From where does Free Energy come?

Whirlpools of Oscillating Power Create their own Rules.

A load is a resistor; it creates voltage as a consequence of its resistance. A power source is a negative resistor; it creates amperage as a consequence of its negative resistance.

A load is a resistor only so long as it resists. It ceases to be a load the instant it stops resisting.

A source of power is a negative resistor so long as it negatively resists. It ceases to be a source of power the instant it stops negatively resisting.

A battery is not a source of power, because it is not a negative resistor. It is a load with an internal resistance based on its change of state. It cannot supply amperage; the wire connecting its two terminals supplies that.

A battery is like a capacitor in that it is capable of storing energy - not supplying it. The difference between the two is that the dielectric material between the two capacitor plates is equivalent to the electrolyte within the battery; both store energy - they do not supply it. Ultimately, energy has to come from somewhere else.

From where does it come? It comes from negative resistance.

What is a negative resistor? A negative resistor is a situation in which it takes less energy to maintain its status as a negative resistor than it takes to induce a change of state within another resistor.

Resistors possess inertia; they don't like to have their status as a resistor altered without a definitive cost. This cost - we have come to know - is the cost of supplying power to its resistance acting as a load. And if we make the mistake of supplying too much power to a load, the load retaliates with heat or - worse – sudden breakdown.

But in the case of an LMD module acting as an intermediate source of power for a load, it merely intermediates its supply of power to a load through other whirlpools of reactive power who have to interact with loads directly. Yet, if merely one whirlpool stands aloof from having to deal with the real world of positive resistors, and merely induce kinetic motion to other whirlpools who directly deal with positively resistive loads, then its own kinetic inertia is preserved while periodically boosting the waning inertia of other whirlpools.

Amperage knows no resistance. That's the job of voltage. Voltage knows no motion. That's the job of amperage. Whirlpools of reactive power can specialize in whether they want to focus on setting forces to move in the real world of matter, heat and light, or else they can remain aloof and exclusively deal with other whirlpools of reactive power at very little – if any – cost to themselves, because it takes very little – if any – energy to transfer its own reactive power to another whirlpool wanting more reactive power. The funny thing about isolated whirlpools is that they get a kick out of demands made upon themselves to serve up more energy to other whirlpools whose task is to lose that power by way of dissipation. This kick amplifies the aloof whirlpool, rather than slowing it down, since it knows no resistance – hence, it knows no voltage, either. Without a voltage drop, amperage can wildly escalate itself; heal itself of having spent itself in service towards other whirlpools who can't possibly heal themselves who have been wound down in direct service towards the outside world of non-reactive power.