Stokes theorem

The Stokes theorem relates the line integral of a closed curve C in a vector field F to the surface integral of the curl of F over the boundary of the surfa...

The Stokes theorem relates the line integral of a closed curve C in a vector field F to the surface integral of the curl of F over the boundary of the surface.

Formally, if F is a continuous vector field on a closed surface S, then the Stokes theorem establishes the following equality:

∫_C F · ds = ∫_S (∇ × F) · dS,

where:

ds is the differential of the curve C in the plane.
dS is the surface element of the boundary S.
∇ is the gradient operator, represented by a nabla symbol.
F is the vector field.
∇ × F is the curl of the vector field, represented by a cross product symbol.

The Stokes theorem tells us that the line integral of a closed curve C in a vector field F is equal to the surface integral of the curl of F over the boundary of the surface. This theorem allows us to evaluate surface integrals of vector fields by evaluating line integrals of simpler curves

The Stokes theorem relates the line integral of a closed curve C in a vector field F to the surface integral of the curl of F over the boundary of the surface.

Formally, if F is a continuous vector field on a closed surface S, then the Stokes theorem establishes the following equality:

∫_C F · ds = ∫_S (∇ × F) · dS,

where:

ds is the differential of the curve C in the plane.
dS is the surface element of the boundary S.
∇ is the gradient operator, represented by a nabla symbol.
F is the vector field.
∇ × F is the curl of the vector field, represented by a cross product symbol.

Stokes theorem

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