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Related Concept Videos

Differential Equations: Problem Solving01:21

Differential Equations: Problem Solving

102
When analyzing the motion of falling objects, it is essential to consider not only the force of gravity but also the opposing force of air resistance. A practical example involves releasing a heavy test weight during a safety check on a ship. As the weight falls from rest, gravity accelerates it downward while air resistance exerts an upward force that increases with velocity. This dynamic interplay of forces is well described by differential equations, which provide a mathematical framework...
102
Modeling with Differential Equations01:25

Modeling with Differential Equations

137
Population dynamics can be described mathematically by considering the population size P(t) as a function of time. The rate of change of the population is then represented by the derivative of P(t). A simple assumption is that the rate of growth is proportional to the size of the population itself. This leads to an exponential growth model, where the population increases rapidly without bound. While this is a useful first approximation, it does not reflect realistic long-term...
137
State Function, Exact and Inexact Differentials01:27

State Function, Exact and Inexact Differentials

28
A state function is a thermodynamic property that depends solely on the current state of a system, irrespective of its history or how it arrived at that state. These functions are represented by capital letters, such as U, H, and S, which stand for internal energy, enthalpy, and entropy, respectively.For instance, the value of internal energy depends on the system's state variables and remains unaffected by the process path. This means that whether the system underwent a linear process or a...
28
Linear Differential Equations01:27

Linear Differential Equations

129
The integrating factor method provides a systematic way to solve first-order linear differential equations, especially those that cannot be handled by separation of variables. This method is particularly useful in modeling time-dependent physical systems influenced by both constant inputs and resistive forces. A common example is the motion of a car subjected to a constant engine force while experiencing air resistance proportional to its velocity.In such scenarios, Newton’s second law...
129
Mechanistic Models: Compartment Models in Algorithms for Numerical Problem Solving01:29

Mechanistic Models: Compartment Models in Algorithms for Numerical Problem Solving

376
Mechanistic models play a crucial role in algorithms for numerical problem-solving, particularly in nonlinear mixed effects modeling (NMEM). These models aim to minimize specific objective functions by evaluating various parameter estimates, leading to the development of systematic algorithms. In some cases, linearization techniques approximate the model using linear equations.
In individual population analyses, different algorithms are employed, such as Cauchy's method, which uses a...
376
Separable Differential Equations01:20

Separable Differential Equations

173
A separable differential equation is a type of first-order differential equation where the derivative dy/dx can be expressed as a product of two functions: one that depends only on x and another that depends only on y. This allows for the rearrangement of the equation so that all terms involving y are on one side, and all terms involving x are on the other. This process, known as the separation of variables, simplifies the process of solving the equation by enabling the integration of both...
173

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Related Experiment Videos

Learning partial differential equations via data discovery and sparse optimization.

Hayden Schaeffer1

  • 1Department of Mathematics , Carnegie Mellon University , Pittsburgh, PA, USA.

Proceedings. Mathematical, Physical, and Engineering Sciences
|March 8, 2017
PubMed
Summary
This summary is machine-generated.

This study introduces a novel algorithm for learning evolution equations from data, identifying partial differential equation terms and coefficients using sparse optimization. The method demonstrates robustness to noisy data and varying data sizes across diverse scientific applications.

Keywords:
feature selectionmachine learningparameter estimationpartial differential equationssparse optimization

Related Experiment Videos

Area of Science:

  • Scientific Machine Learning
  • Applied Mathematics
  • Data-Driven Science

Background:

  • Identifying governing equations from observational data is a fundamental challenge in science.
  • Traditional methods often require prior knowledge of equation structure.
  • Developing automated methods for equation discovery is crucial for advancing scientific understanding.

Purpose of the Study:

  • To develop a data-driven algorithm for learning evolution equations, including identifying partial differential equation (PDE) terms and approximating their coefficients.
  • To enable the discovery of underlying physical laws directly from experimental or simulation data.
  • To provide a robust and versatile tool for scientific modeling.

Main Methods:

  • A novel learning algorithm employing sparse optimization for feature selection and parameter estimation.
  • Data-driven feature construction using nonlinear algebraic equations on spatial derivatives of the data.
  • Application of the algorithm to various complex systems including shock equations, pattern formation, fluid dynamics, and oscillatory convection.

Main Results:

  • The algorithm successfully identifies terms and approximates coefficients of underlying PDEs using only data.
  • Demonstrated robustness to data noise and varying data sizes.
  • Validated capability in capturing true data features and enabling further analytical insights.
  • Successful application across diverse scientific domains, showcasing broad applicability.

Conclusions:

  • The proposed sparse optimization-based algorithm offers a powerful, data-driven approach to learning evolution equations.
  • This method advances the field of scientific machine learning by automating the discovery of physical laws.
  • The algorithm's robustness and versatility make it a valuable tool for scientific research and discovery.