mirror of https://github.com/zcash/halo2.git
[book] src/design/circuit/gadgets/ecc/addition.md: formatting.
Signed-off-by: Daira Hopwood <daira@jacaranda.org>
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@ -31,15 +31,13 @@ which is equivalent to
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Assuming $x_p \neq x_q$,
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$
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\begin{array}{|rrll|}
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\hline
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&(x_r + x_q + x_p) \cdot (x_p - x_q)^2 &=& \lambda^2 \cdot (x_p - x_q)^2\\
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\implies &(x_r + x_q + x_p) \cdot (x_p - x_q)^2 &=& (\lambda \cdot (x_p - x_q))^2\\
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\\\hline
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&y_r &=& \lambda \cdot (x_q - x_r) - y_q\\
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\implies &y_r + y_q &=& \lambda \cdot (x_q - x_r)\\
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\implies &(y_r + y_q) \cdot (x_p - x_q) &=& \lambda \cdot (x_p - x_q) \cdot (x_q - x_r)\\
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\hline
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\begin{array}{lrrll}
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&&(x_r + x_q + x_p) \cdot (x_p - x_q)^2 &=& \lambda^2 \cdot (x_p - x_q)^2 \\
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&\implies &(x_r + x_q + x_p) \cdot (x_p - x_q)^2 &=& \big(\lambda \cdot (x_p - x_q)\big)^2 \\[1.2ex]
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\text{and} \\
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& &y_r &=& \lambda \cdot (x_q - x_r) - y_q \\
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&\implies &y_r + y_q &=& \lambda \cdot (x_q - x_r) \\
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&\implies &(y_r + y_q) \cdot (x_p - x_q) &=& \lambda \cdot (x_p - x_q) \cdot (x_q - x_r)
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\end{array}
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$
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@ -47,18 +45,18 @@ Substituting for $\lambda \cdot (x_p - x_q)$, we get the constraints:
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- $(x_r + x_q + x_p) \cdot (x_p - x_q)^2 - (y_p - y_q)^2 = 0$
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- Note that this constraint is unsatisfiable for $P \;⸭\; (-P)$ (when $P \neq \mathcal{O}$),
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and so cannot be used with arbitrary inputs.
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- $(y_r + y_q)(x_p - x_q) - (y_p - y_q)(x_q - x_r) = 0$
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- $(y_r + y_q) \cdot (x_p - x_q) - (y_p - y_q) \cdot (x_q - x_r) = 0$
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## Complete addition
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$\begin{array}{rcll}
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\mathcal{O} &+& \mathcal{O} &= \mathcal{O} \\
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\mathcal{O} &+& (x_q, y_q) &= (x_q, y_q) \\
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(x_p, y_p) &+& \mathcal{O} &= (x_p, y_p) \\
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(x, y) &+& (x, y) &= [2] (x, y) \\
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(x, y) &+& (x, -y) &= \mathcal{O} \\
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(x_p, y_p) &+& (x_q, y_q) &= (x_p, y_p) \;⸭\; (x_q, y_q), \text{if } x_p \neq x_q
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$\hspace{1em} \begin{array}{rcll}
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\mathcal{O} &+& \mathcal{O} &= \mathcal{O} \\[0.4ex]
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\mathcal{O} &+& (x_q, y_q) &= (x_q, y_q) \\[0.4ex]
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(x_p, y_p) &+& \mathcal{O} &= (x_p, y_p) \\[0.6ex]
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(x, y) &+& (x, y) &= [2] (x, y) \\[0.6ex]
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(x, y) &+& (x, -y) &= \mathcal{O} \\[0.4ex]
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(x_p, y_p) &+& (x_q, y_q) &= (x_p, y_p) \;⸭\; (x_q, y_q), \text{ if } x_p \neq x_q.
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\end{array}$
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Suppose that we represent $\mathcal{O}$ as $(0, 0)$. ($0$ is not an $x$-coordinate of a valid point because we would need $y^2 = x^3 + 5$, and $5$ is not square in $\mathbb{F}_q$. Also $0$ is not a $y$-coordinate of a valid point because $-5$ is not a cube in $\mathbb{F}_q$.)
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@ -80,18 +78,22 @@ Define $\mathsf{inv0}(x) = \begin{cases} 0, &\text{if } x = 0 \\ 1/x, &\text{oth
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Witness $\alpha, \beta, \gamma, \delta, \lambda$ where:
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* $\alpha = \mathsf{inv0}(x_q - x_p)$
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* $\beta = \mathsf{inv0}(x_p)$
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* $\gamma = \mathsf{inv0}(x_q)$
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* $\delta = \begin{cases}
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\mathsf{inv0}(y_q + y_p), &\text{if } x_q = x_p \\
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0, &\text{otherwise}
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\end{cases}$
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* $\lambda = \begin{cases}
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\frac{y_q - y_p}{x_q - x_p}, &\text{if } x_q \neq x_p \\[0.5ex]
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\frac{3{x_p}^2}{2y_p} &\text{if } x_q = x_p \wedge y_p \neq 0 \\[0.5ex]
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0, &\text{otherwise.}
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\end{cases}$
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$\hspace{1em}
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\begin{array}{rl}
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\alpha \,\,=&\!\! \mathsf{inv0}(x_q - x_p) \\[0.4ex]
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\beta \,\,=&\!\! \mathsf{inv0}(x_p) \\[0.4ex]
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\gamma \,\,=&\!\! \mathsf{inv0}(x_q) \\[0.4ex]
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\delta \,\,=&\!\! \begin{cases}
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\mathsf{inv0}(y_q + y_p), &\text{if } x_q = x_p \\
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0, &\text{otherwise}
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\end{cases} \\[2.5ex]
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\lambda \,\,=&\!\! \begin{cases}
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\frac{y_q - y_p}{x_q - x_p}, &\text{if } x_q \neq x_p \\[1.2ex]
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\frac{3{x_p}^2}{2y_p} &\text{if } x_q = x_p \wedge y_p \neq 0 \\[0.8ex]
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0, &\text{otherwise.}
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\end{cases}
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\end{array}
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$
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### Constraints
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@ -99,7 +101,7 @@ $$
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\begin{array}{|c|rcl|l|}
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\hline
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\text{Degree} & \text{Constraint}\hspace{7em} &&& \text{Meaning} \\\hline
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4 & q_\mathit{add} \cdot (x_q - x_p) \cdot ((x_q - x_p) \cdot \lambda - (y_q - y_p)) &=& 0 & x_q \neq x_p \implies \lambda = \frac{y_q - y_p}{x_q - x_p} \\\hline
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4 & q_\mathit{add} \cdot (x_q - x_p) \cdot ((x_q - x_p) \cdot \lambda - (y_q - y_p)) &=& 0 & x_q \neq x_p \implies \lambda = \frac{y_q - y_p}{x_q - x_p} \\\hline \\[-2.3ex]
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5 & q_\mathit{add} \cdot (1 - (x_q - x_p) \cdot \alpha) \cdot \left(2y_p \cdot \lambda - 3{x_p}^2\right) &=& 0 & \begin{cases} x_q = x_p \wedge y_p \neq 0 \implies \lambda = \frac{3{x_p}^2}{2y_p} \\ x_q = x_p \wedge y_p = 0 \implies x_p = 0 \end{cases} \\\hline
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6 & q_\mathit{add} \cdot x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda^2 - x_p - x_q - x_r) &=& 0 & x_p \neq 0 \wedge x_q \neq 0 \wedge x_q \neq x_p \implies x_r = \lambda^2 - x_p - x_q \\
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6 & q_\mathit{add} \cdot x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda \cdot (x_p - x_r) - y_p - y_r) &=& 0 & x_p \neq 0 \wedge x_q \neq 0 \wedge x_q \neq x_p \implies y_r = \lambda \cdot (x_p - x_r) - y_p \\
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@ -118,120 +120,117 @@ Max degree: 6
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### Analysis of constraints
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$$
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\begin{array}{ccl}
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1.&& (x_q - x_p) \cdot ((x_q - x_p) \cdot \lambda - (y_q - y_p)) = 0 \\
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&& \\
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&& \begin{aligned}
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\text{At least one of } &x_q - x_p = 0 \\
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\text{or } &(x_q - x_p) \cdot \lambda - (y_q - y_p) = 0 \\
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\end{aligned} \\
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&& \text{must be satisfied for the constraint to be satisfied.} \\
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&& \\
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&& \text{If } x_q - x_p \neq 0, \text{ then } (x_q - x_p) \cdot \lambda - (y_q - y_p) = 0 \\
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&& \\
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&& \text{If } (x_q - x_p) \cdot \lambda - (y_q - y_p) = 0, \text{ then because } x_q - x_p \neq 0, \\
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&& \text{ by rearranging both sides we get } \lambda = (y_q - y_p) / (x_q - x_p) \\
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&& \\
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&& \text{and therefore:}\\
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&& \hspace{2em} x_q \neq x_p \implies \lambda = (y_q - y_p) / (x_q - x_p).\\
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&& \\
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2.&& (1 - (x_q - x_p) \cdot \alpha) \cdot (2y_p \cdot \lambda - 3x_p^2) = 0\\
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&& \begin{aligned}
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\text{At least one of } &(1 - (x_q - x_p) \cdot \alpha) = 0 \\
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\text{or } &(2y_p \cdot \lambda - 3x_p^2) = 0
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\end{aligned} \\
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&& \text{must be satisfied for the constraint to be satisfied.} \\
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&& \\
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&& \text{If } x_q = x_p, \text{ then } 1 - (x_q - x_p) \cdot \alpha = 0 \text{ has no solution for } \alpha, \\
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&& \text{ so it must be that } 2y_p \cdot \lambda - 3x_p^2 = 0. \\
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&& \\
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&& \text{If } y_p = 0 \text{ then } x_p = 0, \text{ and the constraint is satisfied.}\\
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&& \\
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&& \text{If } y_p \neq 0 \text{ by rearranging both sides we get }\\
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&& \lambda = 3x_p^2 / 2y_p \\
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&& \text{Therefore:} \\
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&& \hspace{2em} (x_q = x_p) \wedge y_p \neq 0 \implies \lambda = 3x_p^2 / 2y_p. \\
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&& \\
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3.& \text{a)} & x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda^2 - x_p - x_q - x_r) = 0 \\
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& \text{b)} & x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda \cdot (x_p - x_r) - y_p - y_r) = 0 \\
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& \text{c)} & x_p \cdot x_q \cdot (y_q + y_p) \cdot (\lambda^2 - x_p - x_q - x_r) = 0 \\
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& \text{d)} & x_p \cdot x_q \cdot (y_q + y_p) \cdot (\lambda \cdot (x_p - x_r) - y_p - y_r) = 0 \\
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&& \\
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&& \begin{aligned}
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\text{At least one of } &x_p = 0 \\
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\text{or } &x_p = 0 \\
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\text{or } &(x_q - x_p) = 0 \\
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\text{or } &(\lambda^2 - x_p - x_q - x_r) = 0 \\
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\begin{array}{rl}
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1. & (x_q - x_p) \cdot ((x_q - x_p) \cdot \lambda - (y_q - y_p)) = 0 \\
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& \\
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& \begin{aligned}
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\text{At least one of } &x_q - x_p = 0 \\
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\text{or } &(x_q - x_p) \cdot \lambda - (y_q - y_p) = 0 \\
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\end{aligned} \\
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& \text{must be satisfied for the constraint to be satisfied.} \\
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& \\
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& \text{If } x_q - x_p \neq 0, \text{ then } (x_q - x_p) \cdot \lambda - (y_q - y_p) = 0. \\
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& \\
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& \text{If } (x_q - x_p) \cdot \lambda - (y_q - y_p) = 0, \text{ then because } x_q - x_p \neq 0, \\
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& \text{by rearranging both sides we get } \lambda = (y_q - y_p) / (x_q - x_p). \\
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& \\
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& \text{Therefore:} \\
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& \hspace{2em} x_q \neq x_p \implies \lambda = (y_q - y_p) / (x_q - x_p).\\
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& \\
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2. & (1 - (x_q - x_p) \cdot \alpha) \cdot (2y_p \cdot \lambda - 3x_p^2) = 0 \\
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& \\
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& \begin{aligned}
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\text{At least one of } &(1 - (x_q - x_p) \cdot \alpha) = 0 \\
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\text{or } &(2y_p \cdot \lambda - 3x_p^2) = 0
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\end{aligned} \\
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& \text{must be satisfied for the constraint to be satisfied.} \\
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& \\
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& \text{If } x_q = x_p, \text{ then } 1 - (x_q - x_p) \cdot \alpha = 0 \text{ has no solution for } \alpha, \\
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& \text{so it must be that } 2y_p \cdot \lambda - 3x_p^2 = 0. \\
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& \\
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& \text{If } y_p = 0 \text{ then } x_p = 0, \text{ and the constraint is satisfied.}\\
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& \\
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& \text{If } y_p \neq 0 \text{ by rearranging both sides we get } \lambda = 3x_p^2 / 2y_p. \\
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& \\
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& \text{Therefore:} \\
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& \hspace{2em} (x_q = x_p) \wedge y_p \neq 0 \implies \lambda = 3x_p^2 / 2y_p. \\
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& \\
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3.\text{ a)} & x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda^2 - x_p - x_q - x_r) = 0 \\
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\text{ b)} & x_p \cdot x_q \cdot (x_q - x_p) \cdot (\lambda \cdot (x_p - x_r) - y_p - y_r) = 0 \\
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\text{ c)} & x_p \cdot x_q \cdot (y_q + y_p) \cdot (\lambda^2 - x_p - x_q - x_r) = 0 \\
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\text{ d)} & x_p \cdot x_q \cdot (y_q + y_p) \cdot (\lambda \cdot (x_p - x_r) - y_p - y_r) = 0 \\
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& \\
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& \begin{aligned}
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\text{At least one of } &x_p = 0 \\
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\text{or } &x_p = 0 \\
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\text{or } &(x_q - x_p) = 0 \\
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\text{or } &(\lambda^2 - x_p - x_q - x_r) = 0 \\
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\end{aligned} \\
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&& \text{must be satisfied for constraint (a) to be satisfied.} \\
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&& \\
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&& \text{Let } x_p \neq 0 \wedge x_q \neq 0 \wedge x_q \neq x_p. \\
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&& \begin{aligned}
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&\text{• Constraint (a) imposes that } x_r = \lambda^2 - x_p - x_q \text{ is satisfied.} \\
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&\text{• Similarly, constraint (b) imposes that } y_r = \lambda \cdot (x_p - x_r) - y_p \text{ is satisfied.} \\
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\end{aligned} \\
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&& \\
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&& \text{Let } x_p \neq 0 \wedge x_q \neq 0 \wedge y_q \neq -y_p. \\
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&& \begin{aligned}
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&\text{• Similarly, constraint (c) imposes that } x_r = \lambda^2 - x_p - x_q \text{ is satisfied.} \\
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&\text{• Similarly, constraint (d) imposes that } y_r = \lambda \cdot (x_p - x_r) - y_p \text{ is satisfied.} \\
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\end{aligned} \\
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&& \\
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&& \text{Therefore:} \\
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&& \begin{aligned}
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&(x_p \neq 0) \wedge (x_q \neq 0) \wedge ((x_q \neq x_p) \vee (y_q \neq -y_p)) \\
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& \text{must be satisfied for constraint (a) to be satisfied.} \\
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& \\
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& \text{Let } x_p \neq 0 \wedge x_q \neq 0 \wedge x_q \neq x_p. \\[1.5ex]
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& \text{• Constraint (a) imposes that } x_r = \lambda^2 - x_p - x_q. \\
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& \text{• Constraint (b) imposes that } y_r = \lambda \cdot (x_p - x_r) - y_p. \\
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& \\
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& \text{Let } x_p \neq 0 \wedge x_q \neq 0 \wedge y_q \neq -y_p. \\[1.5ex]
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& \text{• Constraint (c) imposes that } x_r = \lambda^2 - x_p - x_q. \\
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& \text{• Constraint (d) imposes that } y_r = \lambda \cdot (x_p - x_r) - y_p. \\
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& \\
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& \text{Therefore:} \\
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& \begin{aligned}
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&(x_p \neq 0) \wedge (x_q \neq 0) \wedge ((x_q \neq x_p) \vee (y_q \neq -y_p)) \\
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\implies &(x_r = \lambda^2 - x_p - x_q) \wedge (y_r = \lambda \cdot (x_p - x_r) - y_p).
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\end{aligned} \\
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&& \\
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4.& \text{a)} & (1 - x_p \cdot \beta) \cdot (x_r - x_q) = 0 \\
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& \text{b)} & (1 - x_p \cdot \beta) \cdot (y_r - y_q) = 0 \\
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&& \\
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&& \begin{aligned}
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\text{At least one of } 1 - x_p \cdot \beta &= 0 \\
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\text{or } x_r - x_q &= 0
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& \\
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4.\text{ a)} & (1 - x_p \cdot \beta) \cdot (x_r - x_q) = 0 \\
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\text{ b)} & (1 - x_p \cdot \beta) \cdot (y_r - y_q) = 0 \\
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& \\
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& \begin{aligned}
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\text{At least one of } 1 - x_p \cdot \beta &= 0 \\
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\text{or } x_r - x_q &= 0
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\end{aligned} \\
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&& \\
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&& \text{must be satisfied for constraint (a) to be satisfied.} \\
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&& \text{If } x_p = 0 \text{ then } 1 - x_p \cdot \beta = 0 \text{ has no solutions for } \beta, \\
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&& \text{and so it must be that } x_r - x_q = 0. \\
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&& \\
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&& \text{Similarly, constraint (b) imposes that } y_r - y_q = 0. \\
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&& \\
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&& \text{Therefore:} \\
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&& \hspace{2em} x_p = 0 \implies (x_r, y_r) = (x_q, y_q). \\
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&& \\
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5.& \text{a)} & (1 - x_q \cdot \beta) \cdot (x_r - x_p) = 0 \\
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& \text{b)} & (1 - x_q \cdot \beta) \cdot (y_r - y_p) = 0 \\
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&& \\
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&& \begin{aligned}
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\text{At least one of } 1 - x_q \cdot \beta &= 0 \\
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\text{or } x_r - x_p &= 0
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& \text{must be satisfied for constraint (a) to be satisfied.} \\
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& \\
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& \text{If } x_p = 0 \text{ then } 1 - x_p \cdot \beta = 0 \text{ has no solutions for } \beta, \\
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& \text{and so it must be that } x_r - x_q = 0. \\
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& \\
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& \text{Similarly, constraint (b) imposes that } y_r - y_q = 0. \\
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& \\
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& \text{Therefore:} \\
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& \hspace{2em} x_p = 0 \implies (x_r, y_r) = (x_q, y_q). \\
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& \\
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5.\text{ a)} & (1 - x_q \cdot \beta) \cdot (x_r - x_p) = 0 \\
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\text{ b)} & (1 - x_q \cdot \beta) \cdot (y_r - y_p) = 0 \\
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& \\
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& \begin{aligned}
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\text{At least one of } 1 - x_q \cdot \beta &= 0 \\
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\text{or } x_r - x_p &= 0
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\end{aligned} \\
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&& \\
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&& \text{must be satisfied for constraint (a) to be satisfied.} \\
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&& \\
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&& \text{If } x_q = 0 \text{ then } 1 - x_q \cdot \beta = 0 \text{ has no solutions for } \beta, \\
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&& \text{and so it must be that } x_r - x_p = 0. \\
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&& \\
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&& \text{Similarly, constraint (b) imposes that } y_r - y_p = 0. \\
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&& \\
|
||||
&& \text{Therefore:}\\
|
||||
&& \hspace{2em} x_q = 0 \implies (x_r, y_r) = (x_p, y_p). \\
|
||||
&& \\
|
||||
6.& \text{a)} & (1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta) \cdot x_r = 0 \\
|
||||
& \text{b)} & (1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta) \cdot y_r = 0 \\
|
||||
&& \\
|
||||
&& \begin{aligned}
|
||||
\text{At least one of } &1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta = 0 \\
|
||||
\text{or } &x_r = 0
|
||||
& \text{must be satisfied for constraint (a) to be satisfied.} \\
|
||||
& \\
|
||||
& \text{If } x_q = 0 \text{ then } 1 - x_q \cdot \beta = 0 \text{ has no solutions for } \beta, \\
|
||||
& \text{and so it must be that } x_r - x_p = 0. \\
|
||||
& \\
|
||||
& \text{Similarly, constraint (b) imposes that } y_r - y_p = 0. \\
|
||||
& \\
|
||||
& \text{Therefore:} \\
|
||||
& \hspace{2em} x_q = 0 \implies (x_r, y_r) = (x_p, y_p). \\
|
||||
& \\
|
||||
6.\text{ a)} & (1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta) \cdot x_r = 0 \\
|
||||
\text{ b)} & (1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta) \cdot y_r = 0 \\
|
||||
& \\
|
||||
& \begin{aligned}
|
||||
\text{At least one of } &1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta = 0 \\
|
||||
\text{or } &x_r = 0
|
||||
\end{aligned} \\
|
||||
&& \\
|
||||
&& \text{must be satisfied for constraint (a) to be satisfied.}
|
||||
&& \\
|
||||
&& \text{If } x_r \neq 0, \text{ then it must be that } 1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta = 0. \\
|
||||
&& \\
|
||||
&& \text{However, if } x_q = x_p \wedge y_q = -y_p, \text{ then there are no solutions for } \alpha \text { and } \delta. \\
|
||||
&& \text{Therefore: } x_q = x_p \wedge y_q = -y_p \implies (x_r, y_r) = (0, 0).
|
||||
& \text{must be satisfied for constraint (a) to be satisfied.} \\
|
||||
& \\
|
||||
& \text{If } x_r \neq 0, \text{ then it must be that } 1 - (x_q - x_p) \cdot \alpha - (y_q + y_p) \cdot \delta = 0. \\
|
||||
& \\
|
||||
& \text{However, if } x_q = x_p \wedge y_q = -y_p, \text{ then there are no solutions for } \alpha \text { and } \delta. \\
|
||||
& \\
|
||||
& \text{Therefore: } \\
|
||||
& \hspace{2em} x_q = x_p \wedge y_q = -y_p \implies (x_r, y_r) = (0, 0).
|
||||
\end{array}
|
||||
$$
|
||||
|
||||
|
@ -239,13 +238,13 @@ $$
|
|||
|
||||
$
|
||||
\begin{array}{cl}
|
||||
(1)& x_q \neq x_p \implies \lambda = (y_q - y_p) / (x_q - x_p). \\
|
||||
(2)& (x_q = x_p) \wedge y_p \neq 0 \implies \lambda = 3x_p^2 / 2y_p \\
|
||||
(3)& (x_p \neq 0) \wedge (x_q \neq 0) \wedge ((x_q \neq x_p) \vee (y_q \neq -y_p)) \\
|
||||
&\implies (x_r = \lambda^2 - x_p - x_q) \wedge (y_r = \lambda \cdot (x_p - x_r) - y_p) \\
|
||||
(4)& x_p = 0 \implies (x_r, y_r) = (x_q, y_q) \\
|
||||
(5)& x_q = 0 \implies (x_r, y_r) = (x_p, y_p) \\
|
||||
(6)& x_q = x_p \wedge y_q = -y_p \implies (x_r, y_r) = (0, 0) \\
|
||||
(1)& x_q \neq x_p \implies \lambda = (y_q - y_p) / (x_q - x_p) \\[0.8ex]
|
||||
(2)& (x_q = x_p) \wedge y_p \neq 0 \implies \lambda = 3x_p^2 / 2y_p \\[0.8ex]
|
||||
(3)& (x_p \neq 0) \wedge (x_q \neq 0) \wedge ((x_q \neq x_p) \vee (y_q \neq -y_p)) \\[0.4ex]
|
||||
&\implies (x_r = \lambda^2 - x_p - x_q) \wedge (y_r = \lambda \cdot (x_p - x_r) - y_p) \\[0.8ex]
|
||||
(4)& x_p = 0 \implies (x_r, y_r) = (x_q, y_q) \\[0.8ex]
|
||||
(5)& x_q = 0 \implies (x_r, y_r) = (x_p, y_p) \\[0.8ex]
|
||||
(6)& x_q = x_p \wedge y_q = -y_p \implies (x_r, y_r) = (0, 0)
|
||||
\end{array}
|
||||
$
|
||||
|
||||
|
@ -269,6 +268,7 @@ $(x_p, y_p) + (x_q, y_q) = (x_r, y_r)$
|
|||
|
||||
- Soundness: $(x_r, y_r) = (0, 0)$ is the only solution
|
||||
* $(x, y) + (0, 0)$
|
||||
|
||||
- Completeness:
|
||||
|
||||
$
|
||||
|
@ -288,6 +288,7 @@ $(x_p, y_p) + (x_q, y_q) = (x_r, y_r)$
|
|||
|
||||
- Soundness: $(x_r, y_r) = (x_p, y_p)$ is the only solution
|
||||
* $(0, 0) + (x, y)$
|
||||
|
||||
- Completeness:
|
||||
|
||||
$
|
||||
|
|
Loading…
Reference in New Issue