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15: Dynamic Systems

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    122661

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    • 15.1: Numerical Integration
      This page explains numerical integration, including methods like the Trapezoidal Rule and Simpson's Rule for approximating definite integrals when analytical solutions are unavailable. It highlights the scipy.integrate module in Python, which offers tools like quad and trapezoid for integration. Examples are provided to illustrate function integration using these methods, along with the related results and error estimates.
    • 15.2: Numerical Differentiation
      This page discusses numerical differentiation, which estimates derivatives from discrete data points. Key methods include Forward, Backward, and Central Difference, the latter being the most accurate. Proper selection of step size (h) is crucial, as large values cause truncation errors while small values can lead to round-off errors. The process is also sensitive to noise, necessitating careful data management.
    • 15.3: First-Order Differential Equations
      This page provides guidance on solving first-order ordinary differential equation (ODE) initial value problems (IVPs) using Python. It emphasizes the significance of initial conditions and presents methods available via Python libraries like SciPy for numerical solutions and SymPy for analytical solutions. The document explains the use of `solve_ivp` for numerical solutions and `dsolve` for symbolic solutions, highlighting considerations for accuracy and stability.
    • 15.4: Higher-Order Differential Equations
      This page details solving initial value problems for higher-order ordinary differential equations (ODEs) in Python using the SciPy library. It outlines the process of reducing higher-order ODEs to first-order systems, establishing initial conditions, and employing the `solve_ivp` function for numerical solutions. The document also covers visualizing results, showcasing Python's effectiveness in addressing these problems in scientific and engineering contexts.
    • 15.5: Summary
      This page discusses the importance of numerical methods in scientific computing for solving complex mathematical problems, including integration, differentiation, and ordinary differential equations (ODEs). It highlights techniques like numerical integration using the trapezoidal and Simpson's rules, and differentiation through finite differences.

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