Kernekoncepter
This paper presents a geometric method for finding the roots of a quadratic equation in one complex variable by constructing a line and a circumference in the complex plane, using the known coefficients of the equation.
Resumé
The paper describes a geometric method for finding the roots of a quadratic equation in one complex variable of the form x^2 + c1*x + c2 = 0. The method involves constructing a line L and a circumference C in the complex plane, where the roots are located at the intersections of L and C.
The key steps are:
- Compute the inclination angle θ* of line L from the coefficients c1 and c2.
- Determine the parametric equation of line L using the fixed point p1 = -c1/2 and the direction vector vθ*.
- Construct the circumference C as the Möbius transformation of line L, given by the equation C: c2/L1.
- Locate the intersections between L and C, which correspond to the roots r1 and r2 of the quadratic equation.
The paper also provides a numerical example demonstrating the application of this geometric method. Additionally, it discusses an interesting property related to the rectilinear segments connecting key points in the quadratic LC structure.
Statistik
The paper contains the following key figures and equations:
Equation (1): x^2 + c1*x + c2 = (x-r1)(x-r2) = 0
Equation (2): L1: p1 + tvθ
Equation (3): Ld: (p1 + tvθ)(p1 - tvθ) = p1^2 + t^2(-vθ*^2)
Equation (4): θ* = arg(c1^2/4 - c2) / 2
Equation (5): C: c2/L1 = c2/(p1 + tvθ)
Equation (6): Center of circumference C
Citater
"The quadratic LC method described here, although more elaborate than the traditional quadratic formula, can be extended to find initial approximations to the roots of polynomials in one variable of degree n≥3."
"From Figure 1 we can see that the intersections between line L1 and circumference C occur at points r1 = -2 + 3i and r2 = 3 + 4i. We can see that these values obtained are in fact the ones that satisfy equation (7)."