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---
title: "Heisenberg picture"
firstLetter: "H"
publishDate: 2021-02-24
categories:
- Quantum mechanics
- Physics
date: 2021-02-24T16:46:26+01:00
draft: false
markup: pandoc
---
# Heisenberg picture
The **Heisenberg picture** is an alternative formulation of quantum
mechanics, and is equivalent to the traditionally-taught Schrödinger equation.
In the Schrödinger picture, the operators (observables) are fixed
(as long as they do not depend on time), while the state
$\ket{\psi_S(t)}$ changes according to the Schrödinger equation,
which can be written using the generator of translations
$\hat{U}(t) = \exp{} (- i t \hat{H} / \hbar)$ like so:
$$\begin{aligned}
\ket{\psi_S(t)} = \hat{U}(t) \ket{\psi_S(0)}
\end{aligned}$$
In contrast, the Heisenberg picture reverses the roles:
the states $\ket{\psi_H}$ are invariant,
and instead the operators vary with time.
An advantage of this is that the basis states remain the same.
Given a Schrödinger-picture state $\ket{\psi_S(t)}$, and operator
$\hat{L}_S(t)$ which may or may not depend on time, they can be
converted to the Heisenberg picture by the following change of basis:
$$\begin{aligned}
\boxed{
\ket{\psi_H} \equiv \ket{\psi_S(0)}
\qquad
\hat{L}_H(t) \equiv \hat{U}^\dagger(t) \: \hat{L}_S(t) \: \hat{U}(t)
}
\end{aligned}$$
Since $\hat{U}(t)$ is unitary, the expectation value of a given operator is unchanged:
$$\begin{aligned}
\expval*{\hat{L}_H}
&= \matrixel{\psi_H}{\hat{L}_H(t)}{\psi_H}
= \matrixel{\psi_S(0)}{\hat{U}^\dagger(t) \: \hat{L}_S(t) \: \hat{U}(t)}{\psi_S(0)}
\\
&= \matrixel*{\hat{U}(t) \psi_S(0)}{\hat{L}_S(t)}{\hat{U}(t) \psi_S(0)}
= \matrixel{\psi_S(t)}{\hat{L}_S}{\psi_S(t)}
= \expval*{\hat{L}_S}
\end{aligned}$$
The Schrödinger and Heisenberg pictures therefore respectively
correspond to active and passive transformations by $\hat{U}(t)$
in [Hilbert space](/know/concept/hilbert-space/).
The two formulations are thus entirely equivalent,
and can be derived from one another,
as will be shown shortly.
In the Heisenberg picture, the states are constant,
so the time-dependent Schrödinger equation is not directly useful.
Instead, we will use it derive a new equation for $\hat{L}_H(t)$.
The key is that the generator $\hat{U}(t)$ is defined from the Schrödinger equation:
$$\begin{aligned}
\dv{t} \hat{U}(t) = - \frac{i}{\hbar} \hat{H}_S(t) \hat{U}(t)
\end{aligned}$$
Where $\hat{H}_S(t)$ may depend on time. We differentiate the definition of
$\hat{L}_H(t)$ and insert the other side of the Schrödinger equation
when necessary:
$$\begin{aligned}
\dv{\hat{L}_H}{t}
&= \dv{\hat{U}^\dagger}{t} \hat{L}_S \hat{U}
+ \hat{U}^\dagger \hat{L}_S \dv{\hat{U}}{t}
+ \hat{U}^\dagger \dv{\hat{L}_S}{t} \hat{U}
\\
&= \frac{i}{\hbar} \hat{U}^\dagger \hat{H}_S (\hat{U} \hat{U}^\dagger) \hat{L}_S \hat{U}
- \frac{i}{\hbar} \hat{U}^\dagger \hat{L}_S (\hat{U} \hat{U}^\dagger) \hat{H}_S \hat{U}
+ \Big( \dv{\hat{L}_S}{t} \Big)_H
\\
&= \frac{i}{\hbar} \hat{H}_H \hat{L}_H
- \frac{i}{\hbar} \hat{L}_H \hat{H}_H
+ \Big( \dv{\hat{L}_S}{t} \Big)_H
= \frac{i}{\hbar} [\hat{H}_H, \hat{L}_H] + \Big( \dv{\hat{L}_S}{t} \Big)_H
\end{aligned}$$
We thus get the equation of motion for operators in the Heisenberg picture:
$$\begin{aligned}
\boxed{
\dv{t} \hat{L}_H(t) = \frac{i}{\hbar} [\hat{H}_H(t), \hat{L}_H(t)] + \Big( \dv{t} \hat{L}_S(t) \Big)_H
}
\end{aligned}$$
This equation is closer to classical mechanics than the Schrödinger picture:
inserting the position $\hat{X}$ and momentum $\hat{P} = - i \hbar \: d/d\hat{X}$
gives the following Newton-style equations:
$$\begin{aligned}
\dv{\hat{X}}{t}
&= \frac{i}{\hbar} [\hat{H}, \hat{X}]
= \frac{\hat{P}}{m}
\\
\dv{\hat{P}}{t}
&= \frac{i}{\hbar} [\hat{H}, \hat{P}]
= - \dv{V(\hat{X})}{\hat{X}}
\end{aligned}$$
For a proof, see [Ehrenfest's theorem](/know/concept/ehrenfests-theorem/),
which is closely related to the Heisenberg picture.
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