Actually, time (and maybe space) are infinite (countably so, thanks to Heisenberg's Uncertainty Principle) ?
Not a physicist, so better get a second opinion, but I do not think that this is something you can get out of the uncertainty principle. As far as I can tell it does not turn continuous space and time into some discrete voxel space, i.e. while there is uncertainty, the location of the peak of the amplitude, for example, can still be located anywhere in continuous space.
Energy probably isn't though (maybe it is, if space is ?), that is going to put a limit on non-reversible computation ?
The total energy of the universe might be zero. [1]
Physicist here. You are correct. The uncertainty principle doesnt turn space into some sort of voxel grid.
While we still don't know what spacetime looks like at the smallest scales (we're still waiting on a quantum theory of gravity), quantum field theory measures spacetime using continuous real numbers
> While we still don't know what spacetime looks like at the smallest scales (we're still waiting on a quantum theory of gravity), quantum field theory measures spacetime using continuous real numbers
IIRC, the uncertainty principle limits the precision in any possible measurement to something like 60 or 70 digits. So yes, current theories use continuous real numbers, but I wouldn't generalize that to say that's confirmed because we're nowhere near being able to test that level of precision.
I guess you are confusing two things - think of a mark on a real line at x somewhere between 17 mm and 18 mm from the origin. If you measure its location with a ruler, you might only be able to say that it is somewhere between 17 mm and 18 mm from the origin, but this uncertainty in your measurement in no way constraints x to only be located at integer millimeter positions or something like that.
There is not even a real limit imposed by the uncertainty principle, you can measure positions as precisely as you want, you just have to pay in momentum uncertainty. Where we really seem to run into a wall is that if you keep making the measurement more and more precise, you need higher and higher energies to achieve ever shorter wavelengths and dumping a lot of energy into a small volume to measure the position really precisely will eventually result in black holes.
> There is not even a real limit imposed by the uncertainty principle, you can measure positions as precisely as you want, you just have to pay in momentum uncertainty.
Yes, that's the current continuous model of how this works. That isn't necessarily reflective of reality though.
> Where we really seem to run into a wall is that if you keep making the measurement more and more precise, you need higher and higher energies to achieve ever shorter wavelengths and dumping a lot of energy into a small volume to measure the position really precisely will eventually result in black holes.
Exactly. In other words, all measurements necessarily have finite precision due to various uncertainties or other physical limits.
I didn't pull this limit out of the aether, I came across it from one of Shor's posts [1] where he states that physical constants can't be defined to greater precision than what I specified above. If the physical constants can't have more than 60 digits of precision, then neither can any calculations or measurements based on them.
The fact is, we seem to be bounded on all sides to finite precision.
My point is just that limited measurement precision does not imply anything about the underlying structure, could be continuous or not, I am not arguing for one side or the other.
Because if position and momentum are not quantized like this, you cannot get discrete bits of information (aka negative entropy) and the whole (so-called) "2nd law of thermodynamics" becomes impossible to derive, which is kind of a problem ?
Note that this underlying structure is subjective, relative to the observer, not something objective... (but we already know that there's no such thing as an "objective underlying structure" from elsewhere from quantum mechanics and also from relativity)
> (but we already know that there's no such thing as an "objective underlying structure" from elsewhere from quantum mechanics and also from relativity)
No we don't. Don't confuse the map with the territory.
In the sense that physics is about "map-making", not the "true nature of reality", and has been for a while now (since it split from philosophy ? since the beginning of postmodern physics in 1905 ?).
Even philosophy has pretty much given up that claim : with Gödel/Church/Turing having blown up to smithereens the positivist project of a "theory of everything" for mathematics, and Wittgenstein/Kuhn/Derrida/Foucault/Chomsky having redirected the rest of philosophy towards "the naming of things".
And that project had been ironically doomed from before its start anyway : Descartes both laid the groundwork for it by elevating epistemology to "fist philosophy" and for solipsism - which, while a dead-end, cannot be ruled out !
(Also honorable mention for Max Tegmark's Mathematical Universe I guess, which, in a way, indirectly achieves the claim by positing a mathematical multiverse so vast that "our" reality can only be contained inside it.)
So the only discipline left that still lays claim on Truth and the True Nature of Reality is theology. (Note that this is how Descartes "solved" the problem of solipsism.)
Physics is map making, but from that your claims - subjective nature of reality, no objective structure - do not follow, at best you could claim that physics has nothing to say about the nature of reality. And I have doubts about that, at least to some extend. What kind of answer would you expect for a question like what is the true nature of an electron? You can describe the properties of an electron, what more do you want? What is a thing above and beyond the sum of its properties?
The tricky issue here is that "the electron" itself is a specific model that only makes sense under some paradigms...
There's also a point in how one paradigm might be ontologically radically different compared to the previous one... but what science cares about more is the new paradigm being a "tighter fit" between its new models and the results of the new experiments.
Also, beyound a single "thing", it's when we start considering collections of things that the situation can get very tricky very fast, like chaotic behavior from something as simple as 3 masses under the Newtonian paradigm ! (See also : "emergence")
Or the concept of temperature : it doesn't go "down" to the "true nature of reality", but is a statistical one that is not even always defined, yet is still quite useful.
But yet again I would like to emphasize how in several subfields of physics we now are in a situation where we had to give up an objective viewpoint of the situation for a subjective one, and where the information itself that we have about a system (aka negative entropy) is another variable in a super system that includes us (and our instruments) and the system being studied, and we are forced to consider that supersystem instead, or at least also, in order to go "deeper".
(It's also impressive how in some cases we now study "turtles all the way down" situations, with models having an infinite number of correction steps that we can cheat around thanks to the use of advanced mathematics. But maybe in the future these will be seen as trivial as we see the Zeno paradox today ?)
Well then you seem to be agreeing with my original statement:
> So yes, current theories use continuous real numbers, but I wouldn't generalize that to say that's confirmed because we're nowhere near being able to test that level of precision.
Yes and no, I guess, depending on what exactly you intended to say. We agree, I guess, that we are currently using real numbers but that does not mean that the universe is actually continuous. Where I am not so sure that we agree is about the experimental side. We could run into some barrier when probing shorter and shorter distances, but this would not necessarily imply that space is not continuous. On the other hand we could also observe effects that clearly indicate a non-continuous structure of space without running into some measurement limit.
> Where I am not so sure that we agree is about the experimental side. We could run into some barrier when probing shorter and shorter distances, but this would not necessarily imply that space is not continuous
Agreed, though I personally find continuous quantities implausible, despite preferring them at one point. As long as we had a discrete theory with equal predictive and explanatory power and it was equally parsimonious to a continuous theory, I would likely prefer it. I think the next revolution in physics will see an expansion of discretization or other forms of finitism.
> On the other hand we could also observe effects that clearly indicate a non-continuous structure of space without running into some measurement limit.
I want to tone that down somewhat : I think that I misremembered that Planck's length and time were derived from the uncertainty principle... while looking into it, it might not be as obvious ? (So you need both ?)
And would you get quantification of mass~energy from that of the impulse (through v having dimensions of space and time), or do you need to use a different approach and assume black holes ? (Or both, and pick the biggest value ?)
The Planck length and time don't have any special physical significance, they're just convenient, and coincidentally happen to be roughly the size where we know for sure QFT is insufficient. The "smallest meaningful unit of distance" stuff is nonsense.
> And would you get quantification of mass~energy from that of the impulse (through v having dimensions of space and time), or do you need to use a different approach and assume black holes ? (Or both, and pick the biggest value ?)
Neither, though the impulse thing is at least in the right neighborhood. (Black holes have absolutely nothing to do with this). You get quantized energy whenever the Hamiltonian of your system has a pure point spectrum. Typically this happens for finite dimensional systems, and infinite dimensional systems with potentials that grow rapidly with increasing distance. Generic infinite dimensional systems will usually have continuous spectra.
> (Black holes have absolutely nothing to do with this)
Don't they have, in the sense that to keep probing ever more precisely, you need ever more energy, and at some point too much mass~energy in a too small volume is going to form a black hole and you cannot go further ?
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Argh, I should have known that this discussion would start to involve operators at some point, especially ones with an infinite number of dimensions... XD
Though this seems related mathematically to how the uncertainty principle can be interpreted through Fourier transforms : localized <=> spread out ; quantized <=> continuous ; finite (+ conditions on potential) <=> infinite (+ other conditions on potential) ?
> Don't they have, in the sense that to keep probing ever more precisely, you need ever more energy, and at some point too much mass~energy in a too small volume is going to form a black hole and you cannot go further ?
This may or may not be true - we can't probe those length scales yet, and maybe ever, so we don't really know - but it has no bearing on ordinary QM, which is nonrelativistic.
> Though this seems related mathematically to how the uncertainty principle can be interpreted through Fourier transforms
Not especially. They're both results in functional analysis, but that's about it.
You get the Planck units by setting c, hbar, G, and Boltzmann's constant to 1. This is convenient for notational purposes but it has no inherent physical significance.
That isn't the only way to argue for a minimal significant distance. Arguably QM sets a strict ~60-70 digit precision limit on physical constants [1], beyond which you arguably can't differentiate between discrete and continuous theories, and so a minimum distance seems like a perfectly sensible way to frame it.
> Actually, time (and maybe space) are infinite (countably so, thanks to Heisenberg's Uncertainty Principle) ?
Time is infinite in theory, but not practically. Time is fairly meaningless after the heat death of the universe. Some quantum field theories also suggest that spacetime becomes unstable if energy falls below a certain density IIRC, so even spacetime expansion might have a limit.
What I meant to say is that nothing that can be used for computation is infinite. Resources are finite, there is a finite amount of RAM/hard drive/paper space in the world.
Space is infinite, but we haven't yet found a technique to use pure space as computational memory.
Energy probably isn't though (maybe it is, if space is ?), that is going to put a limit on non-reversible computation ?