Poisson's and Laplace's equation

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    Laplace's equation
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SUMMARY

Poisson's and Laplace's equations are fundamental in electrostatics, derived using Gauss's law. Solutions to Laplace's equation are termed harmonic functions, which are analytic within their domain. The principle of superposition allows for the construction of complex solutions by summing simpler ones. This relationship highlights the regularity of Laplace's equation solutions compared to those of the wave equation.

PREREQUISITES
  • Understanding of Gauss's law in electrostatics
  • Familiarity with differential equations, specifically linear homogeneous types
  • Knowledge of harmonic functions and their properties
  • Basic concepts of analytic functions and power series expansion
NEXT STEPS
  • Study the derivation of Poisson's equation from Gauss's law
  • Explore the applications of harmonic functions in physics
  • Learn about the principle of superposition in linear systems
  • Investigate the differences between solutions of Laplace's and wave equations
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Physicists, electrical engineers, and students studying electrostatics and mathematical physics will benefit from this discussion.

roshan2004
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We can easily derive Poisson's and Laplace's equations in electrostatics by using Gauss's law. However, my question is what are the importance of these equations in Electrostatics ?
 
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Solutions of Laplace's equation are called harmonic functions; they are all analytic within the domain where the equation is satisfied. If any two functions are solutions to Laplace's equation (or any linear homogeneous differential equation), their sum (or any linear combination) is also a solution. This property, called the principle of superposition, is very useful, e.g., solutions to complex problems can be constructed by summing simple solutions.


<br /> <br /> \nabla ^{2} V = 0 <br /> <br />

So


The close connection between the Laplace equation and analytic functions implies that any solution of the Laplace equation has derivatives of all orders, and can be expanded in a power series, at least inside a circle that does not enclose a singularity. This is in sharp contrast to solutions of the wave equation, which generally have less regularity.


http://en.wikipedia.org/wiki/Laplace's_equation
 

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