Vector Fields Click here for discussion of conservative vector fields.
In a Nut Shell: Functions that assign vectors in a plane or in space are termed
vector fields. You are familiar with vectors such as the unit vectors i, j, k along
the x, y, and z-axes.
A vector field in a plane takes the form F(x,y) = P(x,y) i + Q(x,y) j where
P(x,y) and Q(x,y) are scalar fields. (scalar function). Here P(x,y) is the component
of F(x,y) in the x-direction and Q(x,y) is the component of F(x,y) in the y-direction.
A vector field can also be defined by a vector valued function at each point (x,y,z)
in space such as
F(x, y, z) = P(x,y,z) i + Q(x,y,z) j + R(x,y,z) k
where P(x,y,z), Q(x,y,z), and R(x,yz) are scalar fields (scalar function)
There are several theorems dealing with vector fields that are important in your
study of multi-variable calculus. So it is important that you understand and
can work with vector fields.
The Gradient of a scalar field, Grad F, is defined as follows:
in a plane Grad F = ∂F/∂x i + ∂F/∂y j
in space Grad F = ∂F/∂x i + ∂F/∂y j + ∂F/∂z k
Definition of the Divergence of a Vector Field, F , div F
in a plane F(x, y, z) = P(x,y,z) i + Q(x,y,z)
div F = ∂P/∂x i + ∂Q/∂y j
in space F(x, y, z) = P(x,y,z) i + Q(x,y,z) j + R(x,y,z) k
div F = ∂P/∂x i + ∂Q/∂y j + ∂R/∂z k
Click here to continue discussion of vector fields.
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