D203-2 DIY Flux Gate Sensing
Today I want to talk about the DIY construction of a teleportation unit. In this video, I’ll focus on something very specific: the location and sensing of coordinates.
To understand teleportation, you must understand one fundamental point: you need two sets of coordinates. One set for where you’re leaving from, and one set for where you’re going. These coordinates act like fingerprints — no two are alike, and they’re constantly changing from moment to moment. Out of the entire universe, only one unique fingerprint describes one location at one time.
The best way I know to obtain these coordinates is by measuring gravity. There may be other methods, but gravity readings are the method I’m familiar with. You take readings of the gravitational field at a specific location and point in time. This snapshot of change is your “fingerprint.”
The devices that make these measurements are called flux‑gate sensors. Don’t confuse them with the “flux capacitor” from Back to the Future — a flux gate measures extremely small variations in gravity or magnetic flux. In reality, you’re not taking a static picture of gravity; you’re recording how gravity changes.
That’s the heart of it. You measure changes in gravity to create a fingerprint. You then use that fingerprint as your departure coordinates. By altering those numbers, you generate a new set of coordinates for your destination. If you change the time variable, you’re essentially time‑traveling. If you change the location variable, you travel to a different place instantly. If you change the parameters that define the object or person in the teleporter, you can even change that object or person.
This is an extraordinarily powerful tool. In future videos, I’ll talk about how you can use it not just to travel but to alter size, shape, or biological properties. Think of it: bigger hands, smaller eyes, healthier organs — all by adjusting coordinates. You can shift yourself across world‑lines, to environments you’ve never imagined, simply by changing gravitational readings.
Up until 10 or 15 years ago, the idea of measuring gravity so precisely was considered fantasy. Today it’s state‑of‑the‑art. GPS, satellites, and many industrial systems already monitor gravitational changes with compact sensors. Flux gates come in different designs and specializations. You can buy them online; they’re not impossibly expensive.
In my example setup, I recommend taking at least eight simultaneous gravity readings at one point in space. Arrange your sensors in a reproducible array. For illustration, I’ve built a cardboard model using green Legos to represent flux‑gate sensors placed around the teleportation unit. The “heating pad” in my model represents the teleportation mechanism itself — a surface emitting magnetic flux. You’d actually walk into this flux field to teleport.
Around that surface, place your sensors. In my model, four sensors are on the base level, and four are mounted higher up. This gives you eight sensors at two different heights, each recording changes in flux. They’re sensitive enough to detect your heartbeat when you stand near them. That sensitivity is both a strength and a challenge: small mistakes are amplified.
For best results, buy identical sensors from the same manufacturer and arrange them in a precise geometric pattern. I suggest a cone‑like configuration: imagine your egress portal in the center, with an invisible cone around it. Four sensors at about two feet off the ground and four at about five or six feet. You can make the structure with rods or poles arranged in a circle, then mount the sensors at those heights.
This array becomes your standard. Like a rail gauge or a unit of measure, it must be fixed and repeatable. The raw data will look like meaningless alphanumeric numbers until you run it through software. Fortunately, the technology to compile sensor inputs into unified data sets is already available. You can buy complete kits used in geological and industrial work. These kits take multiple sensor inputs and produce meaningful readings — no calculus required.
In future segments, I’ll show you how to take those readings and “massage” them into usable coordinates, isolating your body’s effect from the environment’s background so you get clean data. For now, remember: without accurate egress coordinates, you have no teleportation. The more sensors you use, the more accurate your results.
Even then, the system is surprisingly forgiving. If you round your numbers too coarsely, you won’t vanish into oblivion; you’ll end up in a nearby world‑line. Things will look almost the same, but with odd differences — a different language spoken, different cultural details, different relationships. Your memories stay consistent because they’re not stored in your physical brain but accessed like data from a cloud. Only your body and environment shift.
This is the foundational step of DIY teleportation: learning to measure and organize your coordinates. Once you can do that, you can define your destination. In my next video, I’ll cover how to process and adjust these readings. Until then, use this knowledge carefully. The rewards are enormous, but so are the risks.
And as always, I believe you’ll handle it well.