Leray projection explained

The Leray projection, named after Jean Leray, is a linear operator used in the theory of partial differential equations, specifically in the fields of fluid dynamics. Informally, it can be seen as the projection on the divergence-free vector fields. It is used in particular to eliminate both the pressure term and the divergence-free term in the Stokes equations and Navier–Stokes equations.

Definition

By pseudo-differential approach^[1]

For vector fields

(in any dimension

n\geq2

), the Leray projection

is defined by

P(u)=u-\nabla\Delta^-1(\nabla ⋅ u).

This definition must be understood in the sense of pseudo-differential operators: its matrix valued Fourier multiplier

m(\xi)

is given by

m(\xi)_kj=\delta_kj-

	\xi_k\xi_j
	\vert\xi\vert²

, 1\leqk,j\leqn.

Here,

\delta

is the Kronecker delta. Formally, it means that for all

u\inlS(\Rⁿ⁾ⁿ

, one has

P(u)_k(x)=

	1
	(2\pi)^n/2

\int
	\Rⁿ

\left(\delta_kj-

	\xi_k\xi_j
	\vert\xi\vert²

\right)\widehat{u}_j(\xi)eⁱd\xi, 1\leqk\leqn

where

lS(\Rⁿ⁾

is the Schwartz space. We use here the Einstein notation for the summation.

By Helmholtz–Leray decomposition^[2]

One can show that a given vector field

can be decomposed as

u=\nablaq+v, with \nabla ⋅ v=0.

Different than the usual Helmholtz decomposition, theHelmholtz–Leray decomposition of

is unique (up to anadditive constant for

). Then we can define

P(u)

P(u)=v.

The Leray projector is defined similarly on function spaces other than the Schwartz space, and on different domains with different boundary conditions. The four properties listed below will continue to hold in those cases.

Properties

The Leray projection has the following properties:

The Leray projection is a projection:

P[P(u)]=P(u)

for all

u\inlS(\Rⁿ⁾ⁿ

The Leray projection is a divergence-free operator:

\nabla ⋅ [P(u)]=0

for all

u\inlS(\Rⁿ⁾ⁿ

The Leray projection is simply the identity for the divergence-free vector fields:

P(u)=u

for all

u\inlS(\Rⁿ⁾ⁿ

such that

\nabla ⋅ u=0

The Leray projection vanishes for the vector fields coming from a potential:

P(\nabla\phi)=0

for all

\phi\inlS(\Rⁿ⁾

Application to Navier–Stokes equations

The incompressible Navier–Stokes equations are the partial differential equations given by

	\partialu
	\partialt

-\nu\Deltau+(u ⋅ \nabla)u+\nablap=f

\nabla ⋅ u=0

where

is the velocity of the fluid,

the pressure,

\nu>0

the viscosity and

the external volumetric force.

By applying the Leray projection to the first equation, we may rewrite the Navier-Stokes equations as an abstract differential equation on an infinite dimensional phase space, such as

C^0\left(0,T;L^{2(\Omega)\right)}

, the space of continuous functions from

[0,T]

L^2(\Omega)

where

T>0

and

L^2(\Omega)

is the space of square-integrable functions on the physical domain

\Omega

:^[3]

	du
	dt

+\nuAu+B(u,u)=P(f)

where we have defined the Stokes operator

and the bilinear form

Au=-P(\Deltau) B(u,v)=P[(u ⋅ \nabla)v].

The pressure and the divergence free condition are "projected away". In general, we assume for simplicity that

is divergence free, so that

{P}({f})={f}

; this can always be done, by adding the term

f-P(f)

to the pressure.

Notes and References

Book: Temam, Roger. Navier-Stokes equations : theory and numerical analysis. 2001. AMS Chelsea Pub. 978-0-8218-2737-6. Providence, R.I.. 45505937.
Book: Foias. Ciprian. Navier-Stokes equations and turbulence. Manley. Rosa. Temam. Roger. 2001. Cambridge University Press. 0-511-03936-0. Cambridge. 37–38,49. 56416088.
Book: Constantin. Peter. Navier-Stokes equations. Foias. Ciprian. 1988. 0-226-11548-8. Chicago. 18290660.

Leray projection explained

Definition

By pseudo-differential approach[1]

By Helmholtz–Leray decomposition[2]

Properties

Application to Navier–Stokes equations

Notes and References

By pseudo-differential approach^[1]

By Helmholtz–Leray decomposition^[2]