===== Its about time . note ===== ==== Note ==== This entry is concerned with the notion of time and is a spinoff of [[On physical units . note]]. == Observation == A core assumption of physics that's easy to adopt is that we are able to enumerate some moments in an ordered fashion. $t_1, t_2, t_3, ...$ Usually they are considered as point on some real axis, but I guess the only thing that really matters is that this enables us to count (other) sorts of events //between// such moments. If indeed the moments correspond to real numbers, $t_i, t_j$ say, then $\dfrac{1}{t_j-t_i}$ is what we want to call a //frequency// and as such a unit for all kinds of rates. == Energy as frequency == In [[On physical units . note]] we consider the Schrödinger equation $h_\Psi\cdot\dfrac{{\mathrm d}}{{\mathrm d}t}\Psi = (-2\pi{\mathrm i})\,H\,\Psi$ and note that if $h_\Psi$ is chosen unitless, the conserved quantity of the system (what is also called energy) is a frequency. The cost associated with a process is basically inversely proportional to how quick it takes place, so that Reaching higher frequencies is more expensive. But for a more precise desciption in QM, one must look at the state spaces in the models. A Hamiltonian $H(\langle q,p\rangle)$ is like an $\langle q,p\rangle$-indexed list of prices. A Hamiltonian operator $H$ acting on state vectors in QM is like a stamp with prices. To understand many formulas, units like e.g. mass ($kg=s/m^2$, after setting $\hbar$ unitless) can or should be multiplied by natural constants (e.g. $c^2$) so that they represent a frequency or time scale. == Canonical variables == If ${\mathcal H} \propto {\dot q}\frac{\partial {\mathcal L}}{\partial {\dot q}} \equiv {\dot q} \, p$ is supposed have the unit of a frequency, then $[p]=\dfrac{1}{[q]}$. That's also clear from $[q,p] \propto \hbar$. == List of quantities that multiply to frequency/energy == (this is a temporary list for me to read formulas in terms of units) Electrical field $[E]=\dfrac{1}{[t][x][q_x]}$ and dipole moments $[d]=[x][q_x]$. ----- === Related === [[On physical units . note]], [[Perspective]]