt {1-u^{2}}}}-{\frac {v}{\sqrt {1-v^{2}}}}{\frac {u}{\sqrt {1-u^{2}}}}\cos \alpha &(B)\\\Rightarrow &{\frac {1}{\sqrt {1-\tanh ^{2}\xi }}}={\frac {1}{\sqrt {1-\tanh ^{2}\eta }}}{\frac {1}{\sqrt {1-\tanh ^{2}\zeta }}}-{\frac {\tanh \eta }{\sqrt {1-\tanh ^{2}\eta }}}{\frac {\tanh \zeta }{\sqrt {1-\tanh ^{2}\zeta }}}\cos \alpha \\\Rightarrow &\cosh \xi =\cosh \eta \cosh \zeta -\sinh \eta \sinh \zeta \cos \alpha &(A)\end{matrix}}}$

(3f)

The hyperbolic law of cosines (A) was given by Taurinus (1826) and Lobachevsky (1829/30) and others, while variant (B) was given by Schur (1900/02). By further setting ${\displaystyle \tanh \xi =\tanh \zeta =1}$ or ${\displaystyle u'=u=1}$ it follows:

${\displaystyle {\begin{matrix}(A)&\ \cos \alpha ={\frac {\cos \alpha '+\tanh \eta }{1+\tanh \eta \cos \alpha '}};&\ \sin \alpha ={\frac {\sin \alpha '{\sqrt {1-\tanh ^{2}\eta }}}{1+\tanh \eta \cos \alpha '}};&\ \tan \alpha ={\frac {\sin \alpha '{\sqrt {1-\tanh ^{2}\eta }}}{\cos \alpha '+\tanh \eta }};&\ \tan {\frac {\alpha }{2}}={\sqrt {\frac {1-\tanh \eta }{1+\tanh \eta }}}\tan {\frac {\alpha '}{2}}\\&\ \cos \alpha '={\frac {\cos \alpha -\tanh \eta }{1-\tanh \eta \cos \alpha }};&\ \sin \alpha '={\frac {\sin \alpha {\sqrt {1-\tanh ^{2}\eta }}}{1-\tanh \eta \cos \alpha }};&\ \tan \alpha '={\frac {\sin \alpha {\sqrt {1-\tanh ^{2}\eta }}}{\cos \alpha -\tanh \eta }};&\ \tan {\frac {\alpha '}{2}}={\sqrt {\frac {1+\tanh \eta }{1-\tanh \eta }}}\tan {\frac {\alpha }{2}}\\\\(B)&\ \cos \alpha ={\frac {\cos \alpha '+v}{1+v\cos \alpha '}};&\ \sin \alpha ={\frac {\sin \alpha '{\sqrt {1-v^{2}}}}{1+v\cos \alpha '}};&\ \tan \alpha ={\frac {\sin \alpha '{\sqrt {1-v^{2}}}}{\cos \alpha '+v}};&\ \tan {\frac {\alpha }{2}}={\sqrt {\frac {1-v}{1+v}}}\tan {\frac {\alpha '}{2}}\\&\ \cos \alpha '={\frac {\cos \alpha -v}{1-v\cos \alpha }};&\ \sin \alpha '={\frac {\sin \alpha {\sqrt {1-v^{2}}}}{1-v\cos \alpha }};&\ \tan \alpha '={\frac {\sin \alpha {\sqrt {1-v^{2}}}}{\cos \alpha -v}};&\ \tan {\frac {\alpha '}{2}}={\sqrt {\frac {1+v}{1-v}}}\tan {\frac {\alpha }{2}}\end{matrix}}}$

(3g)

Formulas (3g-B) are the equations of an w:ellipse of eccentricity v, w:eccentric anomaly α' and w:true anomaly α, first geometrically formulated by Kepler (1609) and explicitly written down by Euler (1735, 1748), Lagrange (1770) and many others in relation to planetary motions. They were also used by E:Darboux (1873) as a sphere transformation. In special relativity these formulas describe the aberration of light, see E:velocity addition and aberration.

Historical notation[edit | edit source]

Mercator (1668) – hyperbolic relations[edit | edit source]

While deriving the w:Mercator series, w:Nicholas Mercator (1668) demonstrated the following relations on a rectangular hyperbola:^{[M 1]}

${\displaystyle {\begin{matrix}AD=1+a,\ DF={\sqrt {2a+aa}}\\AH={\frac {1+a+{\sqrt {2a+aa}}}{\sqrt {2}}},\ FH={\frac {1+a-{\sqrt {2a+aa}}}{\sqrt {2}}}\\AI=BI={\frac {1}{\sqrt {2}}}\\1+a=c,\ {\sqrt {2a+aa}}=d,\ 1=cc-dd\\AH*FH={\frac {cc-dd}{{\sqrt {2}}*{\sqrt {2}}}}={\frac {1}{2}}\\AI*BI={\frac {1}{2}}\\\hline AH*FH=AI*BI\\AH.AI::BI.FH\end{matrix}}}$

It can be seen that Mercator's relations ${\displaystyle 1+a=c}$, ${\displaystyle {\sqrt {2a+a^{2}}}=d}$ with ${\displaystyle c^{2}-d^{2}=1}$ implicitly correspond to hyperbolic functions ${\displaystyle c=\cosh \eta }$, ${\displaystyle d=\sinh \eta }$ with ${\displaystyle \cosh ^{2}\eta -\sinh ^{2}\eta =1}$ (which were explicitly introduced by Riccati (1757) much later). In particular, his result AH.AI::BI.FH, denoting that the ratio between AH and AI is equal to the ratio between BI and FH or ${\displaystyle {\tfrac {AH}{AI}}={\tfrac {BI}{FH}}}$ in modern notation, corresponds to squeeze mapping or Lorentz boost (3c) because:

${\displaystyle {\frac {AH}{AI}}={\frac {BI}{FH}}=1+a+{\sqrt {2a+a^{2}}}=c+d=\cosh \eta +\sinh \eta =e^{\eta }}$

or solved for AH and FH:

${\displaystyle AH=e^{\eta }AI}$ and ${\displaystyle FH=e^{-\eta }BI}$.

Furthermore, transforming Mercator's asymptotic coordinates ${\displaystyle AH={\tfrac {c+d}{\sqrt {2}}}}$, ${\displaystyle FH={\tfrac {c-d}{\sqrt {2}}}}$ into Cartesian coordinates ${\displaystyle x_{0},x_{1}}$ gives:

${\displaystyle x_{1}={\tfrac {AH+FH}{\sqrt {2}}}=c=\cosh \eta ,\quad x_{0}={\tfrac {AH-FH}{\sqrt {2}}}=d=\sinh \eta }$

which produces the unit hyperbola ${\displaystyle -x_{0}^{2}+x_{1}^{2}=1}$ as in (3d), in agreement with Mercator's result AH·FH=1/2 when the hyperbola is referred to its asymptotes.

Euler (1735) – True and eccentric anomaly[edit | edit source]

w:Johannes Kepler (1609) geometrically formulated w:Kepler's equation and the relations between the w:mean anomaly, w:true anomaly, and w:eccentric anomaly.^{[M 2][5]} The relation between the true anomaly z and the eccentric anomaly P was algebraically expressed by w:Leonhard Euler (1735/40) as follows:^{[M 3]}

${\displaystyle \cos z={\frac {\cos P+v}{1+v\cos P}},\ \cos P={\frac {\cos z-v}{1-v\cos z}},\ \int P={\frac {\int z{\sqrt {1-v^{2}}}}{1-v\cos z}}}$

and in 1748:^{[M 4]}

${\displaystyle \cos z={\frac {n+\cos y}{1+n\cos y}},\ \sin z={\frac {\sin y{\sqrt {1-n^{2}}}}{1+n\cos y}},\ \tan z={\frac {\sin y{\sqrt {1-n^{2}}}}{n+\cos y}}}$

while w:Joseph-Louis Lagrange (1770/71) expressed them as follows^{[M 5]}

${\displaystyle \sin u={\frac {m\sin x}{1+n\cos x}},\ \cos u={\frac {n+\cos x}{1+n\cos x}},\ \operatorname {tang} {\frac {1}{2}}u={\frac {m}{1+n}}\operatorname {tang} {\frac {1}{2}}x,\ \left(m^{2}=1-n^{2}\right)}$

These relations resemble formulas (3g), while (3e) follows by setting ${\displaystyle [\cos z,\sin z,\cos y,\sin y]=\left[u_{1},u_{2},u'_{1},u'_{2}\right]}$ in Euler's formulas or ${\displaystyle [\cos u,\sin u,\cos x,\sin x]=\left[u_{1},u_{2},u'_{1},u'_{2}\right]}$ in Lagrange's formulas.

Riccati (1757) – hyperbolic addition[edit | edit source]

w:Vincenzo Riccati (1757) introduced hyperbolic functions cosh and sinh, which he denoted as Ch. and Sh. related by ${\displaystyle Ch.^{2}-Sh.^{2}=r^{2}}$ with r being set to unity in modern publications, and formulated the addition laws of hyperbolic sine and cosine:^{[M 6][M 7]}

${\displaystyle {\begin{matrix}CA=r,\ CB=Ch.\varphi ,\ BE=Sh.\varphi ,\ CD=Ch.\pi ,\ DF=Sh.\pi \\CM=Ch.{\overline {\varphi +\pi }},\ MN=Sh.{\overline {\varphi +\pi }}\\CK={\frac {r}{\sqrt {2}}},\ CG={\frac {Ch.\varphi +Sh.\varphi }{\sqrt {2}}},\ CH={\frac {Ch.\pi +Sh.\pi }{\sqrt {2}}},\ CP={\frac {Ch.{\overline {\varphi +\pi }}+Sh.{\overline {\varphi +\pi }}}{\sqrt {2}}}\\CK:CG::CH:CP\\\left[Ch.^{2}-Sh.^{2}=rr\right]\\\hline Ch.{\overline {\varphi +\pi }}={\frac {Ch.\varphi \,Ch.\pi +Sh.\varphi \,Sh.\pi }{r}}\\Sh.{\overline {\varphi +\pi }}={\frac {Ch.\varphi \,Sh.\pi +Ch.\pi \,Sh.\varphi }{r}}\end{matrix}}}$

He furthermore showed that ${\displaystyle Ch.{\overline {\varphi -\pi }}}$ and ${\displaystyle Sh.{\overline {\varphi -\pi }}}$ follow by setting ${\displaystyle Ch.\pi \Rightarrow Ch.-\pi }$ and ${\displaystyle Sh.\pi \Rightarrow Sh.-\pi }$ in the above formulas.

The angle sum laws for hyperbolic sine and cosine can be interpreted as hyperbolic rotations of points on a hyperbola, as in Lorentz boost (3d) with ${\displaystyle \pi =\eta ,\ \varphi =\eta _{1},\ {\overline {\varphi +\pi }}=\eta _{2}}$.

Lambert (1768–1770) – hyperbolic addition[edit | edit source]

While Riccati (1757) discussed the hyperbolic sine and cosine, w:Johann Heinrich Lambert (read 1767, published 1768) introduced the expression tang φ or abbreviated tφ as the w:tangens hyperbolicus ${\displaystyle {\scriptstyle {\frac {e^{u}-e^{-u}}{e^{u}+e^{-u}}}}}$ of a variable u, or in modern notation tφ=tanh(u):^{[M 8][6]}

${\displaystyle \left.{\begin{aligned}\xi \xi -1&=\eta \eta &(a)\\1+\eta \eta &=\xi \xi &(b)\\{\frac {\eta }{\xi }}&=tang\ \phi =t\phi &(c)\\\xi &={\frac {1}{\sqrt {1-t\phi ^{2}}}}&(d)\\\eta &={\frac {t\phi }{\sqrt {1-t\phi ^{2}}}}&(e)\\t\phi ''&={\frac {t\phi +t\phi '}{1+t\phi \cdot t\phi '}}&(f)\\t\phi '&={\frac {t\phi ''-t\phi }{1-t\phi \cdot t\phi ''}}&(g)\end{aligned}}\right|{\begin{aligned}2u&=\log {\frac {1+t\phi }{1-t\phi }}\\\xi &={\frac {e^{u}+e^{-u}}{2}}\\\eta &={\frac {e^{u}-e^{-u}}{2}}\\t\phi &={\frac {e^{u}-e^{-u}}{e^{u}+e^{-u}}}\\e^{u}&=\xi +\eta \\e^{-u}&=\xi -\eta \end{aligned}}}$

In (1770) he rewrote the addition law for the hyperbolic tangens (f) or (g) as:^{[M 9]}

${\displaystyle {\begin{aligned}t(y+z)&=(ty+tz):(1+ty\cdot tz)&(f)\\t(y-z)&=(ty-tz):(1-ty\cdot tz)&(g)\end{aligned}}}$

Lambert also formulated the addition laws for the hyperbolic cosine and sine (Lambert's "cos" and "sin" actually mean "cosh" and "sinh"):

${\displaystyle {\begin{aligned}\sin(y+z)&=\sin y\cos z+\cos y\sin z\\\sin(y-z)&=\sin y\cos z-\cos y\sin z\\\cos(y+z)&=\cos y\cos z+\sin y\sin z\\\cos(y-z)&=\cos y\cos z-\sin y\sin z\end{aligned}}}$

Taurinus (1826) – Hyperbolic law of cosines[edit | edit source]

After the addition theorem for the tangens hyperbolicus was given by Lambert (1768), w:hyperbolic geometry was used by w:Franz Taurinus (1826), and later by w:Nikolai Lobachevsky (1829/30) and others, to formulate the w:hyperbolic law of cosines:^{[M 10][7][8]}

${\displaystyle A=\operatorname {arccos} {\frac {\cos \left(\alpha {\sqrt {-1}}\right)-\cos \left(\beta {\sqrt {-1}}\right)\cos \left(\gamma {\sqrt {-1}}\right)}{\sin \left(\beta {\sqrt {-1}}\right)\sin \left(\gamma {\sqrt {-1}}\right)}}}$

When solved for ${\displaystyle \cos \left(\alpha {\sqrt {-1}}\right)}$ it corresponds to the Lorentz transformation in Beltrami coordinates (3f), and by defining the rapidities ${\displaystyle {\scriptstyle \left(\left[{\frac {U}{c}},\ {\frac {v}{c}},\ {\frac {u}{c}}\right]=\left[\tanh \alpha ,\ \tanh \beta ,\ \tanh \gamma \right]\right)}}$ it corresponds to the relativistic velocity addition formula E:(4e).

Beltrami (1868) – Beltrami coordinates[edit | edit source]

w:Eugenio Beltrami (1868a) introduced coordinates of the w:Beltrami–Klein model of hyperbolic geometry, and formulated the corresponding transformations in terms of homographies:^{[M 11]}

${\displaystyle {\begin{matrix}ds^{2}=R^{2}{\frac {\left(a^{2}+v^{2}\right)du^{2}-2uv\,du\,dv+\left(a^{2}+v^{2}\right)dv^{2}}{\left(a^{2}+u^{2}+v^{2}\right)^{2}}}\\u^{2}+v^{2}=a^{2}\\\hline u''={\frac {aa_{0}\left(u'-r_{0}\right)}{a^{2}-r_{0}u'}},\ v''={\frac {a_{0}w_{0}v'}{a^{2}-r_{0}u'}},\\\left(r_{0}={\sqrt {u_{0}^{2}+v_{0}^{2}}},\ w_{0}={\sqrt {a^{2}-r_{0}^{2}}}\right)\\\hline ds^{2}=R^{2}{\frac {\left(a^{2}-v^{2}\right)du^{2}+2uv\,du\,dv+\left(a^{2}-v^{2}\right)dv^{2}}{\left(a^{2}-u^{2}-v^{2}\right)^{2}}}\\(R=R{\sqrt {-1}},\ a=a{\sqrt {-1}})\end{matrix}}}$

(where the disk radius a and the w:radius of curvature R are real in spherical geometry, in hyperbolic geometry they are imaginary), and for arbitrary dimensions in (1868b)^{[M 12]}

${\displaystyle {\begin{matrix}ds=R{\frac {\sqrt {dx^{2}+dx_{1}^{2}+dx_{2}^{2}+\cdots +dx_{n}^{2}}}{x}}\\x^{2}+x_{1}^{2}+x_{2}^{2}+\cdots +x_{n}^{2}=a^{2}\\\hline y_{1}={\frac {ab\left(x_{1}-a_{1}\right)}{a^{2}-a_{1}x_{1}}}\ {\text{or}}\ x_{1}={\frac {a\left(ay_{1}+a_{1}b\right)}{ab+a_{1}y_{1}}},\ x_{r}=\pm {\frac {ay_{r}{\sqrt {a^{2}-a_{1}^{2}}}}{ab+a_{1}y_{1}}}\ (r=2,3,\dots ,n)\\\hline ds=R{\frac {\sqrt {dx_{1}^{2}+dx_{2}^{2}+\cdots +dx_{n}^{2}-dx^{2}}}{x}}\\x^{2}=a^{2}+x_{1}^{2}+x_{2}^{2}+\cdots +x_{n}^{2}\\\left(R=R{\sqrt {-1}},\ x=x{\sqrt {-1}},\ a=a{\sqrt {-1}}\right)\end{matrix}}}$

Laisant (1874) – Equipollences[edit | edit source]

In his French translation of w:Giusto Bellavitis' principal work on w:equipollences, w:Charles-Ange Laisant (1874) added a chapter related to hyperbolas. The equipollence OM and its tangent MT of a hyperbola is defined by Laisant as^{[M 13]}

(1) ${\displaystyle {\begin{matrix}&\mathrm {OM} \bumpeq x\mathrm {OA} +y\mathrm {OB} \\&\mathrm {MT} \bumpeq y\mathrm {OA} +x\mathrm {OB} \\&\left[x^{2}-y^{2}=1;\ x=\cosh t,\ y=\sinh t\right]\\\Rightarrow &\mathrm {OM} \bumpeq \cosh t\cdot \mathrm {OA} +\sinh t\cdot \mathrm {OB} \end{matrix}}}$

Here, OA and OB are conjugate semi-diameters of a hyperbola with OB being imaginary, both of which he related to two other conjugated semi-diameters OC and OD by the following transformation:

${\displaystyle {\begin{matrix}{\begin{aligned}\mathrm {OC} &\bumpeq c\mathrm {OA} +d\mathrm {OB} &\qquad &&\mathrm {OA} &\bumpeq c\mathrm {OC} -d\mathrm {OD} \\\mathrm {OD} &\bumpeq d\mathrm {OA} +c\mathrm {OB} &&&\mathrm {OB} &\bumpeq -d\mathrm {OC} +c\mathrm {OD} \end{aligned}}\\\left[c^{2}-d^{2}=1\right]\end{matrix}}}$

producing the invariant relation

${\displaystyle (\mathrm {OC} )^{2}-(\mathrm {OD} )^{2}\bumpeq (\mathrm {OA} )^{2}-(\mathrm {OB} )^{2}}$.