It's worth noting that Mitchell Porter's true objection to Many-Worlds is (if I recall correctly) his conviction that quantum phenomena are at the root of human consciousness and qualia, and that this would be ruined in the Everett interpretation.
I don't think that's very relevant in this context. There are other people who aren't enamored with the section on MWI in the sequences, for reasons including those Mitchell outlines here.
He very carefully wrote this post to avoid his real objections and instead come across as a neutral-point-of-view expert. I found this disingenuous, and I think that the context might be especially helpful to readers who haven't been around for all that long.
I wrote the post in order to get a hole in the logic of the Sequences fixed. And the argument I presented was chosen in order to be as simple and convincing as possible: the existence of a whole class of interpretations that are unaddressed in the Sequence, and which exist at approximately the same level of qualitative plausibility as many worlds, when judged by the pre-Copenhagen standards of mathematical physics.
You're also wrong about my "real objections", in two ways. The way you put it was that I want consciousness to be explained by something quantum, and MWI kills this hope. But in fact my proposition is that consciousness is based on entanglement - on a large tensor factor of the quantum state of the brain. MWI has no bearing on that! MWI is entanglement-friendly. If some other version of quantum theory says there's entanglement in the brain, that entanglement will still be present in many-worlds. (Retrocausal theory is actually much less entanglement-friendly, because it generally doesn't believe in wavefunctions as physical objects.) My philosophy-of-mind objections to MWI-based theories of personhood have to do with MWI tolerance of vagueness regarding when on...
The Quantum Mechanics sequence is a failure - but fixing the physics is not the solution.
The point of the quantum mechanics sequence was the contrast between Rationality and Empiricism. Eliezer argues that the rational response to uncertainty when empirical evidence is absent or equipoise is to assign higher probability to the simpler explanation. But by writing at least 2/3 of the text about quantum mechanics, Eliezer obscured this point in order to pick an unnecessary fight about the proper interpretation of particular experimental results in physics.
Even now, it is unclear whether he won that fight, and that counts as a failure because MWI vs. Copenhagen was supposed to be a case study of the larger point about the advantages of Rationality over Empiricism, not the main thing to be debated.
The point of the quantum mechanics sequence was the contrast between Rationality and Empiricism. Eliezer argues that the rational response to uncertainty when empirical evidence is absent or equipoise is to assign higher probability to the simpler explanation.
Schoolkids often learn about this with Ptolemy vs Copernicus, I believe. It's a much less confusing example.
I think the subtext: was: even professional physicists don't get it.
It's hopeless to suggest rewriting the Sequence, I don't think that would be a good use of anyone's time.
Really? I would pledge nonzero money towards this goal.
Tim Maudlin developed an ingenious objection to the transactional interpretation which, to my knowledge, has not been adequately resolved as of yet. According to the TI, offer waves are sent forward in time from particle sources to absorbers. Each absorber responds by sending a confirmation wave backwards in time to the source. One of these transactions is selected with a probability given by the amplitude of the confirmation wave.
Here's Maudlin's objection: Suppose we have a beam splitter that can splits incoming beams of particles along two paths, call them a and b. On path a, at a distance l from the splitter, is a detector A. Let us suppose that a particle would cover the distance l in time t. There is another detector B that is initially also on path a, at a distance 2l from the source, behind A. If the detector A does not detect a particle within time t of the start of the experiment, then the detector B automatically swings onto path b, where it will also be at a distance 2l from the splitter.
Let's say the beam splitter sends half of the particles along path a and half along path b. This means that, for an individual particle, ordinary quantum mechanics predicts it will be d...
I'm curious about the following...
Would John Cramer's transactional interpretation require more complexity (at the level of the fundamental laws, rather than the amount of stuff in the universe) than the many worlds interpretation?
Roughly what proportion of the physics community backs it?
Is it a non-differentiable (or even discontinuous) phenomenon?
Is it non-local in the configuration space?
Does it violate CPT symmetry?
Does it violate Liouville's Theorem (has a many-to-one mapping from initial conditions to outcomes)?
Is it acausal / non-deterministic / inherently random?
Is it non-local in spacetime?
Could it propagate an influence faster than light?
Can it represent a non-linear or non-unitary evolution?
No God-damned puppies were harmed in the making of this comment.
Edit: As pointed out, one of those things is not like the others, so to carve at the joints, let's call the questions after #2 "the antimagic questions", and the idea that we should reject the suggested interpretation if we get "yes" answers to them the cuddly collapsing canine conjecture.
What I would like to see discussed on this occasion is not the physics, but rather how to patch the arguments in the Sequences that depend on this wrong sub-argument.
Personally, I am against linking MWI or even QM to rationality in any way, as the connection seems to be quite arbitrary.
Consider a matrix-like world, where the Universe is simulated on a classical computer (classical computers can do everything quantum computers can do, if slower). Would you deny that simulated humans can think and act rationally, only because the simulation does not incl...
Consider a matrix-like world, where the Universe is simulated on a classical computer (classical computers can do everything quantum computers can do, if slower). Would you deny that simulated humans can think and act rationally, only because the simulation does not include quantum mechanics? If not, would sim-EY not be able to write the Simquences (less the QM Sequence) which are identical (modulo QM) to the ones here?
You make a compelling case that the reference to QM in the sequences is at least as arbitrary as the fundamental physics of our universe. I'm not sure that this is quite as compelling and incisive a revelation as you believe it to be, especially to those who take Occam's Razor as seriously as Eliezer advocates. I'd actually say that this weakens your claim and that it would be better to argue, as Tim does, that the points Eliezer is trying to express don't come across nearly as well as they could.
Voted Up for precision disagreement.
Pros for Down: Claiming error on chain of reasoning without pointing the flawed link, treating a sequence as community manifesto instead of Elizers stance
Pros for Up: Topic that allows education of audience (QM), focused and individualized disagreement. introducing of a subfield of theory, voiced dissent
In favour of this de-bugging. One of the other glaring omissions from the sequence is discussion of modal interpretations of quantum mechanics. These are formally very similar to MWI (there is a wave function for the universe, there is no collapse) but the "many worlds" are interpreted as possible worlds (or universes), only one of which is actual. This approach has a lot going for it, common-sense wise.
Did we independently develop this "MWI and transactional interpretation are on roughly equal footing" rhetorical move? Just curious.
This whole post seems to be a conjecture about what quantum mechanics really means.
What we know about quantum mechanics is summed up in the equations. Interpretations of quantum mechanics aren't arguing about the equations, or the predictions of the equations. They are arguing about what it means that these equations give these predictions.
The important thing here is to understand what exactly these interpretations of quantum mechanics are talking about. They aren't talking about the scientific predictions, as all the interpretations are of the same equati...
clear idea of the role that "the winner is ... Many Worlds!" plays in the overall flow of argument
From what I can remember, part of the sequence explains correctly what predictions QM makes and part of it boldly asserts that MWI is the only reasonable interpretation. The former part is a fairly standard introductory text, it's the latter which makes the sequence unique, and the role of the "MWI is the winner" seems to be pretty central there. But I'd need to read the thing again to have a clearer idea. So, do you think it's worth the time to read (again) through the whole QM sequence to find the exact role of the declaration of MWI's superiority there?
Too much digital ink has already been spilled over this word "obvious"; I suggest we await the revised sequence and see whether or not EY will stick by "obvious" there before returning to the point at hand.
I'm curious about the following...
Would John Cramer's transactional interpretation require more complexity (at the level of the fundamental laws, rather than the amount of stuff in the universe) than the many worlds interpretation?
Roughly what proportion of the physics community backs it?
Is it a non-differentiable (or even discontinuous) phenomenon?
Is it non-local in the configuration space?
Does it violates CPT symmetry?
Does it violate Liouville's Theorem (has a many-to-one mapping from initial conditions to outcomes)?
Is it acausal / non-deterministic / in...
I'm not sure what you are exactly proposing with your suggestion to "patch the argument". Here is my understanding (possibly incorrect, I've not been here for long) of what happened:
Yudkowsky claims to have found a practically usable method of inductive inference that is superior to the mainstream scientific method. In order to demonstrate it, he picks an area where mainstream scientific epistemology failed to yield conclusive and satisfactiory results: the interpretation of quantum mechanics.
Armed with his superior epistemology, he sets forward ...
Proponents of the TI (and the PTI) explicitly say that one advantage of their interpretation over the MWI is that it is a one-world theory
Even the PTI? With the given description, that's really really weird.
Simply saying, "Well, in MWI observers will see all sorts of different frequencies in experimental results, including Born-rule compliant ones" doesn't tell us why observers should expect to see Born-rule compliant frequencies in a QM-governed world.
Not ALL sorts of frequencies. Many - most - ways of looking at the wavefunction won't reveal causal structures isomorphic to observers. For instance, you can consider the wavefunction in the energy basis and interpret it as an infinite number of wheels of various sizes, spinning at different constant speeds. No observers are apparent when viewed this way.
I suspect that the Born Rule is the only rule that leads to observers, but we don't need to prove that it's the only one, and I'm open to the possibility that there are others. GAZP again - if it's in there, it's in there, whether or not you're aware of it.
And if you don't have a story about that, then I don't see how you can claim that the observed frequencies confirm QM (and by extension MWI).
I think you'll agree that the observed frequencies confirm the conjunction of Schrodinger's Equation with the Born Rule. The question at hand is whether the Born Rule needs to be a rule of the universe. Whether collapse is ontologically real or based solely on our parochial viewpoint as observers.
Suppose it is real. That's nice. We get everything we see.
Suppose it isn't, and collapse isn't a real thing. The wavefunction is just doing its thing, and that's all there is. The causal structures in the wavefunction that correspond to people are still there.
The way of looking at us that brings us into focus is the Born Rule. Removing the Born Rule is just like removing a P-zombie's consciousness. It's that switch you flip to grant or remove subjective experience from a computation that implements consciousness.
Even the PTI? With the given description, that's really really weird.
Weird, but true! See the discussion of PTI in the paper I link to in this comment. As far as I can tell, PTI is just a relabeling of the original TI. Where TI would have said only one branch is real and the other branches do not exist, PTI says only one branch is actual and the others are real but not actual. Our universe consists only of that which is actual, so the other branches are not part of our universe. They exist in other possible universes, which (and this is the innovation, ...
This article should really be called "Patching the argumentative flaw in the Sequences created by the Quantum Physics Sequence".
There's only one big thing wrong with that Sequence: the central factual claim is wrong. I don't mean the claim that the Many Worlds interpretation is correct; I mean the claim that the Many Worlds interpretation is obviously correct. I don't agree with the ontological claim either, but I especially don't agree with the epistemological claim. It's a strawman which reduces the quantum debate to Everett versus Bohr - well, it's not really Bohr, since Bohr didn't believe wavefunctions were physical entities. Everett versus Collapse, then.
I've complained about this from the beginning, simply because I've also studied the topic and profoundly disagree with Eliezer's assessment. What I would like to see discussed on this occasion is not the physics, but rather how to patch the arguments in the Sequences that depend on this wrong sub-argument. To my eyes, this is a highly visible flaw, but it's not a deep one. It's a detail, a bug. Surely it affects nothing of substance.
However, before I proceed, I'd better back up my criticism. So: consider the existence of single-world retrocausal interpretations of quantum mechanics, such as John Cramer's transactional interpretation, which is descended from Wheeler-Feynman absorber theory. There are no superpositions, only causal chains running forward in time and backward in time. The calculus of complex-valued probability amplitudes is supposed to arise from this.
The existence of the retrocausal tradition already shows that the debate has been represented incorrectly; it should at least be Everett versus Bohr versus Cramer. I would also argue that when you look at the details, many-worlds has no discernible edge over single-world retrocausality:
I am not especially an advocate of retrocausal interpretations. They are among the possibilities; they deserve consideration and they get it. Retrocausality may or may not be an element of the real explanation of why quantum mechanics works. Progress towards the discovery of the truth requires exploration on many fronts, that's happening, we'll get there eventually. I have focused on retrocausal interpretations here just because they offer the clearest evidence that the big picture offered by the Sequence is wrong.
It's hopeless to suggest rewriting the Sequence, I don't think that would be a good use of anyone's time. But what I would like to have, is a clear idea of the role that "the winner is ... Many Worlds!" plays in the overall flow of argument, in the great meta-sequence that is Less Wrong's foundational text; and I would also like to have a clear idea of how to patch the argument, so that it routes around this flaw.
In the wiki, it states that "Cleaning up the old confusion about QM is used to introduce basic issues in rationality (such as the technical version of Occam's Razor), epistemology, reductionism, naturalism, and philosophy of science." So there we have it - a synopsis of the function that this Sequence is supposed to perform. Perhaps we need a working group that will identify each of the individual arguments, and come up with a substitute for each one.