What is the equation, in standard form, of a parabola that contains the following points?

To find the equation of a parabola, we can use the vertex form of a parabola equation, which is given by:

y = a(x - h)^2 + k

where (h, k) represents the vertex of the parabola. To find the values of a, h, and k, we can use the given points (-2, -20) and (0, -4).

Using the point (-2, -20):

-20 = a(-2 - h)^2 + k

And using the point (0, -4):

-4 = a(0 - h)^2 + k

Simplifying the equations:

-20 = a(4 + 4h + h^2) + k
-4 = ah^2 + k

We now have a system of linear equations:

-20 = 4a + 4ah + ah^2 + k
-4 = ah^2 + k

Subtracting the second equation from the first equation:

-20 + 4 = 4a + 4ah + ah^2 + k - ah^2 - k
-16 = 4a + 4ah
-4 = a + ah

Factoring out a:

-4 = a(1 + h)

Now, we can solve for a:

a = -4 / (1 + h)

Substituting this value of a back into one of the original equations (let's use the second equation):

-4 = ah^2 + k
-4 = (-4 / (1 + h))h^2 + k

Simplifying the equation:

-4 = (-4h^2) / (1 + h) + k
-4(1 + h) = -4h^2 + k(1 + h)
-4 - 4h = -4h^2 + k + kh

Simplifying further:

-4 - 4h = -4h^2 + kh + k
0 = -4h^2 + (k - 4h) + k + 4

0 = -4h^2 + (2k - 4h) + 4

Rearranging the equation:

4h^2 - 4h + (2k - 4) = 0

Now, let's use the point (4, -20) to solve for k:

-20 = a(4 - h)^2 + k
-20 = (-4 / (1 + h))(4 - h)^2 + k

Simplifying the equation:

-20 = (-4h^2 + 16h - 16) / (1 + h) + k
-20(1 + h) = -4h^2 + 16h - 16 + k(1 + h)
-20 - 20h = -4h^2 + (16 + k - 4h) + h(k + 1)

Simplifying further:

-20 - 20h = -4h^2 + (h + 16 + k - 4h) + h(k + 1)
-20h = -4h^2 + (1 - 3h + k)

Rearranging the equation:

4h^2 - 20h + (3h - 1 + k) = 0

Now, we have another equation:

4h^2 - 20h + (3h - 1 + k) = 0

Comparing this equation with the previous equation (4h^2 - 4h + (2k - 4) = 0), we can equate the corresponding coefficients:

3h - 1 + k = 2k - 4

Simplifying:

3h - 1 = k - 4

Rearranging the equation:

3h - k = -3

Now we have a system of linear equations:

4h^2 - 4h + (2k - 4) = 0
3h - k = -3

We can now solve this system of linear equations to find the values of h and k.

Solving the second equation for k:

k = 3h + 3

Substituting this value of k into the first equation:

4h^2 - 4h + 2(3h + 3) - 4 = 0
4h^2 - 4h + 6h + 6 - 4 = 0
4h^2 + 2h + 2 = 0

We can now use the quadratic formula to solve for h:

h = (-b ± √(b^2 - 4ac)) / (2a)
h = (-2 ± √(2^2 - 4*4*2)) / (2*4)
h = (-2 ± √(4 - 32)) / 8
h = (-2 ± √(-28)) / 8

Since the square root of a negative number is not real, there are no real solutions for h. This means that the given points (-2, -20), (0, -4), and (4, -20) do not form a parabola.