NeoAmorfic Quantum

NQE1

NeoAmorfic Quantum Engine

NQE1 is a law-audited pure quantum physics engine for simulating, testing, and designing quantum technologies before hardware maturity. It is built to model quantum states, Hamiltonian dynamics, open-system decoherence, quantum control, photonics, optomechanics, gate fidelity, scientific benchmarks, and internal quantum experiment campaigns.

NQEv1 Release Family NQEv17 Law Architecture 16 Analytic Benchmarks Internal Quantum Lab Pre-Hardware Quantum Design

Institutional Purpose

NQE1 is not intended to imitate large corporate quantum SDKs. Its purpose is to become a precise, inspectable, physics-first engine for quantum technology intelligence. The engine is designed to help NeoAmorfic explore what quantum systems should do, how they fail, how they can be controlled, and which physical designs deserve deeper investigation before expensive hardware work begins.

Quantum Engine

State, Hamiltonian, measurement, evolution, entanglement, noise, control, and photonic physics under a law-audited architecture.

Quantum Lab

Internal experiment campaigns for control robustness, photonic sensitivity, optomechanical coupling, and candidate quantum insights.

Quantum Education

A public-facing learning layer explaining the laws, experiments, benchmarks, and physics concepts behind the engine.

The NQEv17 Law Architecture

NQEv17 does not claim to invent new physical laws. It means that NQE1 encodes and audits seventeen foundational quantum law families as software-governed simulation constraints.

  1. Quantum state physicality
  2. Hilbert-space dimensional consistency
  3. Tensor-product composition
  4. Statevector and density-matrix representation
  5. Superposition and complex amplitude structure
  6. Born probability and measurement statistics
  7. Projective measurement and post-measurement state update
  8. Hermitian Hamiltonian energy law
  9. Closed-system unitary evolution
  10. Trace, norm, and probability conservation
  11. Observable expectation and variance
  12. Subsystem reduction through partial trace
  13. Entanglement and nonseparability
  14. Open-system Lindblad dynamics
  15. Quantum channels and Kraus noise maps
  16. Phase, interference, and photonic mode mixing
  17. Quantum control, process fidelity, and gate-quality evaluation