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motion

Motion is the change in position of a physical object with respect to time, described relative to a chosen frame of reference. An object is in motion if its position changes over time; otherwise, it is at rest. The concept applies across scales and to waves and fields as well as objects.

Kinematics is the branch of mechanics that analyzes motion without regard to its causes. Core quantities are

Motion is often categorized as translational, where an object moves through space, and rotational, where motion

Dynamics connects motion to causes through forces. Newton's laws relate forces to changes in motion, with forces

Classical descriptions typically assume inertial frames of reference. At high speeds or strong gravitational fields, relativistic

displacement
(a
vector
describing
position
change),
velocity
(the
rate
of
change
of
displacement),
and
acceleration
(the
rate
of
change
of
velocity).
In
one
dimension,
with
constant
acceleration,
the
equations
s
=
s0
+
v0
t
+
1/2
a
t^2
and
v
=
v0
+
a
t
relate
position
and
velocity
to
time.
In
general,
velocity
and
acceleration
are
vector
quantities
that
depend
on
the
chosen
coordinate
system.
occurs
about
an
axis.
Rotational
motion
uses
angular
velocity
and
angular
acceleration,
with
torque
and
moment
of
inertia
describing
the
rotational
response.
Many
real-world
motions
combine
these
forms,
and
oscillatory
motion,
such
as
that
of
springs
and
pendulums,
is
also
common.
arising
from
gravity,
contact,
tension,
and
other
interactions.
Energy
concepts
describe
how
work
changes
kinetic
energy,
and
potential
energy
and
momentum
conservation
help
explain
system
behavior
across
diverse
situations.
and
quantum
considerations
become
important,
leading
to
more
general
theories,
but
everyday
motion
is
often
well
described
by
Newtonian
dynamics.