eigensound |

Quantum Mechanics

Uncertainty Principle: Higher values create more chaotic, unpredictable sound patterns as quantum measurements become less precise.

Coherence Time: Determines how long quantum states maintain their phase relationships before environmental decoherence.

Entanglement: Correlates harmonic frequencies non-locally - changing one affects others instantaneously.

Wave Packet Width: Controls the spatial extent of quantum wave functions, affecting interference patterns.

General Relativity

Spacetime Curvature: Creates frequency modulation simulating how curved spacetime affects wave propagation.

Time Dilation: Slows temporal evolution, showing how time passes differently in gravitational fields.

Gravitational Redshift: Lowers frequencies as if sounds are climbing out of gravitational wells.

Event Horizon: Simulates extreme redshift effects near black hole boundaries.

Eigenmode Physics

Eigenmode Density: Controls how many natural resonant frequencies are active in the system.

Eigenvalue Spreading: Determines the spectral distribution - closely spaced modes create beating patterns.

Eigenvector Coupling: How strongly different modes interact and exchange energy.

Quantum Eigenshift: Applies quantum corrections to classical eigenfrequencies.

Modal Damping: How quickly each eigenmode loses energy - affects sustain and decay.

Eigenspace Geometry: Different shapes have different eigenvalue spectra based on their symmetries.

Advanced Physics

Decoherence Rate: Controls how quickly quantum coherence is lost due to environmental interactions.

Vacuum Fluctuations: Adds quantum noise from zero-point energy fluctuations in empty space.

Hawking Radiation: Simulates thermal radiation from black holes, adding characteristic noise patterns.

Cosmic Background: Incorporates subtle effects from the cosmic microwave background radiation.

Quantum Tunneling: Probability of quantum particles passing through energy barriers, creating amplitude spikes.

Spacetime Ripples: Gravitational wave distortions that modulate frequency and amplitude.

Dark Energy: Cosmic expansion effects that subtly influence sound evolution over time.

Information Loss: Black hole information paradox effects creating sudden amplitude changes.

Scientific Accuracy

All effects are based on established physics equations, though simplified for real-time audio synthesis. The eigenmode system accurately models vibrational modes found in quantum systems and acoustic resonators.