D203-1 Introduction

Today, I want to begin a long series of discussions on how to conduct world-line travel—what some people call “stargate travel.” Before I show you any devices or contraptions, it’s important to understand the theory behind them.
Without that foundation, you won’t be able to use the technology effectively. That’s why I talk so much about the Many Worlds Interpretation (MWI) and quantum physics.

I try to explain these things simply. If you’ve followed my writings or videos, you probably already see how straightforward this is. But simplicity is often buried under arcane language, and many people profit from making it sound mysterious.
Suppose you’re a butcher or a baker working long days—you don’t have time to learn about Everett’s conjecture or multi-world theories. So my goal is to simplify.

The mathematics behind this is sound; there’s nothing wrong with it. The problem is that it asks you to look at reality from a different angle. Many people are uncomfortable with that.
Yet this approach works—just as understanding atoms and compounds lets us make new materials, understanding frequencies and world-lines lets us do far more than we think.
Everett devised accurate models for describing systems like this, even if the applications aren’t obvious in contemporary technology.

I know the system works. I was involved with it in 1981 when it was already fairly mature. I understand how and why it works, and I’ll try to explain that clearly.

Everything in the physical world is made up of smaller parts. We call them atoms. Atoms themselves are built from smaller particles—electrons, protons, neutrons.
Quantum physics goes deeper, into quanta, strings, branes, and other idealized forms. All of these models differ slightly in mathematics but are based on the same idea: tiny, vibrating entities.

I often illustrate this by describing vibrating “balls” or clusters. Each component vibrates; each line or block vibrates. What we perceive as a solid cup of coffee is actually a vast collection of vibrating quanta.
Nothing I’m saying here contradicts physics or quantum mechanics.

Everett’s equations are elegant once you understand them. They provide a bridge from “things that vibrate” to “how we perceive them.” For example, color is simply a frequency. Our eyes pick up that frequency and our brain perceives it as color. Everything is a frequency.

This isn’t just New Age talk. People often tell me they’ve had an “aha” moment about frequency. My response is: “Great—now what?” Recognizing frequency isn’t enough; you have to know how to use it.

Everett’s world-line writings describe a simple model: the mathematics of the universe allow multiple universes to exist simultaneously.
Combine that with the fact that everything is frequency and you get something astounding—a world of infinite possibilities, not just the one you see.

There’s a movie called What the Bleep Do We Know? that tries to explain quantum physics to a general audience. I recommend it. But for now, here’s the core concept: everything is a complex series of frequencies.
You can take a “frequency snapshot” of a physical region at a specific point in time, listing all the frequencies present. Just like a camera captures an image, this snapshot can be replicated.

The mechanism for traversing through stargates works like this:

Do it correctly and you’re there. That’s essentially how it works. It’s not conceptually difficult, but it demands precision—otherwise you might end up with a hand growing out of your forehead.

Here’s how it’s measured. You define a region—say, a cylinder one meter in diameter and three meters high—and surround it with at least six extremely sensitive gravity sensors called flux-gate sensors. The more sensors, the more accurate the reading.
They generate enormous amounts of data, which you convert into a 3D image of the portal area.

When you enter, the sensors show a moving “blob” representing you. Algorithms remove that blob to isolate your environment. Do the same at your destination—say Hamburg, Germany—and you now have frequency data for both locations.
Change the gravitational reading of one area to match the other, and you create a portal.

Forget the idea of “tunneling out of the physical world.” You’re not doing that. You’re swapping resonance patterns between two points.

The Navy’s approach (at NASC Pensacola) used an intense magnetic field. You walk into the field—think of it as a charged bath—and while inside, the destination coordinates are swapped in. The field builds gradually to a peak, at which point the transfer occurs.
That’s why you hear a grinding sound and feel vibration.

This system can also project into the future or past, because if you’re mapping how the flux-gate sensors change over time, you can predict other temporal states. In theory, you could even alter your own profile—change your appearance or add features.

In short, this is a teleporter—much like Star Trek. In future installments, I’ll explain the mathematics and construction techniques. Personally, I think the best way to alter your reality is to change your own template through controlled thought, since thoughts also operate on frequencies. That’s worked for me.

If, however, you want to build an actual device, the technology isn’t restricted. Flux-gate sensors are commercially available, and while creating a magnetic field strong enough for a human portal is expensive, it’s feasible.
The real challenge isn’t building the machine—it’s calibrating it. Calibration is critical. The system is forgiving within a fraction of a second, but mistakes in destination coordinates can send you anywhere—or anywhen.

Every frozen moment is a different world-line, and you can change those lines. Most highly paid commentators don’t even grasp this basic fact. But that’s the overview of teleportation 101.

I’ll continue explaining the details in future sessions. For now, whatever you do and however you act, be the best you can possibly be.