Section 8: Predictions and Testable Consequences
By Brian Miller
SEI provides not only a conceptual and mathematical model but also a framework for generating predictions that can be tested in physics, biology, cognition, and cosmology. These predictions distinguish SEI from descriptive metaphysics by proposing falsifiable consequences of its core dynamics.
SEI predicts that coherence between distant systems can emerge purely through shared interaction fields without exchange of particles or information. This reframes quantum entanglement and suggests novel tests involving field structuring rather than entropic correlation.
Rather than attributing time dilation to velocity or gravity alone, SEI predicts that temporal effects arise from asymmetry in the interaction field gradient:
$$T_{SEI} = \frac{\delta X}{\delta(A - B)}$$
Experiments could test for dilation-like effects in systems with large field differentials even without relativistic velocity.
SEI predicts that wavefunction “collapse” is a transition in the field structure X, not a discontinuity or measurement artifact. Quantum behavior should exhibit structural discontinuities in X that align with classical outcomes.
SEI predicts that biological development and cognition follow recursive triadic patterns, where each layer of emergence becomes the polarity structure of a new layer. This model can be applied to systems biology and neural architecture.
The SEI equation set predicts that entanglement structure, geometric curvature, and temporal flow are mathematically linked. Tests could include correlated measurements of field shape, information flow, and time metrics across domains.
SEI predicts that large-scale coherence (e.g., cosmic background symmetry) is a residue of triadic field structuring at the earliest phases of emergence. Anomalies may be predictable by modeling polar tension dynamics during inflation.
These testable consequences give SEI a pathway toward scientific legitimacy, anchoring its universal framework in predictions accessible to current or near-future experimentation.