I attempted Xantix's answer to the first question in order to plot an equilateral triangle given a center point (cx,cy) and radius of the circumcircle (r), which as was pointed out, easily solves coordinates for point C (cx, cy + r).
However, I could not figure out how to get the rotational equations to solve either coordinates for points A & B, so my solution is as follows.
Math time - solve for x
Assume cx = 9, cy = 9, r = 6, and a horizontal base.
First, find the length of the sides of the triangle (a,b,c):
9r^2 = a^2 + b^2 + c^2
r^2 = 36, 9r^2 = 324, 324/3 = 108, sqrt(432) = 10.39
Once we know the length of each side of the triangle (s = 10.39), we can calculate for x coordinates. Add s/2 (5.2) to cx for Bx (14.2), and subtract s/2 from cx for Ax (3.8).
x solved now need y
Speaking of s/2, if we split the triangle in half vertically (from point C to midpoint between points A & B), we can solve for y (ultimately giving us Ay and By):
a^2 + b^2 = c^2
a^2 + 27.04 (1/2 s squared) = 107.95 (length s squared)
a^2 = 80.91
sqrt(80.91) = 8.99
Subtract this y value from cy + r (15 - 8.99 = 6.01) gives us our new y plot for both points A and B.
Center ( 9.00, 9.00)
C ( 9.00,15.00)
B (14.20, 6.01)
A ( 3.80, 6.01)
Once we know the length of the sides of an equilaterial triangle, it's possible to calculate the point coordinates given a center point, circumcircle radius, and a horizontal base.