Simulation hypothesis

The simulation hypothesis proposes that reality is in fact a simulation (most likely a computer simulation). Some versions rely on the development of a simulated reality, a proposed technology that would seem realistic enough to convince its inhabitants. The hypothesis has been a central plot device of many science fiction stories and films.

Origins

There is a long philosophical and scientific history to the underlying thesis that reality is an illusion. This skeptical hypothesis can be traced back to antiquity; for example, to the "Butterfly Dream" of Zhuangzi,[1] or the Indian philosophy of Maya.

Simulation hypothesis

Many works of science fiction as well as some forecasts by serious technologists and futurologists predict that enormous amounts of computing power will be available in the future. Let us suppose for a moment that these predictions are correct. One thing that later generations might do with their super-powerful computers is run detailed simulations of their forebears or of people like their forebears. Because their computers would be so powerful, they could run a great many such simulations. Suppose that these simulated people are conscious (as they would be if the simulations were sufficiently fine-grained and if a certain quite widely accepted position in the philosophy of mind is correct). Then it could be the case that the vast majority of minds like ours do not belong to the original race but rather to people simulated by the advanced descendants of an original race. It is then possible to argue that, if this were the case, we would be rational to think that we are likely among the simulated minds rather than among the original biological ones. Therefore, if we don’t think that we are currently living in a computer simulation, we are not entitled to believe that we will have descendants who will run lots of such simulations of their forebears.
Nick Bostrom, Are you living in a computer simulation?, 2003[2]

Ancestor simulation

In 2003, philosopher Nick Bostrom proposed a trilemma that he called "the simulation argument". Despite the name, Bostrom's "simulation argument" does not directly argue that we live in a simulation; instead, Bostrom's trilemma argues that one of three unlikely-seeming propositions must be true. The trilemma points out that a technologically mature "posthuman" civilization would have enormous computing power; if even a tiny percentage of them were to run "ancestor simulations" (that is, "high-fidelity" simulations of ancestral life that would be indistinguishable from reality to the simulated ancestor), the total number of simulated ancestors, or "Sims", in the universe (or multiverse, if it exists) would greatly exceed the total number of actual ancestors. Therefore, at least one of the following three propositions is almost certainly true:

  1. "The fraction of human-level civilizations that reach a posthuman stage (that is, one capable of running high-fidelity ancestor simulations) is very close to zero", or
  2. "The fraction of posthuman civilizations that are interested in running ancestor-simulations is very close to zero", or
  3. "The fraction of all people with our kind of experiences that are living in a simulation is very close to one"

Bostrom goes on to use a type of anthropic reasoning to claim that, if the third proposition is the one of those three that is true, and almost all people with our kind of experiences live in simulations, then we are almost certainly living in a simulation.

Bostrom claims his argument goes beyond the classical ancient "skeptical hypothesis", claiming that "...we have interesting empirical reasons to believe that a certain disjunctive claim about the world is true", the third of the three disjunctive propositions being that we are almost certainly living in a simulation. Thus, Bostrom, and writers in agreement with Bostrom such as David Chalmers, argue there might be empirical reasons for the "simulation hypothesis", and that therefore the simulation hypothesis is not a skeptical hypothesis but rather a "metaphysical hypothesis". Bostrom states he personally sees no strong argument for which of the three trilemma propositions is the true one: "If (1) is true, then we will almost certainly go extinct before reaching posthumanity. If (2) is true, then there must be a strong convergence among the courses of advanced civilizations so that virtually none contains any relatively wealthy individuals who desire to run ancestor-simulations and are free to do so. If (3) is true, then we almost certainly live in a simulation. In the dark forest of our current ignorance, it seems sensible to apportion one’s credence roughly evenly between (1), (2), and (3)... I note that people who hear about the simulation argument often react by saying, 'Yes, I accept the argument, and it is obvious that it is possibility #n that obtains.' But different people pick a different n. Some think it obvious that (1) is true, others that (2) is true, yet others that (3) is true."

As a corollary to the trilemma, Bostrom states that "Unless we are now living in a simulation, our descendants will almost certainly never run an ancestor-simulation."[3][4][5][6]

Criticism of Bostrom's anthropic reasoning

Bostrom argues that, if "the fraction of all people with our kind of experiences that are living in a simulation is very close to one", then it follows that we probably live in a simulation. Some philosophers disagree, proposing that perhaps "Sims" do not have conscious experiences the same way that unsimulated humans do, or that it can otherwise be self-evident to a human that they are a human rather than a Sim.[4][7] Philosopher Barry Dainton modifies Bostrom's trilemma by substituting "neural ancestor simulations" (ranging from literal brains in a vat, to far-future humans with induced high-fidelity hallucinations that they are their own distant ancestors) for Bostrom's "ancestor simulations", on the grounds that every philosophical school of thought can agree that sufficiently high-tech neural ancestor simulation experiences would be indistinguishable from non-simulated experiences. Even if high-fidelity computer Sims are never conscious, Dainton's reasoning leads to the following conclusion: either the fraction of human-level civilizations that reach a posthuman stage and are able and willing to run large numbers of neural ancestor simulations is close to zero, or we are in some kind of (possibly neural) ancestor simulation.[8]

Some scholars categorically reject or are uninterested in anthropic reasoning, dismissing it as "merely philosophical", unfalsifiable, or inherently unscientific.[4]

Some critics reject the block universe view of time that Bostrom implicitly accepts and propose that we could be in the first generation, such that all the simulated people that will one day be created don't yet exist.[4]

Arguments, within the trilemma, against the simulation hypothesis

Some scholars accept the trilemma, and argue that the first or second of the propositions are true, and that the third proposition (the proposition that we live in a simulation) is false. Physicist Paul Davies deploys Bostrom's trilemma as part of one possible argument against a near-infinite multiverse. This argument runs as follows: if there were a near-infinite multiverse, there would be posthuman civilizations running ancestor simulations, and therefore we would come to the untenable and scientifically self-defeating conclusion that we live in a simulation; therefore, by reductio ad absurdum, existing multiverse theories are likely false. (Unlike Bostrom and Chalmers, Davies (among others) considers the simulation hypothesis to be self-defeating.)[4][9]

Some point out that there is currently no proof of technology which would facilitate the existence of sufficiently high-fidelity ancestor simulation. Additionally, there is no proof that it is physically possible or feasible for a posthuman civilization to create such a simulation, and therefore for the present, the first proposition must be true.[4] Additionally there are proofs of limits of computation.

Consequences of living in a simulation

Some scholars speculate that the creators of our hypothetical simulation may have limited computing power; if so, after a certain point, the creators would have to deploy some sort of strategy to prevent simulations from themselves indefinitely creating high-fidelity simulations in unbounded regress. One obvious strategy would be to simply terminate the overly-intensive simulation at that point. Therefore, if we are simulations (or simulations of simulations), and if, for example, we were to start massively creating simulations in the year 2050, there could be a risk of termination around that point, as there could be a jump in our simulation's required processing power.[10]

Economist Robin Hanson argues a self-interested high-fidelity Sim should strive to be entertaining and praiseworthy in order to avoid being turned off or being shunted into a non-conscious low-fidelity part of the simulation. Hanson additionally speculates that someone who is aware that he might be a Sim, might care less about others and live more for today: "your motivation to save for retirement, or to help the poor in Ethiopia, might be muted by realizing that in your simulation, you will never retire and there is no Ethiopia."[11]

Testing the hypothesis physically

A long-shot method to test one type of simulation hypothesis was proposed in 2012 in a joint paper by physicists Silas R. Beane from the University of Bonn (now at the University of Washington, Seattle), and Zohreh Davoudi and Martin J. Savage from the University of Washington, Seattle.[12] Under the assumption of finite computational resources, the simulation of the universe would be performed by dividing the continuum space-time into a discrete set of points. In analogy with the mini-simulations that lattice-gauge theorists run today to build up nuclei from the underlying theory of strong interactions (known as Quantum chromodynamics), several observational consequences of a grid-like space-time have been studied in their work. Among proposed signatures is an anisotropy in the distribution of ultra-high-energy cosmic rays, that, if observed, would be consistent with the simulation hypothesis according to these physicists.[13] A multitude of physical observables must be explored before any such scenario could be accepted or rejected as a theory of nature.[14]

Science fiction themes

Science fiction has highlighted themes such as virtual reality, artificial intelligence and computer gaming for more than fifty years. Simulacron-3 (1964) by Daniel F. Galouye (alternative title: Counterfeit World) tells the story of a virtual city developed as a computer simulation for market research purposes, in which the simulated inhabitants possess consciousness; all but one of the inhabitants are unaware of the true nature of their world. We Can Remember It for You Wholesale is a short story by American writer Philip K. Dick, first published in The Magazine of Fantasy & Science Fiction in April 1966, and was the basis for Total Recall (1990 film) and Total Recall (2012 film). In Overdrawn at the Memory Bank, a 1983 television movie, the main character pays to have his mind connected to a simulation. More recently, the same theme was repeated in the 1999 film The Matrix, which depicted a world in which artificially intelligent robots enslaved humanity within a simulation set in the contemporary world. The 2012 play World of Wires was partially inspired by the Bostrom essay on the simulation hypothesis.[15] In the episode Extremis (broadcast on 20 May 2017 on BBC One) of the Science Fiction Series Doctor Who aliens called "The Monks" plan an invasion of Earth by running and studying a holographic simulation of Earth with conscious inhabitants. When the virtual Doctor finds out about the simulation he sends an email about the simulation to his real self so that the real Doctor can save the world. In the second season of Rick and Morty, a science-fiction animated comedy, the episode The Ricks Must Be Crazy centers on Rick creating a universe whose primary function, unbeknownst to its occupants, is to generate power for his car battery. Upon entering the secondary universe, Rick discovers that a scientist in this "microverse" has created his own mini-universe to generate power for his people. When the titular characters enter the microverse inside the microverse, they meet another scientist with identical intentions.

See also

References

  1. "You're living in a computer simulation, and math proves it". Gizmodo. Retrieved 29 October 2016.
  2. Bostrom, Nick. "Are you living in a computer simulation?". Retrieved 29 October 2016.
  3. Bostrom, N., 2003, Are You Living in a Simulation?, Philosophical Quarterly (2003), Vol. 53, No. 211, pp. 243-255.
  4. 1 2 3 4 5 6 The Simulation Argument Website FAQ
  5. The Simulation Argument: Why the Probability that You Are Living in a Matrix is Quite High, Nick Bostrom, Professor of Philosophy at Oxford University, 2003
  6. Davis J. Chalmers The Matrix as Metaphysics Dept of Philosophy, U. o Arizona; paper written for the philosophy section of The Matrix website.
  7. Brian Weatherson. "Are you a sim?" The Philosophical Quarterly 53.212 (2003): 425-431.
  8. Dainton, Barry. "On singularities and simulations." Journal of Consciousness Studies 19.1 (2012): 42.
  9. Davies, Paul, Charles William. "Multiverse cosmological models." Modern Physics Letters A 19.10 (2004): 727-743.
  10. Peter Jenkins (2006). "Historical Simulations - Motivational, Ethical and Legal Issues". Journal of Futures Studies. 11 (1): 23–42. SSRN 929327Freely accessible.
  11. Robin Hanson. "How to live in a simulation." Journal of Evolution and Technology 7.1 (2001).
  12. Beane, Silas; Zohreh Davoudi; Martin J. Savage (9 November 2012). "Constraints on the Universe as a Numerical Simulation". arXiv:1210.1847Freely accessible. Lay summary The Physics arXiv Blog (October 10, 2012). ABSTRACT Observable consequences of the hypothesis that the observed universe is a numerical simulation performed on a cubic space-time lattice or grid are explored. The simulation scenario is first motivated by extrapolating current trends in computational resource requirements for lattice QCD into the future. Using the historical development of lattice gauge theory technology as a guide, we assume that our universe is an early numerical simulation with unimproved Wilson fermion discretization and investigate potentially-observable consequences. Among the observables that are considered are the muon g-2 and the current differences between determinations of alpha, but the most stringent bound on the inverse lattice spacing of the universe, b1 > ~ 10^11 GeV, is derived from the high-energy cut off of the cosmic ray spectrum. The numerical simulation scenario could reveal itself in the distributions of the highest energy cosmic rays exhibiting a degree of rotational symmetry breaking that reflects the structure of the underlying lattice.
  13. https://www.scientificamerican.com/article/are-we-living-in-a-computer-simulation
  14. http://www.phys.washington.edu/users/savage/Simulation/Universe/
  15. Brantley, Ben (January 16, 2012). "‘World of Wires' at the Kitchen — Review". The New York Times.

Further reading

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