Differential operator
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In mathematics, a differential operator is a linear operator defined as a function of the differentiation operator. It is helpful, as a matter of notation first, to consider differentiation as an abstract operation, accepting a function and returning another (in the style of a higher-order function in computer science).
Notations
The most commonly used differential operator is the action of taking the derivative itself. Common notations for this operator include:
- []
- [D,\,] where the variable one is differentiating to is clear, and
- [D_x,\,] where the variable is declared explicitly.
- [d^n \over dx^n]
- [D^n\,]
- [D^n_x.\,]
- [\sum_^n c_k D^k]
One of the most frequently seen differential operators is the Laplacian operator, defined by
- [\Delta=\nabla^=\sum_^n .]
- [\Theta = z .]
Adjoint of an operator
Given a linear differential operator
- [Tu = \sum_^n a_k(x) D^k u]
- [\langle u,Tv \rangle = \langle T^*u, v \rangle]
- [\langle f, g \rangle = \int_a^b \overline \, g(x) \,dx. ]
- [T^*u = \sum_^n (-1)^k D^k [a_k(x)u]].
A self-adjoint operator is an operator adjoint of itself.
The Sturm-Liouville operator is a well-known example of formal self-adjoint operator. This second order linear differential operators L can be written in the form
- [Lu = -(pu')'+qu=-(pu+p'u')+qu=-pu-p'u'+qu=(-p) D^2 u +(-p') D u + (q)u\;\!]
- [\beginL^*u &=& (-1)^2 D^2 [(-p)u] + (-1)^1 D [(-p')u] + (-1)^0 (qu) \\ &=& -D^2(pu) + D(p'u)+qu \\ &=& -(pu)+(p'u)'+qu \\ &=& -pu-2p'u'-pu+pu+p'u'+qu \\ &=& -p'u'-pu''+qu \\ &=& -(pu')'+qu &=& Lu\\\end]
Properties of differential operators
Differentiation is linear, i.e.,
- [D (f+g) = (Df) + (Dg)]
- [D (af) = a (Df)]
Any polynomial in D with function coefficients is also a differential operator. We may also compose differential operators by the rule
- (D1oD2)(f) = D1 [D2(f)].
- Dx − xD = 1.
Several variables
The same constructions can be carried out with partial derivatives, differentiation with respect to different variables giving rise to operators that commute (see symmetry of second derivatives).
Coordinate-independent description
In differential geometry and algebraic geometry it is often convenient to have a coordinate-independent description of differential operators between two vector bundles. Let E and F be two vector bundles over a manifold M. An operator is a mapping of sections, P: Γ(E) → Γ(F) which maps the stalk of the sheaf of germs of Γ(E) at a point x ∈ M to the fibre of F at x:
- Γx(E) → Fx .
- iP : Jk(E) → F
- P : Γx(E) → Jk(E)x → Fx .
Examples
- In applications to the physical sciences, operators such as the Laplace operator play a major role in setting up and solving partial differential equations.
- In differential topology the exterior derivative and Lie derivative operators have intrinsic meaning.
- In abstract algebra, the concept of a derivation allows for generalizations of differential operators which do not require the use of calculus. Frequently such generalizations are employed in algebraic geometry and commutative algebra. See also jet (algebraic geometry).
See also
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