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Mental image

January 01, 1970

"Mental images" redirects here. For the computer graphics software company, see Mental Images.
"Mind's eye" redirects here. For other uses, see Mind's eye (disambiguation).

In the philosophy of mind, neuroscience, and cognitive science, a mental image is an experience that, on most occasions, significantly resembles the experience of "perceiving" some object, event, or scene but occurs when the relevant object, event, or scene is not actually present to the senses.[1][2][3][4] There are sometimes episodes, particularly on falling asleep (hypnagogic imagery) and waking up (hypnopompic imagery), when the mental imagery may be dynamic, phantasmagoric, and involuntary in character, repeatedly presenting identifiable objects or actions, spilling over from waking events, or defying perception, presenting a kaleidoscopic field, in which no distinct object can be discerned.[5] Mental imagery can sometimes produce the same effects as would be produced by the behavior or experience imagined.[6]

The nature of these experiences, what makes them possible, and their function (if any) have long been subjects of research and controversy in philosophy, psychology, cognitive science, and, more recently, neuroscience. As contemporary researchers use the expression, mental images or imagery can comprise information from any source of sensory input; one may experience auditory images,[7] olfactory images,[8] and so forth. However, the majority of philosophical and scientific investigations of the topic focus on visual mental imagery. It has sometimes been assumed that, like humans, some types of animals are capable of experiencing mental images.[9] Due to the fundamentally introspective (reflective) nature of the phenomenon, it has been difficult to assess whether or not non-human animals experience mental imagery.

Philosophers such as George Berkeley and David Hume, and early experimental psychologists such as Wilhelm Wundt and William James, understood ideas in general to be mental images. Today, it is very widely believed that much imagery functions as mental representations (or mental models), playing an important role in memory and thinking.[10][11][12][13] William Brant (2013, p. 12) traces the scientific use of the phrase "mental images" back to John Tyndall's 1870 speech called the "Scientific Use of the Imagination". Some have suggested that images are best understood to be, by definition, a form of inner, mental, or neural representation.[14][15] Others reject the view that the image experience may be identical with (or directly caused by) any such representation in the mind or the brain,[16][17][18][19][20][21] but do not take account of the non-representational forms of imagery.

Mind's eye edit

The notion of a "mind's eye" goes back at least to Cicero's reference to mentis oculi during his discussion of the orator's appropriate use of simile.[22]

In this discussion, Cicero observed that allusions to "the Syrtis of his patrimony" and "the Charybdis of his possessions" involved similes that were "too far-fetched"; and he advised the orator to, instead, just speak of "the rock" and "the gulf" (respectively)—on the grounds that "the eyes of the mind are more easily directed to those objects which we have seen, than to those which we have only heard".[23]

The concept of "the mind's eye" first appeared in English in Chaucer's (c. 1387) Man of Law's Tale in his Canterbury Tales, where he tells us that one of the three men dwelling in a castle was blind, and could only see with "the eyes of his mind"; namely, those eyes "with which all men see after they have become blind".[24]

Physical basis edit

The biological foundation of mental imagery is not fully understood. Studies using fMRI have shown that the lateral geniculate nucleus and the V1 area of the visual cortex are activated during mental imagery tasks.[25] Ratey writes:

The visual pathway is not a one-way street. Higher areas of the brain can also send visual input back to neurons in lower areas of the visual cortex. [...] As humans, we have the ability to see with the mind's eye—to have a perceptual experience in the absence of visual input. For example, PET scans have shown that when subjects, seated in a room, imagine they are at their front door starting to walk either to the left or right, activation begins in the visual association cortex, the parietal cortex, and the prefrontal cortex—all higher cognitive processing centers of the brain.[26]

A biological basis for mental imagery is found in the deeper portions of the brain below the neocortex. In a large study with 285 participants, Tabi, Maio, Attaallah, et al. (2022) investigated the association between an established measure of visual mental imagery, Vividness of Visual Imagery Questionnaire (VVIQ) scores, and volumes of brain structures including the hippocampus, amygdala, primary motor cortex, primary visual cortex and the fusiform gyrus. Tabi et al. (2022) found significant positive correlations between visual imagery vividness and the volumes of the hippocampus and primary visual cortex.

 
VVIQ correlations with Hippocampal CA & GC-ML-DG volumes

Significant positive correlations were also obtained between VVIQ scores and hippocampal structures including Bilateral CA1, CA3, CA4 and Granule Cell (GC) and Molecular Layer (ML) of the Dentate Gyrus (DG). Follow-up analysis revealed that visual imagery was in particular correlated with the four subfields presented in the above illustration (Tabi et al., 2022).

The thalamus has been found to be discrete to other components in that it processes all forms of perceptional data relayed from both lower and higher components of the brain. Damage to this component can produce permanent perceptual damage, however when damage is inflicted upon the cerebral cortex, the brain adapts to neuroplasticity to amend any occlusions for perception [citation needed]. It can be thought that the neocortex is a sophisticated memory storage warehouse in which data received as an input from sensory systems are compartmentalized via the cerebral cortex. This would essentially allow for shapes to be identified, although given the lack of filtering input produced internally, one may as a consequence, hallucinate—essentially seeing something that isn't received as an input externally but rather internal (i.e. an error in the filtering of segmented sensory data from the cerebral cortex may result in one seeing, feeling, hearing or experiencing something that is inconsistent with reality).

Not all people have the same mental imagery ability. For many, when the eyes are closed, the perception of darkness prevails. However, some people are able to perceive colorful, dynamic imagery (McKellar, 1957). The use of hallucinogenic drugs increases the subject's ability to consciously access mental imagery including synaestesia (McKellar, 1957).

Furthermore, the pineal gland is a hypothetical candidate for producing a mind's eye. Rick Strassman and others have postulated that during near-death experiences (NDEs) and dreaming, the gland might secrete the hallucinogenic chemical N,N-Dimethyltryptamine (DMT) to produce internal visuals when external sensory data is occluded.[27] However, this hypothesis has yet to be fully supported with neurochemical evidence and plausible mechanism for DMT production.

The condition where a person lacks mental imagery is called aphantasia. The term was first suggested in a 2015 study.[28]

Common examples of mental images include daydreaming and the mental visualization that occurs while reading a book. Another is of the pictures summoned by athletes during training or before a competition, outlining each step they will take to accomplish their goal.[29] When a musician hears a song, they can sometimes "see" the song notes in their head, as well as hear them with all their tonal qualities.[30] This is considered different from an after-effect, such as an afterimage. Calling up an image in our minds can be a voluntary act, so it can be characterized as being under various degrees of conscious control.

There are several theories as to how mental images are formed in the mind. These include the dual-code theory, the propositional theory, and the functional-equivalency hypothesis. The dual-code theory, created by Allan Paivio in 1971, is the theory that we use two separate codes to represent information in our brains: image codes and verbal codes. Image codes are things like thinking of a picture of a dog when you are thinking of a dog, whereas a verbal code would be to think of the word "dog".[31] Another example is the difference between thinking of abstract words such as justice or love and thinking of concrete words like elephant or chair. When abstract words are thought of, it is easier to think of them in terms of verbal codes—finding words that define them or describe them. With concrete words, it is often easier to use image codes and bring up a picture of a human or chair in your mind rather than words associated or descriptive of them.

The propositional theory involves storing images in the form of a generic propositional code that stores the meaning of the concept not the image itself. The propositional codes can either be descriptive of the image or symbolic. They are then transferred back into verbal and visual code to form the mental image.[32]

The functional-equivalency hypothesis is that mental images are "internal representations" that work in the same way as the actual perception of physical objects.[33] In other words, the picture of a dog brought to mind when the word dog is read is interpreted in the same way as if the person was observing an actual dog before them.

Research has occurred to designate a specific neural correlate of imagery; however, studies show a multitude of results. Most studies published before 2001 suggest neural correlates of visual imagery occur in Brodmann area 17.[34] Auditory performance imagery have been observed in the premotor areas, precunes, and medial Brodmann area 40.[35] Auditory imagery in general occurs across participants in the temporal voice area (TVA), which allows top-down imaging manipulations, processing, and storage of audition functions.[36] Olfactory imagery research shows activation in the anterior piriform cortex and the posterior piriform cortex; experts in olfactory imagery have larger gray matter associated to olfactory areas.[37] Tactile imagery is found to occur in the dorsolateral prefrontal area, inferior frontal gyrus, frontal gyrus, insula, precentral gyrus, and the medial frontal gyrus with basal ganglia activation in the ventral posteriomedial nucleus and putamen (hemisphere activation corresponds to the location of the imagined tactile stimulus).[38] Research in gustatory imagery reveals activation in the anterior insular cortex, frontal operculum, and prefrontal cortex.[34] Novices of a specific form of mental imagery show less gray matter than experts of mental imagery congruent to that form.[39] A meta-analysis of neuroimagery studies revealed significant activation of the bilateral dorsal parietal, interior insula, and left inferior frontal regions of the brain.[40] Causal evidence from neurological patients with brain lesions demonstrates that vivid visual mental imagery is possible even when occipital visual areas are lesioned or disconnected from more anterior cortex. Visual mental imagery can instead be impaired by left temporal damage.[41] Consistent with these findings, a meta-analysis of 27 neuroimaging studies demonstrated imagery-related activity in a region of the left ventral temporal cortex, which was dubbed the Fusiform Imagery Node.[42] An additional Bayesian analysis excluded a role for occipital cortex in visual mental imagery, consistent with the evidence from neurological patients.

Imagery has been thought to cooccur with perception; however, participants with damaged sense-modality receptors can sometimes perform imagery of said modality receptors.[43] Neuroscience with imagery has been used to communicate with seemingly unconscious individuals through fMRI activation of different neural correlates of imagery, demanding further study into low quality consciousness.[44] A study on one patient with one occipital lobe removed found the horizontal area of their visual mental image was reduced.[45]

Neural substrates of visual imagery edit

Visual imagery is the ability to create mental representations of things, people, and places that are absent from an individual’s visual field. This ability is crucial to problem-solving tasks, memory, and spatial reasoning.[46] Neuroscientists have found that imagery and perception share many of the same neural substrates, or areas of the brain that function similarly during both imagery and perception, such as the visual cortex and higher visual areas. Kosslyn and colleagues (1999)[47] showed that the early visual cortex, Area 17 and Area 18/19, is activated during visual imagery. They found that inhibition of these areas through repetitive transcranial magnetic stimulation (rTMS) resulted in impaired visual perception and imagery. Furthermore, research conducted with lesioned patients has revealed that visual imagery and visual perception have the same representational organization. This has been concluded from patients in which impaired perception also experience visual imagery deficits at the same level of the mental representation.[48]

Behrmann and colleagues (1992)[49] describe a patient C.K., who provided evidence challenging the view that visual imagery and visual perception rely on the same representational system. C.K. was a 33-year old man with visual object agnosia acquired after a vehicular accident. This deficit prevented him from being able to recognize objects and copy objects fluidly. Surprisingly, his ability to draw accurate objects from memory indicated his visual imagery was intact and normal. Furthermore, C.K. successfully performed other tasks requiring visual imagery for judgment of size, shape, color, and composition. These findings conflict with previous research as they suggest there is a partial dissociation between visual imagery and visual perception. C.K. exhibited a perceptual deficit that was not associated with a corresponding deficit in visual imagery, indicating that these two processes have systems for mental representations that may not be mediated entirely by the same neural substrates.

Schlegel and colleagues (2013)[50] conducted a functional MRI analysis of regions activated during manipulation of visual imagery. They identified 11 bilateral cortical and subcortical regions that exhibited increased activation when manipulating a visual image compared to when the visual image was just maintained. These regions included the occipital lobe and ventral stream areas, two parietal lobe regions, the posterior parietal cortex and the precuneus lobule, and three frontal lobe regions, the frontal eye fields, dorsolateral prefrontal cortex, and the prefrontal cortex. Due to their suspected involvement in working memory and attention, the authors propose that these parietal and prefrontal regions, and occipital regions, are part of a network involved in mediating the manipulation of visual imagery. These results suggest a top-down activation of visual areas in visual imagery.[51]

Using Dynamic Causal Modeling (DCM) to determine the connectivity of cortical networks, Ishai et al. (2010)[52] demonstrated that activation of the network mediating visual imagery is initiated by prefrontal cortex and posterior parietal cortex activity. Generation of objects from memory resulted in initial activation of the prefrontal and the posterior parietal areas, which then activate earlier visual areas through backward connectivity. Activation of the prefrontal cortex and posterior parietal cortex has also been found to be involved in retrieval of object representations from long-term memory, their maintenance in working memory, and attention during visual imagery. Thus, Ishai et al. suggest that the network mediating visual imagery is composed of attentional mechanisms arising from the posterior parietal cortex and the prefrontal cortex.

Vividness of visual imagery is a crucial component of an individual’s ability to perform cognitive tasks requiring imagery. Vividness of visual imagery varies not only between individuals but also within individuals. Dijkstra and colleagues (2017)[46] found that the variation in vividness of visual imagery is dependent on the degree to which the neural substrates of visual imagery overlap with those of visual perception. They found that overlap between imagery and perception in the entire visual cortex, the parietal precuneus lobule, the right parietal cortex, and the medial frontal cortex predicted the vividness of a mental representation. The activated regions beyond the visual areas are believed to drive the imagery-specific processes rather than the visual processes shared with perception. It has been suggested that the precuneus contributes to vividness by selecting important details for imagery. The medial frontal cortex is suspected to be involved in the retrieval and integration of information from the parietal and visual areas during working memory and visual imagery. The right parietal cortex appears to be important in attention, visual inspection, and stabilization of mental representations. Thus, the neural substrates of visual imagery and perception overlap in areas beyond the visual cortex and the degree of this overlap in these areas correlates with the vividness of mental representations during imagery.

Philosophical ideas edit

Main article: Mental representation

Mental images are an important topic in classical and modern philosophy, as they are central to the study of knowledge. In the Republic, Book VII, Plato has Socrates present the Allegory of the Cave: a prisoner, bound and unable to move, sits with his back to a fire watching the shadows cast on the cave wall in front of him by people carrying objects behind his back. These people and the objects they carry are representations of real things in the world. Unenlightened man is like the prisoner, explains Socrates, a human being making mental images from the sense data that he experiences.

The eighteenth-century philosopher Bishop George Berkeley proposed similar ideas in his theory of idealism. Berkeley stated that reality is equivalent to mental images—our mental images are not a copy of another material reality but that reality itself. Berkeley, however, sharply distinguished between the images that he considered to constitute the external world, and the images of individual imagination. According to Berkeley, only the latter are considered "mental imagery" in the contemporary sense of the term.

The eighteenth century British writer Dr. Samuel Johnson criticized idealism. When asked what he thought about idealism, he is alleged to have replied "I refute it thus!"[53] as he kicked a large rock and his leg rebounded. His point was that the idea that the rock is just another mental image and has no material existence of its own is a poor explanation of the painful sense data he had just experienced.

David Deutsch addresses Johnson's objection to idealism in The Fabric of Reality when he states that, if we judge the value of our mental images of the world by the quality and quantity of the sense data that they can explain, then the most valuable mental image—or theory—that we currently have is that the world has a real independent existence and that humans have successfully evolved by building up and adapting patterns of mental images to explain it. This is an important idea in scientific thought.[why?]

Critics of scientific realism ask how the inner perception of mental images actually occurs. This is sometimes called the "homunculus problem" (see also the mind's eye). The problem is similar to asking how the images you see on a computer screen exist in the memory of the computer. To scientific materialism, mental images and the perception of them must be brain-states. According to critics,[who?] scientific realists cannot explain where the images and their perceiver exist in the brain. To use the analogy of the computer screen, these critics argue that cognitive science and psychology have been unsuccessful in identifying either the component in the brain (i.e., "hardware") or the mental processes that store these images (i.e. "software").

In experimental psychology edit

Cognitive psychologists and (later) cognitive neuroscientists have empirically tested some of the philosophical questions related to whether and how the human brain uses mental imagery in cognition.

 
The types of rotation tests used by Shepard and Metzler

One theory of the mind that was examined in these experiments was the "brain as serial computer" philosophical metaphor of the 1970s. Psychologist Zenon Pylyshyn theorized that the human mind processes mental images by decomposing them into an underlying mathematical proposition. Roger Shepard and Jacqueline Metzler challenged that view by presenting subjects with 2D line drawings of groups of 3D block "objects" and asking them to determine whether that "object" is the same as a second figure, some of which rotations of the first "object".[54] Shepard and Metzler proposed that if we decomposed and then mentally re-imaged the objects into basic mathematical propositions, as the then-dominant view of cognition "as a serial digital computer"[55] assumed, then it would be expected that the time it took to determine whether the object is the same or not would be independent of how much the object had been rotated. Shepard and Metzler found the opposite: a linear relationship between the degree of rotation in the mental imagery task and the time it took participants to reach their answer.

This mental rotation finding implied that the human mind—and the human brain—maintains and manipulates mental images as topographic and topological wholes, an implication that was quickly put to test by psychologists. Stephen Kosslyn and colleagues[56] showed in a series of neuroimaging experiments that the mental image of objects like the letter "F" are mapped, maintained and rotated as an image-like whole in areas of the human visual cortex. Moreover, Kosslyn's work showed that there are considerable similarities between the neural mappings for imagined stimuli and perceived stimuli. The authors of these studies concluded that, while the neural processes they studied rely on mathematical and computational underpinnings, the brain also seems optimized to handle the sort of mathematics that constantly computes a series of topologically-based images rather than calculating a mathematical model of an object.

Recent studies in neurology and neuropsychology on mental imagery have further questioned the "mind as serial computer" theory, arguing instead that human mental imagery manifests both visually and kinesthetically. For example, several studies have provided evidence that people are slower at rotating line drawings of objects such as hands in directions incompatible with the joints of the human body,[57] and that patients with painful, injured arms are slower at mentally rotating line drawings of the hand from the side of the injured arm.[58]

Some psychologists, including Kosslyn, have argued that such results occur because of interference in the brain between distinct systems in the brain that process the visual and motor mental imagery. Subsequent neuroimaging studies[59] showed that the interference between the motor and visual imagery system could be induced by having participants physically handle actual 3D blocks glued together to form objects similar to those depicted in the line-drawings. Amorim et al. have shown that, when a cylindrical "head" was added to Shepard and Metzler's line drawings of 3D block figures, participants were quicker and more accurate at solving mental rotation problems.[60] They argue that motoric embodiment is not just "interference" that inhibits visual mental imagery but is capable of facilitating mental imagery.

As cognitive neuroscience approaches to mental imagery continued, research expanded beyond questions of serial versus parallel or topographic processing to questions of the relationship between mental images and perceptual representations. Both brain imaging (fMRI and ERP) and studies of neuropsychological patients have been used to test the hypothesis that a mental image is the reactivation, from memory, of brain representations normally activated during the perception of an external stimulus. In other words, if perceiving an apple activates contour and location and shape and color representations in the brain’s visual system, then imagining an apple activates some or all of these same representations using information stored in memory. Early evidence for this idea came from neuropsychology. Patients with brain damage that impairs perception in specific ways, for example by damaging shape or color representations, seem to generally to have impaired mental imagery in similar ways.[61] Studies of brain function in normal human brains support this same conclusion, showing activity in the brain’s visual areas while subjects imagined visual objects and scenes.[62]

The previously mentioned and numerous related studies have led to a relative consensus within cognitive science, psychology, neuroscience, and philosophy on the neural status of mental images. In general, researchers agree that, while there is no homunculus inside the head viewing these mental images, our brains do form and maintain mental images as image-like wholes.[63] The problem of exactly how these images are stored and manipulated within the human brain, in particular within language and communication, remains a fertile area of study.

One of the longest-running research topics on the mental image has basis on the fact that people report large individual differences in the vividness of their images. Special questionnaires have been developed to assess such differences, including the Vividness of Visual Imagery Questionnaire (VVIQ) developed by David Marks. Laboratory studies have suggested that the subjectively reported variations in imagery vividness are associated with different neural states within the brain and also different cognitive competences such as the ability to accurately recall information presented in pictures[64] Rodway, Gillies and Schepman used a novel long-term change detection task to determine whether participants with low and high vividness scores on the VVIQ2 showed any performance differences.[65] Rodway et al. found that high vividness participants were significantly more accurate at detecting salient changes to pictures compared to low-vividness participants.[66] This replicated an earlier study.[67]

Recent studies have found that individual differences in VVIQ scores can be used to predict changes in a person's brain while visualizing different activities.[68] Functional magnetic resonance imaging (fMRI) was used to study the association between early visual cortex activity relative to the whole brain while participants visualized themselves or another person bench pressing or stair climbing. Reported image vividness correlates significantly with the relative fMRI signal in the visual cortex. Thus, individual differences in the vividness of visual imagery can be measured objectively.

Logie, Pernet, Buonocore and Della Sala (2011) used behavioural and fMRI data for mental rotation from individuals reporting vivid and poor imagery on the VVIQ. Groups differed in brain activation patterns suggesting that the groups performed the same tasks in different ways. These findings help to explain the lack of association previously reported between VVIQ scores and mental rotation performance.

Training and learning styles edit

Some educational theorists[who?] have drawn from the idea of mental imagery in their studies of learning styles. Proponents of these theories state that people often have learning processes that emphasize visual, auditory, and kinesthetic systems of experience.[citation needed] According to these theorists, teaching in multiple overlapping sensory systems benefits learning, and they encourage teachers to use content and media that integrates well with the visual, auditory, and kinesthetic systems whenever possible.

Educational researchers have examined whether the experience of mental imagery affects the degree of learning. For example, imagining playing a five-finger piano exercise (mental practice) resulted in a significant improvement in performance over no mental practice—though not as significant as that produced by physical practice. The authors of the study stated that "mental practice alone seems to be sufficient to promote the modulation of neural circuits involved in the early stages of motor skill learning".[69]

Visualization and religion edit

Mental visualization is used across world religions, particularly as an aid for prayer or meditation.

Christianity edit

Opinions on the value of visualization vary within Christianity. In Catholicism, visualization plays a central role in the recitation of the Rosary, where it may be used to visualize Biblical scenes.[clarification needed] In Eastern Orthodoxy, however, image-based prayer is generally frowned upon, because it is seen as an opening for demonic influence, and as contradictory to the aims of hesychastic prayer.[citation needed]

Tibetan traditions edit

In general, Vajrayana Buddhism and Bön utilize sophisticated visualization or imaginal (in the language of Jean Houston of Transpersonal Psychology) processes in the Tulpa construction of the yidam sadhana, kye-rim, and dzog-rim modes of meditation and in the yantra, thangka, and mandala traditions, where holding the fully realized form in the mind is a prerequisite prior to creating an 'authentic' new art work that will provide a sacred support or foundation for deity.[70][71]

Substitution effects edit

Mental imagery can act as a substitute for the imagined experience: Imagining an experience can evoke similar cognitive, physiological, and behavioral consequences as having the corresponding experience in reality.[72] At least four classes of such effects have been documented.[6]

  1. Imagined experiences are attributed evidentiary value like physical evidence.
  2. Mental practice can instantiate the same performance benefits as physical practice and reduction central neuropathic pain.[73][72]
  3. Imagined consumption of a food can reduce its actual consumption.
  4. Imagined goal achievement can reduce motivation for actual goal achievement.

See also edit

References edit

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Further reading edit

  • Albert, J.-M. ‘’Mental Image and Representation. (French text by Jean-Max Albert and translation by H. Arnold) Paris: Mercier & Associés, 2018. [1]
  • Amorim, Michel-Ange, Brice Isableu and Mohammed Jarraya (2006) Embodied Spatial Transformations: “Body Analogy” for the Mental Rotation. Journal of Experimental Psychology: General.
  • Barsalou, L.W. (1999). "Perceptual Symbol Systems". Behavioral and Brain Sciences. 22 (4): 577–660. CiteSeerX 10.1.1.601.93. doi:10.1017/s0140525x99002149. PMID 11301525. S2CID 351236.
  • Bartolomeo, P (2002). "The Relationship Between Visual perception and Visual Mental Imagery: A Reappraisal of the Neuropsychological Evidence". Cortex. 38 (3): 357–378. doi:10.1016/s0010-9452(08)70665-8. PMID 12146661. S2CID 4485950.
  • Bennett, M.R. & Hacker, P.M.S. (2003). Philosophical Foundations of Neuroscience. Oxford: Blackwell.
  • Bensafi, M.; Porter, J.; Pouliot, S.; Mainland, J.; Johnson, B.; Zelano, C.; Young, N.; Bremner, E.; Aframian, D.; Kahn, R.; Sobel, N. (2003). "Olfactomotor Activity During Imagery Mimics that During Perception". Nature Neuroscience. 6 (11): 1142–1144. doi:10.1038/nn1145. PMID 14566343. S2CID 5915985.
  • Block, N (1983). "Mental Pictures and Cognitive Science". Philosophical Review. 92 (4): 499–539. doi:10.2307/2184879. JSTOR 2184879.
  • Brant, W. (2013). Mental Imagery and Creativity: Cognition, Observation and Realization. Akademikerverlag. pp. 227. Saarbrücken, Germany. ISBN 978-3-639-46288-3
  • Cui, X.; Jeter, C.B.; Yang, D.; Montague, P.R.; Eagleman, D.M. (2007). "Vividness of mental imagery: Individual variability can be measured objectively". Vision Research. 47 (4): 474–478. doi:10.1016/j.visres.2006.11.013. PMC 1839967. PMID 17239915.
  • Deutsch, David (1998). The Fabric of Reality. Penguin Adult. ISBN 978-0-14-014690-5.
  • Egan, Kieran (1992). Imagination in Teaching and Learning. Chicago: University of Chicago Press.
  • Fichter, C.; Jonas, K. (2008). "Image Effects of Newspapers. How Brand Images Change Consumers' Product Ratings". Zeitschrift für Psychologie. 216 (4): 226–234. doi:10.1027/0044-3409.216.4.226. Archived from the original on 2013-01-03.
  • Finke, R.A. (1989). Principles of Mental Imagery. Cambridge, MA: MIT Press.
  • Garnder, Howard. (1987) The Mind's New Science: A History of the Cognitive Revolution New York: Basic Books.
  • Gur, R.C.; Hilgard, E.R. (1975). "Visual imagery and discrimination of differences between altered pictures simultaneously and successively presented". British Journal of Psychology. 66 (3): 341–345. doi:10.1111/j.2044-8295.1975.tb01470.x. PMID 1182401.
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  • Kosslyn, Stephen (1994) Image and Brain: The Resolution of the Imagery Debate. Cambridge, MA: MIT Press.
  • Kosslyn, Stephen M.; Thompson, William L.; Kim, Irene J.; Alpert, Nathaniel M. (1995). "Topographic representations of mental images in primary visual cortex". Nature. 378 (6556): 496–498. Bibcode:1995Natur.378..496K. doi:10.1038/378496a0. PMID 7477406. S2CID 127386.
  • Kosslyn, Stephen M.; Thompson, William L.; Wraga, Mary J.; Alpert, Nathaniel M. (2001). "Imagining rotation by endogenous versus exogenous forces: Distinct neural mechanisms". NeuroReport. 12 (11): 2519–2525. doi:10.1097/00001756-200108080-00046. PMID 11496141. S2CID 43067749.
  • Logie, R.H.; Pernet, C.R.; Buonocore, A.; Della Sala, S. (2011). "Low and high imagers activate networks differentially in mental rotation". Neuropsychologia. 49 (11): 3071–3077. doi:10.1016/j.neuropsychologia.2011.07.011. PMID 21802436. S2CID 7073330.
  • Marks, D.F. (1973). "Visual imagery differences in the recall of pictures". British Journal of Psychology. 64 (1): 17–24. doi:10.1111/j.2044-8295.1973.tb01322.x. PMID 4742442.
  • Marks, D.F. (1995). "New directions for mental imagery research". Journal of Mental Imagery. 19: 153–167.
  • McGabhann. R, Squires. B, 2003, 'Releasing The Beast Within – A path to Mental Toughness', Granite Publishing, Australia.
  • McKellar, Peter (1957). Imagination and Thinking. London: Cohen & West.
  • Norman, Donald. The Design of Everyday Things. ISBN 978-0-465-06710-7.
  • Paivio, Allan (1986). Mental Representations: A Dual Coding Approach. New York: Oxford University Press.
  • Parsons, Lawrence M (1987). "Imagined spatial transformations of one's hands and feet". Cognitive Psychology. 19 (2): 178–241. doi:10.1016/0010-0285(87)90011-9. PMID 3581757. S2CID 38603712.
  • Parsons, Lawrence M (2003). "Superior parietal cortices and varieties of mental rotation". Trends in Cognitive Sciences. 7 (12): 515–551. doi:10.1016/j.tics.2003.10.002. PMID 14643362. S2CID 18955586.
  • Pascual-Leone, Alvaro, Nguyet Dang, Leonardo G. Cohen, Joaquim P. Brasil-Neto, Angel Cammarota, and Mark Hallett (1995). Modulation of Muscle Responses Evoked by Transcranial Magnetic Stimulation During the Acquisition of New Fine Motor Skills. Journal of Neuroscience
  • Plato (2000). The Republic (New CUP translation into English). Cambridge University Press. ISBN 978-0-521-48443-5.
  • Plato (2003). Respublica (New CUP edition of Greek text). E Typographeo Clarendoniano. ISBN 978-0-19-924849-0.
  • Prinz, J.J. (2002). Furnishing the Mind: Concepts and their Perceptual Basis. Boston, MA: MIT Press.
  • Pylyshyn, Zenon W (1973). "What the mind's eye tells the mind's brain: a critique of mental imagery". Psychological Bulletin. 80: 1–24. doi:10.1037/h0034650. S2CID 264755021.
  • Reisberg, Daniel (Ed.) (1992). Auditory Imagery. Hillsdale, NJ: Erlbaum.
  • Richardson, A. (1969). Mental Imagery. London: Routledge & Kegan Paul.
  • Rodway, P.; Gillies, K.; Schepman, A. (2006). "Vivid imagers are better at detecting salient changes". Journal of Individual Differences. 27 (4): 218–228. doi:10.1027/1614-0001.27.4.218.
  • Rohrer, T. (2006). The Body in Space: Embodiment, Experientialism and Linguistic Conceptualization. In Body, Language and Mind, vol. 2. Zlatev, Jordan; Ziemke, Tom; Frank, Roz; Dirven, René (eds.). Berlin: Mouton de Gruyter.
  • Ryle, G. (1949). The Concept of Mind. London: Hutchinson.
  • Sartre, J.-P. (1940). The Psychology of Imagination. (Translated from the French by B. Frechtman, New York: Philosophical Library, 1948.)
  • Schwoebel, John; Friedman, Robert; Duda, Nanci; Coslett, H. Branch (2001). "Pain and the body schema evidence for peripheral effects on mental representations of movement". Brain. 124 (10): 2098–2104. doi:10.1093/brain/124.10.2098. PMID 11571225.
  • Skinner, B.F. (1974). About Behaviorism. New York: Knopf.
  • Shepard, Roger N.; Metzler, Jacqueline (1971). "Mental rotation of three-dimensional objects". Science. 171 (3972): 701–703. Bibcode:1971Sci...171..701S. CiteSeerX 10.1.1.610.4345. doi:10.1126/science.171.3972.701. PMID 5540314. S2CID 16357397.
  • Thomas, Nigel J.T. (1999). "Are Theories of Imagery Theories of Imagination? An Active Perception Approach to Conscious Mental Content". Cognitive Science. 23 (2): 207–245. doi:10.1207/s15516709cog2302_3.
  • Thomas, N.J.T. (2003). In L. Nadel (Ed.), Encyclopedia of Cognitive Science (Volume 2, pp. 1147–1153). London: Nature Publishing/Macmillan.

External links edit

 
Wikiquote has quotations related to Mental image.
  • Mental Imagery in the Stanford Encyclopedia of Philosophy

January 01, 1970
mental, image, redirects, here, computer, graphics, software, company, mental, images, mind, redirects, here, other, uses, mind, disambiguation, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations,. Mental images redirects here For the computer graphics software company see Mental Images Mind s eye redirects here For other uses see Mind s eye disambiguation This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Mental image news newspapers books scholar JSTOR May 2010 Learn how and when to remove this template message In the philosophy of mind neuroscience and cognitive science a mental image is an experience that on most occasions significantly resembles the experience of perceiving some object event or scene but occurs when the relevant object event or scene is not actually present to the senses 1 2 3 4 There are sometimes episodes particularly on falling asleep hypnagogic imagery and waking up hypnopompic imagery when the mental imagery may be dynamic phantasmagoric and involuntary in character repeatedly presenting identifiable objects or actions spilling over from waking events or defying perception presenting a kaleidoscopic field in which no distinct object can be discerned 5 Mental imagery can sometimes produce the same effects as would be produced by the behavior or experience imagined 6 The nature of these experiences what makes them possible and their function if any have long been subjects of research and controversy in philosophy psychology cognitive science and more recently neuroscience As contemporary researchers use the expression mental images or imagery can comprise information from any source of sensory input one may experience auditory images 7 olfactory images 8 and so forth However the majority of philosophical and scientific investigations of the topic focus on visual mental imagery It has sometimes been assumed that like humans some types of animals are capable of experiencing mental images 9 Due to the fundamentally introspective reflective nature of the phenomenon it has been difficult to assess whether or not non human animals experience mental imagery Philosophers such as George Berkeley and David Hume and early experimental psychologists such as Wilhelm Wundt and William James understood ideas in general to be mental images Today it is very widely believed that much imagery functions as mental representations or mental models playing an important role in memory and thinking 10 11 12 13 William Brant 2013 p 12 traces the scientific use of the phrase mental images back to John Tyndall s 1870 speech called the Scientific Use of the Imagination Some have suggested that images are best understood to be by definition a form of inner mental or neural representation 14 15 Others reject the view that the image experience may be identical with or directly caused by any such representation in the mind or the brain 16 17 18 19 20 21 but do not take account of the non representational forms of imagery Contents 1 Mind s eye 2 Physical basis 3 Neural substrates of visual imagery 4 Philosophical ideas 5 In experimental psychology 6 Training and learning styles 7 Visualization and religion 7 1 Christianity 7 2 Tibetan traditions 8 Substitution effects 9 See also 10 References 11 Further reading 12 External linksMind s eye editThe notion of a mind s eye goes back at least to Cicero s reference to mentis oculi during his discussion of the orator s appropriate use of simile 22 In this discussion Cicero observed that allusions to the Syrtis of his patrimony and the Charybdis of his possessions involved similes that were too far fetched and he advised the orator to instead just speak of the rock and the gulf respectively on the grounds that the eyes of the mind are more easily directed to those objects which we have seen than to those which we have only heard 23 The concept of the mind s eye first appeared in English in Chaucer s c 1387 Man of Law s Tale in his Canterbury Tales where he tells us that one of the three men dwelling in a castle was blind and could only see with the eyes of his mind namely those eyes with which all men see after they have become blind 24 Physical basis editThe biological foundation of mental imagery is not fully understood Studies using fMRI have shown that the lateral geniculate nucleus and the V1 area of the visual cortex are activated during mental imagery tasks 25 Ratey writes The visual pathway is not a one way street Higher areas of the brain can also send visual input back to neurons in lower areas of the visual cortex As humans we have the ability to see with the mind s eye to have a perceptual experience in the absence of visual input For example PET scans have shown that when subjects seated in a room imagine they are at their front door starting to walk either to the left or right activation begins in the visual association cortex the parietal cortex and the prefrontal cortex all higher cognitive processing centers of the brain 26 A biological basis for mental imagery is found in the deeper portions of the brain below the neocortex In a large study with 285 participants Tabi Maio Attaallah et al 2022 investigated the association between an established measure of visual mental imagery Vividness of Visual Imagery Questionnaire VVIQ scores and volumes of brain structures including the hippocampus amygdala primary motor cortex primary visual cortex and the fusiform gyrus Tabi et al 2022 found significant positive correlations between visual imagery vividness and the volumes of the hippocampus and primary visual cortex nbsp VVIQ correlations with Hippocampal CA amp GC ML DG volumes Significant positive correlations were also obtained between VVIQ scores and hippocampal structures including Bilateral CA1 CA3 CA4 and Granule Cell GC and Molecular Layer ML of the Dentate Gyrus DG Follow up analysis revealed that visual imagery was in particular correlated with the four subfields presented in the above illustration Tabi et al 2022 The thalamus has been found to be discrete to other components in that it processes all forms of perceptional data relayed from both lower and higher components of the brain Damage to this component can produce permanent perceptual damage however when damage is inflicted upon the cerebral cortex the brain adapts to neuroplasticity to amend any occlusions for perception citation needed It can be thought that the neocortex is a sophisticated memory storage warehouse in which data received as an input from sensory systems are compartmentalized via the cerebral cortex This would essentially allow for shapes to be identified although given the lack of filtering input produced internally one may as a consequence hallucinate essentially seeing something that isn t received as an input externally but rather internal i e an error in the filtering of segmented sensory data from the cerebral cortex may result in one seeing feeling hearing or experiencing something that is inconsistent with reality Not all people have the same mental imagery ability For many when the eyes are closed the perception of darkness prevails However some people are able to perceive colorful dynamic imagery McKellar 1957 The use of hallucinogenic drugs increases the subject s ability to consciously access mental imagery including synaestesia McKellar 1957 Furthermore the pineal gland is a hypothetical candidate for producing a mind s eye Rick Strassman and others have postulated that during near death experiences NDEs and dreaming the gland might secrete the hallucinogenic chemical N N Dimethyltryptamine DMT to produce internal visuals when external sensory data is occluded 27 However this hypothesis has yet to be fully supported with neurochemical evidence and plausible mechanism for DMT production The condition where a person lacks mental imagery is called aphantasia The term was first suggested in a 2015 study 28 Common examples of mental images include daydreaming and the mental visualization that occurs while reading a book Another is of the pictures summoned by athletes during training or before a competition outlining each step they will take to accomplish their goal 29 When a musician hears a song they can sometimes see the song notes in their head as well as hear them with all their tonal qualities 30 This is considered different from an after effect such as an afterimage Calling up an image in our minds can be a voluntary act so it can be characterized as being under various degrees of conscious control There are several theories as to how mental images are formed in the mind These include the dual code theory the propositional theory and the functional equivalency hypothesis The dual code theory created by Allan Paivio in 1971 is the theory that we use two separate codes to represent information in our brains image codes and verbal codes Image codes are things like thinking of a picture of a dog when you are thinking of a dog whereas a verbal code would be to think of the word dog 31 Another example is the difference between thinking of abstract words such as justice or love and thinking of concrete words like elephant or chair When abstract words are thought of it is easier to think of them in terms of verbal codes finding words that define them or describe them With concrete words it is often easier to use image codes and bring up a picture of a human or chair in your mind rather than words associated or descriptive of them The propositional theory involves storing images in the form of a generic propositional code that stores the meaning of the concept not the image itself The propositional codes can either be descriptive of the image or symbolic They are then transferred back into verbal and visual code to form the mental image 32 The functional equivalency hypothesis is that mental images are internal representations that work in the same way as the actual perception of physical objects 33 In other words the picture of a dog brought to mind when the word dog is read is interpreted in the same way as if the person was observing an actual dog before them Research has occurred to designate a specific neural correlate of imagery however studies show a multitude of results Most studies published before 2001 suggest neural correlates of visual imagery occur in Brodmann area 17 34 Auditory performance imagery have been observed in the premotor areas precunes and medial Brodmann area 40 35 Auditory imagery in general occurs across participants in the temporal voice area TVA which allows top down imaging manipulations processing and storage of audition functions 36 Olfactory imagery research shows activation in the anterior piriform cortex and the posterior piriform cortex experts in olfactory imagery have larger gray matter associated to olfactory areas 37 Tactile imagery is found to occur in the dorsolateral prefrontal area inferior frontal gyrus frontal gyrus insula precentral gyrus and the medial frontal gyrus with basal ganglia activation in the ventral posteriomedial nucleus and putamen hemisphere activation corresponds to the location of the imagined tactile stimulus 38 Research in gustatory imagery reveals activation in the anterior insular cortex frontal operculum and prefrontal cortex 34 Novices of a specific form of mental imagery show less gray matter than experts of mental imagery congruent to that form 39 A meta analysis of neuroimagery studies revealed significant activation of the bilateral dorsal parietal interior insula and left inferior frontal regions of the brain 40 Causal evidence from neurological patients with brain lesions demonstrates that vivid visual mental imagery is possible even when occipital visual areas are lesioned or disconnected from more anterior cortex Visual mental imagery can instead be impaired by left temporal damage 41 Consistent with these findings a meta analysis of 27 neuroimaging studies demonstrated imagery related activity in a region of the left ventral temporal cortex which was dubbed the Fusiform Imagery Node 42 An additional Bayesian analysis excluded a role for occipital cortex in visual mental imagery consistent with the evidence from neurological patients Imagery has been thought to cooccur with perception however participants with damaged sense modality receptors can sometimes perform imagery of said modality receptors 43 Neuroscience with imagery has been used to communicate with seemingly unconscious individuals through fMRI activation of different neural correlates of imagery demanding further study into low quality consciousness 44 A study on one patient with one occipital lobe removed found the horizontal area of their visual mental image was reduced 45 Neural substrates of visual imagery editVisual imagery is the ability to create mental representations of things people and places that are absent from an individual s visual field This ability is crucial to problem solving tasks memory and spatial reasoning 46 Neuroscientists have found that imagery and perception share many of the same neural substrates or areas of the brain that function similarly during both imagery and perception such as the visual cortex and higher visual areas Kosslyn and colleagues 1999 47 showed that the early visual cortex Area 17 and Area 18 19 is activated during visual imagery They found that inhibition of these areas through repetitive transcranial magnetic stimulation rTMS resulted in impaired visual perception and imagery Furthermore research conducted with lesioned patients has revealed that visual imagery and visual perception have the same representational organization This has been concluded from patients in which impaired perception also experience visual imagery deficits at the same level of the mental representation 48 Behrmann and colleagues 1992 49 describe a patient C K who provided evidence challenging the view that visual imagery and visual perception rely on the same representational system C K was a 33 year old man with visual object agnosia acquired after a vehicular accident This deficit prevented him from being able to recognize objects and copy objects fluidly Surprisingly his ability to draw accurate objects from memory indicated his visual imagery was intact and normal Furthermore C K successfully performed other tasks requiring visual imagery for judgment of size shape color and composition These findings conflict with previous research as they suggest there is a partial dissociation between visual imagery and visual perception C K exhibited a perceptual deficit that was not associated with a corresponding deficit in visual imagery indicating that these two processes have systems for mental representations that may not be mediated entirely by the same neural substrates Schlegel and colleagues 2013 50 conducted a functional MRI analysis of regions activated during manipulation of visual imagery They identified 11 bilateral cortical and subcortical regions that exhibited increased activation when manipulating a visual image compared to when the visual image was just maintained These regions included the occipital lobe and ventral stream areas two parietal lobe regions the posterior parietal cortex and the precuneus lobule and three frontal lobe regions the frontal eye fields dorsolateral prefrontal cortex and the prefrontal cortex Due to their suspected involvement in working memory and attention the authors propose that these parietal and prefrontal regions and occipital regions are part of a network involved in mediating the manipulation of visual imagery These results suggest a top down activation of visual areas in visual imagery 51 Using Dynamic Causal Modeling DCM to determine the connectivity of cortical networks Ishai et al 2010 52 demonstrated that activation of the network mediating visual imagery is initiated by prefrontal cortex and posterior parietal cortex activity Generation of objects from memory resulted in initial activation of the prefrontal and the posterior parietal areas which then activate earlier visual areas through backward connectivity Activation of the prefrontal cortex and posterior parietal cortex has also been found to be involved in retrieval of object representations from long term memory their maintenance in working memory and attention during visual imagery Thus Ishai et al suggest that the network mediating visual imagery is composed of attentional mechanisms arising from the posterior parietal cortex and the prefrontal cortex Vividness of visual imagery is a crucial component of an individual s ability to perform cognitive tasks requiring imagery Vividness of visual imagery varies not only between individuals but also within individuals Dijkstra and colleagues 2017 46 found that the variation in vividness of visual imagery is dependent on the degree to which the neural substrates of visual imagery overlap with those of visual perception They found that overlap between imagery and perception in the entire visual cortex the parietal precuneus lobule the right parietal cortex and the medial frontal cortex predicted the vividness of a mental representation The activated regions beyond the visual areas are believed to drive the imagery specific processes rather than the visual processes shared with perception It has been suggested that the precuneus contributes to vividness by selecting important details for imagery The medial frontal cortex is suspected to be involved in the retrieval and integration of information from the parietal and visual areas during working memory and visual imagery The right parietal cortex appears to be important in attention visual inspection and stabilization of mental representations Thus the neural substrates of visual imagery and perception overlap in areas beyond the visual cortex and the degree of this overlap in these areas correlates with the vividness of mental representations during imagery Philosophical ideas editMain article Mental representation This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed May 2013 Learn how and when to remove this template message Mental images are an important topic in classical and modern philosophy as they are central to the study of knowledge In the Republic Book VII Plato has Socrates present the Allegory of the Cave a prisoner bound and unable to move sits with his back to a fire watching the shadows cast on the cave wall in front of him by people carrying objects behind his back These people and the objects they carry are representations of real things in the world Unenlightened man is like the prisoner explains Socrates a human being making mental images from the sense data that he experiences The eighteenth century philosopher Bishop George Berkeley proposed similar ideas in his theory of idealism Berkeley stated that reality is equivalent to mental images our mental images are not a copy of another material reality but that reality itself Berkeley however sharply distinguished between the images that he considered to constitute the external world and the images of individual imagination According to Berkeley only the latter are considered mental imagery in the contemporary sense of the term The eighteenth century British writer Dr Samuel Johnson criticized idealism When asked what he thought about idealism he is alleged to have replied I refute it thus 53 as he kicked a large rock and his leg rebounded His point was that the idea that the rock is just another mental image and has no material existence of its own is a poor explanation of the painful sense data he had just experienced David Deutsch addresses Johnson s objection to idealism in The Fabric of Reality when he states that if we judge the value of our mental images of the world by the quality and quantity of the sense data that they can explain then the most valuable mental image or theory that we currently have is that the world has a real independent existence and that humans have successfully evolved by building up and adapting patterns of mental images to explain it This is an important idea in scientific thought why Critics of scientific realism ask how the inner perception of mental images actually occurs This is sometimes called the homunculus problem see also the mind s eye The problem is similar to asking how the images you see on a computer screen exist in the memory of the computer To scientific materialism mental images and the perception of them must be brain states According to critics who scientific realists cannot explain where the images and their perceiver exist in the brain To use the analogy of the computer screen these critics argue that cognitive science and psychology have been unsuccessful in identifying either the component in the brain i e hardware or the mental processes that store these images i e software In experimental psychology editCognitive psychologists and later cognitive neuroscientists have empirically tested some of the philosophical questions related to whether and how the human brain uses mental imagery in cognition nbsp The types of rotation tests used by Shepard and Metzler One theory of the mind that was examined in these experiments was the brain as serial computer philosophical metaphor of the 1970s Psychologist Zenon Pylyshyn theorized that the human mind processes mental images by decomposing them into an underlying mathematical proposition Roger Shepard and Jacqueline Metzler challenged that view by presenting subjects with 2D line drawings of groups of 3D block objects and asking them to determine whether that object is the same as a second figure some of which rotations of the first object 54 Shepard and Metzler proposed that if we decomposed and then mentally re imaged the objects into basic mathematical propositions as the then dominant view of cognition as a serial digital computer 55 assumed then it would be expected that the time it took to determine whether the object is the same or not would be independent of how much the object had been rotated Shepard and Metzler found the opposite a linear relationship between the degree of rotation in the mental imagery task and the time it took participants to reach their answer This mental rotation finding implied that the human mind and the human brain maintains and manipulates mental images as topographic and topological wholes an implication that was quickly put to test by psychologists Stephen Kosslyn and colleagues 56 showed in a series of neuroimaging experiments that the mental image of objects like the letter F are mapped maintained and rotated as an image like whole in areas of the human visual cortex Moreover Kosslyn s work showed that there are considerable similarities between the neural mappings for imagined stimuli and perceived stimuli The authors of these studies concluded that while the neural processes they studied rely on mathematical and computational underpinnings the brain also seems optimized to handle the sort of mathematics that constantly computes a series of topologically based images rather than calculating a mathematical model of an object Recent studies in neurology and neuropsychology on mental imagery have further questioned the mind as serial computer theory arguing instead that human mental imagery manifests both visually and kinesthetically For example several studies have provided evidence that people are slower at rotating line drawings of objects such as hands in directions incompatible with the joints of the human body 57 and that patients with painful injured arms are slower at mentally rotating line drawings of the hand from the side of the injured arm 58 Some psychologists including Kosslyn have argued that such results occur because of interference in the brain between distinct systems in the brain that process the visual and motor mental imagery Subsequent neuroimaging studies 59 showed that the interference between the motor and visual imagery system could be induced by having participants physically handle actual 3D blocks glued together to form objects similar to those depicted in the line drawings Amorim et al have shown that when a cylindrical head was added to Shepard and Metzler s line drawings of 3D block figures participants were quicker and more accurate at solving mental rotation problems 60 They argue that motoric embodiment is not just interference that inhibits visual mental imagery but is capable of facilitating mental imagery As cognitive neuroscience approaches to mental imagery continued research expanded beyond questions of serial versus parallel or topographic processing to questions of the relationship between mental images and perceptual representations Both brain imaging fMRI and ERP and studies of neuropsychological patients have been used to test the hypothesis that a mental image is the reactivation from memory of brain representations normally activated during the perception of an external stimulus In other words if perceiving an apple activates contour and location and shape and color representations in the brain s visual system then imagining an apple activates some or all of these same representations using information stored in memory Early evidence for this idea came from neuropsychology Patients with brain damage that impairs perception in specific ways for example by damaging shape or color representations seem to generally to have impaired mental imagery in similar ways 61 Studies of brain function in normal human brains support this same conclusion showing activity in the brain s visual areas while subjects imagined visual objects and scenes 62 The previously mentioned and numerous related studies have led to a relative consensus within cognitive science psychology neuroscience and philosophy on the neural status of mental images In general researchers agree that while there is no homunculus inside the head viewing these mental images our brains do form and maintain mental images as image like wholes 63 The problem of exactly how these images are stored and manipulated within the human brain in particular within language and communication remains a fertile area of study One of the longest running research topics on the mental image has basis on the fact that people report large individual differences in the vividness of their images Special questionnaires have been developed to assess such differences including the Vividness of Visual Imagery Questionnaire VVIQ developed by David Marks Laboratory studies have suggested that the subjectively reported variations in imagery vividness are associated with different neural states within the brain and also different cognitive competences such as the ability to accurately recall information presented in pictures 64 Rodway Gillies and Schepman used a novel long term change detection task to determine whether participants with low and high vividness scores on the VVIQ2 showed any performance differences 65 Rodway et al found that high vividness participants were significantly more accurate at detecting salient changes to pictures compared to low vividness participants 66 This replicated an earlier study 67 Recent studies have found that individual differences in VVIQ scores can be used to predict changes in a person s brain while visualizing different activities 68 Functional magnetic resonance imaging fMRI was used to study the association between early visual cortex activity relative to the whole brain while participants visualized themselves or another person bench pressing or stair climbing Reported image vividness correlates significantly with the relative fMRI signal in the visual cortex Thus individual differences in the vividness of visual imagery can be measured objectively Logie Pernet Buonocore and Della Sala 2011 used behavioural and fMRI data for mental rotation from individuals reporting vivid and poor imagery on the VVIQ Groups differed in brain activation patterns suggesting that the groups performed the same tasks in different ways These findings help to explain the lack of association previously reported between VVIQ scores and mental rotation performance Training and learning styles editSome educational theorists who have drawn from the idea of mental imagery in their studies of learning styles Proponents of these theories state that people often have learning processes that emphasize visual auditory and kinesthetic systems of experience citation needed According to these theorists teaching in multiple overlapping sensory systems benefits learning and they encourage teachers to use content and media that integrates well with the visual auditory and kinesthetic systems whenever possible Educational researchers have examined whether the experience of mental imagery affects the degree of learning For example imagining playing a five finger piano exercise mental practice resulted in a significant improvement in performance over no mental practice though not as significant as that produced by physical practice The authors of the study stated that mental practice alone seems to be sufficient to promote the modulation of neural circuits involved in the early stages of motor skill learning 69 Visualization and religion editThis section needs expansion You can help by adding to it March 2023 Mental visualization is used across world religions particularly as an aid for prayer or meditation Christianity edit Opinions on the value of visualization vary within Christianity In Catholicism visualization plays a central role in the recitation of the Rosary where it may be used to visualize Biblical scenes clarification needed In Eastern Orthodoxy however image based prayer is generally frowned upon because it is seen as an opening for demonic influence and as contradictory to the aims of hesychastic prayer citation needed Tibetan traditions edit In general Vajrayana Buddhism and Bon utilize sophisticated visualization or imaginal in the language of Jean Houston of Transpersonal Psychology processes in the Tulpa construction of the yidam sadhana kye rim and dzog rim modes of meditation and in the yantra thangka and mandala traditions where holding the fully realized form in the mind is a prerequisite prior to creating an authentic new art work that will provide a sacred support or foundation for deity 70 71 Substitution effects editMental imagery can act as a substitute for the imagined experience Imagining an experience can evoke similar cognitive physiological and behavioral consequences as having the corresponding experience in reality 72 At least four classes of such effects have been documented 6 Imagined experiences are attributed evidentiary value like physical evidence Mental practice can instantiate the same performance benefits as physical practice and reduction central neuropathic pain 73 72 Imagined consumption of a food can reduce its actual consumption Imagined goal achievement can reduce motivation for actual goal achievement See also editAphantasia Animal cognition Audiation imaginary sound Cognition Creative visualization Fantasy psychology Fantasy prone personality Guided imagery Imagination Internal monologue Mental event Mental rotation Mind Motor imagery Spatial ability Tulpa Visual space Vividness of Visual Imagery QuestionnaireReferences edit McKellar 1957 Richardson 1969 Finke 1989 Thomas 2003 Wright Edmond 1983 Inspecting images Philosophy 58 223 57 72 see pp 68 72 doi 10 1017 s0031819100056266 S2CID 170522026 a b Kappes Heather Barry Morewedge Carey K 2016 07 01 Mental Simulation as Substitute for Experience PDF Social and Personality Psychology Compass 10 7 405 420 doi 10 1111 spc3 12257 ISSN 1751 9004 S2CID 4823141 Reisberg 1992 Bensafi et al 2003 Aristotle On the Soul III 3 428a Pavio 1986 Egan 1992 Barsalou 1999 Prinz 2002 Block 1983 Kosslyn 1983 Sartre 1940 Ryle 1949 Skinner 1974 Thomas 1999 Bartolomeo 2002 Bennett amp Hacker 2003 Cicero Marcus Tullius 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performance in pianists Cognitive Brain Research 19 3 219 228 doi 10 1016 j cogbrainres 2003 12 005 PMID 15062860 Bruck Carolin Kreifelts Benjamin Gossling Arnold Christina Wertheimer Jurgen Wildgruber Dirk 2014 11 01 Inner voices the cerebral representation of emotional voice cues described in literary texts Social Cognitive and Affective Neuroscience 9 11 1819 1827 doi 10 1093 scan nst180 ISSN 1749 5016 PMC 4221224 PMID 24396008 Arshamian Artin Larsson Maria 2014 01 01 Same same but different the case of olfactory imagery Frontiers in Psychology 5 34 doi 10 3389 fpsyg 2014 00034 PMC 3909946 PMID 24550862 Yoo Seung Schik Freeman Daniel K McCarthy James J III Jolesz Ferenc A 2003 03 24 Neural substrates of tactile imagery a functional MRI study NeuroReport 14 4 581 585 doi 10 1097 00001756 200303240 00011 PMID 12657890 S2CID 40971701 Lima Cesar F Lavan Nadine Evans Samuel Agnew Zarinah Halpern Andrea R Shanmugalingam Pradheep Meekings Sophie Boebinger Dana Ostarek Markus 2015 11 01 Feel the Noise Relating Individual Differences in Auditory Imagery to the Structure and Function of Sensorimotor Systems Cerebral Cortex 25 11 4638 4650 doi 10 1093 cercor bhv134 ISSN 1047 3211 PMC 4816805 PMID 26092220 Mcnorgan Chris 2012 01 01 A meta analytic review of multisensory imagery identifies the neural correlates of modality specific and modality general imagery Frontiers in Human Neuroscience 6 285 doi 10 3389 fnhum 2012 00285 PMC 3474291 PMID 23087637 Bartolomeo Paolo Hajhajate Dounia Liu Jianghao Spagna Alfredo 2020 Assessing the causal role of early visual areas in visual mental imagery Nature Reviews Neuroscience 21 9 517 doi 10 1038 s41583 020 0348 5 PMID 32665712 S2CID 220506141 Spagna Alfredo Hajhajate Dounia Liu Jianghao Bartolomeo Paolo 2021 Visual mental imagery engages the left fusiform gyrus but not the early visual cortex A meta analysis of neuroimaging evidence Neurosci Biobehav Rev 122 201 217 doi 10 1016 j neubiorev 2020 12 029 PMID 33422567 Kosslyn Stephen 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mind s eye Archives Italiennes de Biologie 148 1 1 9 2010 Patey Douglas Lane January 1986 Johnson s Refutation of Berkeley Kicking the Stone Again Journal of the History of Ideas 47 1 139 145 doi 10 2307 2709600 JSTOR 2709600 Shepard and Metzler 1971 Gardner 1987 Kosslyn 1995 see also 1994 Parsons 1987 2003 Schwoebel et al 2001 Kosslyn et al 2001 Amorim et al 2006 Farah Martha J Sep 30 1987 Is visual imagery really visual Overlooked evidence from neuropsychology Psychological Review 95 3 307 317 doi 10 1037 0033 295x 95 3 307 PMID 3043530 Cichy Radoslaw M Heinzle Jakob Haynes John Dylan June 10 2011 Imagery and Perception Share Cortical Representations of Content and Location PDF Cerebral Cortex 22 2 372 380 doi 10 1093 cercor bhr106 PMID 21666128 Rohrer 2006 Marks 1973 Rodway Gillies and Schepman 2006 Rodway et al 2006 Gur and Hilgard 1975 Cui et al 2007 Pascual Leone et al 1995 The Dalai Lama at MIT Archived 2022 01 21 at the Wayback Machine 2006 Mental Imagery Archived 2008 02 29 at the Wayback Machine a b Kaur Jaskirat Ghosh Shampa Sahani Asish Kumar Sinha Jitendra Kumar 2019 04 15 Mental imagery training for treatment of central neuropathic pain a narrative review Acta Neurologica Belgica 119 2 175 186 doi 10 1007 s13760 019 01139 x ISSN 0300 9009 PMID 30989503 S2CID 115153320 Kaur Jaskirat Ghosh Shampa Sahani Asish Kumar Sinha Jitendra Kumar November 2020 Mental Imagery as a Rehabilitative Therapy for Neuropathic Pain in People With Spinal Cord Injury A Randomized Controlled Trial Neurorehabilitation and Neural Repair 34 11 1038 1049 doi 10 1177 1545968320962498 ISSN 1552 6844 PMID 33040678 S2CID 222300017 Further reading editAlbert J M Mental Image and Representation French text by Jean Max Albert and translation by H Arnold Paris Mercier amp Associes 2018 1 Amorim Michel Ange Brice Isableu and Mohammed Jarraya 2006 Embodied Spatial Transformations Body Analogy for the Mental Rotation Journal of Experimental Psychology General Barsalou L W 1999 Perceptual Symbol Systems Behavioral and Brain Sciences 22 4 577 660 CiteSeerX 10 1 1 601 93 doi 10 1017 s0140525x99002149 PMID 11301525 S2CID 351236 Bartolomeo P 2002 The Relationship Between Visual perception and Visual Mental Imagery A Reappraisal of the Neuropsychological Evidence Cortex 38 3 357 378 doi 10 1016 s0010 9452 08 70665 8 PMID 12146661 S2CID 4485950 Bennett M R amp Hacker P M S 2003 Philosophical Foundations of Neuroscience Oxford Blackwell Bensafi M Porter J Pouliot S Mainland J Johnson B Zelano C Young N Bremner E Aframian D Kahn R Sobel N 2003 Olfactomotor Activity During Imagery Mimics that During Perception Nature Neuroscience 6 11 1142 1144 doi 10 1038 nn1145 PMID 14566343 S2CID 5915985 Block N 1983 Mental Pictures and Cognitive Science Philosophical Review 92 4 499 539 doi 10 2307 2184879 JSTOR 2184879 Brant W 2013 Mental Imagery and Creativity Cognition Observation and Realization Akademikerverlag pp 227 Saarbrucken Germany ISBN 978 3 639 46288 3 Cui X Jeter C B Yang D Montague P R Eagleman D M 2007 Vividness of mental imagery Individual variability can be measured objectively Vision Research 47 4 474 478 doi 10 1016 j visres 2006 11 013 PMC 1839967 PMID 17239915 Deutsch David 1998 The Fabric of Reality Penguin Adult ISBN 978 0 14 014690 5 Egan Kieran 1992 Imagination in Teaching and Learning Chicago University of Chicago Press Fichter C Jonas K 2008 Image Effects of Newspapers How Brand Images Change Consumers Product Ratings Zeitschrift fur Psychologie 216 4 226 234 doi 10 1027 0044 3409 216 4 226 Archived from the original on 2013 01 03 Finke R A 1989 Principles of Mental Imagery Cambridge MA MIT Press Garnder Howard 1987 The Mind s New Science A History of the Cognitive Revolution New York Basic Books Gur R C Hilgard E R 1975 Visual imagery and discrimination of differences between altered pictures simultaneously and successively presented British Journal of Psychology 66 3 341 345 doi 10 1111 j 2044 8295 1975 tb01470 x PMID 1182401 Kosslyn Stephen M 1983 Ghosts in the Mind s Machine Creating and Using Images in the Brain New York Norton Kosslyn Stephen 1994 Image and Brain The Resolution of the Imagery Debate Cambridge MA MIT Press Kosslyn Stephen M Thompson William L Kim Irene J Alpert Nathaniel M 1995 Topographic representations of mental images in primary visual cortex Nature 378 6556 496 498 Bibcode 1995Natur 378 496K doi 10 1038 378496a0 PMID 7477406 S2CID 127386 Kosslyn Stephen M Thompson William L Wraga Mary J Alpert Nathaniel M 2001 Imagining rotation by endogenous versus exogenous forces Distinct neural mechanisms NeuroReport 12 11 2519 2525 doi 10 1097 00001756 200108080 00046 PMID 11496141 S2CID 43067749 Logie R H Pernet C R Buonocore A Della Sala S 2011 Low and high imagers activate networks differentially in mental rotation Neuropsychologia 49 11 3071 3077 doi 10 1016 j neuropsychologia 2011 07 011 PMID 21802436 S2CID 7073330 Marks D F 1973 Visual imagery differences in the recall of pictures British Journal of Psychology 64 1 17 24 doi 10 1111 j 2044 8295 1973 tb01322 x PMID 4742442 Marks D F 1995 New directions for mental imagery research Journal of Mental Imagery 19 153 167 McGabhann R Squires B 2003 Releasing The Beast Within A path to Mental Toughness Granite Publishing Australia McKellar Peter 1957 Imagination and Thinking London Cohen amp West Norman Donald The Design of Everyday Things ISBN 978 0 465 06710 7 Paivio Allan 1986 Mental Representations A Dual Coding Approach New York Oxford University Press Parsons Lawrence M 1987 Imagined spatial transformations of one s hands and feet Cognitive Psychology 19 2 178 241 doi 10 1016 0010 0285 87 90011 9 PMID 3581757 S2CID 38603712 Parsons Lawrence M 2003 Superior parietal cortices and varieties of mental rotation Trends in Cognitive Sciences 7 12 515 551 doi 10 1016 j tics 2003 10 002 PMID 14643362 S2CID 18955586 Pascual Leone Alvaro Nguyet Dang Leonardo G Cohen Joaquim P Brasil Neto Angel Cammarota and Mark Hallett 1995 Modulation of Muscle Responses Evoked by Transcranial Magnetic Stimulation During the Acquisition of New Fine Motor Skills Journal of Neuroscience 2 Plato 2000 The Republic New CUP translation into English Cambridge University Press ISBN 978 0 521 48443 5 Plato 2003 Respublica New CUP edition of Greek text E Typographeo Clarendoniano ISBN 978 0 19 924849 0 Prinz J J 2002 Furnishing the Mind Concepts and their Perceptual Basis Boston MA MIT Press Pylyshyn Zenon W 1973 What the mind s eye tells the mind s brain a critique of mental imagery Psychological Bulletin 80 1 24 doi 10 1037 h0034650 S2CID 264755021 Reisberg Daniel Ed 1992 Auditory Imagery Hillsdale NJ Erlbaum Richardson A 1969 Mental Imagery London Routledge amp Kegan Paul Rodway P Gillies K Schepman A 2006 Vivid imagers are better at detecting salient changes Journal of Individual Differences 27 4 218 228 doi 10 1027 1614 0001 27 4 218 Rohrer T 2006 The Body in Space Dimensions of embodiment The Body in Space Embodiment Experientialism and Linguistic Conceptualization In Body Language and Mind vol 2 Zlatev Jordan Ziemke Tom Frank Roz Dirven Rene eds Berlin Mouton de Gruyter Ryle G 1949 The Concept of Mind London Hutchinson Sartre J P 1940 The Psychology of Imagination Translated from the French by B Frechtman New York Philosophical Library 1948 Schwoebel John Friedman Robert Duda Nanci Coslett H Branch 2001 Pain and the body schema evidence for peripheral effects on mental representations of movement Brain 124 10 2098 2104 doi 10 1093 brain 124 10 2098 PMID 11571225 Skinner B F 1974 About Behaviorism New York Knopf Shepard Roger N Metzler Jacqueline 1971 Mental rotation of three dimensional objects Science 171 3972 701 703 Bibcode 1971Sci 171 701S CiteSeerX 10 1 1 610 4345 doi 10 1126 science 171 3972 701 PMID 5540314 S2CID 16357397 Thomas Nigel J T 1999 Are Theories of Imagery Theories of Imagination An Active Perception Approach to Conscious Mental Content Cognitive Science 23 2 207 245 doi 10 1207 s15516709cog2302 3 Thomas N J T 2003 Mental Imagery Philosophical Issues About In L Nadel Ed Encyclopedia of Cognitive Science Volume 2 pp 1147 1153 London Nature Publishing Macmillan External links edit nbsp Wikiquote has quotations related to Mental image Mental Imagery in the Stanford Encyclopedia of Philosophy Retrieved from https en wikipedia org w index php title Mental image amp oldid 1219665272, wikipedia, wiki, book, books, library,

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