Psychic Mechanics Theory

Essentially synonymous with Psionic Mechanics Theory, but often with a slightly softer, more organic or spiritual connotation. Where "psionic" sounds technological, "psychic" might imply a natural, innate human potential. The mechanics might be framed in terms of "energy channels," "vibrations," or "morphogenetic fields" rather than tachyons.

The branch of mega-engineering and physics concerned with the practical construction, stabilization, and operation of the unimaginably vast structures and energy systems required by high-level Kardashev civilizations. It's the "nuts and bolts" of godlike power: the math for stabilizing a rotating ringworld, the materials science for a Dyson Sphere's solar-collector panels, or the orbital dynamics for moving stars. This is the applied engineering manual for beings who treat planets as LEGO bricks and stars as furnaces.

A speculative branch of physics proposing that the fundamental nature of reality is not particulate (made of tiny balls) but vibrational (made of standing waves, frequencies, and resonances). In this view, what we perceive as solid matter, forces, and even time are emergent properties of underlying vibrational patterns in a field or substrate. "Mechanics" here refers to the study of the motion and interaction of these frequency-based entities. It suggests that changing an object's fundamental frequency could alter its mass, location, or phase of existence—the ultimate "vibe shift" as physics.

A theoretical framework that extends classical mechanics to systems with fractal geometry or fractal dynamics. Traditional mechanics assumes smooth, differentiable trajectories and boundaries. Fractal Mechanics relaxes these assumptions, allowing for paths that are continuous but nowhere differentiable, surfaces with infinite perimeter, and force distributions that are statistically self-similar across scales. It's the physics of mountains, clouds, and cracked earth—where the Euclidean ideal meets the jagged real.

A frontier discipline that applies the tools of dynamical systems theory to complex, adaptive, and networked systems. It doesn't just track a few interacting particles; it models millions of agents, each with internal states, learning rules, and heterogeneous connections. Dynamical-Complex Mechanics asks: How do traffic jams emerge from individual driving decisions? How do ideologies spread across a social network? How do ecosystems reorganize after a perturbation? It's physics for the messy, living world.

The study of motion and force in systems that evolve continuously over time, bridging classical mechanics and dynamical systems theory. It extends Newtonian physics to systems with feedback, nonlinearity, and time-dependent parameters. Where classical mechanics asks "Where will this cannonball land?", Dynamical Mechanics asks "How will this pendulum's swing evolve as energy dissipates, as friction changes with temperature, as the pivot point oscillates?" It's mechanics that respects the fourth dimension.

An approach to studying the mind that models cognitive processes as sequences of discrete, rule-governed operations on symbolic representations. This is the classic "computer metaphor" of cognition: perception inputs data, working memory buffers it, a central processor applies logical rules, and output is produced. It treats thinking as computation, and the brain as the hardware running the software. This paradigm powered the cognitive revolution and remains indispensable for many applications, though its limitations are increasingly apparent.