Trajectory Through the Universe in the Millar Cosmological Model (MCM)

In the Millar Cosmological Model (MCM), our movement through the cosmos is not arbitrary—it is evidence of a directional rupture at the birth of the universe. This rupture, known as the Shatter, is the defining moment when the Chrissy Core™, a singular point of absolute stillness and zero temperature, fractured and launched all of spacetime outward. In contrast to the Standard Model, which views cosmic expansion as a symmetric inflationary process, MCM proposes that the Shatter was an asymmetric, directional event. This distinction has profound implications for understanding the motion of galaxies, the Cosmic Microwave Background (CMB), and especially our own galactic trajectory.

Standard cosmology recognizes that the Milky Way galaxy is moving at roughly 600 km/s toward a region of intense gravitational pull called the Great Attractor. The Local Group of galaxies, including Andromeda and the Milky Way, appears to be caught in this flow, often referred to as the “dipole anisotropy” of the CMB. It suggests that Earth—and by extension, our entire visible universe—is drifting in a particular direction through space.

MCM reinterprets this observation. The 600 km/s motion is not simply a gravitational attraction from a massive cluster; it is part of the original ejection vector from the Shatter. If the rupture occurred asymmetrically, one would expect parts of the newly forming universe to be launched faster in specific directions. The Cold Spot in the CMB, according to MCM, is the observable backside of that rupture—the scar left behind. We are moving away from it.

Let’s quantify this trajectory. The age of the universe is approximately 13.8 billion years. If we have been moving steadily since the moment of the Shatter at an average velocity of 600 km/s, we can calculate the approximate distance traveled.

First, convert 13.8 billion years to seconds:

13.8 billion years = 13.8 × 10^9 years 
= 13.8 × 10^9 × 3.154 × 10^7 seconds/year 
≈ 4.35 × 10^17 seconds

Now multiply by velocity:

Distance = velocity × time 
= 600 km/s × 4.35 × 10^17 s 
= 2.61 × 10^20 km

To convert kilometers to light-years:

1 light-year ≈ 9.461 × 10^12 km 
So,

Distance ≈ 2.61 × 10^20 km / 9.461 × 10^12 km/light-year 
≈ 27.6 billion light-years

This is extraordinary: it suggests that our observable reference frame could have traversed nearly 28 billion light-years since the Shatter. This number may seem counterintuitive—larger than the radius of the observable universe—but in MCM, this is not problematic. Space itself was created as a function of quantum events (blips), and the reference frame we occupy has been stretching outward in parallel with the generation of space.

What makes MCM unique is that this calculation matches not only the magnitude of our observed motion but the directionality as well. The Cold Spot lies behind us. The Great Attractor lies ahead. We are situated along the ejection vector. In essence, the memory of the rupture defines our spatial path.

In the standard model, there is no explanatory framework for why the Cold Spot exists in the specific location it does, nor why our galactic drift aligns so well with the directionality that MCM proposes. Gravitational flow models try to explain the motion toward the Great Attractor, but they struggle with the precise geometry and underlying cause. MCM simplifies this: we are moving outward from the origin point of rupture—our entire observable universe is like a ripple on a pond, expanding from a pebble drop.

The Higgs field, reinterpreted in MCM as a vibrational membrane through which Arnies stretch, carries the memory tension of this ejection. The Cold Spot represents the point of deepest strain—where the rupture imprinted most powerfully on the fabric. Because the Cold Spot lies almost exactly opposite our direction of motion, it strengthens the case that the Cold Spot is the origin point, and our galactic trajectory is the lingering velocity of that birth.

One further implication of this trajectory is in the timing of cosmic structures. In standard cosmology, structure formation is gradual, with slight anisotropies seeding gravitational wells. But in MCM, the Shatter seeded **directional structure**—regions of early dense matter moving along the same vector as us. That’s why galaxies are not uniformly distributed, and why dark flow may exist.

The model also redefines cosmic redshift. While standard models attribute redshift to expansion, MCM includes a secondary factor: **FrictoMass™**, or photon tension memory drag. As light travels across the Memory Fabric, it accumulates tension—losing energy in a way that mimics redshift. This effect is directional, meaning that photons traveling along the ejection vector may appear more redshifted, reinforcing the illusion of acceleration when in fact, they are simply dragging against an older, denser memory path.

In summary, MCM provides a coherent framework that explains:
- Why the Cold Spot exists and appears unique
- Why our galaxy is moving in a particular direction
- How the observed speed and direction of our motion align with a singular rupture event
- Why that motion leads toward a gravitational anomaly (the Great Attractor)
- And why this trajectory is embedded in the quantum structure of the universe itself

The Shatter launched us. The Cold Spot marks the place we came from. And the Memory Fabric remembers it all.

In the Millar Cosmological Model, motion is not an accident of gravity—it is the echo of genesis.

And we are still riding that echo today.