On Friedman equation, quadratic laws and the geometry of our universe

Einstein’s special and general relativity revolutionized physics. The predictions of general relativity are Strong Lensing, Weak Lensing, Microlensing, Black Holes, Relativistic Jets, A Gravitational Vortex, Gravitational Waves, The Sun Delaying Radio Signals, Proof from Orbiting Earth, Expansion of the universe. The density of the universe determines the geometry and fate of the universe. According to Freedman’s equations of general relativity published in 1922 and 1924, the geometry of the universe may be closed, open and fl at. It all depends upon the curvature of the universe also. Various results of Cosmic Microwave Background Radiation (CMBR), NASA’s Wilkinson Microwave Anisotropy Probe (WMAP), and ESA’s Planck spacecraft probes found that our universe is fl at within a margin of 0.4% error. In this short work, by applying the laws of quadratic equations, we attempt to show that OUR UNIVERSE IS FLAT.

The density parameter Ω, the curvature parameter k and the Hubble parameter H are related as [7].
(1 -Ω) = -kc 2 / H 2 R 2 (1) If omega less than 1, k is -1, If omega is equal to 1, k is zero, If omega greater than 1, k is +1. If k is -1, the geometry of the universe is open, if it is greater than one, the shape of the universe is closed and the universe obeys Euclidean geometry if k is equal to zero.
i.e if Ω = 1 , the universe is Euclidean, if Ω = less than 1 the geometry of the universe is open, and if Ω = greater than 1, the universe is closed.
By assuming the above principle (2) in (1b) and applying, +1 for Alpha and Beta.
This implies that our assumptions that Ω is less than 1 and Ω is greater than 1 are not applicable (6).
Consequently we get that our application that Ω = 1 is acceptable (7).
If the discriminant is zero, then there is exactly one real root, -b/2a.
Here b = 2 and a = 1, So, -b/2a = 2/2 = 1 As we have previously seen that is Ω = 1, then the geometry of our universe is FLAT.

Discriminant B 2 -4AC
A quadratic equation with real coef icients can have either one or two distinct real roots, or two distinct complex roots. In this case the discriminant determines the number and nature of the roots. There are three cases If the discriminant is positive, then there are two distinct roots.
If the discriminant is zero, then there is exactly one real root, -b/2a.
If the discriminant is negative, then there are no real roots. Rather, there are two distinct (nonreal) complex roots.
The above equation is quadratic in Ω.

Case 1
According to the laws of quadratic equations, if B 2 -4AC = 0, then the roots are real and distinct.
We have already seen that if Ω = 1, then k = 0.
From this result, we may conclude that the roots of Ω may be distinct and real Result (A)

From this relation we obtain that k is imaginary (Result E)
Since k is the curvature parameter of our universe, it cannot be imaginary.

Discussion
In the irst method we have shown that the shape of our universe is Euclidean. In the second method, case 3 (Result F) is not acceptable. So, cases 1 and 2 are acceptable. The second method shows that the universe may be either closed or lat. But the irst method proves that the t geometry of the universe is Euclidean/ lat. The author has previously found several results in this topic [1][2][3][4][5][6][7].
"Finally, it could be that there's just enough matter for the Universe to have zero curvature. Angles of triangles add up to exactly 180 degrees and the Universe is in inite. If this is the case then it may be that matter can slow the rate of expansion, but it'll never be able to bring it down to zero. The Universe will also expire in a big freeze Observations of the cosmic microwave background (the leftover radiation from the Big Bang) suggest that the Universe is indeed lat, or at least very nearly so. This would imply eternal expansion, at least if the assumptions above are true [https:// plus.maths.org/content/shape-and-fate-universe].
A brief analysis of previous experiments, observations and this author's mathematical formulations make us to arrive at a conclusion that the fate of our Universe is that it will expire in a big freeze.