The uncertainty principle works out the way it does because of the Cauchy-Schwarz inequality. If you define the variance of two operators (which also requires you to define expectation value) when you multiply the variances of the operators you can start approximating it through the CS inequality and that will yield the commutator of the two operators. So if thats 0 the physical quantities commute there is no limit. Which means both quantities can be measured simultaneously and it also means that there exists a common eigen function system for them. So you can force the system into the eigenstate of both of the operators at the same time because such eigenstate exists.

For example with spin or rotations in general J² (think of it as magnitude of spin) commutes with all directors in 3D J1 J2 and J3. But J3 doesn’t commute with J1 and J2 and vica versa. This means that there is a common eigenstate for J3 and J². But you can’t measure J3 and J2 simultaneously as a system cannot be in both a J3 and J2 eigenstate. If thats the case then you have a limit to the variances. For example x and p don’t commute and the limit is hbar/2.

Fourier transforms came in at the wave package solution for free particles. A palne wave is not normalsizable but what if we make a sum of plane waves with different “frequencies” to get a function that has a finite norm. You can do that and the result is a good old wave package. If I tell you the position wavefunction at t=0 you can do an FT to get the sorta momentum function its a function of k the wavenumber vector which is practically momentum. So then you can do an FT with time evolution on the k function which gives you the time evolved wavefunction. And why you can immediately discover the uncertainty principle is because “the FT of a wide function is a narrow function and vica versa”. In the extreme the momentum is a dirac delta and so position will be a constant which is obviously not normalsizable. And so if they are FTs of each other then they can’t be both narrow functions, which means that the product of their spread has to be greater than something.

As far as conserved quantities go, in the Heisenberg picture instead of time evolving the wavefunction you time evolve the operators. Because all we can measure is the absolute square, all we need to keep invariant are scalar products. (Not even that they can be changed up to a unit absolute value complex number, aka phase.) So you can transform time evolution on the operators without changing physics. And why is that good because we can see a cool result. If you take the time derivitive of an operator which you of course introduce properly and if thats 0 the operator doesn’t change over time, so the physical quantity it describes is a constant. And as it turns out because the Hamiltonian doesn’t change over time because time evolution is the exponential of the Hamiltonian and an operator in piece times commute with a function of that operator you have an invariant Hamiltonian and this will be true for any operator that commutes with the Hamiltonian. So if an operator commutes with the Hamiltonian it describes a conserved quantity.