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quantumobservables

Quantumobservables are quantities in quantum mechanics that can be measured. In standard quantum theory, each quantumobservable is represented by a self-adjoint operator on a Hilbert space. The possible measurement outcomes are the operator’s eigenvalues, and the system’s state is described by a state vector or a density operator.

Measurement statistics follow the Born rule: the probability of obtaining a given eigenvalue o for a system

If two quantumobservables O1 and O2 commute, they have a common eigenbasis and can be measured simultaneously;

In dynamics, observables may evolve in time: in the Schrödinger picture states evolve via unitary time evolution

in
state
|ψ⟩
is
|⟨o|ψ⟩|^2,
with
continuous
spectra
described
by
a
probability
density.
The
expectation
value
is
⟨ψ|O|ψ⟩,
and
the
spectral
decomposition
writes
O
=
∑k
o_k
P_k
+
∫
o
dP(o),
where
P_k
are
projection
operators
onto
the
corresponding
eigen-subspaces.
otherwise,
their
measurements
are
subject
to
uncertainty,
as
quantified
by
the
Heisenberg
uncertainty
principle.
After
a
projective
measurement
of
O,
the
system
collapses
to
the
eigenstate
associated
with
the
observed
eigenvalue
(projection
postulate).
More
general
measurement
schemes
are
described
by
POVMs,
which
extend
the
framework
to
include
imperfect
or
indirect
measurements.
while
observables
are
fixed,
and
in
the
Heisenberg
picture
observables
carry
the
time
dependence
O(t)
=
U†OU.
The
operational
meaning
of
quantumobservables
arises
from
concrete
measurement
models,
and,
in
principle,
every
self-adjoint
operator
represents
a
possible
observable,
though
practical
measurement
can
be
challenging;
domains
and
unbounded
operators
add
technical
nuances
in
infinite
dimensions.