5.1. The HT approach and the Elga approach

The first consequence is that some approaches that result in different recommendations for the classic case will make the same recommendation in the duplicating case. Specifically, consider the HT (Halpern and Tuttle) approach and the Elga approach from Halpern (Reference Halpern, Gendler and Hawthorne2006). I chose to discuss the HT approach and the Elga approach because they are generalisations (see Halpern Reference Halpern, Gendler and Hawthorne2006: 125) of Elga's suggested solutions (see Elga Reference Elga2000) to the original Sleeping Beauty problem but formulated in game-theoretic terms,Footnote ¹⁰ so easily applicable to my model. The idea is as follows (the comments in brackets are mine): “To summarize, the HT approach assigns probability among points [nodes] in an information set I by dividing the probability of a run r [a run is what I have called a path of directed edges] among the points in I that lie on r (and then normalizing so that the sum [of the probabilities of nodes in I] is one), while the Elga approach proceeds by giving each and every point in I that is on run r the same probability as that of r, and then normalizing” (Halpern Reference Halpern, Gendler and Hawthorne2006: 127).

The HT approach and the Elga approach differ in their recommendation for the original Sleeping Beauty problem. Consider Figure 1 with its information set {MH, MT, TT}. Two paths of directed edges, i.e., runs r, go through that information set. Let run r ₂ start at S and go through MH and run r ₁ start at S and go through MT and TT. So, only one node from {MH, MT, TT} lies on r ₂ and two such nodes lie on r ₁.

For example, assume that the probability of r ₂ is the probability of a fair coin landing Heads, i.e., p = 1/2, and the probability of r ₁ is the probability of a fair coin landing Tails, i.e., 1 − p = 1/2. Given an information set I, the Elga approach gives every node from I that lies on a run r the same probability as that of r, and then renormalises probabilities over the nodes in I. So, MH gets the probability of r ₂, i.e., 1/2, and both MT and TT get the probability of r ₁, i.e., 1/2. So, every node in {MH, MT, TT} has the probability of ¹/₂. After renormalisation (where 1/2 + 1/2 + 1/2 = 3/2 is the normalising constant), every node in {MH, MT, TT} will have the probability of 1/3. Thus, the probability of Heads is 1/3 since the probability of MH is 1/3 (compare with Halpern Reference Halpern, Gendler and Hawthorne2006: 126). The Elga approach is a game-theoretic instance of Briggs’ thirder rule, see (Briggs Reference Briggs, Gendler and Hawthorne2010: 10). One can translate Briggs’ notation to game-theoretic concepts. Let A be an uncentred proposition (this remains unchanged), W uncentred worlds (runs r), N _W the number of centres in W (the number of decision nodes from a single information set lying on the given r), and Cr _u(W) the probability of a run. For example, assume that A stands for Heads. Then, $\sum _{W\in A}Cr_u( W) N_W = {1 / 2}$ since Cr _u(W) = 1/2 and there is one centre (i.e., node MH) in Heads (i.e., on r ₂), so N _W = 1. Lastly, $\sum _WCr_u( W) N_W$=3/2 is the normalising constant that sums over all the worlds (Briggs’ W* is notationally unnecessary, so I omit it). So, one's credence in Heads according to the thirder rule ${{\sum _{W\in A}Cr_u( W) N_W} \over \vskip3pt{\sum _WCr_u( W) N_W}}$ is 1/3. For Tails, $\sum _{W\in A}Cr_u( W) N_W = 1$ since Cr _u(W) = 1/2 and there are two centres (i.e., MT and TT) in Tails (i.e., on r ₁), so N _W = 2. Then, ${{\sum _{W\in A}Cr_u( W) N_W} \over \vskip3pt{\sum _WCr_u( W) N_W}}$ is 2/3.

Keep assuming that the probability of r ₁ and r ₂ is 1/2. The HT approach assigns probability among nodes in an information set I by dividing the probability of a run r among the nodes in I that lie on that r. Since there is only one node, MH, on r ₂, all the probability of 1/2 goes to that node. So, the probability of Heads is 1/2 (compare with Halpern Reference Halpern, Gendler and Hawthorne2006: 125–6). Since two nodes from {MH, MT, TT} lie on r ₁, the probability of r ₁ will be divided between those two nodes. In general, the HT approach does not give a rule on how to divide the probability among multiple nodes, but let me assume that 1/2 is divided equally between MT and TT (see (Halpern Reference Halpern, Gendler and Hawthorne2006: 126) for the same assumption). So, each gets 1/4. The HT approach is a game-theoretic instance of what Briggs calls the halfer rule, see Briggs (Reference Briggs, Gendler and Hawthorne2010: 9). That is, one's credence in an uncentred proposition A equals to Cr _u(A), which, in the game-theoretic jargon, is the probability of run(s) (i.e., uncentred worlds) where A is true. If A is Heads, then one's credence in A is the probability of r ₂, i.e., 1/2. If A is Tails, then one's credence in A is the probability of r ₁, i.e., 1/2.

Overall, the HT approach and the Elga approach differ in their recommendations for distributing probabilities among multiple nodes from a single information set that lie on the same run. The HT approach divides that probability between nodes, and the Elga approach gives each such node the full probability of the run. In the classic Sleeping Beauty scenario, both approaches differ in assigning probabilities between nodes MT and TT from the information set {MH, MT, TT} that lie on the run r ₁. But for the duplicating scenario in Figure 4, there is no run with more than one node from a single information set. In Figure 4, there are four runs: r ₁ starting at S ₁ and going through MT ₁ and TT ₂, r ₂ starting at S ₁ and going through MH ₁, r ₃ starting at S ₂ and going through MT ₂ and TT ₁, and r ₄ starting at S ₂ and going through MH ₂. Each of these four runs has only a single decision node from any of the two information sets in Figure 4, i.e., {MH ₁, MT ₁, TT ₁} and {MH ₂, MT ₂, TT ₂}. Remember that the HT approach and the Elga approach differ in how they distribute probabilities over multiple nodes that lie on the same run and are from the same information set. But for any run with only one node from a single information set, both the HT approach and the Elga approach assign the whole probability of the run to that single node (e.g., see their assignment of probabilities to MH in the classic scenario). The Elga approach, by definition, assigns the whole probability of the run to any node on that run. The HT approach cannot divide the probability among multiple nodes because there is only one node, so that one node gets all the probability of the run. Since Figure 4 has no runs with multiple nodes from a single information set, the HT approach and the Elga approach will give the same recommendation for the duplicating scenario in Figure 4; this observation is just a subcase of Lemma 3.1 in Halpern (Reference Halpern, Gendler and Hawthorne2006: 128).

The concrete results will depend on the probabilities one assigns to the runs. For example, assume that the probability of each run is 1/2 since the probability of the coin landing Heads/Tails is 1/2. On Sunday, the agent can well locate herself. So, if, for example, she finds herself at S ₁, she knows that the other tree cannot happen (i.e., r ₃ cannot happen for player 1 since she cannot wake up as a duplicate if she is awake on Sunday). Player 1 then focuses only on the runs leading from S ₁, where the probability of Heads (i.e., run r ₂ when the coin lands Heads) and Tails (i.e., run r ₁ when the coin lands Tails) is 1/2 by our assumption. So, e.g., by the Principal Principle, one can set her Sunday credences in Heads/Tails to 1/2. Upon awakening, one cannot locate herself in one of the trees and so must consider both of them, e.g., player 1 must take into account all the runs r ₁, r ₂, and r ₃ with nodes from {MH ₁, MT ₁, TT ₁}. Consider, for example, r ₁ with two nodes MT ₁ and TT ₂; note that each node comes from a different information set. The Elga approach and also the HT approach gives the whole probability of r ₁, i.e., 1/2, to MT ₁ and TT ₂ despite lying on the same run because MT ₁ and TT ₂ come from different information sets. So, every member of {MH ₁, MT ₁, TT ₁} and of {MH ₂, MT ₂, TT ₂} gets the probability of 1/2, which, after normalisation (which happens for each information set separately), gives the probability of 1/3 to every node. So, in our concrete case, one's credence in Heads will be 1/3 (since MH ₁ and MH ₂ get assigned the probability of 1/3); as we have seen, this is true for the Elga approach and also the HT approach.

The question is whether any instance of the thirder or halfer rule (for the original case) will give the same recommendation for Figure 4. It will not, see the next section. It all depends on one's starting assumptions. In this section, my only restriction was the game-theoretic requirement that the probabilities of directed edges leading from a single node sum to one (see footnote 14). One satisfies this requirement by assuming that the probability of Heads (i.e., the probability of r ₂ and r ₄) is 1/2 and the probability of Tails (i.e., the probability of r ₁ and r ₃) is 1/2. So, the sum of probabilities of r ₁ and r ₂ going from S ₁ is one, and the sum of probabilities of r ₃ and r ₄ going from S ₂ is one.

5.2. Compartmentalised conditionalisation

Meacham formulates a hypothetical-priors version of the HT approach and the Elga approach, compartmentalised and centred conditionalisation, where one uses hypothetical priors instead of probabilities of runs. Hypothetical priors are the credences one ought to have if one has no evidence whatsoever, see Meacham (Reference Meacham2008: 248). Meacham assumes that one has hypothetical priors in centres (i.e., time-slices or centred worlds) and uncentred possible worlds. I will now discuss compartmentalised conditionalisation and leave centred conditionalisation for the next section.

In short, compartmentalised conditionalisation first divides one's credences among uncentred worlds and then divides the credence of each uncentred world among the alternatives (centres) at that uncentred world, see Meacham (Reference Meacham2008: 257). One can operationalise it in the following three steps, see Meacham (Reference Meacham2008: 249):

1. 1. One takes her hypothetical priors and sets the credence in every centre (centred world) incompatible with her current evidence to 0.

2. 2. One normalises the credences in the remaining uncentred worlds such that the ratios between them are the same as the ratios between their hypothetical priors.

3. 3. One normalises credences in the remaining centres at each world so that they sum to the credence assigned to that world, and the ratios between them are the same as the ratios between their hypothetical priors.

Meacham shows that compartmentalised conditionalisation assigns 1/2 in Heads for the classic and duplicating case. Assume that, on Sunday, by the Principal Principle (see Meacham Reference Meacham2008: 257) or other reason, one has a 1/2 credence in each, that the coin toss lands Heads/Tails. This means that one's hypothetical priors in Heads and Tails have a ratio of 1:1 (this follows from the properties of Bayesian conditionalisation (see Rédei and Gyenis Reference Rédei and Gyenis2021), which Meacham uses for his updating rules). On Sunday, Meacham says (Reference Meacham2008: 257), the uncentred world Heads has a single centre (Sunday and Heads, i.e., SH), and the uncentred world Tails has a single centre (Sunday and Tails, i.e., ST). For the sake of convenience, also assume that the hypothetical priors in MT and TT are equal, i.e., their ratio is 1:1 (see Meacham Reference Meacham2008: 257, for the same assumption).

For the classic scenario in Figure 1, one's doxastic alternatives (centres) have changed upon awakening. One still has one alternative (Monday) at the Heads-world but two alternatives (Monday and Tuesday) at the Tails-world. None of those centred worlds is eliminated by one's evidence. So, the first step of compartmentalised conditionalisation has no effect. Similarly, upon awakening, despite the change in one's doxastic alternatives, uncentred worlds Heads/Tails from Sunday also remain (i.e., neither of them is eliminated by evidence). Since there is no change in uncentred worlds, and one knows, by assumption, that hypothetical priors in Heads and Tails have a 1:1 ratio, one will again have the credence of 1/2 in Heads/Tails, see Meacham (Reference Meacham2008: 257). So, the second step is satisfied. The third step distributes credences in uncentred worlds to their centres according to one's hypothetical priors. By assumption, hypothetical priors in MT and TT are equal, i.e., their ratio is 1:1, so MT and TT each get 1/4 to preserve that ratio. The conclusion is that credence in Heads is 1/2. Given Meacham's treatment of duplication (Reference Meacham2008: 251, 254–5),Footnote ¹¹ in the duplicating scenario, the centre TT that originally belonged to Beauty will be replaced by the duplicate's centre (my interpretation is that something similar to the situation depicted in Figure 2 happens). Such change does not eliminate any of the uncentred worlds (i.e., Heads or Tails) at any stage of the game. The reasoning is then very similar to the classic case. Using the Principal Principle on Sunday again results in hypothetical priors for uncentred worlds, Heads and Tails, with a 1:1 ratio. Since, upon awakening, no centred or uncentred world gets eliminated, one's credence in Heads will again be 1/2 (and 1/4 goes again to HT and MT).

One can reproduce a similar reasoning about the duplicating scenario for Figure 4. Assume that on Sunday (S ₁ or S ₂), one can locate herself well and knows that the other tree cannot happen since there is no connection between both trees (there is no connected path to get from one to the other, see Figure 5), so she focuses only on runs going from the appropriate Sunday node. For example, focusing on S ₁ and player 1, she knows that r ₃ cannot happen (i.e., Tails can be true only if r ₁ actualises), so she focuses only on r ₁ and r ₂. By assumption, the probability of Heads/Tails is 1/2, so one can use the Principal Principle to set her Sunday credences in Heads/Tails to 1/2. As before, it follows that hypothetical priors in Heads and Tails have a ratio of 1:1. Upon awakening, neither uncentred world Heads nor uncentred world Tails got eliminated. Since one's hypothetical priors in Heads/Tails are in a 1:1 relation (and none of these worlds gets eliminated), one's credence in Heads and Tails, upon awakening, is 1/2. If one again assumes that hypothetical priors between MT ₁ and TT ₁ (two of the new doxastic alternatives upon awakening) are in a 1:1 relation, then MT ₁ and TT ₁ are both assigned the credence of 1/4. So, in this case, the hypothetical priors between r ₁, r ₂, and r ₃ would be 2:1:1, but this breaks none of our assumptions since the only assumptions about hypothetical priors were about the ratio 1:1 of Heads and Tails and the ratio 1:1 of MT ₁ and TT ₁, which all still hold.

Fig. 5. Sunday perspective when a player can locate herself on Sunday, e.g., player 1 at S ₁, indicated by a star. From that perspective, both trees are completely separated.

The difference between my model in Figure 4 and Meacham is that, in my model, doxastic centres have not only changed (from Sunday to Monday nodes), but an agent's inability to locate herself in a world creates a new relation that connects two formerly separated trees (as in Figure 5) via an information set (as in Figure 4). This new relation represents an agent's inability to discriminate (upon awakening) between the elements of the information set that belongs to her. But since, for example, TT ₁ is a part of this new relation for player 1 (i.e., is an element of the information set that belongs to player 1), r ₃ that was eliminated on Sunday must be reintroduced on Monday. In my model, Tails is true if r ₁ or r ₃ (which are mutually exclusive) actualises, so credences (probabilities) in those runs (which one can see as uncentred worlds) must sum to 1/2 to meet the assumption that one's credence in Tails is 1/2. So, uncentred world Tails is a complex entity since it is a union or disjunction of two mutually exclusive uncentred worlds, represented by runs r ₁ and r ₃. In other words, if one thinks of an uncentred proposition as a set of uncentred worlds where that proposition is true, then the uncentred proposition Tails is a set of two uncentred worlds represented by runs r ₁ and r ₃. And these uncentred worlds r ₁ and r ₃ contain centres (i.e., decision nodes MT ₁ and TT ₁). So the difference (e.g., for player 1) between Sunday and Monday is not only about new doxastic alternatives but also about a new relation (represented by an information set) and consequently that r ₃ (a run or an uncentred world), which was eliminated on Sunday (at S ₁ for player 1), is a viable option on Monday. Despite all those additional changes, uncentred worlds Heads and Tails (the complex entity) are not eliminated, as a player moves from Sunday to Monday. I also standardly assume that Beauty knows how the game works from the beginning, so she is aware of these changes from the start.

5.3. Centred conditionalisation and multiple duplicates

To discuss centred conditionalisation, I need to introduce another mechanic of Meacham's approach, continuity. Roughly speaking, continuity tells one how to distribute hypothetical priors over centres in specific cases (i.e., when the centres are continuous). Thus, one can think of continuity as a replacement for the game-theoretic rule of how (in some cases) probabilities of runs distribute over nodes in a decision tree. Centred conditionalisation can be operationalised in the following three steps (see Meacham Reference Meacham2008: 249) with the continuity condition (see Meacham Reference Meacham2008: 252):

1. 1. One takes her hypothetical priors in centres (centred worlds).

2. 2. One sets the credence in every centre incompatible with her current evidence to 0.

3. 3. One normalises the credences in the remaining centres such that the ratios between them are the same as the ratios between one's hypothetical priors. Credences in uncentred worlds are determined by sums of the credences in respective centres.

Continuity: The ratio of priors between new alternatives is the same as the ratio of priors between any old alternatives they are continuous with.

Let me use Elga's conditions for continuity (as formulated by Meacham Reference Meacham2008: 258) for two centres. First, both centres are centred at the same world and individual. In other words, centres (nodes) must lie on the same run, i.e., a continuous path of directed edges, and be in information sets that belong to the same agent. I will also assume that if two nodes are continuous, one must be a direct predecessor of the other (chance nodes can be disregarded). This condition copies conditions (ii) and (iii) of Elga's continuity principle that the new alternative/centre (e.g., think of centres on Monday) is not centred at an earlier time than the old alternative (e.g., think of Sunday), and there is no other new alternative satisfying all the other required conditions for continuity that is centred at an earlier time than this new alternative.

First, consider the classic case (see Figure 1) and assume that, by the Principal Principle, one's credence in centres on Sunday, i.e., SH (Sunday and Heads) and ST (Sunday and Tails), is 1/2 in each. It means that one's hypothetical prior in SH and ST is also 1/2 in each (see Meacham Reference Meacham2008: 258). Upon awakening, centred conditionalisation itself does not tell one how to distribute credences among MH, MT, and TT because it will depend on one's hypothetical priors in MH, MT, and TT, which can be anything. Continuity becomes helpful here. Using the idea that MH and MT are continuous with SH and ST, respectively, one can deduce that hypothetical priors in MH and MT are equal (since, by continuity, they must preserve the ratio of hypothetical priors of SH and ST). But continuity does not tell one what actual value MH or MT has. To find that out, one can use Elga's principle of indifference (see Elga, Reference Elga2000: 144; Reference Elga2004), but I use a formulation from Meacham (Reference Meacham2008: 258): one's credences in doxastic alternatives at the same world should be equal. In the game-theoretic terminology, one's credences in nodes on the same run and in the same information set (since one distributes credences over nodes in one's information set) should be equal. From Elga's principle of indifference, it follows that hypothetical priors in MT and TT are equal. Putting all together, hypothetical priors in MH, MT, and TT are all equal. For probabilistic functions, this holds only if one's hypothetical prior in each of MH, MT, and TT is 1/3. For the duplicating case, the reasoning is the same except that Elga's principle of indifference is now applied to doxastic possibilities MT centred at the original Beauty and TT centred at the duplicate (structurally, I imagine this scenario as the one in Figure 2).

Some philosophers (e.g., see Bostrom Reference Bostrom2007: 63–5; Meacham Reference Meacham2008: 260; Builes Reference Builes2020: 3040–2) claim that this approach becomes problematic if one starts multiplying Beauty's duplicates. One version among many could go as follows: “Let ϕ be a (non-indexical) proposition, to which Beauty assigns a prior credence of 1/2. Beauty is never woken up again after being put to sleep on Monday. If ϕ is true then there will be a total of N > 0 awakenings of doppelgangers in states that are subjectively indistinguishable from Beauty's Monday awakening” (Bostrom Reference Bostrom2007: 64).

I believe that the currently discussed approach becomes problematic if one treats new duplicates as new centres in the same uncentred world (i.e., new nodes from a single information set on the same run). In other words, if one treats each new duplicate as a modification of Figure 2 and prolongs the Tail branch (run) by adding new nodes for each new duplicate (i.e., that duplicate's awakening), then the following problem occurs. For example, consider Figure 6 where there are two duplicates in total with nodes TT ₁ and TT ₂ belonging to duplicate 1 and duplicate 2, respectively (MH _org and MT _org belong to the original Beauty). Assume one uses Figure 6 and let Beauty's Sunday credences in Heads and Tails (one can think of them as SH and ST, respectively) be 1/2, so hypothetical priors in Heads and Tails are equal. Then, by continuity with Sunday, one's credences (upon awakening) in MH _org and MT _org are equal. Moreover, by Elga's principle of indifference, one's credences (upon awakening) in MT _org, TT ₁, and TT ₂ are also equal. So, upon awakening, one's credence in all of MH _org, MT _org, TT ₁, and TT ₂ are equal, which means that each node gets a credence of 1/4, if one has probabilistic credences. So, upon awakening, one's credence in Heads is 1/4 and in Tails 3/4. The more duplicates one adds – in the style of Figure 6 – the more the probability ratio will be in favour of Tails. For example, if one has 9 duplicates in total, one's credence (upon awakening) in Heads will be 1/10 and 9/10 in Tails.

Fig. 6. Multiple duplicates on one run.

First, let me consider how centred conditionalisation works with Figure 4 and then consider multiple duplicates. On Sunday, the agent knows that TT (which TT depends on the choice of S ₁ or S ₂) is impossible and concentrates only on the remaining tree. Given a fair coin, by the Principal Principle, let one's Sunday credence in Heads and Tails be 1/2. So, on Sunday, one's credence in Sunday and Heads is 1/2, and one's credence in Sunday and Tails is also 1/2. It follows that hypothetical priors in Sunday and Tails and Sunday and Heads are equal. In my model (Figure 4), there are no nodes Sunday and Heads (SH) or Sunday and Tails (ST) with which Monday nodes (MH ₁ and MT ₁ or MH ₂ and MT ₂) can be continuous. But one can use the Sunday node that (disregarding the chance node) is a direct predecessor of Monday nodes to implement continuity (a direct predecessor means that there is a continuous path of directed edges, e.g., between S ₁ and MH ₁ and between S ₁ and MT ₁, and no other non-chancy nodes are between them). So, assuming that Monday nodes are continuous with respect to the appropriate Sunday node (i.e., MH ₁ and MT ₁ with S ₁ and MH ₂ and MT ₂ with S ₂), hypothetical priors in Monday nodes will be the same as hypothetical priors in Heads and Tails one had on Sunday. That is, hypothetical priors in Monday nodes are also equal, i.e., have a ratio of 1:1. The crucial difference is that, in Figure 4, one cannot apply Elga's principle of indifference since there is no uncentred world with more than one centre of a single player (i.e., a run with more than one node from a single information set). So, for example, the credences of player 1 will entirely depend on her hypothetical priors in MH ₁, MT ₁, and TT ₁. But one only knows that those priors must be equal for MH ₁ and MT ₁, which leaves many options open. For example, one could go with 1/3 in each, so one's credence in Heads is 1/3, but this is only one of many options.

The non-applicability of Elga's principle of indifference is the reason why the model in Figure 4 can accommodate more than one duplicate without raising credence in Tails by introducing more and more duplicates. Let me again consider only two duplicates, but further extensions are based on the same idea.

In Figure 7, for example, the ratio of hypothetical priors in MH ₁ and MT ₁ that belong to player 1 (who acts at S ₁ and whose information set is represented by the dotted curves) is equal by continuity with the ratio of hypothetical priors in Heads and Tails at S ₁ (i.e., S ₁ is continuous with MH ₁ and MT ₁). But there is no restriction on hypothetical priors of player 1 assigned to TT ₁₁ in the second tree and TT ₁₂ in the third tree. First, because Elga's principle of indifference does not apply to them since they are the only nodes from the information set of player 1 on the given run. Secondly, those nodes are not continuous with any other node in their respective trees since all the other nodes are centred at different agents. So, for example, it is fine to hold a credence of 1/3 in MH ₁ and MT ₁ (the ratio of hypothetical priors in MH ₁ and MT ₁ is 1:1, like Heads and Tails at S ₁) and have hypothetical priors of 1/3n in all the remaining nodes that belong to player 1, where n is the number of the remaining nodes (i.e., the number of duplicates). So, credences of player 1 in all nodes except MH ₁ and MT ₁ sum to 1/3. In our case, for two duplicates, it means that player 1 has a credence of 1/6 in both TT ₁₁ and TT ₁₂. In other words, adding a second duplicate did not change the credence of player 1 in MH ₁ (it is still 1/3), so her credence in Heads remains unchanged. And her credence in Tails is still 2/3. Similarly, adding more duplicates and accommodating them in the style of Figure 7 will not change credence in Heads of player 1 (or any other player in the game). So, sliding towards a higher probability of Tails as more and more duplicates are added does not happen.

Fig. 7. A case with two duplicates, where player 1 starts at S ₁, player 2 at S ₂, and player 3 at S ₃. For example, TT ₁₁ means that player 1 is the duplicate number 1 (where the number of the duplicate is given by the order in which they wake up) or TT ₃₂ means that player 3 is the duplicate number 2.

5.4. Accuracy-based approaches

Finally, consider Kierland and Monton's suggestion that Beauty could find her optimal credence in Heads by minimising expected inaccuracy. Kierland and Monton consider two epistemic goals or methods she could follow: minimising expected average or total inaccuracy. The difference is that: “When one calculates expected total inaccuracy, one sums the inaccuracy for each temporal part, while when one calculates expected average inaccuracy, one averages the inaccuracy for each temporal part” (Kierland and Monton Reference Kierland and Monton2005: 389).

Let me first consider expected total inaccuracy with the original case from Figure 1, where Beauty has three decision nodes (i.e., centres, temporal parts, or time-slices), MH, MT, and TT. The expected total inaccuracy calculates the inaccuracy of Beauty's credence in Heads, c(H), at each node (I follow Kierland and Monton and use the Brier scoreFootnote ¹² to evaluate inaccuracy), weights each score by the probability of reaching the respective node, and sums the weighted scores. For Figure 1, one has: P _MH(1 − c(H))² + P _MT(0 − c(H))² + P _TT(0 − c(H))². Kierland and Monton assume that P _MH = P _MT = P _TT = 1/2 (e.g., see Kierland and Monton Reference Kierland and Monton2005: 389–90), so one has ${1 \over 2}( 1-c( H) ) ^2 + {1 \over 2}[ 2( 0-c( H) ) ^2]$, which is minimised at c(H) = 1/3. I used this form of the expectation formula to show that using expected total inaccuracy for the classic case results in weighted scoring, where the score (1 − c(H))² is weighted by 1 since there is one node (MH) with this inaccuracy score and the score (0 − c(H))² is weighted by 2 because there are two nodes (MT and TT) with this inaccuracy score. The problem is that strictly proper scoring rules (e.g., the Brier score) weighted with unequal positive weights stop being strictly proper (see footnote 12), but strict propriety is one of the fundamental assumptions in accuracy-based arguments, e.g., see Pettigrew (Reference Pettigrew2016: 66). So, unless one can find a strictly proper weighted scoring rule (with unequal positive weights), I do not consider expected total inaccuracy a suitable method for the classic case; although, Kierland and Monton say that they do not have a conclusive reason to prefer expected total or average inaccuracy minimisation for the classic case, see Kierland and Monton (Reference Kierland and Monton2005: 390).

Kierland and Monton, however, say that one should refrain from using expected total inaccuracy minimisation for the duplicating case (see Kierland and Monton Reference Kierland and Monton2005: 393). Remember that expected total inaccuracy sums the inaccuracy score (weighted by a probability) for each node, but it does not say to whom those nodes should belong. This is fine for the classic case where all nodes belong to a single agent (i.e., Beauty), but it matters in the duplicating case. When Kierland and Monton minimise expected total inaccuracy for the duplicating case, they minimise it for the original Beauty and a possible duplicate of her together (see Kierland and Monton, Reference Kierland and Monton2005: 393). So, e.g., considering Figure 2, the expectation formula is given by $P_{MH_{org}}( 1-c( H) ) ^2 + P_{MT_{org}}( 0-c( H) ) ^2 + P_{TT_{dup}}( 0-c( H) ) ^2$. For $P_{MH_{org}} = P_{MT_{org}} = P_{TT_{dup}} = {1 / 2}$, one gets the optimal credence of 1/3 in Heads. This expectation formula is very similar to the one from the previous paragraph for the classic case, but the current formula mixes inaccuracy scores of the original Beauty (i.e., the inaccuracy scores for MH _org and MT _org) and her duplicate (i.e., the inaccuracy score for TT _dup). Kierland and Monton say that scores of different agents should not be mixed, i.e., one should focus only on her own expected inaccuracy and should not care about the inaccuracies of other people. Since their approach to computing expected total inaccuracy for the duplicating case mixes inaccuracy scores of different agents, Kierland and Monton dismiss expected total inaccuracy minimisation as an appropriate epistemic goal for the duplicating case (see Kierland and Monton Reference Kierland and Monton2005: 393).

Still considering the duplicating case, Builes (Reference Builes2020: 3038–40) computes expected total inaccuracy focusing on minimising one's own expected inaccuracy and concludes that Beauty ought to have a credence of 1/2 in Heads when she wakes up. The idea is that, regardless of whether the coin lands Heads or Tails, there always is only one epistemically possible centre (node) that is her (see Builes Reference Builes2020: 3038–9, fn 9). If the coin lands Heads, Beauty's total inaccuracy will be (1 − c(H))² since there is only one node where Heads is true. If the coin lands Tails, the agent knows that she is either Beauty (and not the duplicate) or that she is the duplicate (and not the original Beauty). Those are two mutually exclusive options, each with the inaccuracy score of (0 − c(H))². So, only one of them is epistemically possible (or relevant), and one's total inaccuracy is (0 − c(H))². Thus, for a fair coin, Beauty should minimise 1/2(1 − c(H))² + 1/2(0 − c(H))², which gives c(H) = 1/2 as optimal. In contrast, for the classic case, Builes argues (Reference Builes2020: 3036–7) that minimising expected total inaccuracy recommends the credence of 1/3 in Heads. Given Builes’ approach, minimising expected total inaccuracy recommends different optimal credences in Heads for the classic and the duplicating case. Builes further argues (Reference Builes2020: 3039) that the difference in recommendation results from the change in personal identity facts from one scenario to the other. So, the recommendations that minimising expected total inaccuracy gives explicitly depend on the personal identity facts, which is inconsistent with Time-Slice Rationality. Thus, time-slicers should minimise expected average inaccuracy and not expected total inaccuracy (see Builes Reference Builes2020: 3040).

One can reconstruct Builes’ reasoning for Figure 2 and Figure 4. I expressed my worries about using Figure 2 to model the duplicating case,Footnote ¹³ so I will consider only Figure 4. Consider player 1 with {MH ₁, MT ₁, TT ₁}; from now on, I will use player 1 as my main example when discussing Figure 4, but all my reasoning can be easily reapplied to player 2 and {MH ₂, MT ₂, TT ₂}. If Heads, she will be at MH ₁ with a score of (1 − c(H))² or not woken up at all. So, there is only one relevant node of her, and her total inaccuracy is (1 − c(H))². If Tails, player 1 will be either at MT ₁ or TT ₁ with a score of (0 − c(H))² at each (but she cannot be at both nodes since the trees represent mutually exclusive situations). So, there is again only one relevant node for player 1 if Tails and her total inaccuracy is (0 − c(H))². Since, regardless of whether the coin lands Heads or Tails, there is always only one relevant node for player 1, she should minimise 1/2(1 − c(H))² + 1/2(0 − c(H))² if the coin is fair. If, for example, player 1 is the original Beauty, then her optimal credence in Heads is 1/2. But one could argue that all nodes in {MH ₁, MT ₁, TT ₁} belong to player 1, so if one uses inaccuracy scores from all those three nodes to compute expected total inaccuracy for player 1, then player 1 still focuses on her own inaccuracy. That is, there is no mixing of inaccuracy scores from nodes belonging to different agents since player 1 uses inaccuracy scores from nodes that belong only to her and considers no scores from nodes that belong to player 2. Expected total inaccuracy of player 1 is then given by $P_{MH_1}( 1-c( H) ) ^2 + P_{MT_1}( 0-c( H) ) ^2 + P_{TT_1}( 0-c( H) ) ^2$, which is almost the same expectation formula as Kierland and Monton's formula for the duplicating case. For $P_{MH_1} = P_{MT_1} = P_{TT_1} = {1 / 2}$,Footnote ¹⁴ it still holds that the optimal credence in Heads is 1/3, and the weighted expectation is not strictly proper, i.e., is unsuitable for accuracy-based arguments. But the difference is that one uses nodes MH ₁, MT ₁, and TT ₁ instead of MH _org, MT _org, and TT _dup, so all the nodes now belong to the same agent, i.e., player 1.

I have so far assumed that focusing on one's own expected inaccuracy means not mixing the inaccuracy scores of different players. That is, in Figure 4, one does not mix scores of player 1 from nodes in the set {MH ₁, MT ₁, TT ₁} with scores of player 2 from nodes in {MH ₂, MT ₂, TT ₂}. But there is a stricter interpretation of how to focus on one's own expected inaccuracy. That is, no player should mix the inaccuracy scores from the nodes where she is the original Beauty with the inaccuracy score(s) from the node(s) where she is the duplicate. For player 1, this excludes inaccuracy scores from any node in {MH ₂, MT ₂, TT ₂} but also separates inaccuracy scores she gets at MH ₁ and MT ₁ (since this is where player 1 is the original Beauty) from the score at TT ₁ (it is where she is the duplicate). Then, player 1 always computes expected total inaccuracy with respect to only one tree and ignores the other (since she is the original Beauty in the tree with MH ₁ and MT ₁ and the duplicate in the tree with TT ₁). Given a fair coin, c(H) = 1/2 is optimal for the tree with MH ₁ and MT ₁ and c(H) = 0 is optimal for the tree with TT ₁. These, however, are not helpful recommendations since they only say what to do if one is in a specific tree. But that is all one can do under the stricter interpretation. For the sake of argument, assume one tries to find a followable advice by taking the expected total inaccuracy for each tree and weights it by the probability that one finds herself in the given tree to create an overall expectation formula. One now mixes inaccuracy scores from MH ₁ and MT ₁ with the score from TT ₁, which is prohibited in this interpretation of “one's own inaccuracy”.

In general, I agree that one should focus on one's own expected inaccuracy. But, as I have shown, one can still take multiple approaches to compute expected total inaccuracy, and I do not have a definitive reason to prefer one over the other. However, the consensus (albeit for different reasons) between Builes, Kierland and Monton, and me is that one should not minimise expected total inaccuracy in the duplicating case; I have also expressed my strict-propriety-related reason why I think that it is a wrong approach to the classic case.

Let me now turn to the minimisation of expected average inaccuracy. The idea is that the sum of every achievable score is averaged by the number of nodes (i.e., time-slices, temporal parts, or centres) where that score can be achieved. For the classic scenario in Figure 1, one has two nodes with the result Tails (i.e., score of (0 − c(H))²) and one node with the result Heads (i.e., score of (1 − c(H))²). So, one divides the sum (0 − c(H))² + (0 − c(H))² by 2 and (1 − c(H))² by 1, which gives: $P_{MH}( 1-c( H) ) ^2 + {1 \over 2}[ P_{MT}( 0-c( H) ) ^2 + P_{TT}( 0-c( H) ) ^2]$. One then multiplies the score for each achievable node by the probability of it being achieved. For P _MH = P _MT = P _TT = 1/2, one gets ${1 \over 2}( 1-c( H) ) ^2 + {1 \over 2}( 0-c( H) ) ^2$, which is minimised at c(H) = 1/2, given the strict propriety of the Brier score. In contrast to the expected total inaccuracy, averaging the scores ensures that one does not end up with a weighted scoring rule (e.g., the weighted Brier score discussed in footnote 12) that is not strictly proper due to unequal positive weights.

In the duplicating case (consider Figure 4), expected average inaccuracy works the same as in the classic case, but one uses the decision nodes from the information set {MH ₁, MT ₁, TT ₁} or {MH ₂, MT ₂, TT ₂}. That is, an agent averages over the inaccuracy scores she receives at nodes in her information set. For example, consider player 1 and {MH ₁, MT ₁, TT ₁}. If $P_{MH_1} = P_{MT_1} = P_{TT_1} = {1 / 2}$, then one has $P_{MH_1}( 1-c( H) ) ^2 + $ ${1 \over 2}[ P_{MT_1}( 0-c( H) ) ^2 + P_{TT_1}( 0-c( H) ) ^2] = 1{\rm /}2( 1-c( H) ^2) + 1{\rm /}2( 0-c( H) ) ^2$ that is minimised at c(H) = 1/2. Consider now the duplicating case with n ∈ ℕ duplicates (a generalisation of Figure 7 for n + 1 agents), so a single agent considers n + 1 nodes where Tails is true. Let, for example, TT _1n be a node at which player 1 considers to be an nth duplicate. If $P_{MH_1} = P_{MT_1} = P_{TT_{11}} = \cdots = P_{TT_{1n}} = {1 / 2}$ (see footnote 14), the expected average inaccuracy will always recommend the credence of 1/2 in Heads because any number of (0 − c(H))² (i.e., scores for nodes where Tails is true) will be averaged out. That is, for n duplicates, the expected average inaccuracy formula is given by ${1 \over 2}( 1-c( H) ) ^2 + {1 \over 2}{1 \over {n + 1}}[ ( n + 1) ( 0-c( H) ) ^2] = {1 \over 2}( 1-c( H) ) ^2 + {1 \over 2}( 0-c( H) ) ^2$, which is minimised at c(H) = 1/2.

One could ask why one should not differentiate, for example, between MH ₁ and MT ₁ on one side and TT ₁ on the other side (as I discussed earlier for the expected total inaccuracy). I think this would go against the idea of expected average inaccuracy. Kierland and Monton defended the expected average inaccuracy for the duplicating scenario by saying that: “If her goal is to minimise her own expected inaccuracy, then she should minimise the expected average inaccuracy for her and the possible duplicate of her, since she does not know which of those possible individuals she is” (Kierland and Monton Reference Kierland and Monton2005: 393). The general idea is that averaging minimises the expected inaccuracy of one's current node (time-slice), so one always focuses on her own inaccuracy (compare with Kierland and Monton Reference Kierland and Monton2005: 390, or Builes Reference Builes2020: 3039). That is, the reason (exploring different ways in which one can focus on one's own expected inaccuracy) why I considered MH ₁ and MT ₁ separately from TT ₁ for the expected total inaccuracy does not apply here since expected average inaccuracy, by definition, focuses on the expected inaccuracy of one's current node (i.e., one's own expected inaccuracy). Moreover – as mentioned in the quote – when one minimises expected average inaccuracy, one should also consider the possibility that she is the duplicate. So, separating MH ₁ and MT ₁ (where player 1 is the original Beauty) from TT ₁ (where player 1 is the duplicate) does not make sense for the expected average inaccuracy. But also note that, when computing expected average inaccuracy (e.g., in Figure 4), one still keeps separate inaccuracy scores from nodes belonging to different players. That is, player 1 computes expected average inaccuracy using only nodes from {MH ₁, MT ₁, TT ₁} and player 2 computes it using inaccuracy scores only from nodes in {MH ₂, MT ₂, TT ₂}. Since each information set contains a TT node, despite considering nodes only from one's own information set, each player also considers the possibility that she is the duplicate.

Overall, I agree with Builes, Kierland, and Monton – and my models in Figure 1 and Figure 4 (i.e., its generalisations for n duplicates) can accommodate it – that (for a fair coin) the expected average inaccuracy recommends a credence of 1/2 in Heads for both scenarios. I also agree that the expected total inaccuracy is not an optimal accuracy-based approach to the duplicating case. Moreover, I agree with Builes that minimising expected total inaccuracy is not a suitable method for the classic scenario, but I think this holds not only for time-slicers. For reasons discussed in section 4, I, however, disagree that the classic and the duplicating scenario are structurally identical (at least in game-theoretic terms) or that the only (epistemically) relevant difference between those two scenarios concerns identity facts, e.g., compare with Builes (Reference Builes2020: 3038–9) or Kierland and Monton (Reference Kierland and Monton2005: 392). I consider the change/difference in the personal identity facts (introducing a new player or players, i.e., a duplicate or duplicates) from one scenario to the other to be fundamental or the most relevant in the sense that it is the change/difference that leads to other – at least game-theoretic but still epistemically relevant – changes/differences between the classic and duplicating Sleeping Beauty scenario.