The Expanding Observable Universe vs. a Non-Expanding Universe: Understanding the Hypergeometrical Universe Theory

Introduction

The concept of a universe expanding is widely accepted in mainstream cosmology, yet there are unique theories that challenge this notion. One such theory is the Hypergeometrical Universe (HU) Theory, which proposes an alternative perspective on the structure and evolution of the universe. In this article, we will explore how the HU Theory reconciles the apparent expansion of the observable universe with the idea of a non-expanding universe.

Understanding the Hypergeometrical Universe Theory (HU)

The HU Theory suggests that our universe is a vast hypersurface on a lightspeed expanding hypersphere. This unique perspective allows us to understand the apparent expansion of our observable universe while positing that the universe as a whole is not expanding.

The Geometry of the Universe in HU

In the HU Theory, space is not a simple 3D volume but a 4D spatial manifold. The universe we observe is the outer shell of this hyperspherical structure, while past observations reveal the inner shells. This hyper-shell can be thought of as a shockwave or a hypersurface that is expanding at lightspeed.

The Fabric of Space and Particle Motion

The HU Theory introduces the concept of the 'fabric of space' (FS), a local metric that governs the motion of particles. This fabric can be in a relaxed state, allowing particles to move radially outward, or in a tense state, enabling particles to move tangentially. The state of the FS is influenced by interactions, and the resulting tangential motion manifests as inertial mass.

Interpreting the Expansion of the Observable Universe

While the universe as a whole might be infinite and non-expanding, the observable universe is expanding due to the lightspeed expansion of the outer hypersphere. As the outer hypersphere grows, the observable universe appears to expand. This expansion is a result of the hyperspherical shockwave, which is expanding at the speed of light.

Interpreting Type 1A Supernovae Data

To better understand this concept, we can look at how the HU Theory explains the observations from the Type 1A supernova survey. In this model, the fabric of space on the outermost hypersphere is tilted at an angle α2. This tilt indicates that the fabric is still in a tense state, allowing for tangential motion and the appearance of galaxies moving radially. As the hypersphere expands and the angle α2 decreases, the fabric of space relaxes, and galaxies appear to move radially.

Mapping the Expanding Universe

Given the knowledge of redshifts (z) of distant supernovae, the HU Theory allows for precise mapping and prediction of distances. This is achieved by understanding the relationship between the tilted angle of the fabric of space and the expansion of the outer hypersphere.

Conclusion: The Exploration of Cosmic Scale

The HU Theory presents a fascinating alternative to traditional cosmology, challenging our understanding of the universe's expansion. By proposing that the observable universe is expanding while the universe as a whole is infinite and non-expanding, the HU Theory opens up new avenues for exploration and interpretation of cosmic phenomena.

Explore More: For further insights, you can read the detailed explanations and calculations of HU Theory, including the Big Pop Cosmogenesis Equation of State, on the official HU Theory website.