2. The Past Hypothesis and the orthodox BSA

Understanding the Past Hypothesis requires a brief discussion about some of the foundations of Boltzmannian statistical mechanics (SM). At any given time t, the precise microstate of an n-particle system is given by a point ${X_t}$ in a $6n$ -dimensional phase space ${\rm{\Gamma }}$ , which represents all possible instantaneous states of the system. The deterministic Hamiltonian equations of motion define a vector field on the phase space that fixes the dynamics of the phase point ^{Footnote 6} so that its temporal evolution corresponds to a curve in phase space.

Creatures like us are unable to discern the precise microstates of macroscopic systems. Instead, we characterize such systems in terms of macrovariables like temperature, volume, density, and pressure. Specifying the values of these macrovariables confines the system’s microstate to a subregion ${{\rm{\Gamma }}_R}$ of ${\rm{\Gamma }}$ ; the volume of any such region is given by the Liouville measure ${\mu _{\rm{L}}}$ . Intuitively, knowing the macrostate of a system constrains its microstate to be one of those that realizes the macrostate in question, but typically there are many different microstates that do so. The basic assumption of Boltzmannian SM is that macrostates supervene on microstates: there can be no change in the system’s macrostate without a corresponding change in its microstate.

For many systems there is a dominant macrostate, called the equilibrium macrostate ${{\rm{\Gamma }}_{{\rm{eq}}}}$ , which takes up the majority of the volume of ${\rm{\Gamma }}$ according to the measure ${\mu _{\rm{L}}}$ , i.e. ${\mu _{\rm{L}}}\left( {{{\rm{\Gamma }}_{{\rm{eq}}}}} \right)/{\mu _{\rm{L}}}\left( {\rm{\Gamma }} \right) \approx 1$ . A system in thermal equilibrium has a microstate within ${{\rm{\Gamma }}_{{\rm{eq}}}}$ .

The Boltzmann entropy ${S_{\rm{B}}}$ of a system with phase point $X$ is given by

(1) $${S_{\rm{B}}}\left( X \right) = {k_{\rm{B}}}\ {\rm{log}}\left( {{\mu _{\rm{L}}}\left( {{{\rm{\Gamma }}_X}} \right)} \right),$$

where ${k_{\rm{B}}}$ is the Boltzmann constant and ${{\rm{\Gamma }}_X}$ is the macrostate containing $X$ . A system’s entropy is thus proportional to the phase space volume of the macrostate that it occupies. It follows that the equilibrium macrostate (if it exists) is the highest-entropy macrostate.

Given this setup, part of what Boltzmann was able to make plausible is that if a system is currently in a non-maximum-entropy macrostate, it is overwhelmingly likely that it will evolve through macrostates of increasing entropy and eventually reach the equilibrium macrostate. A hand-wavy argument for this is as follows. Suppose that at time t a system is in a non-maximum-entropy macrostate $M\left( t \right)$ , corresponding to phase space region ${{\rm{\Gamma }}_{M\left( t \right)}}$ . Impose a probability distribution that is uniform on ${\mu _{\rm{L}}}$ over the microstates in ${{\rm{\Gamma }}_{M\left( t \right)}}$ . Then the probability that the system will evolve into ${{\rm{\Gamma }}_{{\rm{eq}}}}$ is overwhelmingly high. That is because most of the microstates in ${{\rm{\Gamma }}_{M\left( t \right)}}$ are ones that deterministically increase in entropy toward the future until they reach ${{\rm{\Gamma }}_{{\rm{eq}}}}$ . So given a uniform probability measure over the microstates in ${{\rm{\Gamma }}_{M\left( t \right)}}$ , it is overwhelmingly probable that a system in $M\left( t \right)$ lies on an entropy-increasing trajectory. Intuitively, unless the dynamics conspire to confine it to a small subregion of ${\rm{\Gamma }}$ , its phase point will aimlessly “wander” around ${\rm{\Gamma }}$ and find itself in macrostates whose phase space volume (read: entropy) is larger and larger until it reaches the largest-volume (equilibrium) macrostate, where it is overwhelmingly likely to stay. ^{Footnote 7}

Thus we appear to have an account of the pervasive regularity that systems evolve to higher entropy in the future. The hope is that this sort of reasoning can be applied not just to gases in boxes (a typical starting point in these sorts of discussions), but to arbitrary macroscopic systems and even the universe as a whole. Processes as diverse as book pages becoming yellower, hair turning grey, and ice melting in glasses of water would then all be accounted for by this explanation of entropy increase.

The problem, however, is that the Hamiltonian equations of motion are time-reversal invariant, and therefore all of this reasoning works equally well toward the past. That is, given a system in a non-maximum-entropy macrostate at time ${t_1}$ , we can use these arguments to predict that it will very likely be in a higher-entropy macrostate at ${t_2}$ . But we can also use these arguments to retrodict that it was very likely in a higher-entropy macrostate at ${t_0}$ . The same reasoning that leads us to infer that the half-melted ice cube in a glass of water will almost certainly be more melted in a few minutes also leads us to infer that it was almost certainly more melted a few minutes ago, and fluctuated into its current lower-entropy, less-melted state.

Applying this reasoning to the universe as a whole produces even more problematic results. Given that the universe is currently in a non-maximum-entropy macrostate, we can infer that it is overwhelmingly likely to evolve to higher-entropy macrostates in the future. But we can also infer that it is overwhelmingly likely to have evolved from higher-entropy states in the past. If that were right, it would mean that all of the records we appear to have of the past—memories, photographs, written accounts, etc.—are not accurate. They were produced not as a result of the events they appear to record, but by chaotic molecular fluctuations.

This problem is often called the Reversibility Objection:

This is problematic, of course, because we know that those systems were not in higher-entropy states toward the past. Given the abundance of non-equilibrium systems in our environment, then, Boltzmannian statistical mechanics licenses an enormous variety of egregiously incorrect inferences about the past.

A standard way of fixing this is to add the Past Hypothesis to the fundamental principles of Boltzmannian SM. That is, we posit that the universe started in a very-low-entropy macrostate $M\left( 0 \right)$ corresponding to a very-small-volume region ${{\rm{\Gamma }}_0}$ of the universe’s phase space. We then apply the aforementioned uniform probability distribution, on the Liouville measure ${\mu _{\rm{L}}}$ , over the microstates in ${{\rm{\Gamma }}_0}$ (this is the Statistical Postulate). In doing so, we arrive at Albert and Loewer’s Mentaculus. ^{Footnote 8}

With these additions, the thought is that Boltzmannian SM still makes all the correct predictions that it made without PH and SP, but it no longer makes the problematic retrodictions about the past being higher entropy. In particular, when we go to retrodict past states based on the present macrostate $M\left( t \right)$ , we conditionalize not only on $M\left( t \right)$ , but also on the fact that the universe began in $M\left( 0 \right)$ . Then, since entropy-increasing trajectories are so much more common than entropy-decreasing trajectories, the probability that we reached $M\left( t \right)$ on an entropy-decreasing trajectory is minuscule; instead, it is far more likely that we got here on a trajectory that was more or less uniformly increasing in entropy since it began in $M\left( 0 \right)$ . This blocks the conclusion that our present records of the past probably coalesced out of molecular chaos, and instead suggests that they were produced in roughly the manner that we think they were.

Many authors have been skeptical about one or another aspect of this project, but here I’m going to assume that the Mentaculus does indeed allow us to derive the universal increase in entropy over time as well as the various temporal asymmetries of our experience. That is, I’m going to suppose that it does everything that Albert and Loewer hope that it does. If so, how should we think about the nomological status of the Past Hypothesis and Statistical Postulate?

It is difficult to address this question in a vacuum, namely, without a metaphysical account of laws of nature on hand. Many people who have regarded PH and SP as laws have done so on a Humean Best System framework. ^{Footnote 9} The argument for the lawhood of PH and SP according to the BSA is fairly straightforward. The best system is the one that achieves the best balance between simplicity, strength (i.e. informativeness), and fit (i.e. how probable the best system says the mosaic is) with the actual mosaic. The intuition here is that the best system should provide a concise and informative summary of what happens in the mosaic. Here is Lange making the point by imagining a conversation with God:

Given this picture, the argument that PH and SP qualify as BSA laws is as follows. The dynamical laws by themselves are time-reversal invariant, so they capture nothing about the pervasive temporal asymmetries (collectively, the “arrow of time”) in the mosaic. But add PH and SP and suddenly all those asymmetries come into focus. So the Mentaculus is far more informative about the character of the mosaic than are the dynamical laws by themselves, and yet it is not significantly more complicated. Plausibly, then, it qualifies as the best system, and its members as laws (cf. Loewer Reference Loewer, Price and Corry2007).

One might admit that the Mentaculus is the best system and still demur from attributing nomological status to PH and SP. Lewis himself suggested that particular facts such as initial conditions could conceivably be included in the best system, but that only the regularities of the best system qualify as laws (1983, 367). However, many commentators have pointed out that PH and SP look and act like laws in a number of important respects—they support counterfactuals, explain other laws, underwrite inductive inferences, etc. ^{Footnote 11} In short, in addition to figuring in the best system, they also play some standard law roles, so they should be counted as laws.

Of course, if PH and SP don’t make it into the best system in the first place, then regardless of how much they act like laws in other respects, they will not count as laws in the best systems framework. Ultimately, I think that PH will not make it in, though a modified version of SP will. To get clearer on why that is, we need to look at the motivations behind Lewis’s conception of the BSA.

3. From the BSA to the BPSA

Hall (Reference Halln.d.) has persuasively argued that there is a unique challenge for Humean accounts of lawhood that doesn’t arise for non-Humean accounts. If Humeanism is right and the laws are mere patterns in the particular matters of fact, then it is unclear why we should be so interested in discovering them. In Hall’s words, the question is why laws are “distinctively appropriate targets of scientific inquiry,” or DATSIs. While non-Humeans can appeal to the laws’ exalted metaphysical status here, Humeanism has no such luxury. Patterns in the mosaic are a dime a dozen, and nothing in the Humean viewpoint singles out some of those patterns as having any special metaphysical status. What Humeanism needs, then, is an alternative explanation of why the laws are DATSIs. And as Hall suggests, the most natural place to look is to their instrumental value: what makes the laws a worthy target of our investigations is their practical utility to creatures like us.

A number of recent authors have argued that the BSA fails to address this concern. This is because an efficient summary of the mosaic lacks significant practical utility. ^{Footnote 12} Such a summary might report facts such as the universe’s total mass or energy, the average lifespans of stars and sizes of galaxies, the total number of particles, etc. Indeed, one would expect the best system to contain a good deal of statistical facts reported in the form of averages, standard deviations, and so forth; such measures are designed to condense large amounts of information into an easily digestible form.

While these sorts of facts about the mosaic might be academically interesting, it is hard to see how they would be much use to an agent embedded within the mosaic attempting to navigate it. How would knowing the universe’s total energy or the average galaxy size help you find your way around and pursue your goals? Coupled with Hall’s argument that the Humean should appeal to the practical utility of the laws to explain their status at DATSIs, this gives us the Pragmatic Objection to the BSA:

This is a serious difficulty. Discovering the laws of nature is one of the central aims of science, and the BSA makes that aim appear misguided. The issue is that the BSA’s standards of simplicity, strength, and fit are designed to achieve a goal—producing an efficient summary—that is just not that useful. What’s needed, then, is a modification of these systematizing standards.

The requisite modifications have, I think, been proposed in the accounts developed by Hicks (Reference Hicks2018), Dorst (Reference Dorst2019a), and Jaag and Loew (Reference Jaag and Loew2020). Here I focus primarily on my Best Predictive System Account (BPSA). The idea behind the BPSA is that we can address the Pragmatic Objection by tuning the systematizing standards to generate, not a maximally informative and concise summary of the mosaic, but rather an optimal predictive system for creatures in our epistemic situation. The laws are those patterns picked out by the best predictive system (BPS). ^{Footnote 13}

In Dorst (Reference Dorst2019a), I argued that such a system would be responsive to a number of “predictive desiderata” (see also Callender (Reference Callender2017, chapters 7 and 8), Jaag and Loew (Reference Jaag and Loew2020), and Loewer (Reference Loewer2020) for related discussions). Rather than recapitulating each of these desiderata and their motivations in detail, here I will simply describe the general type of system they are designed to produce. If nature is kind, the best predictive system will be one that has an input/output form that enables it to amplify a given chunk of information about the mosaic into a great deal more information. Any particular system might be better at amplifying some kinds of chunks rather than others; the best predictive system will be one that is optimized to amplifying the kinds of chunks that we typically have access to. That is, we will be able to plug in a chunk of information that we already know (or have the capacity to figure out), and the system will output a great deal more information in return.

This motivates two general kinds of predictive desiderata: “output maximizers” and “input constraints.” Output maximizers are aimed, straigthforwardly, at ensuring that the BPS can output a lot of information that is useful to us. By contrast, input constraints aim at restricting the input information that is required to generate a given output. More specifically, they try to ensure that the BPS doesn’t require information that it would be prohibitively difficult for us to ascertain. Thus they will tend to reflect our epistemic limitations. For example, given that it is practically impossible for us to discern the precise microstate of typical macroscopic systems, Jaag and Loew (Reference Jaag and Loew2020) suggest that the laws should be “error tolerant”: they should return approximately accurate predictions given approximately accurate inputs.

To some extent, output maximizers and input constraints conflict, much like strength and simplicity in the orthodox BSA. ^{Footnote 14} The system that gives us the laws is the one that achieves the best balance of these desiderata, and the system with the “best balance” is the one with the highest predictive utility.

The benefits of shifting from the BSA to the BPSA are manifold, ^{Footnote 15} but for our purposes it will suffice to note that the BPSA straightforwardly addresses the Pragmatic Objection to the orthdodox BSA. That objection arose because an efficient summary of the Humean mosaic is not sufficiently useful to creatures like us, and therefore doesn’t explain why the laws are DATSIs. By contrast, a system of principles that are maximally predictively useful to creatures in our epistemic situation would clearly be quite useful to us, and easily explains why the laws are DATSIs.

If the BPSA is the right account of laws, then the actual laws will tend to conform to its systematizing standards. This is indeed what we find if we look at putative actual laws from physical practice—including, most notably for present purposes, the dynamical laws of classical mechanics; these laws are highly effective at amplifying our information about the mosaic.

In sum, the BPSA improves on the BSA in both explaining why the laws are DATSIs and in selecting principles that better align with putative actual laws of nature found in scientific practice. It does so by bringing the epistemic situations of the users of that system into clearer view, and giving them a more prominent role in shaping the character of the best system. Given this change in perspective, however, we have to consider anew the question of whether the BPSA would deem PH and SP to be laws.

4. Why the Past Hypothesis is not a BPSA law

5. Loose ends

The argument I just advanced raises a number of significant questions. This section addresses several of them.

Does this argument imply that any principles that agree with our intuitive judgments or expectations cannot be members of the best predictive system?

The reason one might think this is that if everyone you might end up being (once the veil is lifted) correctly expects a given type of physical system to behave in a certain way, then information to that effect needn’t be included in the best predictive system because it would already be part of the GEP. But the above argument does not imply this. For example, everyone correctly expects a cannonball fired at a positive angle to the horizontal to follow an arcing trajectory and fall back to the ground. So why should Newton’s equations of motion, which predict such behavior, make it into the BPS? The answer is obvious: Newton’s equations of motion provide far more information than our naive expectations. Given facts like the mass of the cannonball and the force generated by the cannon explosion, they allow us to make a far more precise prediction about the trajectory of the cannonball than we could get by relying on our (widely shared) expectations. In general, a principle’s agreement with our intuitive expectations isn’t grounds for excluding it from the BPS if that principle also goes beyond those expectations in certain ways, e.g. by precisifying them or otherwise extending them beyond the point where they give out.

The system ${\mathcal {S}}$ is empirically incoherent, since it implies that our present evidence for it is unreliable. By contrast, ${{\mathcal {S}}^ + }$ is empirically coherent given its inclusion of PH and SP. Isn’t this reason to prefer ${{\mathcal {S}}^ + }$ to ${\mathcal {S}}$ as the best predictive system?

In short, no. This worry makes the same mistake we have already seen: it tries to evaluate ${\mathcal {S}}$ in a vacuum, whereas ${\mathcal {S}}$ is really designed to function in the context of the GEP. And the total body of knowledge encompassed by both the GEP and ${\mathcal {S}}$ is not empirically incoherent.

Perhaps the worry is rather that ${\mathcal {S}}$ is inconsistent with the GEP, because they reach inconsistent verdicts about the past. But of course, they are not strictly inconsistent; it’s not as if ${\mathcal {S}}$ says that it is impossible for the past to have been lower entropy, only that it is monumentally unlikely. In more mundane contexts, we routinely accept many pairs of claims, each of which makes the other improbable when considered in isolation. Indeed, the traditional Mentaculus itself is like this, since PH is massively unlikely on the basis of the classical dynamical laws. So it’s hard for me to see why the near inconsistency of ${\mathcal {S}}$ and the GEP would be a problem.

Price (Reference Price1996 , Reference Price and Hitchcock 2004 ) has argued that we ought to try to explain why the universe’s initial state had remarkably low entropy. If PH is part of the best system, then we have such an explanation: it was required by law. ^{Footnote 24} But if PH isn’t in the best system and therefore isn’t a law, this explanation is foreclosed. Isn’t this an explanatory deficiency of ${\mathcal {S}}$ as compared to ${{\mathcal {S}}^ + }$ ? ^{Footnote 25}

The appropriate response here is to keep firmly in mind that explanatory considerations are not part of the criteria for membership in the best system, at least not according to the BPSA. If one candidate system is better than another, that is because it is a better predictive system for creatures like us, not because it is more explanatory. Of course, insofar as the explanatory superiority of one system can be parlayed into predictive superiority, that system will be better. (In Dorst (Reference Dorst2019b) I suggested that this will often be the case, providing an indirect account of the value of seeking explanations in the first place: they lead us to predictively superior theories.) But as we’ve seen, ${{\mathcal {S}}^ + }$ is not predictively superior to ${\mathcal {S}}$ , so its ability to offer an explanation of the initial low entropy does not help it in the competition.

This accords nicely with the position of Callender (Reference Callender2004), who questions why we ought to demand an explanation of initial low entropy. Certainly we should not eschew one if there are independent reasons to find it plausible. But that is a far cry from deciding between two theories solely on the basis of their (in)abilities to explain such a state. As Callender puts it, “to know beforehand, as it were … that the [low-entropy initial state] needs explanation seems too strong” (207, Callender’s emphasis).

If these arguments succeed, they show that ${\mathcal {S}}$ is a better predictive system than ${{\mathcal {S}}^ + }$ , since the latter contains redundant information. But could the same be said of ${\mathcal {S}}$ ? It contains both the classical dynamical laws and SP $^*$ ; what about a system, which we might call ${{\mathcal {S}}^ - }$ , which consists of the dynamical laws alone? Is there a case to be made that it is superior to ${\mathcal {S}}$ for reasons similar to the ones that render ${\mathcal {S}}$ superior to ${{\mathcal {S}}^ + }$ ?

In order for ${{\mathcal {S}}^ - }$ to be superior to ${\mathcal {S}}$ , it would have to reveal at least as much information about the mosaic (when combined with the GEP). If that were the case, then it would be a better predictive system because it is more compact and yet returns the same outputs, making it better at amplifying our information. The problem is that ${{\mathcal {S}}^ - }$ does not reveal as much information about the mosaic as does ${\mathcal {S}}$ , for the former does not provide us with any probabilities. It deems propositions possible or impossible based on whether they are consistent with the dynamical laws, but it does not assign probabilities to these possibilities. This wouldn’t be problematic if we could derive the probabilities from the GEP, for then the combination of ${{\mathcal {S}}^ - }$ and the GEP together would be just as informative as the combination of ${\mathcal {S}}$ and the GEP (the SP $^{\rm{*}}$ -licensed probabilities from ${\mathcal {S}}$ would be redundant). But I do not see any way of getting the probabilities out of the GEP. The relevant probabilities are ones that are uniform, on the Liouville measure ${\mu _{\rm{L}}}$ , over the microstates compatible with a given macrostate. What in the GEP directs us to apply a uniform probability distribution as opposed to a non-uniform one? Even confining ourselves to uniform probability distributions, altering the measure would still alter the resulting probabilities. What in the GEP fixes the correct measure? As far as I can see, nothing in our shared epistemic state does anything to underwrite either a uniform probability distribution or the Liouville measure as the correct grounds for making predictions on the basis of the dynamical laws. These have to be supplied by the predictive system itself, rendering ${\mathcal {S}}$ superior to ${{\mathcal {S}}^ - }$ .

What should we make of the probabilities posited by SP ${^*}$ ? Are they objective, epistemic, or some mixture thereof?

This question has been raised with respect to the probabilities employed by the Mentaculus. ^{Footnote 26} The basic puzzle is that the Hamiltonian equations of motion are deterministic, so it is hard to see how to fit probabilities into the picture unless they are epistemic. But if they are epistemic, then it is hard to see how they can figure into a fundamental theory that is supposed to license explanations of the phenomena within its scope. Of course, the same sorts of questions can be raised about the probabilities employed by ${\mathcal {S}}$ , since it uses the same deterministic equations of motion as ${{\mathcal {S}}^ + }$ .

This is a large question, and I doubt that anything I can say here will be decisive, but here is my answer: the probabilities employed by ${\mathcal {S}}$ are objective enough. By that I mean that they can play the explanatory roles required of them.

My reason for thinking this is that these probabilities have the same ontological status as any other structures that are posited by the best predictive system, and such structures often have significant explanatory roles. To summarize a large literature very briefly, a number of philosophers (e.g. Callender (Reference Callender2017), Cohen and Callender (Reference Cohen and Callender2009), Loewer (Reference Loewer, Price and Corry2007, Reference Loewer2020), Hall (Reference Halln.d.), and Miller (Reference Miller2014)) have suggested that the best system may introduce what we might call “manufactured structures” along with the laws to help achieve a better overall balance of the systematizing standards. For example, Hall (Reference Halln.d.) proposes doing this with the magnitudes of mass and charge. Consider a mosaic in which the only fundamental non-modal facts concern the locations of particles at times. We might then allow candidate systems to posit additional magnitudes possessed by these particles, where the motivation for making such posits is for the candidate system to achieve a better overall balance of the relevant standards. In that event, as Hall puts it, “what would make it the case that there are masses and charges is just that there is a candidate system that says so, and that, partly by saying so, manages to achieve an optimal combination of simplicity and informativeness” (27).

Although this maneuver was originally proposed in the context of the orthodox BSA, it works equally well in the context of the BPSA. The BPS would then be allowed to posit structures that are not fundamental elements of the mosaic, and claims about such structures would be made true by the fact that the candidate system that posits them is the best predictive system.

I do not mean to take a stand here on exactly which structures might be legitimately introduced by the BPS in this manner. ^{Footnote 27} All that I would point out is that such structures often have significant explanatory roles to play within the relevant theories. Mass and charge, for example, are supposed to help explain particle motions within classical mechanics. If they can be made to do this even though they are really manufactured structures (on this view), then surely the probabilities employed by SP ${^{\rm{*}}}$ —which gain entry into the BPS in the same manner, i.e. by producing a better predictive system overall—can play those explanatory roles as well. Undoubtedly this will require a rather deflationary notion of explanation in order to work, but that’s something Humeans should already be on board with.

Still, you might push back: “Are these probabilities really objective? Aren’t they at least somewhat epistemic?” After all, if one uses them while ignoring parts of the GEP, one can derive all sorts of falsities about the past. But of course, they aren’t designed to be used while ignoring the GEP. They are manufactured structures tuned to the epistemic conditions of creatures like us, just like mass and charge would be on Hall’s proposal, or like the wavefunction on Miller’s, or indeed like the laws themselves on the BPSA. Does that make them epistemic as opposed to objective? The best I can do here is to echo Dennett (Reference Dennett1991, 51): I think the view itself is clearer than either of the labels, so I shall leave that question to anyone who still finds illumination in them.

6. Conclusion: Why physics can’t explain everything

Frisch (Reference Frisch and Wilson2014) (from which this section borrows its title) argues that the pragmatic motivations behind Albert and Loewer’s conception of the BSA make it hard to see why the Mentaculus would qualify as the best system. Without questioning whether the Mentaculus would be part of the best system, he suggests that various special science laws would likely be included as well. This, in turn, leads him to some broader conclusions regarding limitations on the explanatory ambitions of physics.

In a sense, I have argued for the converse claim. Whereas Frisch thinks that the best system will consist of the Mentaculus and then some, I have argued that it will consist of less than the Mentaculus. ^{Footnote 28} In particular, I have suggested that in the context of the BPSA, the Past Hypothesis is otiose: it adds nothing that is not already captured by the combination of ${\mathcal {S}}$ and the GEP.

Despite drawing the converse conclusion about the Mentaculus, I agree with Frisch in thinking that there are lessons here about the explanatory ambitions of physics (or, more accurately, of physical laws) from a Humean perspective. According to the BPSA, the laws are “designed” for creatures whose epistemic lives occur in medias res: some kinds of facts we have already established; many others we have not. If this is the right way to think of the laws, then they may take for granted the same sorts of facts that we do. But then the expectation that we should be able to explain everything by appeal to the laws alone is unrealistic; the laws cannot be expected to explain the sorts of facts that they take for granted. In particular, I don’t think we should expect the laws to license an explanation of the arrow of time. Facts about the arrow are already assumed in the epistemic milieu that provides the practical need—and hence, on the Humean view, the metaphysical foundations—for the laws in the first place.