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×B

×B is the notation often used to indicate the cross product with the vector B, a standard operation in three-dimensional vector mathematics and physics. When A × B is formed, A and B are vectors in three-dimensional space, and the result is a vector perpendicular to the plane containing A and B. The expression ×B can also denote the linear operator that maps any vector v to v × B.

Mathematically, the cross product with B can be represented by a matrix acting on v. If B

Key properties include bilinearity and antisymmetry: for vectors u, v and scalar α, (αu) × B = α(u

Applications of ×B appear in physics and engineering, such as the Lorentz force F = q(v × B)

Example: with B = (1, 2, 3) and v = (4, 5, 6), v × B = (3, −6, 3).

=
(B_x,
B_y,
B_z),
the
operator
is
given
by
the
skew-symmetric
matrix
[B]_×
=
[[0,
-B_z,
B_y],
[B_z,
0,
-B_x],
[-B_y,
B_x,
0]].
Then
v
×
B
=
[B]_×
v.
This
matrix
form
makes
the
operator
linear
in
v
and
highlights
its
skew-symmetric
nature.
×
B)
and
u
×
(αB)
=
α(u
×
B),
with
u
×
B
=
−(B
×
u).
The
cross
product
is
orthogonal
to
both
operands,
and
its
magnitude
satisfies
|u
×
B|
=
|u||B|sinθ,
where
θ
is
the
angle
between
u
and
B.
If
u
is
parallel
to
B,
then
u
×
B
=
0.
In
three
dimensions,
many
identities
involving
cross
products
hold,
though
generalizations
exist
in
higher
dimensions.
and
in
describing
rotational
motion
and
gyroscopic
effects.
It
also
appears
in
vector
calculus
and
electromagnetism,
where
cross
products
with
field
vectors
are
common.
See
also
cross
product,
skew-symmetric
matrix,
and
Lorentz
force.