I am doing a course in dynamical systems, and the term "time invariant" when it comes to systems is quite not clear.
I understand if time is not an explicit variable in the equation then it's a time invariant system, but again aren't all dynamical systems from time dependent?
I mean, a pendulum location and speed is dependent on its time, and yes the laws of physics governing it are the same regardless of the time, but this won't affect that it's still dependent on time in its motion
So what am I missing or have misunderstood? Thanks alot!
Best Answer
A dynamical system is described by a Lagrangian function $L$. It is a function that takes time, position and velocity as inputs, so we write it as $L(t,q,\dot q)$, where $t$ is time variable, $q$ is position variable, $\dot q$ is velocity variable.
To say that a dynamical system is time-invariant means $\frac{\partial L}{\partial t}=0$.
Physically, time-invariant means the following:
You do an experiment observing the movement of a pendulum that experiences no friction. You give the pendulum an initial push, or some initial height, or a mixture of both. You record the whole motion of the pendulum for a while. You do the same experiment again some time later, with the same initial conditions. If the system is time-invariant, the whole motion is the same as before.
If the system is time-dependent, for example, the pendulum is charged, and someone messes with your lab by applying some electric field with varying field strength over time, you may observe different motions of pendulum if you start your experiment at different times.