Editing Psionics (section)

= Psionic Equations =
== New Psi Equations Relating to Consciousness ==

==== '''Psi-Consciousness Interaction Equation''': ====
<math>\nabla \cdot (\Psi \vec{E}) - \nabla \cdot (\Psi \vec{B}) = -\frac{{\partial \Psi}}{{\partial t}} + \nabla^2 \Psi + \kappa \cdot C</math>
* This equation builds upon the concept of the psi energy density scalar field (<math>\Psi</math>) interacting with electromagnetic-like fields (<math>\vec{E}</math> and <math>\vec{B}</math>), as well as with consciousness (<math>C</math>).
** <math>\nabla \cdot (\Psi \vec{E})</math> and <math>\nabla \cdot (\Psi \vec{B})</math> describe the divergence of psi-induced electric and magnetic fields, respectively.
** <math>\frac{{\partial \Psi}}{{\partial t}}</math> represents the temporal evolution of the psi energy density scalar field.
** <math>\nabla^2 \Psi</math> represents the spatial distribution of psi energy density.
** <math>\kappa</math> is a constant representing the strength of interaction between psi phenomena and consciousness.
** <math>C</math> represents a measure of consciousness, which could be derived from neural activity patterns, information processing metrics, or other indicators of conscious awareness.

==== '''Psi Information Integration Equation''': ====
<math>\Phi = \int \left( \Phi^{\mathrm{max}}_{\mathrm{unc}} - \Phi^{\mathrm{max}} \right) P_O(o) \, do + \gamma \cdot I</math>
* This equation extends Integrated Information Theory (IIT) to incorporate psi-related information integration, where <math>\Phi</math> represents integrated information as in IIT.
** <math>\Phi^{\mathrm{max}}_{\mathrm{unc}}</math> and <math>\Phi^{\mathrm{max}}</math> represent the maximum integrated information in the absence of constraints and in the actual system, respectively.
** <math>P_O(o)</math> represents the probability distribution of system states, as in IIT.
** <math>\gamma</math> is a constant representing the degree to which psi-related information integration contributes to overall integrated information.
** <math>I</math> represents a measure of psi-related information integration, potentially derived from experimental data on psi phenomena or subjective reports of psi experiences.

==== '''Psi Neural Activation Equation''': ====
<math>\frac{\partial u(x, t)}{\partial t} = -u(x, t) + \int W(x - x') \, f(u(x', t)) \, dx' + \delta \cdot P</math>
* This equation extends neural field theory to incorporate the influence of psi phenomena on neural activation patterns.
** <math>u(x, t)</math> represents the activity of neural populations at position <math>x</math> and time <math>t</math>, as in the Wilson-Cowan model.
** <math>W(x - x')</math> represents the synaptic connectivity between neurons, as in the Wilson-Cowan model.
** <math>f(u(x', t))</math> represents the neural activation function, as in the Wilson-Cowan model.
** <math>\delta</math> is a constant representing the influence of psi phenomena on neural activation.
** <math>P</math> represents a measure of psi-related neural activation, potentially derived from neuroimaging data during psi tasks or experiments.



== Psi Field Equations ==



=== Psi Field Propagation Equation ===
<math>\nabla^2 \Psi - \frac{1}{c^2} \frac{\partial^2 \Psi}{\partial t^2} = k \rho_{\text{psi}}</math>
* Describes the propagation of psi energy or information through space.
* Represents spatial gradients of the Psi Field and its temporal evolution.
* <math>k</math> is a constant governing psi interactions, and <math>\rho_{\text{psi}}</math> represents the density of psi energy or information sources.

=== Psi Field-Matter Interaction Equation ===
<math>\nabla \cdot \mathbf{F}_{\text{psi}} = \rho_{\text{matter}}</math>
* Describes the interaction between the Psi Field (<math>\mathbf{F}_{\text{psi}}</math>) and conventional matter.
* Indicates that the divergence of the Psi Field flux is proportional to the density of matter sources (<math>\rho_{\text{matter}}</math>).

=== Psi Field Energy Density Equation ===
<math>\mathcal{E}_{\text{psi}} = \frac{1}{2} \Psi^2 + \frac{1}{2\mu_0} \mathbf{B}_{\text{psi}}^2</math>
* Calculates the energy density (<math>\mathcal{E}_{\text{psi}}</math>) of the Psi Field.
* <math>\Psi</math> represents the scalar psi field, and <math>\mathbf{B}_{\text{psi}}</math> represents the psi magnetic field.
* Accounts for both scalar psi energy and psi magnetic energy.

=== Psi Field Wave Equation ===
<math>\Box^2 \Psi - \frac{1}{c^2} \frac{\partial^2 \Psi}{\partial t^2} = 0</math>
* Describes the wave-like behavior of psi phenomena.
* <math>\Box^2</math> represents the d'Alembertian operator.
* Indicates that psi waves propagate at the speed of light (<math>c</math>).

=== Psi Field Entropy Equation ===
<math>S_{\text{psi}} = - k \sum_i P_i \log P_i</math>
* Calculates the entropy (<math>S_{\text{psi}}</math>) of the Psi Field.
* <math>P_i</math> represents the probability distribution of psi states.
* Quantifies the uncertainty or disorder in the Psi Field configuration, analogous to entropy in information theory.

== Contextual Psi Field Equations ==
=== Psi Field Equation Analogous to Electromagnetism ===
<math>
\begin{align}
\nabla \cdot \mathbf{E}_{\text{psi}} &= \frac{\rho_{\text{psi}}}{\varepsilon_0} \\
\nabla \cdot \mathbf{B}_{\text{psi}} &= 0 \\
\nabla \times \mathbf{E}_{\text{psi}} &= -\frac{\partial \mathbf{B}_{\text{psi}}}{\partial t} \\
\nabla \times \mathbf{B}_{\text{psi}} &= \mu_0 \mathbf{J}_{\text{psi}} + \mu_0 \varepsilon_0 \frac{\partial \mathbf{E}_{\text{psi}}}{\partial t}
\end{align}
</math>

* Description: These equations are analogous to Maxwell's equations for electromagnetism but describe the behavior of the Psi Field ( <math> \mathbf{E}_{\text{psi}}</math> and <math>\mathbf{B}_{\text{psi}} </math> ). The first equation represents Gauss's law for the Psi Field, stating that the divergence of the Psi electric field (<math>\mathbf{E}_{\text{psi}}</math>) is equal to the psi charge density (<math>\rho_{\text{psi}}</math>) divided by the vacuum permittivity (<math>\varepsilon_0</math>). The second equation states that the divergence of the Psi magnetic field (<math>\mathbf{B}_{\text{psi}}</math>) is zero, indicating no psi magnetic monopoles. The third equation represents Faraday's law of electromagnetic induction, stating that the curl of the Psi electric field is equal to the negative time rate of change of the Psi magnetic field. The fourth equation represents Ampère's law with Maxwell's addition, stating that the curl of the Psi magnetic field is equal to the sum of the Psi current density (<math>\mathbf{J}_{\text{psi}}</math>) and the time rate of change of the Psi electric field, scaled by the vacuum permeability (<math>\mu_0</math>) and vacuum permittivity (<math>\varepsilon_0</math>).
* <math>\nabla</math>: Nabla operator representing the gradient of a scalar field or the divergence of a vector field.
* <math>\mathbf{E}_{\text{psi}}</math>: Psi electric field vector.
* <math>\mathbf{B}_{\text{psi}}</math>: Psi magnetic field vector.
* <math>\rho_{\text{psi}}</math>: Psi charge density.
* <math>\varepsilon_0</math>: Vacuum permittivity.
* <math>\mu_0</math>: Vacuum permeability.
* <math>\mathbf{J}_{\text{psi}}</math>: Psi current density vector.

=== Psi Field Poynting Vector Equation ===
<math>
\mathbf{S}_{\text{psi}} = \frac{1}{\mu_0} \mathbf{E}_{\text{psi}} \times \mathbf{B}_{\text{psi}}
</math>
* Description: This equation calculates the Poynting vector (<math>\mathbf{S}_{\text{psi}}</math>) for the Psi Field, representing the directional energy flux density of psi energy. It's derived from the cross product of the Psi electric field (<math>\mathbf{E}_{\text{psi}}</math>) and magnetic field (<math>\mathbf{B}_{\text{psi}}</math>). The Poynting vector indicates the direction and magnitude of psi energy flow in space.
* <math>\mathbf{S}_{\text{psi}}</math>: Psi Poynting vector representing the directional energy flux density of the Psi Field.
* <math>\mathbf{E}_{\text{psi}}</math>: Psi electric field vector.
* <math>\mathbf{B}_{\text{psi}}</math>: Psi magnetic field vector.
* <math>\mu_0</math>: Vacuum permeability.

=== Psi Field Stress-Energy Tensor Equation ===
<math>
T^{\mu\nu}_{\text{psi}} = \varepsilon_{\text{psi}} c^2 u^\mu u^\nu + p_{\text{psi}} g^{\mu\nu}
</math>
* Description: This equation defines the stress-energy tensor (<math>T^{\mu\nu}_{\text{psi}}</math>) for the Psi Field, analogous to stress-energy tensors in general relativity. The first term represents the energy density (<math>\varepsilon_{\text{psi}}</math>) of the Psi Field, scaled by the speed of light squared (<math>c^2</math>) and the 4-velocity (<math>u^\mu</math>). The second term represents the pressure (<math>p_{\text{psi}}</math>) of the Psi Field, scaled by the metric tensor (<math>g^{\mu\nu}</math>). The stress-energy tensor describes the distribution of energy, momentum, and stress within the Psi Field.
* <math>T^{\mu\nu}_{\text{psi}}</math>: Psi stress-energy tensor.
* <math>\varepsilon_{\text{psi}}</math>: Psi energy density.
* <math>c</math>: Speed of light in vacuum.
* <math>u^\mu</math>: 4-velocity vector.
* <math>p_{\text{psi}}</math>: Psi pressure.
* <math>g^{\mu\nu}</math>: Metric tensor.

=== Psi Field Scalar Field Equation ===
<math>
\nabla^2 \Phi_{\text{psi}} = -\frac{\rho_{\text{psi}}}{\varepsilon_0}
</math>
* Description: This equation describes a scalar field (<math>\Phi_{\text{psi}}</math>) associated with the Psi Field. It relates the Laplacian of the scalar psi field to the psi charge density (<math>\rho_{\text{psi}}</math>), similar to how Poisson's equation relates the Laplacian of the gravitational potential to mass density. The equation describes the spatial variation of the psi scalar field in response to psi charge distributions.
* <math>\nabla^2</math>: Laplacian operator representing the divergence of the gradient of a scalar field.
* <math>\Phi_{\text{psi}}</math>: Psi scalar field.
* <math>\rho_{\text{psi}}</math>: Psi charge density.
* <math>\varepsilon_0</math>: Vacuum permittivity.