Notation and Units
Complete Symbol Reference for Planck Core Thermodynamics
Primary Thermodynamic Quantities
| Symbol |
Name |
Units |
Dimensions |
Definition |
| sigma_theta |
Drift Scalar / Entropy Production |
s^-1 |
T^-1 |
sigma_theta = D(1 – L) |
| T_ITT |
ITT Temperature |
K |
Theta |
T_ITT = T_0 * sigma_theta |
| S_theta |
Recursive Entropy |
J/K |
ML^2 T^-2 Theta^-1 |
S_theta = integral k_sigma sigma_theta d_tau |
| S_theta_max |
Maximum Entropy |
J/K |
ML^2 T^-2 Theta^-1 |
S_theta_max = n_max * ell_P^2 * N_folds |
Drift-Lock Components
| Symbol |
Name |
Units |
Range |
Definition |
| D |
Drift Magnitude |
s^-1 |
[0, infinity) |
Rate of glyph field evolution |
| L |
Shell-Lock |
— |
[0, 1] |
Recursive stability coefficient |
| 1 – L |
Unlock Factor |
— |
[0, 1] |
Fraction available for drift |
Drift Magnitude Expansion
D(x, t) = alpha_M ||dM_ij/dt||_F + alpha_Phi ||d(grad Phi)/dt||_2
Shell-Lock Definition
L(x, t) = <C(x,t), C_ref(x)> / (||C|| * ||C_ref||)
Glyph Field Stack
| Symbol |
Name |
Type |
Units |
Role |
| Phi |
Intent Potential |
Scalar field |
— |
Latent permission field |
| F_i = d_i Phi |
Intent Gradient |
Vector field |
L^-1 |
Directional intent |
| C_i |
Curvent |
Vector field |
L^-1 |
Recursive fold direction |
| M_ij |
Memory Tensor |
Rank-2 tensor |
L^2 |
Coherence structure |
| Psi |
Field Stack |
Tuple |
— |
{Phi, F_i, C_i, M_ij} |
Dilation and Alignment
| Symbol |
Name |
Units |
Range |
Definition |
| gamma_ITT |
Dilation Factor |
— |
(0, 1] |
gamma = sqrt(1 – A^2 * mu) |
| A |
Alignment Functional |
— |
[0, 1] |
Substrate load fraction |
| Tr(M) |
Memory Trace |
L^2 |
[0, infinity) |
Total memory load |
| mu |
Memory Saturation |
— |
[0, 1] |
Tr(M)/Tr(M)_max |
Recursion Parameters
| Symbol |
Name |
Units |
Range |
Description |
| n |
Recursion Index |
— |
Z+ union |
Current recursive depth |
| n_max |
Maximum Recursion |
— |
(0, infinity) |
Computational ceiling |
| tau |
Recursion Parameter |
s |
[0, infinity) |
Continuous recursion time |
| t_P |
Planck Time |
s |
— |
5.391 x 10^-44 s |
| R_hat |
Recursive Operator |
— |
— |
Psi_{n+1} = R_hat(Psi_n) |
Fundamental Constants
| Symbol |
Name |
Value |
Units |
| hbar |
Reduced Planck constant |
1.055 x 10^-34 |
J*s |
| G |
Gravitational constant |
6.674 x 10^-11 |
m^3/(kg*s^2) |
| c |
Speed of light |
2.998 x 10^8 |
m/s |
| k_B |
Boltzmann constant |
1.381 x 10^-23 |
J/K |
| t_P |
Planck time |
5.391 x 10^-44 |
s |
| ell_P |
Planck length |
1.616 x 10^-35 |
m |
| m_P |
Planck mass |
2.176 x 10^-8 |
kg |
| E_P |
Planck energy |
1.956 x 10^9 |
J |
| T_P |
Planck temperature |
1.417 x 10^32 |
K |
Coupling Constants
| Symbol |
Name |
Units |
Role |
| alpha_M |
Memory Coupling |
— |
Weight of d_t M in drift |
| alpha_Phi |
Intent Coupling |
— |
Weight of d_t grad Phi in drift |
| k_sigma |
Entropy Coupling |
J/(K*s^-1) |
dS/d_tau = k_sigma sigma_theta |
| T_0 |
Reference Temperature |
K |
T_ITT = T_0 sigma_theta |
Black Hole / Planck Core Quantities
| Symbol |
Name |
Units |
Definition |
| M |
Mass |
kg |
Total gravitational mass |
| r_s |
Schwarzschild radius |
m |
r_s = 2GM/c^2 |
| r_PC |
Planck Core radius |
m |
r_PC ~ sqrt(n_max) * ell_P |
| A |
Horizon area |
m^2 |
A = 4 pi r_s^2 |
| T_H |
Hawking temperature |
K |
T_H = hbar c^3 / (8 pi G M k_B) |
| N_folds |
Fold site count |
— |
Resolution-dependent info sites |
Core Equations
The Master Equation: Entropy Production
sigma_theta = D(1 - L)
ITT Temperature
T_ITT = T_0 * sigma_theta
Planck-Lock Condition
L = 1 => sigma_theta = 0 => T_ITT = 0
ITT Entropy Bound
S_theta_max = n_max * ell_P^2 * N_folds
LOAD Identity
gamma_ITT = sqrt(1 - A^2 * Tr(M)/Tr(M)_max)
Bekenstein-Hawking Entropy (GR)
S_BH = k_B c^3 A / (4 G hbar) = k_B A / (4 ell_P^2)
Hawking Temperature (GR)
T_H = hbar c^3 / (8 pi G M k_B)
Norms and Operators
| Notation |
Name |
Definition |
Application |
|
|
v |
|
|
|
A |
|
|
Inner product |
sum_i u_i v_i |
Dot product |
| Tr(*) |
Trace |
sum_i A_ii |
Sum of diagonal |
| d_i |
Spatial derivative |
d/dx_i |
i in |
| d_t |
Time derivative |
d/dt |
With respect to tau |
| grad |
Gradient |
(d_1, d_2, d_3) |
Spatial gradient |
Index Conventions
| Index Type |
Symbols |
Range |
Usage |
| Spatial |
i, j, k |
{1, 2, 3} |
Vector/tensor components |
| Recursion |
n, m |
Z+ union |
Discrete state labels |
| Summation |
— |
— |
Einstein convention (repeated indices summed) |
Dimensional Analysis
Key Dimensional Checks
| Equation |
Dimensional Analysis |
| sigma_theta = D(1-L) |
T^-1 = T^-1 * 1 |
| T = T_0 sigma_theta |
Theta = Theta * T^-1 * T = Theta |
| S = n_max ell_P^2 N |
ML^2 T^-2 Theta^-1 (with k_B) |
| gamma = sqrt(1 – A^2 mu) |
1 = sqrt(1) |
| t_P = sqrt(hbar G / c^5) |
s = sqrt(Js * m^3/(kgs^2) / (m/s)^5) |
Unit Systems
SI Units (Default)
All equations in this documentation use SI units unless otherwise specified.
Planck Units (hbar = c = G = k_B = 1)
In Planck units: t_P = 1, ell_P = 1, E_P = 1, T_P = 1
Simplifies equations but obscures physical magnitudes.
Geometrized Units (c = G = 1)
Common in general relativity. Length and time have same units.
Quick Reference Card
| Quantity |
Symbol |
Key Equation |
| Entropy Production |
sigma_theta |
= D(1-L) |
| Temperature |
T_ITT |
= T_0 sigma_theta |
| Maximum Entropy |
S_theta_max |
= n_max ell_P^2 N_folds |
| Dilation Factor |
gamma_ITT |
= sqrt(1 – A^2 mu) |
| Planck-Lock |
— |
L = 1 implies T = 0 |
| Hawking Temp (GR) |
T_H |
= hbar c^3 / (8 pi G M k_B) |
| BH Entropy (GR) |
S_BH |
= k_B A / (4 ell_P^2) |
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