Consider a system with state space X for which evolution is deterministic and reversible. For concreteness let us also suppose time is a parameter that ranges over the set of real numbers R. Then time evolution is given by a family of bijective state transformations

${\displaystyle (\operatorname {F} _{t,s}\colon X\rightarrow X)_{s,t\in \mathbb {R} }}$ .

F_{t, s}(x) is the state of the system at time t, whose state at time s is x. The following identity holds

${\displaystyle \operatorname {F} _{u,t}(\operatorname {F} _{t,s}(x))=\operatorname {F} _{u,s}(x).}$ 

To see why this is true, suppose x ∈ X is the state at time s. Then by the definition of F, F_{t, s}(x) is the state of the system at time t and consequently applying the definition once more, F_{u, t}(F_{t, s}(x)) is the state at time u. But this is also F_{u, s}(x).

In some contexts in mathematical physics, the mappings F_{t, s} are called propagation operators or simply propagators. In classical mechanics, the propagators are functions that operate on the phase space of a physical system. In quantum mechanics, the propagators are usually unitary operators on a Hilbert space. The propagators can be expressed as time-ordered exponentials of the integrated Hamiltonian. The asymptotic properties of time evolution are given by the scattering matrix.^[1]

A state space with a distinguished propagator is also called a dynamical system.

To say time evolution is homogeneous means that

${\displaystyle \operatorname {F} _{u,t}=\operatorname {F} _{u-t,0}}$  for all ${\displaystyle u,t\in \mathbb {R} }$ .

In the case of a homogeneous system, the mappings G_t = F_t,0 form a one-parameter group of transformations of X, that is

${\displaystyle \operatorname {G} _{t+s}=\operatorname {G} _{t}\operatorname {G} _{s}.}$ 

For non-reversible systems, the propagation operators F_{t, s} are defined whenever t ≥ s and satisfy the propagation identity

${\displaystyle \operatorname {F} _{u,t}(\operatorname {F} _{t,s}(x))=\operatorname {F} _{u,s}(x)}$  for any ${\displaystyle u\geq t\geq s}$ .

In the homogeneous case the propagators are exponentials of the Hamiltonian.

In quantum mechanics edit

In the Schrödinger picture, the Hamiltonian operator generates the time evolution of quantum states. If ${\displaystyle \left|\psi (t)\right\rangle }$  is the state of the system at time ${\displaystyle t}$ , then

${\displaystyle H\left|\psi (t)\right\rangle =i\hbar {\partial \over \partial t}\left|\psi (t)\right\rangle .}$ 

This is the Schrödinger equation. Given the state at some initial time (${\displaystyle t=0}$ ), if ${\displaystyle H}$  is independent of time, then the unitary time evolution operator ${\displaystyle U(t)}$  is the exponential operator as shown in the equation

${\displaystyle \left|\psi (t)\right\rangle =U(t)\left|\psi (0)\right\rangle =e^{-iHt/\hbar }\left|\psi (0)\right\rangle .}$ 

• Arrow of time
• Time translation symmetry
• Hamiltonian system
• Propagator
• Time evolution operator
• Hamiltonian (control theory)

General references edit

• Amann, H.; Arendt, W.; Neubrander, F.; Nicaise, S.; von Below, J. (2008), Amann, Herbert; Arendt, Wolfgang; Hieber, Matthias; Neubrander, Frank M; Nicaise, Serge; von Below, Joachim (eds.), Functional Analysis and Evolution Equations: The Günter Lumer Volume, Basel: Birkhäuser, doi:10.1007/978-3-7643-7794-6, ISBN 978-3-7643-7793-9, MR 2402015.
• Jerome, J. W.; Polizzi, E. (2014), "Discretization of time-dependent quantum systems: real-time propagation of the evolution operator", Applicable Analysis, 93 (12): 2574–2597, arXiv:1309.3587, doi:10.1080/00036811.2013.878863, S2CID 17905545.
• Lanford, O. E. (1975), "Time evolution of large classical systems", in Moser J. (ed.), Dynamical Systems, Theory and Applications, Lecture Notes in Physics, vol. 38, Berlin, Heidelberg: Springer, pp. 1–111, doi:10.1007/3-540-07171-7_1, ISBN 978-3-540-37505-0.
• Lanford, O. E.; Lebowitz, J. L. (1975), "Time evolution and ergodic properties of harmonic systems", in Moser J. (ed.), Dynamical Systems, Theory and Applications, Lecture Notes in Physics, vol. 38, Berlin, Heidelberg: Springer, pp. 144–177, doi:10.1007/3-540-07171-7_3, ISBN 978-3-540-37505-0.

• Lumer, Günter (1994), "Evolution equations. Solutions for irregular evolution problems via generalized solutions and generalized initial values. Applications to periodic shocks models", Annales Universitatis Saraviensis, Series Mathematicae, 5 (1), MR 1286099.