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Each point in the Bloch ball is a possible quantum state for a qubit. In QBism, all quantum states are representations of personal probabilities.
In
physics and the
philosophy of physics,
quantum Bayesianism (abbreviated
QBism, pronounced "
cubism") is an
interpretation of quantum mechanics
that takes an agent's actions and experiences as the central concerns
of the theory. This interpretation is distinguished by its use of a
subjective Bayesian account of probabilities to understand the quantum mechanical
Born rule as a
normative addition to good decision-making. Rooted in the prior work of
Carlton Caves,
Christopher Fuchs, and Rüdiger Schack during the early 2000s, QBism
itself is primarily associated with Fuchs and Schack and has more
recently been adopted by
David Mermin. QBism draws from the fields of
quantum information and
Bayesian probability
and aims to eliminate the interpretational conundrums that have beset
quantum theory. The QBist interpretation is historically derivative of
the views of the various physicists that are often grouped together as
"the"
Copenhagen interpretation, but is itself distinct from them.
Theodor Hänsch has characterized QBism as sharpening those older views and making them more consistent.
More generally, any work that uses a Bayesian or personalist (aka
"subjective") treatment of the probabilities that appear in quantum
theory is also sometimes called quantum Bayesian. QBism, in particular, has been referred to as "the radical Bayesian interpretation".
QBism deals with common questions in the interpretation of quantum theory about the nature of
wavefunction superposition,
quantum measurement, and
entanglement.
According to QBism, many, but not all, aspects of the quantum formalism
are subjective in nature. For example, in this interpretation, a
quantum state is not an element of reality—instead it represents the
degrees of belief an agent has about the possible outcomes of measurements. For this reason, some
philosophers of science have deemed QBism a form of
anti-realism.
The originators of the interpretation disagree with this
characterization, proposing instead that the theory more properly aligns
with a kind of realism they call "participatory realism", wherein
reality consists of
more than can be captured by any putative third-person account of it.
In addition to presenting an interpretation of the existing mathematical
structure of quantum theory, some QBists have advocated a research
program of
reconstructing quantum theory from basic physical
principles whose QBist character is manifest. The ultimate goal of this
research is to identify what aspects of the
ontology of the physical world make quantum theory a good tool for agents to use. However, the QBist interpretation itself, as described in the
Core positions section, does not depend on any particular reconstruction.
History and development
British philosopher, mathematician, and economist Frank Ramsey, whose interpretation of probability theory closely matches the one adopted by QBism.
E. T. Jaynes,
a promoter of the use of Bayesian probability in statistical physics,
once suggested that quantum theory is "[a] peculiar mixture describing
in part realities of Nature, in part incomplete human information about
Nature—all scrambled up by
Heisenberg and
Bohr into an omelette that nobody has seen how to unscramble." QBism developed out of efforts to separate these parts using the tools of
quantum information theory and
personalist Bayesian probability theory.
There are many
interpretations of probability theory.
Broadly speaking, these interpretations fall into one of two
categories: those which assert that a probability is an objective
property of reality and those which assert that a probability is a
subjective, mental construct which an agent may use to quantify their
ignorance or degree of belief in a proposition. QBism begins by
asserting that all probabilities, even those appearing in quantum
theory, are most properly viewed as members of the latter category.
Specifically, QBism adopts a personalist Bayesian interpretation along
the lines of Italian mathematician
Bruno de Finetti and English philosopher
Frank Ramsey.
According to QBists, the advantages of adopting this view of
probability are twofold. First, for QBists the role of quantum states,
such as the wavefunctions of particles, is to efficiently encode
probabilities; so quantum states are ultimately degrees of belief
themselves. (If one considers any single measurement that is a minimal,
informationally complete
POVM,
this is especially clear: A quantum state is mathematically equivalent
to a single probability distribution, the distribution over the possible
outcomes of that measurement.)
Regarding quantum states as degrees of belief implies that the event of
a quantum state changing when a measurement occurs—the "
collapse of the wave function"—is simply the agent updating her beliefs in response to a new experience. Second, it suggests that quantum mechanics can be thought of as a local theory, because the
Einstein–Podolsky–Rosen (EPR)
criterion of reality can be rejected. The EPR criterion states, "If,
without in any way disturbing a system, we can predict with certainty
(i.e., with probability equal to
unity) the value of a physical quantity, then there exists an element of reality corresponding to that quantity." Arguments that quantum mechanics should be considered a
nonlocal theory
depend upon this principle, but to a QBist, it is invalid, because a
personalist Bayesian considers all probabilities, even those equal to
unity, to be degrees of belief. Therefore, while many
interpretations of quantum theory conclude that quantum mechanics is a nonlocal theory, QBists do not.
Fuchs introduced the term "QBism" and outlined the interpretation in more or less its present form in 2010, carrying further and demanding consistency of ideas broached earlier, notably in publications from 2002. Several subsequent papers have expanded and elaborated upon these foundations, notably a
Reviews of Modern Physics article by Fuchs and Schack; an
American Journal of Physics article by Fuchs, Mermin, and Schack; and
Enrico Fermi Summer School lecture notes by Fuchs and Stacey.
Prior to the 2010 paper, the term "quantum Bayesianism" was used
to describe the developments which have since led to QBism in its
present form. However, as noted above, QBism subscribes to a particular
kind of Bayesianism which does not suit everyone who might apply
Bayesian reasoning to quantum theory (see, for example, the
Other uses of Bayesian probability in quantum physics
section below). Consequently, Fuchs chose to call the interpretation
"QBism," pronounced "cubism," preserving the Bayesian spirit via the
CamelCase in the first two letters, but distancing it from Bayesianism more broadly. As this
neologism is a homonym of
Cubism the art movement, it has motivated conceptual comparisons between the two, and media coverage of QBism has been illustrated with art by
Picasso and
Gris. However, QBism itself was not influenced or motivated by Cubism and has no lineage to a potential
connection between Cubist art and Bohr's views on quantum theory.
Core positions
According
to QBism, quantum theory is a tool which an agent may use to help
manage his or her expectations, more like probability theory than a
conventional physical theory.
Quantum theory, QBism claims, is fundamentally a guide for decision
making which has been shaped by some aspects of physical reality. Chief
among the tenets of QBism are the following:
- All probabilities, including those equal to zero or one, are
valuations that an agent ascribes to his or her degrees of belief in
possible outcomes. As they define and update probabilities, quantum states (density operators), channels (completely positive trace-preserving maps), and measurements (positive operator-valued measures) are also the personal judgements of an agent.
- The Born rule is normative,
not descriptive. It is a relation to which an agent should strive to
adhere in his or her probability and quantum state assignments.
- Quantum measurement outcomes are personal experiences for the agent
gambling on them. Different agents may confer and agree upon the
consequences of a measurement, but the outcome is the experience each of
them individually has.
- A measurement apparatus is conceptually an extension of the agent.
It should be considered analogous to a sense organ or prosthetic
limb—simultaneously a tool and a part of the individual.
Reception and criticism
Jean Metzinger, 1912, Danseuse au café. One advocate of QBism, physicist David Mermin,
describes his rationale for choosing that term over the older and more
general "quantum Bayesianism": "I prefer [the] term 'QBist' because
[this] view of quantum mechanics differs from others as radically as
cubism differs from renaissance painting ..."
Reactions to the QBist interpretation have ranged from enthusiastic to strongly negative.
Some who have criticized QBism claim that it fails to meet the goal of
resolving paradoxes in quantum theory. Bacciagaluppi argues that QBism's
treatment of measurement outcomes does not ultimately resolve the issue
of nonlocality,
and Jaeger finds QBism's supposition that the interpretation of
probability is key for the resolution to be unnatural and unconvincing. Norsen has accused QBism of
solipsism, and
Wallace identifies QBism as an instance of
instrumentalism;
QBists have argued insistently that these characterizations are
misunderstandings, and that QBism is neither solipsist nor
instrumentalist. A critical article by Nauenberg in the
American Journal of Physics prompted a reply by Fuchs, Mermin, and Schack.
Some assert that there may be inconsistencies; for example, Stairs
argues that when a probability assignment equals one, it cannot be a
degree of belief as QBists say.
Further, while also raising concerns about the treatment of
probability-one assignments, Timpson suggests that QBism may result in a
reduction of explanatory power as compared to other interpretations. Fuchs and Schack replied to these concerns in a later article. Mermin advocated QBism in a 2012
Physics Today article,
which prompted considerable discussion. Several further critiques of
QBism which arose in response to Mermin's article, and Mermin's replies
to these comments, may be found in the
Physics Today readers' forum. Section 2 of the
Stanford Encyclopedia of Philosophy entry on QBism also contains a summary of objections to the interpretation, and some replies.
Others are opposed to QBism on more general philosophical grounds; for
example, Mohrhoff criticizes QBism from the standpoint of
Kantian philosophy.
Certain authors find QBism internally self-consistent, but do not subscribe to the interpretation. For example, Marchildon finds QBism well-defined in a way that, to him,
many-worlds interpretations are not, but he ultimately prefers a
Bohmian interpretation.
Similarly, Schlosshauer and Claringbold state that QBism is a
consistent interpretation of quantum mechanics, but do not offer a
verdict on whether it should be preferred. In addition, some agree with most, but perhaps not all, of the core tenets of QBism; Barnum's position, as well as Appleby's, are examples.
Popularized or semi-popularized media coverage of QBism has appeared in
New Scientist, Scientific American,
Nature,
Science News, the
FQXi Community, the
Frankfurter Allgemeine Zeitung,
Quanta Magazine,
Aeon, and
Discover. In 2018, two popular-science books about the interpretation of quantum mechanics, Ball's
Beyond Weird and Ananthaswamy's
Through Two Doors at Once, devote sections to QBism. Furthermore,
Harvard University Press published a popularized treatment of the subject,
QBism: The Future of Quantum Physics, in 2016.
Relation to other interpretations
Copenhagen interpretations
The views of many physicists (
Bohr,
Heisenberg,
Rosenfeld,
von Weizsäcker,
Peres,
etc.) are often grouped together as the "Copenhagen interpretation" of
quantum mechanics. Several authors have deprecated this terminology,
claiming that it is historically misleading and obscures differences
between physicists that are as important as their similarities.
QBism shares many characteristics in common with the ideas often
labeled as "the Copenhagen interpretation", but the differences are
important; to conflate them or to regard QBism as a minor modification
of the points of view of Bohr or Heisenberg, for instance, would be a
substantial misrepresentation.
QBism takes probabilities to be personal judgments of the
individual agent who is using quantum mechanics. This contrasts with
older Copenhagen-type views, which hold that probabilities are given by
quantum states that are in turn fixed by objective facts about
preparation procedures.
QBism considers a measurement to be any action that an agent takes to
elicit a response from the world and the outcome of that measurement to
be the experience the world's response induces back on that agent. As a
consequence, communication between agents is the only means by which
different agents can attempt to compare their internal experiences.
Most variants of the Copenhagen interpretation, however, hold that the
outcomes of experiments are agent-independent pieces of reality for
anyone to access.
QBism claims that these points on which it differs from previous
Copenhagen-type interpretations resolve the obscurities that many
critics have found in the latter, by changing the role that quantum
theory plays (even though QBism does not yet provide a specific
underlying
ontology). Specifically, QBism posits that quantum theory is a
normative tool which an agent may use to better navigate reality, rather than a mechanics of reality.
Other epistemic interpretations
Approaches to quantum theory, like QBism,
which treat quantum states as expressions of information, knowledge,
belief, or expectation are called "epistemic" interpretations.
These approaches differ from each other in what they consider quantum
states to be information or expectations "about", as well as in the
technical features of the mathematics they employ. Furthermore, not all
authors who advocate views of this type propose an answer to the
question of what the information represented in quantum states concerns.
In the words of the paper that introduced the
Spekkens Toy Model,
...if
a quantum state is a state of knowledge, and it is not knowledge of
local and noncontextual hidden variables, then what is it knowledge
about? We do not at present have a good answer to this question. We
shall therefore remain completely agnostic about the nature of the
reality to which the knowledge represented by quantum states pertains.
This is not to say that the question is not important. Rather, we see
the epistemic approach as an unfinished project, and this question as
the central obstacle to its completion. Nonetheless, we argue that even
in the absence of an answer to this question, a case can be made for the
epistemic view. The key is that one can hope to identify phenomena that
are characteristic of states of incomplete knowledge regardless of what
this knowledge is about.
Leifer
and Spekkens propose a way of treating quantum probabilities as
Bayesian probabilities, thereby considering quantum states as epistemic,
which they state is "closely aligned in its philosophical starting
point" with QBism.
However, they remain deliberately agnostic about what physical
properties or entities quantum states are information (or beliefs)
about, as opposed to QBism, which offers an answer to that question. Another approach, advocated by
Bub and Pitowsky, argues that quantum states are information about propositions within event spaces that form
non-Boolean lattices. On occasion, the proposals of Bub and Pitowsky are also called "quantum Bayesianism".
Zeilinger
and Brukner have also proposed an interpretation of quantum mechanics
in which "information" is a fundamental concept, and in which quantum
states are epistemic quantities.
Unlike QBism, the Brukner–Zeilinger interpretation treats some
probabilities as objectively fixed. In the Brukner–Zeilinger
interpretation, a quantum state represents the information that a
hypothetical observer in possession of all possible data would have. Put
another way, a quantum state belongs in their interpretation to an
optimally-informed agent, whereas in QBism,
any agent can formulate a state to encode her own expectations.
Despite this difference, in Cabello's classification, the proposals of
Zeilinger and Brukner are also designated as "participatory realism," as
QBism and the Copenhagen-type interpretations are.
Bayesian, or epistemic, interpretations of quantum probabilities were proposed in the early 1990s by
Baez and Youssef.
Von Neumann's views
R. F. Streater argued that "[t]he first quantum Bayesian was
von Neumann," basing that claim on von Neumann's textbook
The Mathematical Foundations of Quantum Mechanics.
Blake Stacey disagrees, arguing that the views expressed in that book
on the nature of quantum states and the interpretation of probability
are not compatible with QBism, or indeed, with any position that might
be called quantum Bayesianism.
Relational quantum mechanics
Comparisons have also been made between QBism and the
relational quantum mechanics (RQM) espoused by
Carlo Rovelli and others. In both QBism and RQM, quantum states are not intrinsic properties of physical systems.
Both QBism and RQM deny the existence of an absolute, universal
wavefunction. Furthermore, both QBism and RQM insist that quantum
mechanics is a fundamentally
local theory.
In addition, Rovelli, like several QBist authors, advocates
reconstructing quantum theory from physical principles in order to bring
clarity to the subject of quantum foundations.
One important distinction between the two interpretations is their
philosophy of probability: RQM does not adopt the Ramsey–de Finetti
school of personalist Bayesianism. Moreover, RQM does not insist that a measurement outcome is necessarily an agent's experience.
Other uses of Bayesian probability in quantum physics
QBism should be distinguished from other applications of
Bayesian inference in quantum physics, and from quantum analogues of Bayesian inference. For example, some in the field of computer science have introduced a kind of quantum
Bayesian network, which they argue could have applications in "medical diagnosis, monitoring of processes, and genetics". Bayesian inference has also been applied in quantum theory for updating probability densities over quantum states, and
MaxEnt methods have been used in similar ways. Bayesian methods for
quantum state and process tomography are an active area of research.
Technical developments and reconstructing quantum theory
Conceptual
concerns about the interpretation of quantum mechanics and the meaning
of probability have motivated technical work. A quantum version of the
de Finetti theorem, introduced by Caves, Fuchs, and Schack (independently reproving a result found using different means by Størmer) to provide a Bayesian understanding of the idea of an "unknown quantum state", has found application elsewhere, in topics like
quantum key distribution and
entanglement detection.
Adherents of several interpretations of quantum mechanics, QBism
included, have been motivated to reconstruct quantum theory. The goal of
these research efforts has been to identify a new set of axioms or
postulates from which the mathematical structure of quantum theory can
be derived, in the hope that with such a reformulation, the features of
nature which made quantum theory the way it is might be more easily
identified. Although the core tenets of QBism do not demand such a reconstruction, some QBists—Fuchs, in particular—have argued that the task should be pursued.
One topic prominent in the reconstruction effort is the set of
mathematical structures known as symmetric, informationally-complete,
positive operator-valued measures (
SIC-POVMs).
QBist foundational research stimulated interest in these structures,
which now have applications in quantum theory outside of foundational
studies and in pure mathematics.
The most extensively explored QBist reformulation of quantum
theory involves the use of SIC-POVMs to rewrite quantum states (either
pure or
mixed) as a set of probabilities defined over the outcomes of a "Bureau of Standards" measurement. That is, if one expresses a
density matrix
as a probability distribution over the outcomes of a SIC-POVM
experiment, one can reproduce all the statistical predictions implied by
the density matrix from the SIC-POVM probabilities instead. The
Born rule
then takes the role of relating one valid probability distribution to
another, rather than of deriving probabilities from something apparently
more fundamental. Fuchs, Schack and others have taken to calling this
restatment of the Born rule the
urgleichung, from the
German for "primal equation" (see
Ur- prefix), because of the central role it plays in their reconstruction of quantum theory.
The following discussion presumes some familiarity with the mathematics of
quantum information theory, and in particular, the modeling of measurement procedures by
POVMs. Consider a quantum system to which is associated a
-dimensional
Hilbert space. If a set of
rank-1
projectors satisfying
exists, then one may form a SIC-POVM
. An arbitrary quantum state
may be written as a linear combination of the SIC projectors
where
is the Born rule probability for obtaining SIC measurement outcome
implied by the state assignment
.
We follow the convention that operators have hats while experiences
(that is, measurement outcomes) do not. Now consider an arbitrary
quantum measurement, denoted by the POVM
. The urgleichung is the expression obtained from forming the Born rule probabilities,
, for the outcomes of this quantum measurement,
where
is the Born rule probability for obtaining outcome
implied by the state assignment
. The
term may be understood to be a conditional probability in a cascaded
measurement scenario: Imagine that an agent plans to perform two
measurements, first a SIC measurement and then the
measurement. After obtaining an outcome from the SIC measurement, the
agent will update her state assignment to a new quantum state
before performing the second measurement. If she uses the
Lüders rule for state update and obtains outcome
from the SIC measurement, then
. Thus the probability for obtaining outcome
for the second measurement conditioned on obtaining outcome
for the SIC measurement is
.
They functionally differ only by a dimension-dependent
affine transformation
of the SIC probability vector. As QBism says that quantum theory is an
empirically-motivated normative addition to probability theory, Fuchs
and others find the appearance of a structure in quantum theory
analogous to one in probability theory to be an indication that a
reformulation featuring the urgleichung prominently may help to reveal
the properties of nature which made quantum theory so successful.
It is important to recognize that the urgleichung does not
replace the law of total probability. Rather, the urgleichung and the law of total probability apply in different scenarios because
and
refer to different situations.
is the probability that an agent assigns for obtaining outcome
on her second of two planned measurements, that is, for obtaining outcome
after first making the SIC measurement and obtaining one of the
outcomes.
, on the other hand, is the probability an agent assigns for obtaining outcome
when she does not plan to first make the SIC measurement. The law of total probability is a consequence of
coherence
within the operational context of performing the two measurements as
described. The urgleichung, in contrast, is a relation between different
contexts which finds its justification in the predictive success of
quantum physics.
The SIC representation of quantum states also provides a reformulation of quantum dynamics. Consider a quantum state
with SIC representation
. The time evolution of this state is found by applying a
unitary operator to form the new state
, which has the SIC representation
The second equality is written in the
Heisenberg picture
of quantum dynamics, with respect to which the time evolution of a
quantum system is captured by the probabilities associated with a
rotated SIC measurement
of the original quantum state
. Then the
Schrödinger equation is completely captured in the urgleichung for this measurement:
In
these terms, the Schrödinger equation is an instance of the Born rule
applied to the passing of time; an agent uses it to relate how she will
gamble on informationally complete measurements potentially performed at
different times.
Those QBists who find this approach promising are pursuing a
complete reconstruction of quantum theory featuring the urgleichung as
the key postulate. (The urgleichung has also been discussed in the context of
category theory.)
Comparisons between this approach and others not associated with QBism
(or indeed with any particular interpretation) can be found in a book
chapter by Fuchs and Stacey and an article by Appleby
et al. As of 2017, alternative QBist reconstruction efforts are in the beginning stages.