Lectures related to Dynamics of Discrete Systems

Stellar Orbits: Integrals of Motion and Phase Space Visualization

Covers integrals of motion and surfaces of section in stellar dynamics.

Space Mission Design: Starship Test and Rendezvous Techniques

Discusses SpaceX's Starship test flight and the principles of rendezvous in space missions.

Explores the Eigenstate Thermalization Hypothesis in quantum systems, emphasizing the random matrix theory and the behavior of observables in thermal equilibrium.

Quantum Chemistry

Covers Quantum Chemistry topics like SP Hybridization and orbital conservation.

Introduction to Dynamical System Theory

Introduces dynamical system theory for engineers, covering trajectories, orbits, and solutions.

Private Space Missions to ISS

Covers private space missions to the ISS, including future plans, nodal regression, Sun-synchronous orbits, and rendezvous strategies.

Kepler's Laws and Orbital Mechanics

Explores Kepler's laws, orbital mechanics, energy of motion, flight path angles, orbital maneuvers, Hohmann transfers, geostationary orbits, and Lagrange points.

State Space Control: Discrete Systems

Explores the shift from continuous to discrete control systems, focusing on the challenges and benefits of digital implementation.

Elliptical Orbits: Examples and Formulas

Covers examples and formulas related to elliptical orbits and how to determine parameters of an elliptical orbit using known points.

Crew-7 Return and Space Mission Design Overview

Discusses Crew-7's return from the ISS and key principles of space mission design.

Interplanetary Trajectories: Concepts and Strategies

Explores interplanetary trajectories, including departure strategies, sphere of influence, and orbit insertion around the destination planet.

Dynamical Systems: Equilibrium Points and Stability

Covers dynamical systems, equilibrium points, stability analysis, and phase plots using examples like the pendulum system.

State-space Modeling

Introduces the state-space approach to modeling dynamical systems and its utility for high-speed solution of differential equations and computer algorithms.

Introduction to Quantum Chaos

Covers the introduction to Quantum Chaos, classical chaos, sensitivity to initial conditions, ergodicity, and Lyapunov exponents.

Chaos Theory: Turbulence and Double Pendulum

Delves into Chaos Theory, exploring chaotic systems, sensitivity to initial conditions, and the dynamics of the double pendulum.

Multivariable Control: System Theory and Linear Systems

Introduces the basics of multivariable control, focusing on system theory and linear systems.

Basic Notions, Ch III: Group Actions

Explores group actions on sets, orbits, fixed points, and classic results.

Galaxy Disk Models: Orbits and Potentials

Explores galaxy disk models, orbits, potentials, and circular velocity in disk galaxies.

Nonlinear Dynamics: Homoclinic Orbits and Bifurcations

Delves into homoclinic orbits, bifurcations, and limit cycles in nonlinear dynamics.

Quantum Chemistry: Molecular Orbital Theory

Covers the fundamentals of quantum chemistry, focusing on molecular orbital theory and conservation of orbital equivalence.