| name | quantum-cognition |
| description | Quantum cognition methodology for modeling cognitive processes using quantum probability theory. Combines neuroscience insights with quantum information formalism to model decision making, context-dependent reasoning, mental state dynamics, and non-classical cognitive correlations. Use when: (1) modeling cognitive phenomena that violate classical probability (order effects, conjunction fallacy), (2) building quantum-like models of decision making, (3) analyzing contextuality in mental representations, (4) designing quantum neural architectures for brain-inspired computing, (5) studying quantum effects in biological systems (radical-pair mechanism, cryptochrome), (6) implementing quantum photonic neural networks for neuromorphic computing.
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Quantum Cognition
Model cognitive processes using quantum probability theory and quantum information formalism.
This methodology spans two interpretations: quantum-like cognition (informational) and physical
quantum brain hypotheses.
Two Paradigms
1. Quantum-Like Cognition (Informational)
Uses quantum formalism to model cognition without claiming quantum processes in the brain.
Based on Khrennikov's framework: mental contexts induce non-classical correlations analogous
to quantum entanglement. Key insight: incompatible measurements arise naturally from
context-dependent mental representations.
When to use: decision making, judgment under uncertainty, concept combinations,
cognitive biases, order effects in survey responses.
2. Physical Quantum Brain Hypotheses
Proposes actual quantum coherence in biological substrates. Wakaura (2026) evaluates CQEC
(covariant quantum error correction) in radical-pair proteins MAO-A and cryptochrome.
Key finding: CQEC can maintain coherence over 200ms behavioral windows, but layer-protein
tradeoffs exist — no single protein optimizes all layers.
When to use: biophysical modeling of neural processes, radical-pair mechanism analysis,
quantum error correction in biological systems.
Core Mathematical Framework
Quantum Probability Model
Replace classical Kolmogorov probability with quantum probability:
import numpy as np
def quantum_probability(state_vector, projector):
"""P(outcome) = |<outcome|state>|^2 = ||projector @ state||^2"""
return np.abs(np.dot(projector, state_vector))**2
def interference_effect(p_A, p_B, theta):
"""Classical: p = p_A + p_B
Quantum: p = p_A + p_B + 2*sqrt(p_A*p_B)*cos(theta)"""
return p_A + p_B + 2 * np.sqrt(p_A * p_B) * np.cos(theta)
Contextuality Detection
Bell-CHSH inequality violation indicates non-classical correlations:
def chsh_inequality(E_ab, E_ab_prime, E_a_prime_b, E_a_prime_b_prime):
"""|S| = |E(ab) - E(ab') + E(a'b) + E(a'b')| <= 2 (classical)
Quantum bound: |S| <= 2*sqrt(2) (Tsirelson bound)"""
S = abs(E_ab - E_ab_prime + E_a_prime_b + E_a_prime_b_prime)
return S, S > 2.0, S <= 2 * np.sqrt(2)
Cognitive State Evolution
Mental states evolve via unitary transformations (closed system) or Lindblad dynamics (open system):
from scipy.linalg import expm
def mental_state_evolution(H, psi_0, t):
"""|psi(t)> = exp(-iHt)|psi(0)> — unitary evolution"""
U = expm(-1j * H * t)
return U @ psi_0
Quantum Photonic Neural Networks (QPNN)
Boras Vazquez et al. (2026): time-bin-encoded QPNN for quantum information processing.
Key architectural insight: time-encoded networks use constant number of photonic elements
regardless of size/depth, enabling scaling. Trained via realistic nonlinearities (quantum
dot + waveguide) to achieve 0.96+ fidelity Bell-state analysis.
def qpnn_architecture(n_modes, depth, nonlinearity="kerr"):
"""Time-bin QPNN: same elements regardless of network depth.
Layers: (1) time-delay interferometer, (2) phase shifters,
(3) nonlinear element (Kerr or quantum dot scattering)"""
return {
"encoding": "time-bin",
"elements": "constant with depth",
"nonlinearity": nonlinearity,
"fidelity": ">0.96 (realistic), >0.99 (time-gated)"
}
Quantum Error Correction in Biological Systems
CQEC protocol for radical-pair proteins:
- Three-layer architecture: nuclear spin memory → electron spin interface → electrochemistry
- Coherence preservation: CQEC extends T2 coherence beyond decoherence rate
- Layer-protein tradeoff: CRY has longer T2 (52ms) but shorter T1 (0.53ns); MAO-A has opposite
- Behavioral threshold: 200ms Schultze-Kraft veto window is the minimum coherence requirement
Decision Making Patterns
Order Effects
P(A then B) ≠ P(B then A) — classical commutativity violation
Quantum: P(A then B) = ||P_B P_A |psi>||^2 ≠ ||P_A P_B |psi>||^2
Conjunction Fallacy
Linda problem: P(bank teller AND feminist) > P(bank teller)
Explained by quantum interference between mental representations.
Disjunction Effect
Violation of sure-thing principle in decision making under uncertainty.
Modeled via quantum interference term in probability calculation.
Application Workflow
- Identify classical probability violation in cognitive data
- Construct quantum state space (Hilbert space dimension = number of distinguishable outcomes)
- Define mental state vector and measurement projectors
- Fit interference parameters to empirical data
- Validate with contextuality tests (Bell-CHSH, Leggett-Garg inequalities)
- Predict novel effects (order reversal, compatibility effects)
Key Findings from Literature
- CQEC coherence: 0.83 at decoherence rate 0.19 (6.9x improvement over uncorrected)
- QPNN fidelity: 0.96 with realistic nonlinearity, 0.99+ with time gating
- Contextuality: Mental markers exhibit quantum-like incompatibility without physical quantum processes
- Layer tradeoff: No single radical-pair protein optimizes both T1 and T2 coherence times
References
See references/ for detailed mathematical derivations and implementation guides.
Recent Papers (2026)
- arXiv:2601.10588 - Searching for Quantum Effects in the Brain: A Bell-Type Test for Nonclassical Latent Representations in Autoencoders → See
quantum-nonclassicality-latent-test skill
- arXiv:2605.23943 - Spacetime Formation under Requirements: Contextual Realization and Form-Dependent Probability (quantum cognition as fixed-spacetime projection)
- arXiv:2605.29877 - Verifying Adversarial Robustness in QML → See
qml-adversarial-robustness-verification skill
- arXiv:2605.29557 - Quantum Subliminal Learning → See
quantum-subliminal-learning skill
- arXiv:2605.24152 - Neuro-Inspired Inverse Learning for Planning and Control → See
neuro-inspired-inverse-learning skill
