lines 6-88 of file: xrst/theory/sin_cos_reverse.xrst {xrst_begin sin_cos_reverse} Trigonometric and Hyperbolic Sine and Cosine Reverse Theory ########################################################### We use the reverse theory :ref:`standard math function` definition for the functions :math:`H` and :math:`G`. In addition, we use the following definitions for :math:`s` and :math:`c` and the integer :math:`\ell` .. csv-table:: :widths: auto Coefficients,,:math:`s`,,:math:`c`,,:math:`\ell` Trigonometric Case,,:math:`\sin [ X(t) ]`,,:math:`\cos [ X(t) ]`,,1 Hyperbolic Case,,:math:`\sinh [ X(t) ]`,,:math:`\cosh [ X(t) ]`,,-1 We use the value .. math:: z^{(j)} = ( s^{(j)} , c^{(j)} ) in the definition for :math:`G` and :math:`H`. The forward mode formulas for the :ref:`sine and cosine` functions are .. math:: :nowrap: \begin{eqnarray} s^{(j)} & = & \frac{1 + \ell}{2} \sin ( x^{(0)} ) + \frac{1 - \ell}{2} \sinh ( x^{(0)} ) \\ c^{(j)} & = & \frac{1 + \ell}{2} \cos ( x^{(0)} ) + \frac{1 - \ell}{2} \cosh ( x^{(0)} ) \end{eqnarray} for the case :math:`j = 0`, and for :math:`j > 0`, .. math:: :nowrap: \begin{eqnarray} s^{(j)} & = & \frac{1}{j} \sum_{k=1}^{j} k x^{(k)} c^{(j-k)} \\ c^{(j)} & = & \ell \frac{1}{j} \sum_{k=1}^{j} k x^{(k)} s^{(j-k)} \end{eqnarray} If :math:`j = 0`, we have the relation .. math:: :nowrap: \begin{eqnarray} \D{H}{ x^{(j)} } & = & \D{G}{ x^{(j)} } + \D{G}{ s^{(j)} } c^{(0)} + \ell \D{G}{ c^{(j)} } s^{(0)} \end{eqnarray} If :math:`j > 0`, then for :math:`k = 1, \ldots , j-1` .. math:: :nowrap: \begin{eqnarray} \D{H}{ x^{(k)} } & = & \D{G}{ x^{(k)} } + \D{G}{ s^{(j)} } \frac{1}{j} k c^{(j-k)} + \ell \D{G}{ c^{(j)} } \frac{1}{j} k s^{(j-k)} \\ \D{H}{ s^{(j-k)} } & = & \D{G}{ s^{(j-k)} } + \ell \D{G}{ c^{(j)} } k x^{(k)} \\ \D{H}{ c^{(j-k)} } & = & \D{G}{ c^{(j-k)} } + \D{G}{ s^{(j)} } k x^{(k)} \end{eqnarray} {xrst_end sin_cos_reverse}