Abstract
The Gröbner Basis is a subset of finite generating polynomials in the ideal of the polynomial ring k[x
1,…,xn
]. The Gröbner basis has a wide range of applications in various areas of mathematics, including determining implicit polynomial equations. The quadratic rational Bézier curve is a rational parametric curve that is generated by three control points P
0(x
0,y
0), P
1(xi
,yi
), P
2(x
2,y
2) in ℝ2 and weights ω
0, ω
1, ω
2, where the weights ω
i
are corresponding to control points Pi
(xi, yi
), for i = 0,1, 2. According to Cox et al (2007), the quadratic rational Bézier curve can represent conic sections, such as parabola, hyperbola, ellipse, and circle, by defining the weights ω
0 = ω
2 = 1 and ω
1 = ω for any control points P
0(x
0, y
0), P
1(x
1, y
1), and P
2(x
2, y
2). This research is aimed to obtain an implicit polynomial equation of the quadratic rational Bézier curve using the Gröbner basis. The polynomial coefficients of the conic section can be expressed in the term of control points P
0(x
0, y
0), P
1(x
1, y
1), P
2(x
2, y
2) and weight ω, using Wolfram Mathematica. This research also analyzes the effect of changes in weight ω on the shape of the conic section. It shows that parabola, hyperbola, and ellipse can be formed by defining ω = 1, ω > 1, and 0 < ω < 1, respectively.
Designing Developable C-Bézier Surface with Shape Parameters
