1. Introduction
Throughout the history of quantum mechanics, it has been noted that observers seem to play a special role in the theory, and this has led to speculations that there is something observer dependent or perspectival about quantum mechanics. Separately, the central role of relational observables in general relativity and quantum gravity also seems to point to a special role for internal perspectives in the formulation of a diffeomorphism-invariant physical theory.
Such developments have motivated the development a class of views that I will refer to as physical perspectivalism. These views often de-emphasize consciousness and instead focus on perspectives, defined by physical systems that play the role of a reference frame. A common thread running through this class of views is the idea that it is a mistake to try to formulate a “view from nowhere,” and this statement is often interpreted to mean that there cannot be any kind of fact about physical reality that is not relativized to a perspective.
However, it is possible that the tendency to move immediately to this particularly strong form of perspectivalism has obscured some of the insight that could be offered by the perspectival approach. We should also consider intermediate options, such as the view that I will call moderate physical perspectivalism, which maintains that empirically meaningful facts must be relativized to physical perspectives but also admits the existence of some perspective-neutral facts.
My goal in this article is, first, to articulate more clearly the distinctions between strong physical perspectivalism and moderate physical perspectivalism and between epistemic perspectivalism and physical perspectivalism. And second, to argue that both scientific evidence and philosophical considerations point more strongly toward moderate physical perspectivalism than strong physical perspectivalism. Specifically, I will consider a number of arguments and intuitions from both physics and philosophy that may seem to support strong physical perspectivalism, and I will argue that they actually support moderate physical perspectivalism instead.
I will begin in section 2 by explaining the scientific case for physical perspectivalism and differentiating between strong and moderate physical perspectivalism. In section 3, I will argue that the scientific evidence currently favors moderate physical perspectivalism over strong physical perspectivalism. Then, in section 4, I will explore the relationship between epistemic perspectivalism and physical perspectivalism, arguing that various epistemic considerations that appear to motivate some physical perspectivalists are in fact motivations only for moderate physical perspectivalism, not strong physical perspectivalism. Finally, in section 5, I will consider some methodological recommendations for scientific practice that might follow from moderate physical perspectivalism, thus demonstrating that perspectivalism can potentially give valuable insights into the quantum measurement problem even if we adopt only moderate rather than strong physical perspectivalism.
2. Perspectives in physics
Recent developments in the foundations of physics have emphasized the role of perspectives in physical science. The motivations for this are twofold. First, in the context of quantum mechanics, it has been argued that some form of perspectivalism may help to resolve the Wigner’s friend paradox (Wigner, Reference Wigner and Mehra1961) and various extended Wigner’s friend paradoxes (Bong et al., Reference Bong, Aníbal Utreras-Alarcón, Yeong-Cherng Liang, Cavalcanti, Pryde and Wiseman2020). Second, in the context of general relativity and quantum gravity, it has been argued that physically meaningful observables must be understood in relational terms, meaning that they must be relativized to something like a reference frame or “perspective” (Rovelli, Reference Rovelli1996). The fact that both theories exhibit perspectival elements has been identified as a possible connection that might help make progress toward a unified theory of quantum gravity (Vidotto, Reference Vidotto and Allori2022). This line of thought goes right back to Bohr (Reference Bohr1929), who argued that there is no “view from nowhere” from which quantum systems can be described and connected this idea to relativistic principles: “the theory of relativity reminds us of the subjective character of all physical phenomena.” Thus, it seems potentially very important to understand exactly what form of perspectivalism is indicated by these developments.
In the Wigner’s friend scenario (Wigner, Reference Wigner1960), an observer, Alice, performs a quantum measurement on a system
$S$
inside a closed laboratory while another observe, Bob, looks on. Alice presumably now knows a definite value for some variable of
$S$
, but if Bob describes the whole scenario using standard unitary quantum mechanics, he predicts that Alice and
$S$
are now in a state
${\psi _{AS}}$
corresponding to a superposition of all of the possible measurement outcomes, so to him it appears as if Alice has not seen a definite value for any variable of
$S$
. Thus, this scenario motivates the adoption of some kind of perspectival view, in order that we can say that the state of
$S$
is different relative to Alice and to Bob (Dieks, Reference Dieks2022).
Meanwhile, a central feature of general relativity is the fact that it exhibits diffeomorphism invariance (Wallace, Reference Wallace, Brading and Castellani2002; Earman, Reference Earman2002), and many physicists expect that a successful theory of quantum gravity will also exhibit diffeomorphism invariance. In such a theory, it is usually assumed that histories related by a diffeomorphism are one and the same history, so physically meaningful observables must be invariant under diffeomorphisms (Wallace, Reference Wallace, Brading and Castellani2002; Earman, Reference Earman2002). And it appears that the class of diffeomorphism-invariant observables best suited to express the kind of empirical content available to observers like us is relational observables (Rickles, Reference Rickles and Dieks2008), for example, observables of the form “the position of the pendulum relative to the clock reading a time
$t$
.”
One influential approach to this issue, originated by Rovelli (Reference Rovelli2002), makes use of the notion of a “partial observable,” that is, a physical quantity such as position, mass, and charge, “to which we can associate a measuring procedure leading to a number.” Partial observables are not diffeomorphism invariant and hence are not physically real according to the standard interpretation of diffeomorphism-invariant theories, but the relations between partial observables are diffeomorphism invariant, and thus these relations constitute “complete observables” that are physically real according to the standard interpretation. Although partial observables are not real on their own, we can arrive at a physically meaningful description in terms of partial observables by means of adopting a “perspective” to which these observables can be relativized. Thus, it is possible for us to “observe” partial observables even though they are not individually physically real; we can observe them provided that they are relativized appropriately to our measuring instrument or body (Rovelli and Vidotto, Reference Rovelli, Vidotto, Bambi, Modesto and Shapiro2023). So, this way of thinking about observables in a diffeomorphism-invariant theory naturally leads to a form of perspectivalism.
2.1. Physical perspectivalism
The increasing emphasis on perspectives in the foundations of physics has given rise to a class of views that I will refer to as physical perspectivalism, suggesting that physically meaningful descriptions must always be relativized to a perspective.
It is important to emphasize that physical perspectivalism is not primarily about knowledge. This is clear from the role that physical perspectivalism is supposed to play in the Wigner’s friend experiment. In this experiment, if we think the state
${{\boldsymbol\psi} _{AS}}$
assigned by Bob merely reflects Bob’s lack of knowledge about Alice’s measurement outcome, we will naturally conclude that the true state of Alice and
$S$
is
$\phi _{AS}^i = \left| {i{\rangle _A} \otimes } \right|i{\rangle _S}$
, where
$i$
corresponds to the definite value that Alice has actually seen. But if unitary quantum mechanics is correct, it must be the case that when Bob subsequently performs measurements on Alice and
$S$
, he will always see outcomes consistent with the state
${{\boldsymbol\psi} _{AS}}$
, which are different from the outcomes we’d expect to see if the true state were either
$\phi _{AS}^i$
or some probabilistic mixture of states of the form
$\phi _{AS}^i$
. Therefore, the idea that the state is
${{\boldsymbol\psi} _{AS}}$
relative to Bob cannot be merely a characterization of Bob’s ignorance but must be a substantive assertion about the actual dynamics that will take effect when Bob interacts with Alice and
$S$
. To resolve the puzzle, we need physical perspectivalism to be a claim about physics rather than epistemology.
Because physical perspectivalism is not about knowledge, the “perspectives” to which facts are relativized need not be associated with possible knowers, so consciousness need not play any special role in this kind of perspectivalism. Thus, although some physical perspectivalists, such as Brukner (Reference Brukner2021) and Cavalcanti (Reference Cavalcanti2021), do focus on perspectives associated with conscious agents, it’s not clear that this limitation is well motivated. Other physical perspectivalists have employed a more liberal notion of a perspective: Any physical system can act as the origin of a coordinate system relative to which we may describe the position of other physical systems, and physical perspectivalism generalizes this idea, suggesting that any physical system can anchor an “internal view” relative to which we may describe the degrees of freedom of other physical systems.
One example of this approach is Rovelli’s relational quantum mechanics (Rovelli, Reference Rovelli1996), which maintains that quantum descriptions must always be relativized to an “observer” but then stipulates that any physical system can play the role of an observer. Another is Dieks’s perspectival quantum realism, which posits that “objects may possess different, but equally objective properties with respect to different physically defined perspectives” (Dieks, Reference Dieks2022). Dieks emphasizes that “realism should not focus on agents and their subjective points of view; if perspectivalism is to be part of a realist scheme, the perspectives in question should be defined with respect to physical systems.”
Physical perspectivalism also appears to be a motivator for the quantum reference frame (QRF) formalism (de la Hamette et al., Reference de la Hamette, Galley, Hoehn, Loveridge and Mueller2021; Giacomini et al., Reference Giacomini, Castro-Ruiz and Brukner2019; Castro-Ruiz et al., Reference Castro-Ruiz, Giacomini, Belenchia and Brukner2020; Vanrietvelde et al., Reference Vanrietvelde, Hoehn, Giacomini and Castro-Ruiz2020; Höhn and Vanrietvelde, Reference Höhn and Vanrietvelde2020; Giacomini and Brukner, Reference Giacomini and Brukner2022), which provides a suite of tools for defining an internal view relativized to a given physical system and for switching from one such internal view to another. Proponents of this formalism talk about “jumping into the perspective of a quantum system” (Vanrietvelde et al., Reference Vanrietvelde, Hoehn, Giacomini and Castro-Ruiz2020), but this is presumably not intended to suggest that QRFs generally have conscious perspectives. Rather, the idea is that in a universe without a fixed background space-time, we must describe physics relative to a physical system, and if that system is quantum in nature, then we will thereby be describing physics relative to a QRF.
2.2. Strong versus moderate physical perspectivalism
Let us differentiate two possible versions of physical perspectivalism. The first, which I will refer to as strong physical perspectivalism, maintains that all facts about physical reality must be relativized to a (physical) perspective. The second, which I will refer to as moderate physical perspectivalism, maintains that empirically meaningful facts about physical reality must be relativized to a (physical) perspective, where we say a fact is “empirically meaningful” if it gives a description of some part of reality in terms of phenomena of the kind that could be directly experienced by a realistic observer. Unlike strong physical perspectivalism, moderate physical perspectivalism allows that there may exist some perspective-neutral facts about physical reality, but it maintains that such facts are typically quite abstract and do not have direct empirical content.
Perspectivalists are fond of the mantra “there is no view from nowhere” (Di Biagio and Rovelli, Reference Di Biagio and Rovelli2022; Berghofer, Reference Berghofer2024), and strong physical perspectivalists typically interpret this statement as asserting that there cannot exist physical facts of any kind that are not relativized to a perspective. However, moderate physical perspectivalists would interpret this statement differently. One natural way to understand the term view is to think of it as referring to a description of some part of reality in terms that we ourselves can conceptualize or visualize—that is, a description expressed in empirically meaningful language referring to phenomena of the kind that could be directly observed by a realistic observer. And moderate physical perspectivalism does indeed maintain that any such “view” must be relativized to a physical perspective, so there is a sense in which it upholds the idea that “there is no view from nowhere.”
Even without appealing to the scientific results discussed in section 2, there are good reasons to believe that something like moderate physical perspectivalism is true. For although scientific theories are often formulated in an abstract, third-person way, in order to extract from a theory predictions that are useful for an embodied observer in a specific physical scenario, we necessarily have to move away from an abstract third-person description and adopt some kind of first-person view. As van Fraassen (Reference van Fraassen2008) puts it, “If someone is to use (special relativity) to predict the behavior of electrically charged bodies in motion, bodies with which s/he is directly concerned, choice of a coordinate system correlated to a defined physical frame of reference is required. The user must leave the God-like reflections on the structure of spacetime behind in order to apply the implications of those reflections to his or her actual situation.” That is, realistic observers necessarily have experiences from within a particular embodied perspective, so any empirical content of the kind that could be experienced by a realistic observer must at least implicitly appeal to the perspective of a possible observer who could have the corresponding experience.
Moderate physical perspectivalism also seems like a good way of capturing the features of quantum mechanics and relativity discussed in section 2. We have seen that the Wigner’s friend paradox pushes us toward relativizing quantum states to perspectives, and quantum states encode predictions for measurement outcomes that could be obtained by observers, so they fall into the category of “empirically meaningful descriptions.” Thus, the relativization of states to perspectives in a quantum context looks like an instance of the idea that empirically meaningful descriptions must be relativized to a perspective. Meanwhile, in the framework of partial/complete observables, statements about phenomena that could be experienced by observers are necessarily expressed in terms of partial observables, and the formalism tells us that partial observables must always be relativized to some physical system or “perspective,” so again we have an instance of the idea that empirically meaningful facts should be relativized to a perspective.
Additionally, because perspectivalism has been cited as a potential route to unifying quantum mechanics and relativity, we should consider what is suggested by the combination of both theories. At present, it is not straightforward to extract empirical content from existing proposals for full theories of quantum gravity, so I will instead address this question by considering some general consequences of the Dirac quantization procedure (Dirac, Reference Dirac1981), which is the usual approach to quantizing theories subject to constraints. Because many physicists expect that a theory of quantum gravity will satisfy diffeomorphism invariance just as general relativity does, a natural way of approaching the problem is to use Dirac quantization with a diffeomorphism constraint.
In the process of Dirac quantization, we start from a “kinematical” Hilbert space encoding the most general possibilities, and we impose constraints in order to move to a “physical” Hilbert space encoding only states that are physically possible, in the sense that they respect the symmetries associated with the constraints. But in the case of a diffeomorphism constraint, the physical Hilbert space is quite abstract and contains redundancies in its representations, so “in order to make operational sense out of physical phenomena, we must make additional choices to fix these redundancies,” which can be done by choosing a system from the perspective-neutral picture to serve as our reference frame” (Vanrietvelde et al., Reference Vanrietvelde, Hoehn, Giacomini and Castro-Ruiz2020). That is, once again, we find that in order to extract empirically meaningful content, it is necessary to adopt an internal reference frame; thus, current ideas about quantum gravity also seem to support the idea that empirically meaningful descriptions must be relativized to perspectives.
3. Scientific evidence
It appears that considerations from quantum mechanics and relativity do provide support for the idea that empirically meaningful descriptions typically have to be relativized to a perspective. But this in and of itself does not tell us whether we should adopt moderate or strong physical perspectivalism. To make that choice, we must decide whether these considerations suggest that all facts about physical reality must be relativized to a perspective or whether they instead support the existence of some perspective-neutral facts about physical reality, over and above descriptions relativized to perspectives.
First of all, consider the quantum case. Accepting for the moment that quantum states must be relativized to physical perspectives, does that suggest that all physical facts must be relativized to physical perspectives? One way to argue for such a conclusion might involve maintaining that quantum mechanics is complete, that is, that the quantum state of a system is a complete description of all of its physical properties (Maudlin, Reference Maudlin1995). In that case, it would follow from the relativization of quantum states that there cannot be any properties of physical systems that are not relativized to a perspective.
However, there still appear to be certain kinds of relations that must remain perspective neutral. For example, the only reason why Wigner’s friend scenario poses a problem in the first place is because we are assuming that both Alice’s observations and Bob’s observations should be in accordance with the predictions of quantum mechanics. That is, the formulation of the paradox relies on the assumption that there exists a certain kind of relation between these perspectives—although Alice and Bob may differ on the outcomes of specific measurements, both perspectives exhibit the same kinds of regularities. This, if true, is a fact about physical reality. Moreover, the description of the paradox assumes that this is a perspective-neutral fact because we cannot arrive at any paradox or contradiction here if we are not able to compare the contents of the two perspectives from a third-person point of view. So, it seems impossible to even formulate the motivation for physical perspectivalism in quantum mechanics without a commitment to some kind of perspective-neutral facts about the relations between perspectives, and thus the quantum considerations described in section 2 appear more compatible with moderate physical perspectivalism than strong physical perspectivalism.
Another way to argue for strong physical perspectivalism in the quantum context would be to suggest it can be used to restore locality to quantum mechanics. For example, in the Wigner’s friend scenario described in section 2, suppose we adopt the perspectival strategy of saying that the state of
$S$
is different relative to Alice and Bob, and suppose in addition, we advocate the kind of strong perspectivalist view maintaining that Alice and Bob can never come into contact—they will never inhabit the same perspective. Then we can say that what is “real” for Alice is simply the set of facts revealed to her by her own interactions with the world, and thus because all of her interactions necessarily occur on a single world-line, nothing can ever be nonlocal. However, this move comes at a very high cost; as noted by Adlam (Reference Adlam2022), it entails that Alice cannot ever gain access to any information about Bob’s perspective, so it undermines all scientific methodologies that rely on intersubjective sharing of information. Given the essential role of the epistemic community in scientific practice, I think this cost is too high; whatever locality’s virtues, it is not so valuable that we should undermine the whole of scientific epistemology to preserve it, and thus the argument from locality does not really provide a compelling motivation for strong physical perspectivalism.
Second, consider the relativistic case. We have seen that within the partial/complete framework, empirical content is encoded in the relativized partial observables, but of course, this framework also posits complete observables in addition to partial observables. Complete observables are diffeomorphism invariant, are delocalized, and do not undergo change over time, so they do not appear to be relativized to a perspective; facts about complete observables are perspective neutral in the strongest possible sense. And although these facts do not directly describe possible experiences that any observer could have, they are clearly still facts about physical reality because the standard interpretation of diffeomorphism-invariant theories tells us that only the complete observables are physically real.
More generally, it is common to formulate diffeomorphism-invariant theories, such as general relativity, in terms of tensors because tensorial descriptions “encode the physics as experienced in any local spacetime reference frame at once: an abstract tensor has to be contracted with a vector frame, in order to determine the numbers that a corresponding observer would find in a measurement of the quantities embodied by the tensor. In this sense, tensors abstractly constitute a description of the local physics before a choice of reference frame has been made; they are reference frame perspective-neutral structures” (de la Hamette et al., Reference de la Hamette, Galley, Hoehn, Loveridge and Mueller2021). That is, the purpose of writing the equations of the theory in tensorial form is precisely to capture the perspective-neutral content of the theory. And again, these tensorial descriptions are clearly intended to encode facts about physical reality because they are considered an equally valid formulation of the theory, and indeed, many people working in the foundations of physics hold the view that all space-time theories should be formulated in a coordinate-free way based on objects like tensors (Malament, Reference Malament2012; Earman and Friedman, Reference Earman and Friedman1973; Anderson, Reference Anderson1971). So, our current understanding of diffeomorphism-invariant theories appears to presuppose the existence of perspective-neutral facts, and thus relativistic considerations appear more compatible with moderate physical perspectivalism rather than strong physical perspectivalism.
Finally, with regard to quantum gravity, we have seen that in the context of Dirac quantization, it is necessary to use something like the QRF formalism to extract empirical content out of a state defined on the physical Hilbert space. However, it remains the case that “the physical Hilbert space encodes and links all internal frame perspectives, which is why it is also called the perspective-neutral Hilbert space” (de la Hamette et al., Reference de la Hamette, Galley, Hoehn, Loveridge and Mueller2021). Thus, the global state
${\rm{\Psi }}$
defined on the physical Hilbert space represents “a perspective-neutral super structure that encodes, so to speak, all perspectives at once and requires additional choices to ‘jump’ into the perspective of a specific frame” (Vanrietvelde et al., Reference Vanrietvelde, Hoehn, Giacomini and Castro-Ruiz2020). As argued by Vanrietvelde et al. (Reference Vanrietvelde, Hoehn, Giacomini and Castro-Ruiz2020), this perspective-neutral structure plays a similar role to Minkowski space-time in special relativity, unifying all of the individual reference frames; it achieves this by virtue of a quantum coordinate map that maps from the state
${\rm{\Psi }}$
into the perspective of an individual quantum reference system, so we can always transform between internal reference frames by composing an inverse quantum coordinate map from the first reference frame to the global state
${\rm{\Psi }}$
with another quantum coordinate map from
${\rm{\Psi }}$
to the second reference frame (de la Hamette et al., Reference de la Hamette, Galley, Hoehn, Loveridge and Mueller2021). So, although the Dirac quantization procedure does support the idea that empirically meaningful facts must be relativized to perspectives, it also suggests the existence of a perspective-neutral background structure encoding the relationships between all the various physical perspectives, and therefore it provides evidence for the existence of perspective-neutral facts in a quantum theory of gravity. Thus, scientific considerations based on quantum mechanics, relativity, and their combination all seem to point toward moderate rather than strong physical perspectivalism.
4. The philosophical case against strong physical perspectivalists
The recent perspectival turn in the foundations of physics has been dominated by what appears to be strong physical perspectivalism. There is some uncertainty here because the existing literature does not distinguish clearly between what I have called strong and moderate physical perspectivalism, so it is possible that some authors who appear to be advocating strong physical perspectivalism actually intend to be advocating something more similar to moderate physical perspectivalism. However, there certainly seem to be some inclinations toward a fairly radical form of perspectivalism—for example, Brukner (Reference Brukner, Bertlmann and Zeilinger2017) takes Wigner’s friend scenarios to show that “‘facts’ can only exist relative to the observer,” and Cavalcanti (Reference Cavalcanti2021) suggests that these scenarios may motivate a move toward a pragmatic rather than a correspondence theory of truth.
Because it appears that the scientific evidence does not clearly support strong physical perspectivalism, this enthusiasm for strong perspectivalism is presumably driven to some degree by philosophical convictions rather than just scientific evidence. Thus, in this section I will consider some of the philosophical intuitions lying behind physical perspectivalism and discuss whether they in fact favor strong or moderate physical perspectivalism.
4.1. Rejecting the Cartesian–Hegelian ideal
One important motivation for physical perspectivalism is the idea that modern physics has revealed the bankruptcy of what one might call the traditional “Cartesian–Hegelian” metaphysics, in which it is assumed that the most fundamental description of reality is completely observer independent and can be characterized in wholly third-person terms. Descartes and Hegel were prominent defenders of scientific objectivity, with Descartes believing that “scientific knowledge—and especially mathematical physics—is God’s gift to humans that allows them to overcome the sorts of errors to which they are prone, largely because of their embodied nature” (Halvorson, Reference Halvorson, Kemp and Wietzkeforthcoming), and meanwhile Hegel “conceiv(ing) of the epistemic ideal as the backward-looking, stationary state of the detached spectator, i.e. the god’s eye view” (Halvorson, Reference Halvorson, Kemp and Wietzkeforthcoming). Since that time, the Cartesian–Hegelian ideal has come under sustained attack for both philosophical and scientific reasons, and many physical perspectivalists appear to see their position as a logical culmination of this intellectual development. For example, Cuffaro and Hartmann (Reference Cuffaro and Hartmann2024) write, “the ideal of an observer-independent reality is not methodologically necessary for science and … modern physics (especially, but not only, quantum theory) has taught us … that there is a limit to the usefulness of pursuing this ideal.’’
Now, we have seen that both quantum and relativistic considerations provide good reasons to question the Cartesian–Hegelian metaphysics. However, the Cartesian–Hegelian picture is characterized not only by the idea that there exists a perspective-neutral description of reality but also by the stronger claim that this perspective-neutral description constitutes the most fundamental and complete characterization of reality. One way of rejecting the Cartesian–Hegelian picture is to deny the existence claim, which leads to strong physical perspectivalism, but another way of rejecting the Cartesian–Hegelian picture is to simply deny the claim about the fundamentality of the third-person perspective while leaving the existence claim alone, which leads instead to something like moderate physical perspectivalism, in which we stipulate that both perspectival and perspective-neutral facts exist and both are equally fundamental. That is, moderate physical perspectivalism suggests that although we may be able to map between the perspectival and perspective-neutral descriptions, first-person perspectives are an essential feature of reality as we experience it, and we should not be seeking to eliminate them in favor of a third-person view. Thus, although it may well be true that quantum mechanics and/or relativity give us reasons to reject the traditional Cartesian–Hegelian metaphysical picture, this does not mean we must be strong physical perspectivalists; moderate physical perspectivalism offers an alternative way of responding to this situation.
For example, given the central role of partial observables in our empirical experience, there is a sense in which the partial observables must be taken seriously as elements of reality even though they are not individually real according to the standard interpretation; as Rickles (Reference Rickles and Dieks2008) puts it, “both spaces—the space of genuine (complete) observables and partial observables—are invested with physicality by Rovelli.” Insofar as this is a correct characterization of Rovelli’s views, one way to understand it would be to see Rovelli as investing the partial observables with physicality because he sees the first-person perspective (relative to which partial observables are defined) as having equal validity to the third-person perspective (in which complete observables are defined)—so this way of thinking about the relation between partial and complete observables does indeed look like a form of moderate physical perspectivalism.
4.2. Epistemic perspectivalism
Other philosophical intuitions lying behind the adoption of strong physical perspectivalism appear to be linked to previous philosophical perspectivalisms. There is a long tradition of such philosophical views, stretching back at least to the work of Leibniz (Reference Leibniz1714) and continuing through the work of Nietzsche (Reference Nietzsche1887), Kuhn (Reference Kuhn1996), Rorty (Reference Rorty1991), and Giere (Reference Giere2006), among many others. In general, such views maintain that all knowledge is necessarily relativized to the perspective of the knower, and no matter how hard we try to achieve “objectivity,” we will never wholly escape our perspective to achieve perspective-neutral knowledge. As Rorty (Reference Rorty1991) puts it, “the image of climbing out of our minds—to something external from which we can turn and look at them – needs to be replaced.”
Notably, these previous philosophical perspectivalisms have typically fallen into the category of what I will refer to as epistemic perspectivalism—that is, positions that pertain to what it is possible for beings like us to know or believe, rather than what exists. That is, when epistemic perspectivalists assert that “there is no view from nowhere,” this is not a claim about the existence or otherwise of perspective-neutral facts; rather, it is asserting that the “view from nowhere” is not a perspective that can be taken up by any realistic observer. Relatedly, because epistemic perspectivalism is a claim about what certain kinds of beings can know or how they can think, it is typically concerned only with “perspectives” associated with conscious subjects.
Evidently, then, these previous philosophical perspectivalisms are different from physical perspectivalism. It does seem plausible that physical perspectivalism entails some form of epistemic perspectivalism, for if all facts, or all empirically meaningful facts, must be relativized to a perspective, then it seems natural to think that knowledge of such facts must also be associated with a perspective. But the converse implication is not so obvious. Many presentations of epistemic perspectivalism explicitly endorse the existence of an external perspective-neutral reality while maintaining that we cannot have perspective-independent knowledge of it; for example, Massimi (Reference Massimi2018) defines perspectival realism as the view that “states of affairs about the world are perspective-independent; whereas our scientific knowledge claims about these states of affairs are perspective-dependent.”
It is true that there exist some philosophical views that would have the effect of erasing the distinction between epistemic and physical perspectivalism. For example, if one is committed to some form of idealism positing that (human) thought is the foundation of reality (Guyer and Horstmann, Reference Guyer, Horstmann, Edward and Nodelman2023), then the claim that agents cannot have knowledge that is not relativized to their own perspective inevitably leads to the claim that all physical facts must be relativized to a perspective. Similarly, some forms of pragmatism and positivism, or the phenomenological approaches that have recently been revisited within quantum foundations (French, Reference French2023), would erase the distinction between epistemology and ontology, so the perspectival nature of all knowledge would necessarily entail that all facts are perspectival.Footnote 1 However, these kinds of views do not combine well with versions of physical perspectivalism that attribute perspectives to all physical systems—for a description relative to a nonconscious physical system is not known or perceived by anyone, so it would not make sense for a typical idealist, positivist, or phenomenologist to see this perspective as physically meaningful. Thus, although it may be the case that the physical perspectivalists who focus on conscious perspectives are ultimately peddling a new form of idealism, positivism, or phenomenology, other physical perspectivalists who employ a more liberal notion of “perspective” cannot be considered idealists, positivists, or phenomenologists.
So, in at least some cases, it appears that physical perspectivalism must be understood as a distinct position from epistemic perspectivalism. But nonetheless, many physical perspectivalists appear to be motivated by intuitions linked to epistemic perspectivalism. In particular, one common motivation for epistemic perspectivalism is a kind of epistemic humility, based on the observation that all knowledge is possessed by physically embodied observers who are subject to various kinds of limitations in terms of their epistemic access to reality. For example, Giere’s scientific perspectivism (Giere, Reference Giere2006) is motivated by consideration of the epistemic limitations to which we are subject, such as the limitations of our scientific instruments: “instruments are sensitive only to a particular kind of input. They are, so to speak, blind to everything else. Second, no instrument is perfectly transparent. That is, the output is a function of both the input and the internal constitution of the instrument.” Giere argues that our instruments are perspectival because of the way in which existing theory influences their design and intended applications, and thus the scientific knowledge we obtain from them is also necessarily perspectival.
And some proponents of physical perspectivalism also seem to be motivated by a similar kind of epistemic humility. For example, Rovelli (Reference Rovelli2024) first notes that there are inevitable limitations on human knowledge— “we live in this space between ignorance and certainty. The two extremes are of no interest. What matters to us is the space in between”—and then uses this observation to motivate the conclusion that “reality is more tenuous than the clear-cut one imagined by the old physics models; it is made up of happenings, discontinuous events, without permanence, located with respect to one another and only existing relatively to one another.” Here, epistemic considerations are used to motivate what appears to be a form of physical perspectivalism. Similarly, Evans (Reference Evans2020) invokes Giere’s arguments about the limitations of scientific instruments to motivate a version of physical perspectivalism intended to address the Wigner’s friend paradoxes. It appears that these authors believe that the considerations that support epistemic perspectivalism also lend some support to physical perspectivalism.
And in fact, it seems plausible that epistemic humility provides some support for moderate physical perspectivalism. Such an argument might go something like this:
-
(1) Realistic observers are always subject to limitations in their epistemic access to reality.
-
(2) Therefore, all of the direct empirical content that can be experienced by a realistic observer is filtered through the lens of their epistemic limitations.
-
(3) Perspective-neutral facts about reality are, by definition, not filtered through the lens of any epistemic limitations.
-
(4) Therefore, perspective-neutral facts cannot express direct empirical content of the kind that could be experienced by a realistic observer.
But can epistemic humility support strong physical perspectivalism? Such an argument would presumably go something like this:
-
(1) Realistic observers are always subject to limitations in their epistemic access to reality.
-
(2) Therefore, scientific inquiry can only yield knowledge that is relativized to a perspective.
-
(3) Therefore, scientific inquiry cannot give us any evidence for the existence of facts that are not relativized to a perspective.
-
(4) Thus, applying Ockham’s razor, we should believe that there do not exist any facts that are not relativized to a perspective.
However, there are two important problems with this argument.Footnote 2 I will go through these two problems in some detail because I think this will help to clarify the connection between epistemic and physical perspectivalism and will therefore provide a clearer understanding of the philosophical motivations for strong physical perspectivalism.
4.2.1. Self-undermining
The first problem with the argument is that its conclusion is inconsistent with its starting premise—for if I accept that strong physical perspectivalism is correct, then I cannot meaningfully articulate the thought that I have limitations in my epistemic access to reality, and therefore I will not be able to affirm premise 1 in the earlier argument.
To see this, consider the following claim,
$C$
: “There are features of reality that my perspective fails to grasp.” Claim
$C$
is, if true, a fact about physical reality, and therefore the strong physical perspectivalist is obliged to maintain that
$C$
must be relativized to a perspective. Yet which perspective could it possibly be relativized to?
Claim
$C$
cannot be relativized to my own perspective because it explicitly makes assertions about features of reality that are external to my perspective. Could claim
$C$
be relativized to the perspective of some other system
$X$
? It seems not, because in order to make such a statement from within the perspective of
$X$
, it would be necessary for the perspective of
$X$
to have access to facts about the content of my perspective. But if the perspective of
$X$
has access to such facts, that means there exist some systematic connections between my perspective and the perspective of
$X$
, and the existence of those connections would be a fact about reality that is not relativized to any perspective, in violation of the central tenet of strong physical perspectivalism. We could try to say that the existence of such connections is themselves relativized to a third perspective
$Y$
, but that does not seem to help us, for if the connections only exist within the perspective of
$Y$
, then it will still not be possible to assert claim
$C$
relative to the perspective of
$X$
because it is not a fact relative to
$X$
that
$X$
has access to facts about my perspective. So, no matter how far we push the regress of relativization, there does not seem to be any meaningful way we can assert claim
$C$
in the context of strong perspectivalism.
One might think that although, as a strong physical perspectivalist, I cannot directly articulate the idea that I am limited in my access to the world, I might be able to observe that other agents are limited in their access to the world and then appeal to some kind of symmetry principle in order to conclude that I myself must be similarly limited in my access to the world. But this kind of reasoning is impossible for a strong physical perspectivalist because the invocation of a symmetry principle in this connection makes sense only if I regard the perspectives of others as equally real and meaningful as my own, and yet if I do that, I am asserting some kind of perspective-neutral fact about the existence or meaningfulness of those other perspectives. As soon as I take the perspectives of other observers seriously enough to admit facts about their perspectives as meaningful constraints on my own knowledge, I am necessarily stepping outside of the bounds of strong physical perspectivalism.
Now, in order to rehabilitate the argument, one might consider reframing it as something like a reductio, where we suppose, only for the sake of argument, that there exists an external reality to which we have limited access and then show that the reality assumption will always be superfluous, so it should be rejected.Footnote 3 This argument would no longer be inconsistent, but I think it would no longer capture the spirit of the intuitions that motivate perspectivalism because those who argue for perspectivalism on the grounds of epistemic modesty do not appear to be discussing our limited access to reality merely as a supposition; they take themselves to be commenting on a real and significant feature of our epistemic predicament. And indeed, there are good reasons for this, for the recognition that we are limited in our access to reality is in fact a powerful insight that has driven and continues to drive many advances in science. It is important to recognize that embodied observers are subject to specific epistemic limitations, in order that we can endeavor to understand those limitations, for once we realize that some feature of our experience is actually an artifact of our own limitations, we can often get a better grasp of the nature of the reality lying behind those experiences. For example, one way of thinking about the science of thermodynamics is that it is a resource-relative theory; that is, it describes what can be achieved by agents with certain fixed resources to manipulate systems, and thus thermodynamics is a science that helps us understand the consequences of our specific epistemic and physical limitations (Robertson and Prunkl Reference Robertson and Prunkl2023). This way of thinking about scientific theories seems to be ruled out if we adopt a view that cannot acknowledge the potential existence of features of reality beyond the perspective of an individual agent. So, entertaining the possibility that we have limited access to reality only in order to dismiss it seems insufficient here; we will miss out on important scientific insights if we do not let ourselves try to imagine features of reality beyond the perspective of an individual agent.
So in fact, although epistemic humility is certainly laudable, it actually seems that strong physical perspectivalism prevents us from doing justice to the insights that follow from epistemic humility. If we want to make use of such insights, we are better off adopting something like moderate physical perspectivalism, which allows us to maintain the existence of a third-person reality within which our own perspective can be situated and thus allows us to coherently discuss the limitations of our own perspective. In so doing, we of course acknowledge that we will never know all of the facts about that third-person reality, but even simply acknowledging the ways in which our perspectives are limited can be a useful aid to progress. As Nagel (Reference Nagel1986) puts it, “it is necessary to combine the recognition of our contingency, our finitude, and our containment in the world with an ambition of transcendence, however limited may be our success in achieving it. The right attitude in philosophy is to accept aims that we can achieve only fractionally and imperfectly, and cannot be sure of achieving even to that extent.”
4.2.2. Moderate epistemic perspectivalism
The second problem with this argument pertains to the move from premise 1 to premise 2 because the fact that observers are always subject to limitations in their epistemic access to reality does not imply that all knowledge is relativized to an individual perspective, unless we make the additional assumption that there is no possible way in which individual observers can transcend their epistemic limitations, and this assumption seems questionable.
For example, consider the following statement of perspectivalism: “(various different forms of perspectivalism) share the general idea that there is no ‘view from nowhere,’ and that scientific knowledge cannot transcend a human perspective” (Ruyant, Reference Ruyant2020). There is an essential ambiguity in this kind of statement. If the claim is that scientific knowledge cannot transcend the perspective of an individual human, then the claim is wrong. Scientific knowledge is created and possessed by an entire epistemic community, and in that sense, it does transcend the perspective of any one individual. Conversely, if the claim is that scientific knowledge cannot transcend certain limitations that are shared by all humans, then the claim is probably right, but it’s no longer clear that this claim entails that there is no “view from nowhere,” in the strongest sense of that phrase, because knowledge belonging to our entire epistemic community is not a view from any specific place and time; it is delocalized over many individual perspectives at different places and times, and thus even if it is not precisely a view from nowhere, it is nonetheless also not a view from any particular location.
Moreover, the knowledge of the community is not just the sum of knowledge from a variety of individual perspectives; it also includes the relations between these perspectives, and a fact about the relation between two perspectives is not itself internal to either of those perspectives. That is, trivially, Alice can observe only Alice’s observations, and Bob can observe only Bob’s observations, and the relation between an observation of Alice and an observation of Bob does not belong to the set of either of their observations. Alice can, of course, ask Bob about his observation in order to make inferences about this relation, but what she observes in that case is his response to her, not the relation itself; in order to use his response to arrive at beliefs about the actual relationships between their observations, she must take Bob seriously as an epistemic peer and acknowledge his observations as meaningful constraints on her own knowledge. Thus, by acting as a community, we can broaden our perspective away from the view of any individual, so this methodology represents progress toward knowledge of facts that are not relativized to a perspective. For example, Nietzsche (Reference Nietzsche1887) espoused a version of perspectivalism in which, by acting as a community, we may “approach ‘objectivity’ (in a revised conception) asymptotically, by exploiting the difference between one perspective and another, using each to overcome the limitations of others” (Anderson, Reference Anderson, Edward and Nodelman2024). More recently, Longino (Reference Longino1990) argues that the process of discussion and critique of scientific ideas across the community is a defining property of scientific practice that helps to “average out” individual limitations and biases in order to produce knowledge that has more weight than the conclusions that could be drawn by any individual alone. Of course, these social practices are not going to transcend all of our limitations, but nonetheless, they represent progress toward knowledge of something perspective neutral.
Moreover, if we look at the reality of actual scientific practice, it is clear that science does and always has included both first-person and third-person views on the world. This is particularly clear in the theory of special relativity, which provides us with tools for describing physics relative to individual perspectives but also provides us with Minkowski space-time in order to formulate a third-person, “god’s-eye” description of the way in which all of the perspectives are related (van Fraassen, Reference van Fraassen2008). It would be very strange to argue that either the first- or the third-person descriptions should be eliminated from special relativity; we need first-person descriptions relative to reference frames in order to obtain useful predictions from the theory, but we also need the third-person descriptions to reveal the underlying invariant structures. Although authors may disagree on whether the reference frame description or the Minkowski space-time description is more “fundamental,” there is no reason to think that either kind of description is illegitimate or meaningless.
These considerations motivate what we might call moderate epistemic perspectivalism—a class of views that emphasize the essential role of first-person knowledge in science but nonetheless maintain that it is sometimes possible to transcend the limitations of one’s individual perspective. For example, Shimony (Reference Shimony1993) argues that the epistemology of science can be understood as a process of “closing the circle,” which “envisages the identification of the knowing subject (or more generally, the experiencing subject) with a natural system that interacts with other natural systems. In other words, the program regards the first person and an appropriate third person as the same entity.” The methodology of closing the circle does not involve eliminating either the internal or the external view in favor of the other; it is simply a process of learning to map between them. Similarly, Nagel (Reference Nagel1986) emphasizes that in science and in intellectual activity more generally, we are constantly navigating between first-person and third-person views of reality, and he contends that we should resist the tendency to eliminate one type of view in favor of the other: “the correct course is not to assign victory to either standpoint but to hold the opposition clearly in one’s mind without suppressing either element.” Thus both Nagel and Shimony appear to be advocating what I have called moderate epistemic perspectivalism.
And the possibility of some kind of moderate epistemic perspectivalism is highly relevant to physical perspectivalism, for if it turns out that the relevant epistemic considerations support only moderate epistemic perspectivalism and not strong epistemic perspectivalism, then surely insofar as those epistemic considerations imply anything about physical reality, they can only support moderate physical perspectivalism and not strong physical perspectivalism. After all, if we conclude that, in fact, observers in our actual world do sometimes have knowledge about features of reality that are not relativized to an individual perspective, it is then surely impossible to maintain that there do not exist any features of reality that are not relativized to an individual perspective, and thus strong physical perspectivalism collapses. Thus, it seems to me that the argument from epistemic humility is not, in fact, a good motivation for strong physical perspectivalism; these epistemic considerations point much more strongly toward moderate physical perspectivalism.
4.3. First-person-plural views
In light of concerns about the social nature of science, some epistemic perspectivalists have adopted what we might call a first-person-plural view, where perspectives are associated not merely with single individuals but also with entire epistemic communities. Thus, epistemic perspectivalists can accept that, indeed, social features of science allow us to transcend the perspectives of individual observers, but they still maintain that the resulting knowledge is relativized to a perspective—it is simply the perspective of the whole epistemic community, rather than an individual observer. For example, Rorty (Reference Rorty1991) argues that “whatever good the ideas of ‘objectivity’ and ‘transcendence’ have done for our culture can be attained equally well by the idea of a community which strives after both intersubjective agreement and novelty.”
And in light of the concerns expressed in the previous section, physical perspectivalists might be tempted to make a similar move. This would involve arguing that in addition to facts relativized to the perspectives of individual observers, there also exist facts relativized to some kind of emergent perspective that results from information being shared across a community, so physical perspectivalists can acknowledge the role of the community in the acquisition of scientific knowledge.
One example of such a view is Healey’s “desert pragmatism” (Healey, Reference Healey2012), in which quantum states and measurement outcomes are relativized to the situation defined by a “decoherence environment,” that is, a region of space-time in which environmental decoherence stabilizes the value of some variable such that it can meaningfully be assigned a value. Because decoherence will spread rapidly through a community of macroscopic observers, it is reasonable to expect that the entire human community belongs to the same decoherence environment, so Healey’s picture suggests that our entire epistemic community shares a set of relativized facts about quantum states and outcomes.
Similarly, Evans (Reference Evans2020) puts forward a notion of “perspectival objectivity,” in which “a scenario in which some feature of the world is in part a function of the agent perspective while at the same time, given such a perspective that is inescapably shared between similar agents, there is an (intersubjectively) objective fact of the matter concerning that feature.” Evans (Reference Evans2020) appears to be arguing that this kind of objectivity can exist even in the context of physical perspectivalism because he explains the motivation for the view as follows: “to attempt to accommodate the recent claims from quantum foundations that quantum mechanics rules out the possibility of ‘observer-independent facts.’” That is, Evans is positing that in the context of physical perspectivalism, the process of sharing information can bring into being a higher-level emergent perspective associated with a whole epistemic community, and thus we can still do justice to the important role of intersubjective sharing of information as a means of achieving a higher level of objectivity.
Now, both of these approaches work well in the context of moderate physical perspectivalism. For example, Evans’s notion of perspectival objectivity would be a helpful way for the moderate physical perspectivalist to explain how empirically meaningful facts relativized to individual perspectives can nonetheless be understood as having a kind of objectivity by virtue of the way in which they are shared between the perspectives of different agents.
But can such approaches be employed in the context of strong physical perspectivalism? This seems challenging because strong physical perspectivalism is committed to denying the existence of any mechanisms that could bring about connections between the perspectives of different agents. Moderate physical perspectivalists can maintain that there exists some kind of perspective-neutral underlying structure that connects all of the perspectives together and explains the relations between them, such as Minkowski space or the global state
${\rm{\Psi }}$
described in section 3, but strong physical perspectivalists cannot allow such a possibility; they would have to insist that facts about such a structure must themselves be relativized to something, and thus, as Riedel (Reference Riedel2024) puts it, we inevitably end up with an “iteration of relativization.” So, we can’t simply get rid of external reality and yet maintain that information is really shared across a community; the first-person-plural approach in the context of strong physical perspectivalism amounts to telling the same story as in the moderate case but then pulling out the rug in a way that destabilizes the whole view.
We can see this in action with regard to Evans’s concept of perspectival objectivity, for in order for this concept to apply to some set of observers
$\left\{ O \right\}$
in certain specific circumstances, there must exist certain facts about (a) the nature of the observers in
$\left\{ O \right\}$
; (b) their current circumstances; (c) the ways in which the observers are constrained in their access to the world; and (d) the relations that hold between different observers, such as the fact that intersubjective sharing of certain kinds of information is possible for them. But in the context of strong physical perspectivalism, we are not allowed to postulate any facts that are not relativized to a perspective, so which perspective could facts (a) through (d) be relativized to?
We might try to say that these facts are simply relativized to some particular observer
$O{\rm{'}}$
in the set
$\left\{ O \right\}$
. However, in that case, it is true only relative to that
$O{\rm{'}}$
that information is shared across the set of observers, so the “shared” information is no more objective than any other piece of information relativized to
$O{\rm{'}}$
; the higher level of objectivity that is supposed to be conferred by the fact that the information is shared by the whole community is lost.
We might try to say that facts (a) through (d) are true relative to the joint perspective of all of the observers in the set
$\left\{ O \right\}$
. But the joint perspective of a community does not simply come into being as a fundamental unit; rather, the community is brought into being by dynamical interactions that create correlations between individual perspectives, and in order to make sense of this process, we need to be able to describe these dynamical interactions in a way that does not presuppose the existence of the joint perspective that is supposed to be created by those very interactions. In addition, if we simply postulate the whole epistemic community as a fundamental unit, we will be left with no principled way to distinguish between groups of observers who share a joint perspective and groups of observers who do not: It is precisely the existence of perspective-neutral facts about the spread of information that allows us to identify when an epistemic community has been formed. Thus, in order to do justice to the dynamical, participatory formation of an epistemic community, we must be able to offer a perspective-neutral description of the way in which dynamical processes create connections between perspectives.
Finally, we might try to say that facts (a) through (d) are true relative to some other observer outside of the set
$\left\{ O \right\}$
. But it is hard to see how this would yield any meaningful notion of objectivity. What Evans wants is for the members of the community
$\left\{ O \right\}$
to be able to see their own scientific judgments as (quasi-)objective, by virtue of information being shared across the whole community, and it is no help from the point of view of an observer in the set
$\left\{ O \right\}$
that some other observer thinks the information is shared across the whole community.
Moreover, the need for perspectival objectivity to be backed up by perspective-neutral facts is clear from Evans’s motivating examples. Evans cites color vision and causation as perspectivally objective phenomena, but the perspectival objectivity of these phenomena is grounded on underlying perspective-neutral facts about how our individual perspectival experiences of these phenomena are related. For example, Evans argues that although color is not part of the fundamental furniture of the world, it has a kind of “objectivity” by virtue of the fact that most members of our epistemic community agree about judgments of color. But that agreement does not exist in a vacuum. The members of our epistemic community agree about color because there exists an underlying mechanism according to which objects reflect certain frequencies of light and the reflected light causes observers like us to have certain kinds of experiences. And the facts about which frequencies of light are reflected by a certain object are not relativized to any perspective, which is precisely what allows these facts to ground connections between color experiences featuring in two different perspectives. If there were no such mechanism connecting our experiences of color vision, we wouldn’t generally agree about judgments of color, and thus there would be no perspectival objectivity.
For these reasons, it seems to me that we cannot invoke anything like Evans’s notion of perspectival objectivity or Healey’s desert pragmatism in the context of strong physical perspectivalism. These approaches work much better if we think of them as forms of moderate physical perspectivalism. So, there exist a number of interesting routes to explore here for the moderate physical perspectivalist, but options appear very limited for the strong physical perspectivalist.
5. Methodological recommendations
A final important philosophical motivation for strong physical perspectivalism is the idea that our difficulties in interpreting quantum mechanics arise from our unwillingness to put aside the naive classical notion of an observer-independent universe.
However, in fact, moderate physical perspectivalism can offer similar kinds of resolutions to these issues, for in order to diagnose the interpretive difficulties of quantum mechanics as arising from neglect of the first-person perspective, it is not necessary to reject all perspective-neutral facts: The problem may not be that we are trying to achieve objectivity but rather that we are doing it too much or in the wrong way.
For example, Nagel (Reference Nagel1986) offers some methodological recommendations about how to properly balance the first and third-person views on reality: We should avoid “excessive impersonality,” and we should avoid “false objectification.” Excessive impersonality refers to the tendency to become so focused on the objective standpoint that we forget we are also “creature(s) with an empirical perspective and individual life.” False objectification refers to cases in which “the success of a particular form of objectivity in expanding our grasp of some aspects of reality (tempts) us to apply the same methods in areas where they will not work.”
And indeed, it appears that in the context of moderate perspectivalism, these recommendations could plausibly help us with our quantum woes. For example, one might argue that “excessive impersonality” is committed by the proponents of the Everett interpretation (Saunders et al., Reference Saunders, Barrett, Kent and Wallace2010), for quantum mechanics is, as proponents of perspectival approaches are fond of pointing out, a formalism developed by human observers as a characterization of specific aspects of the world accessible to creatures like us. But the Everett approach takes this formalism and considers it literally as an objective, observer-independent characterization of the world as a whole. From the point of view of a moderate physical perspectivalist, it may appear that the Everettian move amounts to disregarding the pragmatic, human-oriented origins of the formalism and turning it into an impersonal description in a way that is not justified by the empirical facts.
Similarly, one might argue that “false objectification” is committed by the proponents of wave-function-collapse views (Ghirardi et al., Reference Ghirardi, Rimini and Weber1986; Ghirardi, Reference Ghirardi and Edward2016). In earlier scientific theories, we have achieved significant success by taking wavelike structures seriously as literal elements of reality—such as, for example, in our understanding of sound and in the pre-quantum formulation of electromagnetism. Wave-function-collapse views extrapolate this to quantum mechanics and seek to take the quantum wave function literally as an element of reality, similar to a sound wave or electromagnetic wave, but from the point of view of a moderate physical perspectivalist, it may appear that this is a case of us being tempted to apply a particular form of objectification in an area where it will not work.
These examples indicate that although our difficulties with quantum mechanics may indeed have something to do with failures to appreciate the important role of perspectives in physics, it is not necessary to go all the way to strong physical perspectivalism to rectify these failures. Moderate physical perspectivalism already offers important new ideas about how to think about quantum descriptions, and it does so without encountering the severe conceptual difficulties that affect approaches based on strong physical perspectivalism.
6. Conclusion
There are indeed good scientific reasons, coming both from quantum mechanics and relativity, to think that physical perspectives play a central role in defining our experience of reality. But the scientific evidence appears to favor moderate physical perspectivalism over strong physical perspectivalism. And I have argued throughout this article that even at a more purely philosophical level, the motivations for strong physical perspectivalism seem dubious.
In light of this, I have two recommendations. The first is that the literature on perspectivalism in quantum mechanics and relativity would do well to keep in mind the possibility of moderate physical perspectivalism, as well as more radical forms of perspectivalism. The second is that this literature would benefit from simply making clearer distinctions between various different forms of perspectivalism because work on this subject has a tendency to equivocate between what I have called epistemic perspectivalism and physical perspectivalism and between what I have called perspectivalism and moderate physical perspectivalism. Explicitly adopting the terminology suggested in this article could help to clarify disagreements and thus foster better understanding of how current formulations of physical perspectivalism relate to earlier philosophical perspectivalisms.
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