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Physics
Applied and Interdisciplinary Physics
Computational Physics
1. Introduction to Computational Physics
2. Mathematical Foundations
3. Programming Fundamentals
4. Computer Arithmetic and Error Analysis
5. Root Finding Methods
6. Numerical Differentiation
7. Numerical Integration
8. Linear Systems
9. Eigenvalue Problems
10. Ordinary Differential Equations
11. Partial Differential Equations
12. Monte Carlo Methods
13. Molecular Dynamics
14. Data Analysis and Visualization
15. Applications in Classical Mechanics
16. Applications in Electromagnetism
17. Applications in Quantum Mechanics
18. Applications in Statistical Mechanics
19. Applications in Fluid Dynamics
20. High-Performance Computing
15.
Applications in Classical Mechanics
15.1.
Single Particle Dynamics
15.1.1.
Projectile Motion
15.1.2.
Oscillatory Motion
15.1.3.
Central Force Problems
15.2.
Many-Body Systems
15.2.1.
N-Body Problem
15.2.2.
Gravitational Systems
15.2.3.
Solar System Dynamics
15.3.
Rigid Body Dynamics
15.3.1.
Rotation Matrices
15.3.2.
Euler Angles
15.3.3.
Quaternions
15.4.
Chaotic Systems
15.4.1.
Lorenz System
15.4.2.
Double Pendulum
15.4.3.
Lyapunov Exponents
15.4.4.
Poincaré Sections
15.5.
Celestial Mechanics
15.5.1.
Orbital Mechanics
15.5.2.
Perturbation Theory
15.5.3.
Asteroid Dynamics
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14. Data Analysis and Visualization
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16. Applications in Electromagnetism