MHD Core: Difference between revisions
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* ''E'': Zero-point energy | * ''E'': Zero-point energy | ||
* ''\hbar'': Reduced Planck's constant | * ''<math>\hbar</math>'': Reduced Planck's constant | ||
* ''\omega'': Angular frequency | * ''<math>\omega</math>'': Angular frequency | ||
'''Casimir Effect Force Between Two Plates:''' | '''Casimir Effect Force Between Two Plates:''' | ||
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<math>\Gamma = \frac{\pi \omega_{\text{cavity}}^2}{3c^2} \left( \frac{\Delta L}{L} \right)^2</math> | <math>\Gamma = \frac{\pi \omega_{\text{cavity}}^2}{3c^2} \left( \frac{\Delta L}{L} \right)^2</math> | ||
* ''\Gamma'': Photon generation rate | * ''<math>\Gamma</math>'': Photon generation rate | ||
* ''\omega''<sub>cavity</sub>: Resonant frequency of the cavity | * ''<math>\omega</math>''<sub>cavity</sub>: Resonant frequency of the cavity | ||
* ''\Delta L'': Modulation amplitude of cavity length | * ''<math>\Delta L</math>'': Modulation amplitude of cavity length | ||
* ''L'': Original cavity length | * ''<math>L</math>'': Original cavity length | ||
'''Expectation Value of the Energy-Momentum Tensor:''' | '''Expectation Value of the Energy-Momentum Tensor:''' | ||
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<math>\nabla^2 \phi - \frac{1}{c^2} \frac{\partial^2 \phi}{\partial t^2} = -\frac{\rho}{\epsilon_0}</math> | <math>\nabla^2 \phi - \frac{1}{c^2} \frac{\partial^2 \phi}{\partial t^2} = -\frac{\rho}{\epsilon_0}</math> | ||
* ''\phi'': Scalar potential | * ''<math>\phi</math>'': Scalar potential | ||
* ''\rho'': Charge density | * ''<math>\rho</math>'': Charge density | ||
* ''\epsilon_0'': Vacuum permittivity | * ''<math>\epsilon_0</math>'': Vacuum permittivity | ||
'''Magnetic Flux Quantum:''' | '''Magnetic Flux Quantum:''' | ||
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<math>\Phi_0 = \frac{h}{2e}</math> | <math>\Phi_0 = \frac{h}{2e}</math> | ||
* ''\Phi''<sub>0</sub>: Magnetic flux quantum | * ''<math>\Phi</math>''<sub>0</sub>: Magnetic flux quantum | ||
* ''h'': Planck's constant | * ''h'': Planck's constant | ||
* ''e'': Elementary charge | * ''e'': Elementary charge | ||
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<math>\Phi = n \Phi_0</math> | <math>\Phi = n \Phi_0</math> | ||
* ''\Phi'': Magnetic flux through a superconducting loop | * ''<math>\Phi'': Magnetic flux through a superconducting loop | ||
* ''n'': Integer (quantum number) | * ''n'': Integer (quantum number) | ||
* ''\Phi''<sub>0</sub>: Magnetic flux quantum (\(\Phi_0 = \frac{h}{2e}\)) | * ''<math>\Phi''<sub>0</sub>: Magnetic flux quantum (\(\Phi_0 = \frac{h}{2e}\)) | ||
'''Energy Gap in Superconductors:''' | '''Energy Gap in Superconductors:''' |
Revision as of 09:51, 10 November 2024
Magneto Hydro Dynamic Core
A Levitation Power Core
Fundimental Technology for the operation of a Star Speeder and Magneto Speeder
https://github.com/Jthora/MHD-Core
MHD Core Project: Mathematical Equations and Data
This document compiles all the mathematical equations, values, and data discussed in the MHD Core project presentations.
Theoretical Foundations
Quantum Field Theorist's Equations
Zero-Point Energy of a Quantum Harmonic Oscillator:
- E: Zero-point energy
- : Reduced Planck's constant
- : Angular frequency
Casimir Effect Force Between Two Plates:
- FCasimir: Casimir force
- c: Speed of light
- A: Area of the plates
- L: Separation between the plates
Dynamic Casimir Effect Photon Generation Rate:
- : Photon generation rate
- cavity: Resonant frequency of the cavity
- : Modulation amplitude of cavity length
- : Original cavity length
Expectation Value of the Energy-Momentum Tensor:
- Tμν: Energy-momentum tensor
- gμν: Metric tensor of spacetime
Electromagnetic Field Specialist's Equations
Modified Wave Equation with Scalar Potential:
- : Scalar potential
- : Charge density
- : Vacuum permittivity
Magnetic Flux Quantum:
- 0: Magnetic flux quantum
- h: Planck's constant
- e: Elementary charge
Material Development
Superconducting Material Properties
Yttrium Barium Copper Oxide (YBCO):
- Critical Temperature (Tc): Approximately 92 K
- Critical Current Density (Jc): Exceeding \(1 \times 10^6\) A/cm² at 77 K
Barium Zirconate Nanoparticles Enhancement:
- Increase in Critical Current Density: 30% under high magnetic fields
Quantum Behaviors in Superconducting Materials
Cooper Pair Formation:
- Electrons form bound pairs enabling zero electrical resistance.
Flux Quantization Equation:
- Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \Phi'': Magnetic flux through a superconducting loop * ''n'': Integer (quantum number) * ''<math>\Phi''<sub>0</sub>: Magnetic flux quantum (\(\Phi_0 = \frac{h}{2e}\)) '''Energy Gap in Superconductors:''' <math>\Delta E = 2\Delta}
- \Delta E: Energy required to break a Cooper pair
- \Delta: Energy gap parameter
Engineering Design
Levitation System Equations
Magnetic Force Equation:
- \mathbf{F}mag: Magnetic force
- \mathbf{m}: Magnetic moment
- \mathbf{B}: Magnetic field
Electrostatic Force Equation:
- \mathbf{F}elec: Electrostatic force
- Q: Electric charge
- \mathbf{E}: Electric field
Control Systems and Simulations
Levitation Control Equations
State Equations:
- \mathbf{x}: Position vector
- \mathbf{v}: Velocity vector
- m: Mass of the core
- \mathbf{F}dist: Disturbance force
Cost Function for Nonlinear Model Predictive Control (NMPC):
- J: Cost function
- Tp: Prediction horizon
- \mathbf{x}ref: Reference position
- \mathbf{u}: Control input
- Q, R: Weighting matrices
Charge Regulation Equations
Sliding Surface Definition:
- s(t): Sliding surface
- e(t) = q_{\text{ref}}(t) - q(t): Charge error
- \lambda: Positive constant
Control Law:
- u(t): Control input
- k: Adaptive gain
- sign(s(t)): Sign function
Acoustic Integration
Hypersound Frequencies and Phonon Interactions
- Hypersound Frequency Range: Above 1 GHz
- Phonon-Electron Coupling: Interaction mechanism between high-frequency phonons and electrons in materials.
Environmental Alignment
Schumann Resonance Frequencies
Mode | Frequency (Hz) | Wavelength (km) |
---|---|---|
1 | ~7.83 | ~38,300 |
2 | ~14.3 | ~21,000 |
3 | ~20.8 | ~14,400 |
4 | ~27.3 | ~11,000 |
5 | ~33.8 | ~8,900 |
- Variability: Frequencies can shift by ±0.5 Hz due to ionospheric conditions.
Geomagnetic Pulsation Frequencies
Category | Frequency Range | Associated Phenomena |
---|---|---|
Pc1 | 0.2–5.0 Hz | Electromagnetic ion cyclotron waves |
Pc2 | 5–10 mHz | Field line resonances |
Pc3 | 10–45 mHz | Cavity modes in the magnetosphere |
Pc4 | 45–150 mHz | Large-scale magnetospheric oscillations |
Pc5 | 1–7 mHz | Solar wind coupling effects |
Mathematical Modeling
System Dynamics Equations
Core Motion Equations:
- \ddot{\mathbf{x}}: Acceleration
- \mathbf{I}: Coil currents
State-Space Representation:
- \boldsymbol{\theta}: Orientation angles
- \boldsymbol{\omega}: Angular velocities
- \boldsymbol{\tau}mag, \boldsymbol{\tau}elec: Magnetic and electrostatic torques
- \mathbf{I}: Moment of inertia tensor
Sliding Surface for Adaptive Sliding Mode Control (ASMC):
Control Law for ASMC:
Control Algorithms Parameters
Parameters Definitions:
- m: Mass of the core
- \mathbf{x}, \mathbf{v}: Position and velocity vectors
- \boldsymbol{\theta}, \boldsymbol{\omega}: Orientation and angular velocity vectors
- \mathbf{F}mag, \mathbf{F}elec: Magnetic and electrostatic forces
- \mathbf{F}dist: Disturbance forces
- \mathbf{I}: Moment of inertia tensor
- \boldsymbol{\tau}mag, \boldsymbol{\tau}elec: Magnetic and electrostatic torques
- e(t): Error signal
- \lambda: Positive constant for sliding surface
- k: Adaptive gain for control law
- \mathbf{u}(t): Control input vector
Key Constants and Physical Quantities
- Planck's Constant (h): \(6.62607015 \times 10^{-34}\) Js
- Reduced Planck's Constant (\hbar): \(\frac{h}{2\pi}\)
- Speed of Light (c): \(3.0 \times 10^8\) m/s
- Elementary Charge (e): \(1.602176634 \times 10^{-19}\) C
- Vacuum Permittivity (\epsilon_0): \(8.854187817 \times 10^{-12}\) F/m
This document compiles all the mathematical equations, values, and data relevant to the MHD Core project, providing a comprehensive reference for team members and stakeholders.