In mathematics, the Dirichlet boundary condition is imposed on an ordinary or partial differential equation, such that the values that the solution takes along the boundary of the domain are fixed. The question of finding solutions to such equations is known as the Dirichlet problem. In the sciences and engineering, a Dirichlet boundary condition may also be referred to as a fixed boundary condition or boundary condition of the first type. It is named after Peter Gustav Lejeune Dirichlet (1805–1859).[1]
In finite-element analysis, the essential or Dirichlet boundary condition is defined by weighted-integral form of a differential equation.[2] The dependent unknown u in the same form as the weight function w appearing in the boundary expression is termed a primary variable, and its specification constitutes the essential or Dirichlet boundary condition.
Examples
editODE
editFor an ordinary differential equation, for instance, the Dirichlet boundary conditions on the interval [a,b] take the form where α and β are given numbers.
PDE
editFor a partial differential equation, for example, where denotes the Laplace operator, the Dirichlet boundary conditions on a domain Ω ⊂ Rn take the form where f is a known function defined on the boundary ∂Ω.
Applications
editFor example, the following would be considered Dirichlet boundary conditions:
- In mechanical engineering and civil engineering (beam theory), where one end of a beam is held at a fixed position in space.
- In heat transfer, where a surface is held at a fixed temperature.
- In electrostatics, where a node of a circuit is held at a fixed voltage.
- In fluid dynamics, the no-slip condition for viscous fluids states that at a solid boundary, the fluid will have zero velocity relative to the boundary.
Other boundary conditions
editMany other boundary conditions are possible, including the Cauchy boundary condition and the mixed boundary condition. The latter is a combination of the Dirichlet and Neumann conditions.
See also
editReferences
edit- ^ Cheng, A.; Cheng, D. T. (2005). "Heritage and early history of the boundary element method". Engineering Analysis with Boundary Elements. 29 (3): 268–302. doi:10.1016/j.enganabound.2004.12.001.
- ^ Reddy, J. N. (2009). "Second order differential equations in one dimension: Finite element models". An Introduction to the Finite Element Method (3rd ed.). Boston: McGraw-Hill. p. 110. ISBN 978-0-07-126761-8.