Lab for Determinants and Conic Section Curves
Exercise 5. Use the determinant method
to find the standard equation of a parabola through the points (6,1), (2,2) and (1,4).
Remark. In Exercises 4 and 6 the same points
are used to find the circle and alternate parabola.
Solution 5. The points are entered into Mathematica with the command:
![[Graphics:../Images/cof_gr_54.gif]](../Images/cof_gr_54.gif)
Then a row vector corresponding to equation (5) is defined:
![[Graphics:../Images/cof_gr_55.gif]](../Images/cof_gr_55.gif)
The matrix A for the linear system in (6) and the determinant is now created. The vector R is stored in the first row by issuing the command A = {R}. Then the remaining three rows of A are generated with the loop command:
![[Graphics:../Images/cof_gr_56.gif]](../Images/cof_gr_56.gif)
For the given three points, the homogeneous system AC = 0 is:
![[Graphics:../Images/cof_gr_57.gif]](../Images/cof_gr_57.gif)
The determinant of this matrix is computed by typing:
![[Graphics:../Images/cof_gr_58.gif]](../Images/cof_gr_58.gif)
The desired equation is:
![[Graphics:../Images/cof_gr_59.gif]](../Images/cof_gr_59.gif)
The conic is the standard parabola shown in Figure 5. It is plotted using the commands:
![[Graphics:../Images/cof_gr_60.gif]](../Images/cof_gr_60.gif)
![[Graphics:../Images/cof_gr_61.gif]](../Images/cof_gr_61.gif)
(c) John H. Mathews
![[Graphics:../Images/cof_gr_62.gif]](../Images/cof_gr_62.gif){kind=small}