CLP-1 Differential Calculus

\begin{align*} \tilde\varepsilon_{n+1} \amp = \frac{x_{n-1} f(x_n) - x_n f(x_{n-1}) }{f(x_n)-f(x_{n-1})} -r \\ \amp = \frac{[r+\tilde\varepsilon_{n-1}] f(x_n) - [r+\tilde\varepsilon_n] f(x_{n-1}) } {f(x_n)-f(x_{n-1})} -r \\ \amp = \frac{\tilde\varepsilon_{n-1} f(x_n) - \tilde\varepsilon_n f(x_{n-1}) } {f(x_n)-f(x_{n-1})} \end{align*}

\begin{align*} f(x_n)\amp = f(r) + f'(r)\tilde\varepsilon_n +\frac{1}{2} f''(c_1) \tilde\varepsilon_n^2 \\ \amp = f'(r)\tilde\varepsilon_n +\frac{1}{2} f''(c_1) \tilde\varepsilon_n^2 \\ f(x_n)-f(x_{n-1})\amp = f'(c_2)[x_n-x_{n-1}] \\ \amp = f'(c_2)[\tilde\varepsilon_n-\tilde\varepsilon_{n-1}] \end{align*}

\begin{align*} f(x_n)\amp \approx f'(r)\tilde\varepsilon_n +\frac{1}{2} f''(r) \tilde\varepsilon_n^2 \\ f(x_{n-1})\amp \approx f'(r)\tilde\varepsilon_{n-1} +\frac{1}{2} f''(r) \tilde\varepsilon_{n-1}^2 \\ f(x_n)-f(x_{n-1})\amp \approx f'(r)[\tilde\varepsilon_n-\tilde\varepsilon_{n-1}] \end{align*}

\begin{align*} \tilde\varepsilon_{n+1} \amp = \frac{\tilde\varepsilon_{n-1} f(x_n) - \tilde\varepsilon_n f(x_{n-1}) } {f(x_n)-f(x_{n-1})} \\ \amp \approx \frac{ \tilde\varepsilon_{n-1} [f'(r)\tilde\varepsilon_n +\frac{1}{2} f''(r) \tilde\varepsilon_n^2] - \tilde\varepsilon_n [f'(r)\tilde\varepsilon_{n-1} +\frac{1}{2} f''(r) \tilde\varepsilon_{n-1}^2] } { f'(r)[\tilde\varepsilon_n-\tilde\varepsilon_{n-1}] } \\ \amp = \frac{\frac{1}{2}\tilde\varepsilon_{n-1}\tilde\varepsilon_nf''(r)[\tilde\varepsilon_n-\tilde\varepsilon_{n-1}]} { f'(r)[\tilde\varepsilon_n-\tilde\varepsilon_{n-1}] } \\ \amp = \frac{f''(r)} {2f'(r)} \tilde\varepsilon_{n-1}\tilde\varepsilon_n \end{align*}

\begin{equation*} \varepsilon_{n+1}\approx K \varepsilon_{n-1}\varepsilon_n\qquad \text{with }K = \left|\frac{f''(r)} {2f'(r)} \right| \tag{E7} \end{equation*}

\begin{alignat*}{2} \delta_2\amp \amp \amp \approx \delta_0\delta_1 \\ \delta_3\amp \approx \delta_1\delta_2 \amp \amp \approx \delta_0\delta_1^2 \\ \delta_4\amp \approx \delta_2\delta_3 \amp \amp \approx \delta_0^2\delta_1^3 \\ \delta_5\amp \approx \delta_3\delta_4 \amp \amp \approx \delta_0^3\delta_1^5 \\ \delta_6\amp \approx \delta_4\delta_5 \amp \amp \approx \delta_0^5\delta_1^8 \\ \delta_7\amp \approx \delta_5\delta_6 \amp \amp \approx \delta_0^8\delta_1^{13} \end{alignat*}

\begin{equation*} \delta_0^{\alpha_{n+1}}\delta_1^{\beta_{n+1}} \approx \delta_0^{\alpha_{n-1}}\delta_1^{\beta_{n-1}} \delta_0^{\alpha_n}\delta_1^{\beta_n} \end{equation*}

\begin{equation*} \alpha_{n+1}=\alpha_{n-1}+\alpha_{n} \qquad \beta_{n+1}=\beta_{n-1}+\beta_{n} \tag{E8} \end{equation*}

\begin{align*} F_0\amp =0 \\ F_1\amp =1 \\ F_n\amp =F_{n-1}+F_{n-2}\qquad\text{for }n>1 \end{align*}

\begin{equation*} \delta_n \approx \delta_0^{\alpha_n}\delta_1^{\beta_n} = \delta_0^{F_{n-1}}\delta_1^{F_n} \end{equation*}

\begin{equation*} F_n\approx\frac{\varphi^n}{\sqrt{5}}\qquad\text{where } \varphi=\frac{1+\sqrt{5}}{2} \approx 1.61803 \end{equation*}

\begin{align*} K\varepsilon_n \amp = \delta_n \approx \delta_0^{F_{n-1}}\delta_1^{F_n} \approx \delta_0^{\frac{\varphi^{n-1}}{\sqrt{5}}} \delta_1^{\frac{\varphi^n}{\sqrt{5}}} = \delta_0^{\frac{1}{\sqrt{5}\varphi}\times\varphi^n} \delta_1^{\frac{1}{\sqrt{5}}\times\varphi^n}\\ \amp = d^{\varphi^n}\qquad\text{where}\quad d=\delta_0^{\frac{1}{\sqrt{5}\,\varphi}}\delta_1^{\frac{1}{\sqrt{5}}}\\ \amp \approx d^{1.6^n} \end{align*}

\begin{gather*} K\varepsilon_n\approx d^{2^n}\qquad\text{where}\quad d=(K\varepsilon_1)^{1/2} \end{gather*}