In cognitive science and

semantics Semantics (from grc, σημαντικός ''sēmantikós'', "significant") is the study of reference, meaning, or truth. The term can be used to refer to subfields of several distinct disciplines, including philosophy, linguistics and comp ...

, the symbol grounding problem concerns how it is that

word A word is a basic element of language that carries an objective or practical meaning, can be used on its own, and is uninterruptible. Despite the fact that language speakers often have an intuitive grasp of what a word is, there is no conse ...

s ( symbols in general) get their meanings, and hence is closely related to the problem of what meaning itself really is. The problem of meaning is in turn related to the problem of how it is that

mental state A mental state, or a mental property, is a state of mind of a person. Mental states comprise a diverse class, including perception, pain experience, belief, desire, intention, emotion, and memory. There is controversy concerning the exact definiti ...

s are meaningful, hence to the problem of consciousness: what is the connection between certain physical systems and the contents of subjective experiences.

Background

Referents

Gottlob Frege Friedrich Ludwig Gottlob Frege (; ; 8 November 1848 – 26 July 1925) was a German philosopher, logician, and mathematician. He was a mathematics professor at the University of Jena, and is understood by many to be the father of analytic ph ...

distinguished a referent (the thing that a word refers to) and the word's meaning. This is most clearly illustrated using the proper names of concrete individuals, but it is also true of names of kinds of things and of abstract properties: (1) "Tony Blair", (2) "the prime minister of the UK during the year 2004", and (3) "Cherie Blair's husband" all have the same referent, but not the same meaning. Some have suggested that the meaning of a (referring) word is the rule or features that one must use in order to successfully pick out its referent. In that respect, (2) and (3) come closer to wearing their meanings on their sleeves, because they are explicitly stating a rule for picking out their referents: "Find whoever was prime minister of the UK during the year 2004", or "find whoever is Cherie's current husband". But that does not settle the matter, because there's still the problem of the meaning of the components of that rule ("prime minister", "UK", "during", "current", "Cherie", "husband"), and how to pick ''them'' out. The phrase "Tony Blair" (or better still, just "Tony") does not have this recursive component problem, because it points straight to its referent, but how? If the meaning is the rule for picking out the referent, what is that rule, when we come down to non-decomposable components like proper names of individuals (or names of ''kinds'', as in "an unmarried man" is a "bachelor")?

Referential process

Humans are able to pick out the intended referents of words, such as "Tony Blair" or "bachelor," but this process need not be explicit. It is probably an unreasonable expectation to know the explicit rule for picking out the intended referents. So if we take a word's meaning to be the means of picking out its referent, then meanings are in our brains. That is meaning in the ''narrow'' sense. If we use "meaning" in a ''wider'' sense, then we may want to say that meanings include both the referents themselves and the means of picking them out. So if a word (say, "Tony-Blair") is located inside an entity (e.g., oneself) that can use the word and pick out its referent, then the word's wide meaning consists of both the means that that entity uses to pick out its referent, and the referent itself: a wide causal nexus between (1) a head, (2) a word inside it, (3) an object outside it, and (4) whatever "processing" is required in order to successfully connect the inner word to the outer object. But what if the "entity" in which a word is located is not a head but a piece of paper (or a computer screen)? What is its meaning then? Surely all the (referring) words on this screen, for example, have meanings, just as they have referents. In the 19th century, philosopher

Charles Sanders Peirce Charles Sanders Peirce ( ; September 10, 1839 – April 19, 1914) was an American philosopher, logician, mathematician and scientist who is sometimes known as "the father of pragmatism". Educated as a chemist and employed as a scientist for t ...

suggested what some think is a similar model: according to his triadic sign model, meaning requires (1) an interpreter, (2) a sign or representamen, (3) an object, and is (4) the virtual product of an endless regress and progress called semiosis. Some have interpreted Peirce as addressing the problem of grounding, feelings, and intentionality for the understanding of semiotic processes. In recent years, Peirce's theory of signs has been rediscovered by an increasing number of artificial intelligence researchers in the context of symbol grounding problem.

Grounding process

There would be no connection at all between written symbols and any intended referents if there were no minds mediating those intentions, via their own internal means of picking out those intended referents. So the meaning of a word on a page is "ungrounded." Nor would looking it up in a dictionary help: If one tried to look up the meaning of a word one did not understand in a dictionary of a language one did not already understand, one would just cycle endlessly from one meaningless definition to another. One's search for meaning would be ungrounded. In contrast, the meaning of the words in one's head—those words one ''does'' understand—are "grounded". That mental grounding of the meanings of words mediates between the words on any external page one reads (and understands) and the external objects to which those words refer.

Requirements for symbol grounding

Another symbol system is natural language ( Fodor 1975). On paper or in a computer, language, too, is just a formal symbol system, manipulable by rules based on the arbitrary shapes of words. But in the brain, meaningless strings of squiggles become meaningful thoughts. Harnad has suggested two properties that might be required to make this difference: #Capacity to pick referents #Consciousness

Capacity to pick out referents

One property that static paper or, usually, even a dynamic computer lack that the brain possesses is the capacity to pick out symbols' referents. This is what we were discussing earlier, and it is what the hitherto undefined term "grounding" refers to. A symbol system alone, whether static or dynamic, cannot have this capacity (any more than a book can), because picking out referents is not just a computational (implementation-independent) property; it is a dynamical (implementation-dependent) property. To be grounded, the symbol system would have to be augmented with nonsymbolic, sensorimotor capacities—the capacity to interact autonomously with that world of objects, events, actions, properties and states that their symbols are systematically interpretable (by us) as referring to. It would have to be able to pick out the referents of its symbols, and its sensorimotor interactions with the world would have to fit coherently with the symbols' interpretations. The symbols, in other words, need to be connected directly to (i.e., grounded in) their referents; the connection must not be dependent only on the connections made by the brains of external interpreters like us. Just the symbol system alone, without this capacity for direct grounding, is not a viable candidate for being whatever it is that is really going on in our brains when we think meaningful thoughts (Cangelosi & Harnad 2001). Meaning as the ability to recognize instances (of objects) or perform actions is specifically treated in the paradigm called "Procedural Semantics", described in a number of papers including "Procedural Semantics" by Philip N. Johnson-Laird and expanded by William A. Woods in "Meaning and Links".William A. Woods. "Meaning and Links" (AI Magazine Volume 28 Number 4 (2007); see http://www.aaai.org/ojs/index.php/aimagazine/article/view/2069/2056) A brief summary in Woods' paper reads: "The idea of procedural semantics is that the semantics of natural language sentences can be characterized in a formalism whose meanings are defined by abstract procedures that a computer (or a person) can either execute or reason about. In this theory the meaning of a noun is a procedure for recognizing or generating instances, the meaning of a proposition is a procedure for determining if it is true or false, and the meaning of an action is the ability to do the action or to tell if it has been done."

Consciousness

The necessity of groundedness, in other words, takes us from the level of the pen-pal

Turing test The Turing test, originally called the imitation game by Alan Turing in 1950, is a test of a machine's ability to exhibit intelligent behaviour equivalent to, or indistinguishable from, that of a human. Turing proposed that a human evaluato ...

, which is purely symbolic (computational), to the robotic Turing test, which is hybrid symbolic/sensorimotor (Harnad 2000, 2007). Meaning is grounded in the robotic capacity to detect, categorize, identify, and act upon the things that words and sentences refer to (see entries for

Affordance Affordance is what the environment offers the individual. American psychologist James J. Gibson coined the term in his 1966 book, ''The Senses Considered as Perceptual Systems'', and it occurs in many of his earlier essays. However, his best-know ...

and for

Categorical perception Categorical perception is a phenomenon of perception of distinct categories when there is a gradual change in a variable along a continuum. It was originally observed for auditory stimuli but now found to be applicable to other perceptual modalit ...

). On the other hand, if the symbols (words and sentences) refer to the very bits of '0' and '1', directly connected to their electronic implementations, which a (any?) computer system can readily manipulate (thus detect, categorize, identify and act upon), then even non-robotic computer systems could be said to be "sensorimotor" and hence able to "ground" symbols in this narrow domain. To categorize is to do the right thing with the right ''kind'' of thing. The categorizer must be able to detect the sensorimotor features of the members of the category that reliably distinguish them from the nonmembers. These feature-detectors must either be inborn or learned. The learning can be based on trial and error induction, guided by feedback from the consequences of correct and incorrect categorization; or, in our own linguistic species, the learning can also be based on verbal descriptions or definitions. The description or definition of a new category, however, can only convey the category and ground its name if the words in the definition are themselves already grounded category names (Blondin-Massé et al. 2008). So ultimately grounding has to be sensorimotor, to avoid infinite regress (Harnad 2005). But if groundedness is a necessary condition for meaning, is it a sufficient one? Not necessarily, for it is possible that even a robot that could pass the Turing test, "living" amongst the rest of us indistinguishably for a lifetime, would fail to have in its head what Searle has in his: It could be a

p-zombie A philosophical zombie or p-zombie argument is a thought experiment in philosophy of mind that imagines a hypothetical being that is physically identical to and indistinguishable from a normal person but does not have consciousness, conscious ex ...

, with no one home, feeling feelings, meaning meanings (Harnad 1995). However, it is possible that different interpreters (including different intelligent species of animals) would have different mechanisms for producing meaning in their systems, thus one cannot require that a system different from a human "experiences" meaning in the same way that a human does, and vice versa. Harnad thus points at consciousness as a second property. The problem of discovering the causal mechanism for successfully picking out the referent of a category name can in principle be solved by cognitive science. But the problem of explaining how consciousness could play an "independent" role in doing so is probably insoluble, except on pain of

telekinetic Psychokinesis (from grc, ψυχή, , soul and grc, κίνησις, , movement, label=ㅤ), or telekinesis (from grc, τηλε, , far off and grc, κίνησις, , movement, label=ㅤ), is a hypothetical psychic ability allowing a person ...

dualism. Perhaps symbol grounding (i.e., robotic TT capacity) is enough to ensure that conscious meaning is present, but then again, perhaps not. In either case, there is no way we can hope to be any the wiser—and that is Turing's methodological point (Harnad 2001b, 2003, 2006).

Formulation

To answer this question we have to formulate the symbol grounding problem itsel
(Harnad 1990)

Functionalism

There is a school of thought according to which the computer is more like the brain—or rather, the brain is more like the computer. According to this view (called "

computationalism In philosophy of mind, the computational theory of mind (CTM), also known as computationalism, is a family of views that hold that the human mind is an information processing system and that cognition and consciousness together are a form of c ...

", a variety of functionalism), the future theory explaining how the brain picks out its referents, (the theory that cognitive neuroscience may eventually arrive at) will be a purely computational one ( Pylyshyn 1984). A computational theory is a theory at the software level. It is essentially a computer algorithm: a set of rules for manipulating symbols. And the algorithm is "implementation-independent." That means that whatever it is that an algorithm is doing, it will do the same thing no matter what hardware it is executed on. The physical details of the

dynamical system In mathematics, a dynamical system is a system in which a function describes the time dependence of a point in an ambient space. Examples include the mathematical models that describe the swinging of a clock pendulum, the flow of water in ...

implementing the computation are irrelevant to the computation itself, which is purely formal; any hardware that can run the computation will do, and all physical implementations of that particular computer algorithm are equivalent, computationally. A computer can execute any computation. Hence once computationalism finds a proper computer algorithm, one that our brain could be running when there is meaning transpiring in our heads, meaning will be transpiring in that computer too, when it implements that algorithm. How would we know that we have a proper computer algorithm? It would have to be able to pass the

. That means it would have to be capable of corresponding with any human being as a pen-pal, for a lifetime, without ever being in any way distinguishable from a real human pen-pal.

Searle's Chinese room argument

John Searle formulated the " Chinese room argument" in order to disprove computationalism. The Chinese room argument is based on a thought experiment: in it, Searle stated that if the Turing test were conducted in Chinese, then he himself, Searle (who does not understand Chinese), could execute a program that implements the same algorithm that the computer was using without knowing what any of the words he was manipulating meant. At first glance, it would seem that if there's no meaning going on inside Searle's head when he is implementing that program, then there's no meaning going on inside the computer when it is the one implementing the algorithm either, computation being implementation-independent. But on a closer look, for a person to execute the same program that a computer would, at very least it would have to have access to a similar bank of memory that the computer has (most likely externally stored). This means that the new computational system that executes the same algorithm is no longer just Searle's original head, but that plus the memory bank (and possibly other devices). In particular, this additional memory could store a digital representation of the intended referent of different words (like images, sounds, even video sequences), that the algorithm would use as a model of, and to derive features associated with, the intended referent. The "meaning" then is not to be searched in just Searle's original brain, but in the overall system needed to process the algorithm. Just like when Searle is reading English words, the meaning is not to be located in isolated logical processing areas of the brain, but probably in the overall brain, likely including specific long-term memory areas. Thus, Searle's not perceiving any meaning in his head alone when simulating the work of a computer, does not imply lack of meaning in the overall system, and thus in the actual computer system passing an advanced Turing test.

Implications

How does Searle know that there is no meaning going on in his head when he is executing such a Turing-test-passing program? Exactly the same way he knows whether there is or is not meaning going on inside his head under any other conditions: He ''understands'' the words of English, whereas the Chinese symbols that he is manipulating according to the algorithm's rules mean nothing whatsoever to him (and there is no one else in his head for them to mean anything to). However, the complete system that is manipulating those Chinese symbols – which is not just Searle's brain, as explained in the previous section – may have the ability to extract meaning from those symbols, in the sense of being able to use internal (memory) models of the intended referents, pick out the intended referents of those symbols, and generally identifying and using their features appropriately. Note that in pointing out that the Chinese words would be meaningless to him under those conditions, Searle has appealed to consciousness. Otherwise one could argue that there ''would'' be meaning going on in Searle's head under those conditions, but that Searle himself would simply not be conscious of it. That is called th
"Systems Reply"
to Searle's Chinese Room Argument, and Searl
rejects
the Systems Reply as being merely a reiteration, in the face of negative evidence, of the very thesis (computationalism) that is on trial in his thought-experiment: "Are words in a running computation like the ungrounded words on a page, meaningless without the mediation of brains, or are they like the grounded words in brains?" In this either/or question, the (still undefined) word "ungrounded" has implicitly relied on the difference between inert words on a page and consciously meaningful words in our heads. And Searle is asserting that under these conditions (the Chinese Turing test), the words in his head would not be consciously meaningful, hence they would still be as ungrounded as the inert words on a page. So if Searle is right, that (1) both the words on a page and those in any running computer program (including a Turing-test-passing computer program) are meaningless in and of themselves, and hence that (2) whatever it is that the brain is doing to generate meaning can't be just implementation-independent computation, then what ''is'' the brain doing to generate meanin
(Harnad 2001a)

Brentano's notion of intentionality

" Intentionality" has been called the "mark of the mental" because of some observations by the philosopher

Brentano Brentano is an Italian surname. Notable people with the surname include: * Antonie Brentano, philanthropist * August Brentano, bookseller * Bernard von Brentano, novelist * Christian Brentano, German writer * Clemens Brentano, poet and novelist ...

to the effect that mental states always have an inherent, intended (mental) object or content toward which they are "directed": One sees something, wants something, believes something, desires something, understands something, means something etc., and that object is always something that one has ''in mind''. Having a mental object is part of having anything in mind. Hence it is the mark of the mental. There are no "free-floating" mental states that do not also have a mental object. Even hallucinations and imaginings have an object, and even feeling depressed feels like something. Nor is the object the "external" physical object, when there is one. One may see a real chair, but the "intentional" object of one's "intentional state" is the mental chair one has in mind. (Yet another term for intentionality has been "aboutness" or "representationality": thoughts are always ''about'' something; they are (mental) "representations" ''of'' something; but that something is what it is that the thinker has in mind, not whatever external object may or may not correspond to it.) If this all sounds like skating over the surface of a problem rather than a real break-through, then the foregoing description has had its intended effect: neither the problem of intentionality is the symbol grounding problem; nor is grounding symbols the solution to the problem of intentionality. The symbols inside an autonomous dynamical symbol system that is able to pass the robotic Turing test are grounded, in that, unlike in the case of an ungrounded symbol system, they do not depend on the mediation of the mind of an external interpreter to connect them to the external objects that they are interpretable (by the interpreter) as being "about"; the connection is autonomous, direct, and unmediated. But ''grounding is not meaning''. Grounding is an input/output performance function. Grounding connects the sensory inputs from external objects to internal symbols and states occurring within an autonomous sensorimotor system, guiding the system's resulting processing and output. Meaning, in contrast, is something mental. But to try to put a halt to the name-game of proliferating nonexplanatory synonyms for the mind/body problem without solving it (or, worse, implying that there is more than one mind/body problem), let us cite just one more thing that requires no further explication: ''feeling''. The only thing that distinguishes an internal state that merely has grounding from one that has meaning is that it ''feels like something'' to be in the meaning state, whereas it does not feel like anything to be in the merely grounded functional state. Grounding is a functional matter; feeling is a felt matter. And that is the real source of Brentano's vexed peekaboo relation between "intentionality" and its internal "intentional object". All mental states, in addition to being the functional states of an autonomous dynamical system, are also feeling states. Feelings are not merely "functed," as all other physical states are; feelings are also felt. Hence feeling ( sentience) is the real mark of the mental. But the symbol grounding problem is not the same as the mind/body problem, let alone a solution to it. The mind/body problem is actually the feeling/function problem, and symbol-grounding touches only its functional component. This does not detract from the importance of the symbol grounding problem, but just reflects that it is a keystone piece to the bigger puzzle called the mind. The neuroscientist

Antonio Damasio Antonio Damasio ( pt, António Damásio) is a Portuguese-American neuroscientist. He is currently the David Dornsife Chair in Neuroscience, as well as Professor of Psychology, Philosophy, and Neurology, at the University of Southern California, ...

investigates this marking function of feelings and emotions in his

somatic marker hypothesis The somatic marker hypothesis, formulated by Antonio Damasio and associated researchers, proposes that emotional processes guide (or bias) behavior, particularly decision-making. ''Descartes' Error'' "Somatic markers" are feelings in the body th ...

. Damasio adds the notion of biologic

homeostasis In biology, homeostasis (British also homoeostasis) (/hɒmɪə(ʊ)ˈsteɪsɪs/) is the state of steady internal, physical, and chemical conditions maintained by living systems. This is the condition of optimal functioning for the organism and ...

to this discussion, presenting it as an automated bodily regulation process providing intentionality to a mind via emotions. Homeostasis is the mechanism that keeps all bodily processes in healthy balance. All of our actions and perceptions will be automatically "evaluated" by our body hardware according to their contribution to homeostasis. This gives us an implicit orientation on how to survive. Such bodily or somatic evaluations can come to our mind in the form of conscious and non-conscious feelings ("gut feelings") and lead our decision-making process. The meaning of a word can be roughly conceptualized as the sum of its associations and their expected contribution to homeostasis, where associations are reconstructions of sensorimotor perceptions that appeared in contiguity with the word. Yet, the somatic marker hypothesis is still hotly debated and critics claim that it has failed to clearly demonstrate how these processes interact at a psychological and evolutionary level. The recurrent question that the somatic marker hypothesis does not address remains: how and why does homeostasis (as in any servomechanism such as a thermostat and furnace) become ''felt'' homeostasis?

Notes

References

:Note: ''This article is based on an entry originally published in Nature/Macmillan Encyclopedia of Cognitive Science that has since been revised by the author and the Wikipedia community.'' * Blondin Masse, A, G. Chicoisne, Y. Gargouri, S. Harnad, O. Picard, O. Marcotte (2008
How Is Meaning Grounded in Dictionary Definitions?
''TextGraphs-3 Workshop, 22nd International Conference on Computational Linguistics, Coling 2008'', Manchester, 18–22 August 2008 * Cangelosi, A. & Harnad, S. (2001
The Adaptive Advantage of Symbolic Theft Over Sensorimotor Toil: Grounding Language in Perceptual Categories.
''Evolution of Communication'' 4(1) 117–142. * Cangelosi, A.; Greco, A.; Harnad, S
From robotic toil to symbolic theft: grounding transfer from entry-level to higher-level categories.
''Connection Science''12(2) 143–62. * Fodor, J. A. (1975) ''The language of thought''. New York: Thomas Y. Crowell * Frege, G. (1952/1892). On sense and reference. In P. Geach and M. Black, Eds., ''Translations of the Philosophical Writings of Gottlob Frege''. Oxford: Blackwell * Harnad, S. (1990
The Symbol Grounding Problem.
''Physica D'' 42: 335–346. * Harnad, S. (1992
There Is Only One Mind/Body Problem
Symposium on the Perception of Intentionality, XXV World Congress of Psychology, Brussels, Belgium, July 1992 ''International Journal of Psychology'' 27: 521 * Harnad, S. (1994
Computation Is Just Interpretable Symbol Manipulation: Cognition Isn't.
''Minds and Machines'' 4:379–390 (Special Issue on "What Is Computation") * Harnad, S. (1995
Why and How We Are Not Zombies.
''Journal of Consciousness Studies'' 1: 164–167. * Harnad, S. (2000
Minds, Machines and Turing: The Indistinguishability of Indistinguishables
''Journal of Logic, Language, and Information'' 9(4): 425–445. (Special Issue on "Alan Turing and Artificial Intelligence") * Harnad, S. (2001a
Minds, Machines and Searle II: What's Wrong and Right About Searle's Chinese Room Argument?
In: M. Bishop & J. Preston (eds.) ''Essays on Searle's Chinese Room Argument''. Oxford University Press. * Harnad, S. (2001b
No Easy Way Out.
''The Sciences'' 41(2) 36–42. * Harnad, Stevan (2001a
Explaining the Mind: Problems, Problems
''The Sciences'' 41: 36–42. * Harnad, Stevan (2001b
The Mind/Body Problem is the Feeling/Function Problem: Harnad on Dennett on Chalmers
Technical Report. Department of Electronics and Computer Sciences. University of Southampton. * Harnad, S. (2003
Can a Machine Be Conscious? How?.
''Journal of Consciousness Studies'' 10(4–5): 69–75. * Harnad, S. (2005
To Cognize is to Categorize: Cognition is categorization.
in Lefebvre, C. and Cohen, H., Eds. ''Handbook of Categorization''. Elsevier. * Harnad, S. (2007
The Annotation Game: On Turing (1950) on Computing, Machinery and Intelligence.
In: Epstein, Robert & Peters, Grace (Eds.) ''The Turing Test Sourcebook: Philosophical and Methodological Issues in the Quest for the Thinking Computer''. Kluwer * Harnad, S. (2006
Cohabitation: Computation at 70 Cognition at 20.
In Dedrick, D., Eds. ''Essays in Honour of Zenon Pylyshyn''.
MacDorman, Karl F.
(1999). Grounding symbols through sensorimotor integration. Journal of the Robotics Society of Japan, 17(1), 20–24
Online version

MacDorman, Karl F.
(2007). Life after the symbol system metaphor. Interaction Studies, 8(1), 143–158
Online version
* Pylyshyn, Z. W. (1984) ''Computation and cognition''. Cambridge MA: MIT/Bradford * Searle, John. R. (1980
Minds, brains, and programs.
''Behavioral and Brain Sciences'' 3(3): 417–457 * Taddeo, Mariarosaria & Floridi, Luciano (2005). The symbol grounding problem: A critical review of fifteen years of research. ''

Journal of Experimental and Theoretical Artificial Intelligence The ''Journal of Experimental and Theoretical Artificial Intelligence'' is a quarterly peer-reviewed scientific journal published by Taylor and Francis. It covers all aspects of artificial intelligence and was established in 1989. The editor-in-chi ...

, 17''(4), 419–445
Online version
* Turing, A.M. (1950
Computing Machinery and Intelligence.
''Mind'' 49 433–460 eprinted in ''Minds and machines''. A. Anderson (ed.), Engelwood Cliffs NJ: Prentice Hall, 1964. {{DEFAULTSORT:Symbol Grounding Cognitive science Symbolism Arguments in philosophy of mind Semantics Philosophy of language