Quartic point group operation: Difference between revisions

The point group operation over quartic (or hyperelliptic ^[1]) curves (of degree four) is defined geometrically as follows. Let

${\displaystyle y^{2}=px^{4}+qx^{3}+rx^{2}+sx+t}$

be a quartic curve on the x-y plane of real numbers, the polynomial in x on the right having either the coefficient p>0 or at least two real roots counting multiplicity.

A quartic square dance

Every operation over a quartic curve will be defined geometrically by a “square dance” of the four points of intersection of the quartic curve and a parabola ^[2] whose axis is parallel to the y-axis, and otherwise to be determined.

Namely if P, Q, R, and S are four points of the quartic curve, through which a parabola with an axis parallel to the y-axis passes, then we will say that

${\displaystyle P\oplus Q\oplus R\oplus S=O}$

where O is the additional “point at infinity” which serves as the additive group identity.

Additive inverses

If P is a point on the elliptic curve, then its inverse is found by solving for ${\displaystyle Q=-P}$ in this “square dance” equation

${\displaystyle P\oplus P\oplus Q\oplus Q=O}$

where the parabola is required to be tangent ^[3] to the curve both at the point P and at the unknown point Q. Simple algebra and calculus should yield a unique solution.

Point averaging

The average or “mean” of two points P and Q may be found by solving the square dance equation

${\displaystyle P\oplus Q\oplus R\oplus R=O}$

Here let the parabola pass through the points P and Q and be tangent to the quartic curve at R. Take the inverse to find the mean: ${\displaystyle {\frac {P\oplus Q}{2}}=-R}$.

Point trebling

To treble a point P, solve the “square dance” equation

${\displaystyle P\oplus P\oplus P\oplus Q=O}$

and then take the inverse of Q to find ${\displaystyle 3P=-Q}$. Here the parabola is required to osculate ^[4] the quartic curve at the point P which appears with a multiplicity of three in the equation, and intersect simply at the point Q.

Point trisection

Trisecting a point is exactly the same as trebling, except that it is at the unknown point Q where the parabola and the quartic curve are required to osculate, and a simple intersection is permitted at the point P.

${\displaystyle P\oplus Q\oplus Q\oplus Q=O}$.

Now take the inverse of Q to find ${\displaystyle {\frac {P}{3}}=-Q}$.

Point doubling

Point doubling is performed by trebling and then averaging

${\displaystyle 2P={\frac {P\oplus 3P}{2}}}$.

Point bisection

Point bisection or “halving” is performed by doubling a point and averaging with its additive inverse.

${\displaystyle {\frac {1}{2}}P={\frac {2P\oplus (-P)}{2}}}$

Point group addition

${\displaystyle P\oplus Q={\dfrac {\left({\dfrac {P\oplus Q}{2}}\right)\oplus 3\left({\dfrac {P\oplus Q}{2}}\right)}{2}}}$

The most essential and basic operation of “adding” two points, which should serve as the point group operation for cryptographic purposes, is now derived at the end of a long, roundabout square dance routine by calculating the mean of two points, and then doubling by means of trebling and averaging.

The algebra and calculus equations should be simplified, and made as efficient as possible. The operation has been suitably defined, and nothing has been introduced here that should violate the axioms of an Abelian group.

Fitting the curves

When the resolvent quadratic equation

${\displaystyle y=ax^{2}+bx+c}$

is squared and diminished by the equation of the quartic curve

${\displaystyle y^{2}=q_{4}x^{4}+q_{3}x^{3}+q_{2}x^{2}+q_{1}x+q_{0}}$

and the leading coefficient of the resultant equation

${\displaystyle {\begin{array}{rcl}(a^{2}-q_{4})x^{4}\\+(2ab-q_{3})x^{3}\\+(b^{2}+2ac-q_{2})x^{2}\\+(2bc-q_{1})x\\+c^{2}-q_{0}&=&0\end{array}}}$

is set to one, then after performing a partial fractions decomposition, we can start building a system of equations to determine the coefficients of the resolvent. The leading coefficient a is immediately determined, and at least one point x₁ is known in every case, while the resolvent coefficients b and c may be determined using a method of least squares.

The equations to be solved simulateously are

${\displaystyle {\begin{array}{rcl}a^{2}-q_{4}&=&1\\-2ab+q_{3}&=&x_{1}+x_{2}+x_{3}+x_{4}\\{\bar {x}}&=&{\frac {x_{1}+x_{2}+x_{3}+x_{4}}{4}}\\{\mathcal {Var}}(x)&=&{\frac {1}{4}}\sum _{i=1}^{4}(x_{i}-{\bar {x}})^{2}\\{\bar {y}}&=&a{\bar {x}}^{2}+b{\bar {x}}+c+a\cdot {\mathcal {Var}}(x)\\{\bar {y}}&=&{\frac {1}{4}}\sum _{i=1}^{4}(ax_{i}^{2}+bx_{i}+c)\\{\bar {y}}&=&{\frac {1}{4}}\sum _{i=1}^{4}\pm {\sqrt {q_{4}x_{i}^{4}+q_{3}x_{i}^{3}+q_{2}x_{i}^{2}+q_{1}x_{i}+q_{0}}}\end{array}}}$

Next steps

Once you have mastered the quartic point group operation, the proof of Mordell’s theorem by infinite descent, methods of bounding heights of rational numbers, and the theory of numerical and floating point approximations for curve fitting, you may move on to the quintic point group operation.

Appendix: R code for example curve plot

#! /usr/bin/R -f

H <- function(x){
    sqrt((5/17)*(11-2*x^2/3)*(x+2/7)^2)
}

xvals <- seq(0,sqrt(16.5),0.0001)

plot(x=c(xvals,rev(xvals),-xvals,-rev(xvals)),
    y=c(H(xvals),-H(rev(xvals)),-H(-xvals),H(-rev(xvals))),
    type="l", lwd=3, col="brown",
    xlab="x", ylab="y", asp="1",
    main=expression(17*y^2 == 5*(11-2*x^2/3)*(x+2/7)^2)
)
abline(0,0)