Some Different Ways to Examine




by

James W. Wilson and Sherry L. Hix
University of Georgia


It has now become a rather standard exercise, with available technology, to construct graphs to consider the equation

and to overlay several graphs of

for different values of a, b, or c as the other two are held constant. From these graphs, students will be able to make many conjectures about the characteristics of a, b, and c.

A discussion of the patterns of the roots can be very useful. For example, if we set

for b = -3, -2, -1, 0, 1, 2, 3, and (after viewing each graph separately) overlay the graphs, we obtain the following picture.

Students should be able to discuss the "movement" of the parabola as b is changed. A meaningful discussion of this family of graphs will be the bridge to all similar families. Can students determine what points on the graph are important? One point on the graph is common to all the parabolas, the point (0, 1) . This is completely as we would expect when we examine the equations used.

The roots of the equations can be seen along the x-axis. Can the students make general comments about what sorts of roots the equations have either by looking at the equation or (of particular interest) by looking at the picture? And can they understand what it means on the graph when they find roots of the equation ?

For b < -2, the parabola will intersect the x-axis in two points with positive x values (i.e. the original equation will have positive real roots). For b = -2 and b = 2, the parabola is tangent to the x-axis and so the original equation has one real and positive root at the point of tangency. For -1 < b < 2, the parabola does not intersect the x-axis -- the original equation has no real roots. And for b > 2, the parabola intersects the x-axis twice to show two negative real roots for each b. This all begs the question "What is a root?" Can students answer this question? And once they know this with great certainty, do they know why a quadratic may have one or no real roots? These are items which I have found painfully lacking in students' repertoires.

Having successfully mastered all this , consider the locus of the vertices of the set of parabolas graphed from

The locus is, in fact, a parabola with the equation

The general form for this equation is

for any family of graphs.

Now we can see even better the next location of the parabola in the family (b = 4 or b = -4).

Consider again the equation

Graph this relation in the xb plane.

Naturally, the graph is a hyperbola (the two variables are x and b). If we take any particular value of b, say b = 3 and overlay this equation on the graph, we add a line parallel to the x-axis. The points of intersection of the curve and the line (in the xb plane) give the roots of the original equation.

The approximate roots of the equation then when b = 3 are -2.6 and -0.4, which can be seen back in the xy plane.

Looking back at the equation in the xb plane

we can make hypotheses about the roots without necessarily graphing so many members of the family.

The top blue line is where b = 2. If b > 2, x is negative and has two intersection points with the line. This means in the xy plane the parabola has two negative real roots. If b < -2, x is positive and has two intersection points with the line. Then in the xy plane the parabola has two positive real roots. If b = 2 , then x = -1. If b = -2, then x = 1. Therefore, at these two values of b, x has one real root (one negative and one positive, respectively). If -2 < b < 2, there are no intersection points, so there are no real roots between these values of b. The line x = 0 is asymptotic to the hyperbola because if x = 0 in the equation

then it reduces to 1 = 0. This means there are no roots at x = 1. This is as we would expect since in the above graph in the xy plane where b ranges from -3 to 3, all the parabolas go through x = 1. There exists roots at every number on the x axis on either side of 1, but not including 1.


Now consider the equation

Similar to above, if the equation is graphed in the xc plane, certainly the graph will be a parabola. Overlaying any value of c, will give a line crossing this parabola in 0, 1, or 2 points. The intersection points are the roots of the original equation at that value of c. Observe the graph when c = 1, then

will have two negative roots -- approximately -0.2 and -4.8.

Consider the parabola above while sliding the green line up and down the graph. There is one value of c where the equation will have only 1 real root -- at c = 6.25, the green line will intersect the parabola in one point. For c > 6.25, the green line will not intersect the parabola, the equation will have no real roots. For c < 6.25, the green line will intersect the parabola in two points. Both these x values will be positive for 0 < c < 6.25. When c = 0, x (or the roots of the original equation) will be -5 and 0. When c < 0, there will be one positive root and one negative root.


When studying the equation

if you hold c constant (for example, c = 1) then the graph in the xb plane will show the roots of the original equation for different values of b. Likewise, holding b constant (for example, b = 5) then the graph in the xc plane also shows the roots of the original equation for different values of c. In examining the original problem in different ways, students will gain great insight into the mathematics.


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