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oppositeparallel

Oppositeparallel is a term used in geometry to describe a specific relation between two straight lines that are parallel but oriented in opposite directions, when considering an oriented-line model. In this context, a line is given not only by its locus of points but also by a chosen direction along which it is traversed. Two lines are called oppositeparallel if they share the same direction up to a sign change and are not the same line.

Formal definition (oriented lines). Let L1 be the oriented line through a point p1 with direction vector

Properties. Oppositeparallel lines are parallel in the usual geometric sense and have a constant separation along

Examples. Consider L1 as the x-axis with orientation to the right, and L2 as the line y

Applications and notes. The idea can assist in discussions of directed lines in computational geometry, CAD,

See also. Parallelism, oriented line, directed line, symmetry, geometric transformation.

v,
and
let
L2
be
the
oriented
line
through
a
point
p2
with
direction
vector
-v,
where
v
is
a
nonzero
vector.
If
p2
is
not
on
L1,
then
L1
and
L2
are
oppositeparallel.
Geometrically,
the
two
lines
are
parallel
(they
have
the
same
or
opposite
direction)
and
distinctly
separated
in
the
plane;
the
defining
feature
is
that
their
direction
vectors
are
exact
negatives
of
each
other.
a
direction
perpendicular
to
the
shared
orientation.
In
an
oriented-line
framework,
the
concept
highlights
a
symmetry
where
reversing
the
line’s
direction
while
preserving
parallelism
yields
a
corresponding
parallel
line
through
a
different
point.
The
concept
does
not
apply
to
ordinary,
non-oriented
lines
in
standard
Euclidean
geometry
without
introducing
an
orientation
convention.
=
2
with
orientation
to
the
left.
If
the
second
line
is
described
with
direction
vector
-v
relative
to
L1’s
v,
and
the
lines
are
distinct
(one
sits
above
the
other),
they
constitute
an
oppositeparallel
pair
under
the
oriented-lines
interpretation.
and
pattern
design
where
line
orientation
matters.
It
is
not
a
standard
Euclidean
concept
in
most
textbooks,
but
serves
as
a
useful
framework
in
contexts
that
distinguish
line
direction
in
addition
to
position.