Frontier Systems
Hybrid discoveries across physics, bioengineering, and consciousness.
A curated map of frontier topics: bionic vision, neuromorphic computing, tDCS, quantum entanglement phenomena, gravitational computation, biocomputation, microwave engineering, bio-waves, fungi synapses, and cosmic-scale energy systems.
Hybrid research
Science + engineering + IA workflows.
Evidence-first, open-source paths.
Bionic vision
Retinal prosthetics, optogenetics, and cortical visual pipelines.
Signal encoding, stimulation patterns, and perceptual calibration.
Neuromorphic computing
Spiking neural networks, synaptic plasticity, and event-driven hardware.
Edge inference for real-time biosignal systems.
tDCS + neurostimulation
Protocol design, safety constraints, and signal monitoring.
Closed-loop augmentation experiments.
Quantum + gravitational computation
Entanglement models, information constraints, and theoretical architectures.
Exploratory models for gravitational signaling.
Biocomputation + bio-waves
Cellular computation, bioelectric signaling, and emergent dynamics.
Physiological wave models and sensory entrainment.
Fungi synapses + networks
Mycelial signaling, distributed sensing, and adaptive networks.
Cross-domain analogies for communication research.
Microwave engineering + biowave interfaces
Signal integrity, antenna design, and biomedical safety constraints.
RF sensing and adaptive communication protocols.
Human energy + cosmic systems
Planetary-scale energy flows, environmental coupling, and system modeling.
Evidence-based models grounded in physics and physiology.
Suggested starting points
1. Map the fundamentals in physics, math, and signal processing.
2. Build prototypes with BCI, robotics, and neuromorphic stacks.
3. Run controlled experiments and publish reproducible data.
4. Collaborate openly through shared learning paths.
Frontier Computation Lab
Research-grade calculators for each frontier system
Enter parameters, compute models, and review theory + citations.