ÒMagic and the
Brain: How Magicians ÔTrickÕ the MindÓ Scientific American.
How
to Do a Magic Trick: The magician Teller demonstrates how to pull
coins out of thin air
http://blogs.scientificamerican.com/observations/2012/05/14/how-neuroscientists-and-magicians-are-conjuring-brain-insights/ Also at http://worldtraining.net/Magic.htm
blog post: ÒNeuroscience and
Magic: the Science of Stealing a Watch.Ó
The Blind Spot - Part
One (Thomas Fraps)
http://www.theflickingfingers.com/bl_spot.html
To
ignore questions of why we are so easily fooled by conjuring is a serious
oversight of psychologists,
for there is far
more to it than mere sleight of hand,or the hand moving faster than the eye can
follow.
Richard L. Gregory
"Magic takes place in the spectator's head." One often runs
into this sentence in books or lectures on magic. In a trivial way it's
true—there is no magical effect without a spectator. No magic occurs when
one practices at home in front of a mirror. Not until the minds of spectators
become involved do such ordinary things as a top change or a
false transfer become magic.
Exactly what happens in the minds of the
spectators? What causes a spectator to believe that the coin which appeared
under the salt shaker is the same one which
disappeared from the performer's hand? Why does a lemon "appear"
under a cup, although it was only transferred from a jacket pocket into the
cup?
Misdirection, timing, and technique are a few
terms capable of explaining why it's possible to distract the spectator against
his will. Why are certain actions and movements cut out (i.e., not observed),
although they take place before our eyes? The answer is only hinted at in the
volumes of literature on magic: "It works," that's the important
thing.
A few exceptions are, for example: The
Psychology of Deception—Why Magic Works, Randall, 1982; The works of Arturo
de Ascanio in Ascanio's Magic, as well as Conjuror's Psychological Secrets,
Sharpe, 1992. "Directing Attention" in Card
College, Vol. 2, Giobbi, 1996. See also Richard L. Gregory, Odd
Perceptions, Routledge, London, 1986.
With equal validity the opening quotation, from
one of the most famous researchers on the mysteries of perception, can be
applied to magicians as well. In fact, it's a grave omission of magicians to
ignore this question. Our explanations, with few exceptions, are
merely more discriminating versions of those proposed by laymen. What is
remarkable is that the explanation for what happens is sought in the magician,
as if he alone were responsible for the illusion's occurrence.
We do the necessary absurd things—like
doing a pass, wearing a thumbtip, or sewing in a Topit—in order to give
the impression of magic. But without the active help of the viewer's perceptive
faculties, this impression couldn't be made at all. Why not turn things around
and look for the explanation in the spectator. The world acts crazy in his
head, not ours.This leads us to the question of how
the signals from our environment are put together in our heads to form a
picture of reality. In order to throw a little light on why magic as such
works, a few cross-references to research on perception follow. This will not
directly improve your stage presence, but it might give you a deeper
understanding of what a magician actually does when he performs. This helps to
increase the magical content of the individual tricks and their impact on the
audience, a goal which no magician should forget.
Seeing is Believing: Although
all five senses contribute to our perception of the outer world, vision
dominates. The following illustrations are, therefore, limited to the visual
system. At first glance,
perception appears to be a passive process comparable with photography. One
assumes the outer world is pictured on the retina (the way a film is exposed in
a camera) and the incoming information must only be decoded. But this first glance
deceives. The analogy to a camera is, at best, valid only for the first step of
perception, the focusing of light rays through the lens on the retina. Several
complex switching mechanisms take place in the retina which
are representative of the entire perceptive process; research has shown that at
this stage more has already happened than the mere copying of a picture of the
outer world. On the
contrary, from the incoming physical stimulation—in this case,
lightwaves—our brain actually constructs its own picture of its
surroundings. This picture does not necessarily coincide with physical reality.
As a simple example, consider your first glance in the mirror in the morning.
After you have recognized the person in the mirror, measure the length of your
face on the plane of the mirror. You will discover that it's only half as long
as that of your actual face. Obviously, there is something wrong with our
perceptive facility which makes the face in the mirror
appear to be actual size. This has nothing to do with how tired you are, but
with the way we perceive the size of things, i.e., the way the brain calculates
the actual perceived picture from the visual input (retina picture). Such
"calculation processes" usually occur unconsciously: they take place
without our willful control.
Comment: Not only is the size of the
corresponding retina picture used in the estimation of an object's size, but
also its distance. This has the advantage that the object's size remains
constant while it moves toward or away from us. If we estimate the distance of
an object incorrectly, this directly effects the
perceived size. In case of the mirror, our face appears twice as large because
we estimate the distance to be twice as large. A further example is the
"moon illusion." A moon rising on the horizon in the early evening
appears many times larger when in the night sky. (See Perception by Irvin Rock,
W H Freeman & Co., 1995)
Look at the two tables in figure 1 At first
glance you won't notice anything unusual, but if you measure the edges of these
tables, you will be astonished to discover that both are identical. This
example illustrates that between the original sensory stimulation and the
conscious perceived picture, mental processes (of which we are not conscious)
automatically take place. These processes are capable of creating an illusion
all by themselves. See Mind Sights: Original Visual Illusions, Ambiguities, and
Other Anomalies, With a Commentary on the Play of Mind in Perception and Art by
Roger N. Shepard, W. H. Freeman & Co., 1990 See also Sam H. Sharpe
Conjuror's Optical Secrets, Hades Publications, 1992.
Although these mechanisms fabricate a false
picture of the outer world under certain circumstances, they work very well for
everyday use, and are needed to compensate for the insufficient data at the
lowest level of visual perception—the eye. Figure 2 shows a schematic of the eye. Outside light passes
through both the cornea and the lens before falling onto the retina. The latter
consists of rows of cells of which the most important are light receptors.
There are two types. About 120 million "rods" are responsible for
black-white vision under limited lighting. The "cones," on the other
hand, are responsible for colored vision and the recognition of details under
normal illumination. The distribution of the two types of receptors on the
retina is interesting. The rods are concentrated at the edge, whereas the cones
are almost exclusively concentrated at one point, the Fovea centralis. This
tiny area, which has a diameter of only 2 mm, is responsible for clear vision.
If we want to observe an object precisely, we fix our eyes so that the object's
image falls in the area of the Fovea. At the same time we see another part of
the object, which is pictured in the peripheral area of the retina, unclearly. Comment: Stretch your right arm in
front of you with the thumb pointing upward and close the left eye. If you now
look at another object in the room, the size of your thumb is approximately the
area in the field of vision which you can see sharply.
This is the physiological basis for the "tube effect," was first described in the magical
literature by the late Arturo Ascanio. The attempt to divide your
attention between light and dark areas corresponds to the two types of
receptors in the retina and their distribution. See: The Psychology of Palming, p.4, Ascanio
(translation by R. Giobbi), 1982.
In general we are not aware of how narrow the
area of clear vision is, we always see the entire picture sharply—at
least it appears so. We have this impression, however, because our eyes
constantly shift from one point to another while probing our surroundings,
making snapshots during the short fixation phases. While the eyes move, the
picture on the retina is blurred and useless as a source of information for
further perceptive mechanisms. A
shift in attention always accompanies eye movement, regardless of whether it's
the reflex from a stimulation in the peripheral area
of the retina (for example, seeing a tiger in the corner of the eye) or
consciously controlled (as in looking at a painting). Therefore, the eye
movements indicate the focus of our attention. One of the first measurements of
the path of eye movement in observing a face show
clearly that the eyes are a center of attention (figure 3). See A. L. Yarbus Eye Movements and
Visions, Plenum Press, 1965.
This proves the rule that the performer can
direct the audiences' eyes with his own. A perfect application of this
principle based on the physiological characteristics discussed is the
"crossing the gaze" technique proposed by Slydini and Tamariz. An extended discussion can be found in
The Five Points of Magic, Tamariz, 1988, as well as in The Best of Slydini and
More, Fulves, 1976. The organization of the retina is, therefore, responsible
for two central principles of misdirection, and what is needed for a successful
application already exists at the lowest level of physical perception.
A
Blind Spot:
Right next to the Fovea centralis, however, there is another area
whose existence we don't even suspect. For this reason, it illustrates how we
perceive best. It's an area in which there are no receptors at all, the point
where the optic nerve exits the eye to connect with the brain (see figure 2).
The lack of light sensitive receptors in this area has given it the name
"Blind Spot." The fascinating thing is that we don't even see that we
don't see at this point. If perception functioned like a camera, we would
constantly have a black hole in our field of vision, however, the brain
automatically fills this hole for us on its own.
To prove the existence of the Blind Spot, close
your left eye and fix your right eye on the black "plus" sign of
figure 4 Now move your head close to the screen until
the black dot suddenly disappears. Since the missing information is
"patched in" from the surrounding parts of the retina, you see only a
white area.
If you do the same thing with a white
"plus" sign, you'll discover that your brain completes the
disappearance of the white dot by filling in black. This shows that the process
of completion, an extremely complex ability of the visual system is dependent
on the context of the picture. This has far reaching consequences for the
entire perceptive system. Your brain "patches" the hole caused by the
lack of receptors in the Blind Spot with information it gleans from adjacent
receptors: the "completion process."
See: V. A. Ramachandran, "Compensation of
the Blind Spot," Scientific American, June, 1992.
The Blind Spot - Part Two
Filling the Holes
In addition to filling the Blind Spot by the
completion process, we constantly also fill other holes in our perception. We
are, however, always dependent on the context. For example, if one leaves out
the letter e in the rst of ths sntnc, you ar still abl to undrstand what th sntnc mans. It isnt' vn ncssary to know wic lttr as bn
lft out, or avn't you noticd tat h is also missing?
Completion is usually a very useful mechanism,
but it doesn't always function correctly with respect to reality. In the above
example of the Blind Spot, we complete a white (black) dot, although a black
(white) dot is printed on the paper. It's easy to compare this with a magic
trick: in the course of every trick there is one or more "dark" point
where the necessary technique must be carried out. In the ideal case, the
spectator doesn't notice these techniques; he shouldn't even suspect them, as
was so well described by S. W. Erdnase in The Expert at the Card Table, just as
we don't even suspect the existence of the Blind spot.
Another form of completion occurs when watching
movies or television. Although there are only a certain number of static
pictures projected on the screen per second (24 frames per second in a motion
picture), we see a fluid moving image. The brain fills the gaps between the
pictures and gives us the illusion of motion. Once again the lowest level of
the retina is responsible, since after the disappearance of a retinal picture,
the receptors continue firing for a moment and transfer the signal to the brain
so that we fill out the temporal holes between the individual pictures and are
not aware of any flickering. But this does not completely explain the
perception of apparent motion.
One can create a simplified version of apparent
movement by projecting two light-points situated next to each other on a screen
and turning them on and off one after the other. If the physical and temporal
conditions are matched, the spectator has the impression that one light moves
back and forth on the screen (a phenomena that one often observes in a similar
form at construction sites on highways). Although we know that there are two
individual lights, we cannot escape the impression of seeing the motion of one
single light-point.
The explanation for this lies in the manner in
which we perceive real motion. When you move your finger back and forth
quickly, the impression will not differ very much from apparent motion even
though the finger remains visible between the extremes. In experiments it has
been shown that, in fact, only the end points of the finger's motion are
important for the perception of this type of movement. If the end points are
covered, one does not perceive the movement in the middle. When one covers the
middle area so that only the end points are visible, one is aware of the
motion. This is due to the characteristics of an apparent movement.
If one considers the apparent movement as a
problem of perception—object A disappears at one point, while at a nearby
point object B suddenly appears—the assumption (extrapolating from
real-world experience) is that the object moved from point A to B.
See: Chapter 7 in Perception by Irvin Rock, W H
Freeman & Co., 1995.
So we are again filling a hole—the
region between the points—this time with an apparent movement. Yank Hoe's
"Sympathetic Coins" is a suitable example of this. The way in which
the late Albert Goshman used to vanish a coin also takes advantage of this
principle. A coin is apparently thrown from the right hand into the left, however, the hands do not touch during the throwing
gesture. The spectator has the impression of having seen the coin in flight.
This vanish is more deceptive than many others (anyone who saw Goshman could
verify this) for the simple reason that the spectator deceives himself because
his brain completes the picture of the coin's apparent flight, a process
against which he cannot defend himself any more than against the above
mentioned apparent movement of one light-point.
See "The Toss 'Vanish" in Magic by
Gosh, Page and Goshman, 1985.
We remain with Goshman and assume the coin
disappears from his left hand to reappear under a salt shaker
on the table. This effect, which Goshman constantly repeats during his famous close-up-act, is based in an extended way on the solution of
a perceptive problem by assumption of movement. In this case there are coins,
not lights, which suddenly vanish and reappear. As a "solution," the
spectator concludes that the coin has moved. The only difference is the fact
that he does not see the coin visually "jump" under the salt shaker (in the way he sees the light jumping back and
forth). But this is precisely the reason for the perception of the event as a
magical effect. The psychologist, Ernst von Glasersfeld writes the following:
"Here I want to emphasise that this
continuity with respect to the existence of an individual object is the result
of manipulation carried out by the spectator and can never be a proof for its
objective reality. No one uses this abstract possibility more skillfully than
the magician. During a performance he asks, for example, for a signet ring from
the audience, throws it half way through the room to his helper and lets the
baffled spectator find the ring in his own pocket. The magic is to guide the
perception of the spectator so that unconsciously, from the first appearance of
the ring to the throwing of an object through the room, a continuous identity
is constructed. If this succeeds, then in fact only magic can transfer the same
ring into the pocket of the spectator."
See "Introduction to Radical
Constructivism" in Radical Constructivism by Ernst von Glasersfeld,
published by Falmer Press, July 1996.
Our task as performers is to leave the spectator
only one possible interpretation. We give him beginning and end points and he
himself constructs, by an unconscious automatic functioning process of his
perception, a reality (the traveling of a coin), which simultaneously
contradicts his conscious perception. The stronger this
contradiction, the more powerful the magic.
Why doesn't the spectator interpret his
perception as the appearance and disappearance of two objects? He doesn't see
the coin in motion as in the case of the light. The performance helps here, but
one can also say that we have simply learned incorrectly. In the course of
growing up, we learn hrough experience that objects don't simply appear and
disappear. Gradually we create more and more categories and judgments about how
the world looks. For example, we learn that objects still exist when they are
lost from view for a short time or when we turn away. In addition to cause and
effect thinking, the concept of object permanence, as the psychologists call
it, is one of the learned schemes which help us to
order the "outer" world. We give the incoming sense stimulations a
structure which is bound inseparably with our physiological perception
apparatus, but which is learned. Division and ordering of objects in the
learning process occurs in the first two years of life. The development
psychologist Jean Piaget spent his entire life studying this. In his book The
Construction of Reality in the Child he writes:
The child's world is a word of pictures, of
which each individual is known to a greater or lesser extent and can be
analyzed, but which all disappear in an unpredictable way and appear again (. . .) Observation and experiment seem to demonstrate that
the concept of an object is far from being instinctive or pre-programmed
through experience, but is slowly built up. Six individual phases can be
distinguished, which correspond to the general psychological development.
See: Construction of Reality in the Child by
Jean Piaget, Ballantine Books, 1986.
Piaget studied and documented the individual
phases in innumerable experiments. He established that a two
month old baby appears to consider objects to be permanent when he can
grasp them:
Permanence is only the action of grasping. When
I hide the clock behind my hands before Jacqueline's eyes, she doesn't react
and immediately forgets everything: when there is no physical contact, the
visual pictures appear to blend into one another without materializing. Here is
a further proof: I lay the eraser that Jacqueline just had in her hand on her
knee. The instant that she wants to grasp it again, I place my hand between her
eyes and the eraser: she gives up immediately as if the object doesn't exist
any more."
As simple as it might be to let an eraser
disappear for a child in this age—a false transfer isn't even
necessary—it's useless for the performer because no magic takes place in
the child's head since there is no contradiction to reality. Reality is magic
and consists of pictures which appear and disappear. The child doesn't even
look for the eraser, but gives up immediately when she doesn't see it anymore.
Only when the child is many months older does she look for it:
"Jacqueline looks at a ring which I place
in my hand. She opens my hand by lifting the fingers and finds the object with
ecstasy. Now I place the ring visibly in my left hand. Then I place the left
hand against the right hand and show both closed hands (the ring passed to the
right hand). Jacqueline, who is astonished, says 'Ring, ring, where is it?', but doesn't come up with the idea of looking in my right
hand."
In the course of the first years, we construct
concepts such as object, permanence, causality, etc. The existence of these
concepts is absolutely necessary to allow the magic trick to work. This means
that these higher order processes of perception are the basis for experiencing
a magical effect, the performer works with and against them at the same time.
With the magic trick we create a contradiction to the experienced values of our
perception on one hand, but on the other hand we use precisely these special
effects for its realization.
Higher Perception
A further decisive characteristic of perception
is that our experience and knowledge influence how we process incoming
stimulations. This process is termed "top-down" because higher brain
functions exert a dominant influence over stimulation processing. In this case,
knowledge wins over pure perception. The reverse is true of the
"bottom-up" processes which we have
considered up to this point. In figure 1, perception wins out over knowledge.
Although we know that both table areas are the same size, our perception of
them differs. Almost all visual effects of magic fall into this category.
Consider, for example, Francis Tabary's rope trick. Even though one knows how
it works, one is deluded at certain points. The same goes for visual card changes
(see "Instant Camera Card" or "Sympathetic Ten" earlier in
this book). Knowledge about the trick technique does not prevent us from
perceiving a transformation as magic.
See chapter 4 in Psychology (2nd edition) by
Philip G. Zimbardo, Ann L. Weber, Longman Publication Group, 1997 Effects which
are less visual and take place on an intellectual level, for example, mental
effects, tend to be based on the "top-down" principles of perception
by using mental distractions to disrupt the audience's perception. These take
advantage of the fact that we constantly create hypotheses based on our
knowledge and experience, and within this frame interpret incoming sensual
data.
In reading, for example, we not only register
letters and words (bottom-up), but we also perceive the letters independently
of our expectations and the particular context (top-down). In figure 5 you
probably read "The Cat." If one compares the middle letter in each
word, one finds that they are identical in form. The context, given through
knowledge of the English words, causes us to perceive the same object
differently.
An example of the influence of experience on
perception is shown in figure 6a and b. Usually we can easily identify the
faces of fellow-creatures and quickly notice small differences. Since we very
seldom turn a face upside-down, the interpretation of the expression breaks
down at the position of the eyes and angle of the mouth. We notice a small
difference between the two photos of Margaret Thatcher, but only see the extent
of the distortion when we turn the book around and view the faces in the usual
position.
In a further example of a "top-down"
process, figure 7 shows the influence of experience on grouping objects, an
internal step in perception, which serves to order the individual areas of a
retinal picture to geometric objects and structures which
belong together.
On the left side we see the two branches behind
the tree as two crossed branches. Although the configuration of the two bent
branches on the right could also be possible (or four individual branches),
this interpretation is apparently not as easy for us to grasp. We chose instead
the simplest solution and connect the opposite branches together since this
completion gives a straight line.
From experience we know that lines and forms of
objects in our surroundings usually do not exhibit abrupt changes of direction.
This fact influences the processes of grouping and organizing pictures from the
retina so that we prefer straight or steady constructions.
Comment: This "Principle of Good Form"
was first formulated by the Gestalt psychologist Max Wertheimer: We connect
those parts of a pattern, the way we assume continuity, because these lie on a
line or deviate from it only by a small angle. In contrast, we consider contours
with abrupt changes in direction to be unrelated. It's interesting that the
completion mechanism of the Blind spot creates two crossing branches. Look at
the picture so that the bend in the branches on the right falls in your Blind
spot.
There are a number of examples of tricks whose
technique is based on this principle, in particular Bob Carver's
"Professor's Nightmlare," Jay Sankey's "Cardboard
Contortionists," and Paul Harris' "Immaculate Connection."
In an extended connection, one can certainly say
that perception of a magic trick by which the spectator influences the trick
himself are usually "bottom-up" processes,
though the presentation works from "top-down" processes. In the
latter, the lecture (or the music) arouses certain associations, expectations
and feelings, which have an influence on the ordering of the sensual
stimulants.
Experience and knowledge lead us to choose one
from more than one possible interpretation of the incoming stimulations while
perception is in process. In an extended sense, this means that our knowledge,
our expectations, and our feelings determine what we perceive and what we
consider to be "real." Just as the limitations determine which of the
incoming data we process through the construction of our nervous system, the
receptors of the retina, for example, are only sensitive to a certain region of
the electromagnetic spectrum which we perceive as light in different colors.
Similarly, we can only hear sound waves as a tone in a limited frequency
region.
We are not aware that our perception, that we
consider to be the end picture of an objective reality, is subject to so many
limitations and automatic mechanisms. More precisely, we construct only one
model from the information content of the incoming sensual stimulants, and it's
this model of reality that we perceive. In transforming the sentence
"seeing is believing," one could also say "believing is
seeing," or as Heinz von Foerster, a biophysicist expressed it: "The
world, as we perceive it, is our own invention."
Comment: Heinz von Foerster, "Das
Konstruieren einer Wirklichkeit" (The Construction of a Reality) in The
Invented Reality; How Do We Know What We Believe We Know?:
Contributions to Constructivism by Paul Watzlawick, W. W. Norton & Co.,
1984.
Magic and Constructed Reality
There have been a number of scientific
experiments and daily incidents which support von
Foerster; one only needs to think of the "invention" of the
perception apparatus which eliminates the blind spot from our experience by
constructing a substitute. Another impressive example comes from neurobiology
and has to do with color perception.
See: "The Retinex Theory of Color
Vision" by Edwin Landon, p.108 in Scientific American, September,
1968.
By 1672 the phenomenon of colored shadows, which
can easily be demonstrated, had already been described. If an object, such as
your hand, is illuminated by two light sources, one red and the other white,
they throw two different shadows in the actual light circle. One is red and the
other is green. But where does the green color come from, when all that one
could expect was red, white or a rose mixture of the two? This happens because
what we perceive as color and consider in the above case to be green is not
necessarily a property of the observed object, but represents a pattern of
arousal of the nerve cells of our retina. This pattern can be caused by a
chance combination of light waves of wavelengths other than green. Humberto
Maturana, a neurobiologist from Chile, was one of the first to discover this
and wrote at the end of his study:
"The result is that the activity of nerve
cells from living cells do not reflect a non dependent environment and,
therefore, do not make it possible to construct an absolute existing outer
world."
See: Humberto Maturana, et.
al., "A Biological Theory of the Relativistic
Color Coding in the Primate Retina " in Arch. Biologia y Med.. Exp.,
Suplemento No.1, Santiago: University of Chile, 1968.
This is somewhat easier to understand when one
considers a further functional principal of the retina and the entire nervous
system. The receptors of the retina absorb impinging electromagnetic rays of a
certain wavelength ("light") and are excited by it. They transmit
this excitement to the brain in the form of periodic electric charges (action
potentials, see figure 8). The only source of information for the brain is the
frequency of these periodic charges, which is higher when the stimulating
intensity is greater.
This means that the nerve cells
which are connected to the receptors only transmit the quantity, but not
the quality, of the stimulation. For further processing in the brain the only
information available is about the amount of stimulation but not about its
type. This makes it all the more astonishing that we are able to construct the
colored, three dimensional word that we perceive. The
necessity of construction is preprogrammed at the lowest level of perception
and continues through the highest levels. We constantly construct or invent
patterns and meanings from actual neutral stimulation. Who has never, lying in
the meadow and watching the random forms of clouds in the sky, seen the face of
a man wearing a hat, a lion, or a tree? The recognition of order and causality
are processed similarly, as Paul Watzlawick described using a deck of cards:
"When we mix the cards and then find them
ordered in the four colors from Ace to King, this would appear too orderly to
be believed. If a statistician teaches us that this order is exactly as
probable as every other, we would probably not understand him at first, until
we realize that in fact every order (or disorder) obtained by mixing the cards
is as probable or improbable as every other. The only reason why this order
appears so unusual is that for reasons that have nothing to do with probabilit,y but only with our definition of order, we attribute
meaning, importance and prominence to this result and discard all others as
lacking order."
See How Real Is Real?:
Confusion, Disinformation, Communication by Paul Watzlawick, Random House,
1977.
One immediately thinks of "Out of this
World" by Paul Curry or the end effect of Lennart Green's world
championship card routine: After he has mixed cards for ten minutes, thrown
them around and in his inimitable way otherwise mutilated them, at the end they
are all in "new pack order," cleanly separated according to color
from Ace to King. We offer the audience a few cornerstones, a scaffold on which
he can hang his perceptive mechanisms so that he can fill in the holes between
them to build reality. The spectator constructs the magic himself in the act of
filling in the holes. Less cornerstones are necessary
than one would think. In the attempt to distract the spectator, we often give
too much information, we verbalize things that don't need
any explanation and fall into one of the holes that the spectator will fill
himself. Sentences such as "I have here a completely normal pack of cards
. . ." causes the opposite of what you intend by giving too much
information. In the book The Secrets of Brother John Hamman, Richard Kaufman
writes:
"Every word you say limits what the
spectator will think about what he sees. If you say nothing, his thoughts are
limited only by his imagination—and that's far more powerful than any
measly trick you can do. Brother Hamman discovered that if you say less about
what you're doing, the spectator will be forced to
think more. The more he thinks, the greater his self deception will be (. . .) Brother John says less, makes fewer claims, leads
people to fewer conclusions verbally. He lets them imagine magical things
happen because he doesn't say anything to the contrary." See:
"Double-Deal Card to Pocket" on p.19 in The Secrets of Brother John
Hamman, Kaufman, 1989..
This must not be limited to close-up tricks or general
performances. Jim Steinmeyer, one of the most creative designers of great
illusions, said basically the same thing when he compared the magical effect to
a caricature:
"An effective caricature manages to tell
you more about a subject than the best photographs. It does it with a simplicity of line. Every magic trick is as deceptive and
illusory as is a caricature. It needs to convey the essence of an effect
quickly, but in an understandable manner: the simplicity of a few lines.
Understanding an effect in this way is a key toward solving it and creating the
illusion."
See
Strange Powers, Steinmeyer, 1992.
If we assume we are a successful artist and the
audience recognizes the caricature (the effect) on the basis of the
"simple lines" which we give him, we run immediately into the limits
of the comparison: As artists, we were immediately able to recognize the
caricature with the spectator. As magicians, this is denied us, we do not
experience the effect ourselves, we do not recognize
our own drawing.
Comparison with "tip" pictures is the
closest to a magic performance. A classical tip picture is shown in figure 9 You see either a grandmother with kerchief or a young woman
with a hat, who turns her head to the side, but you probably don't see both pictures
at the same time. If you look at the picture together with a second person,
it's possible that both pictures can be perceived at the same time. Although
perception of the picture constantly shifts back and forth, you perhaps see the
young woman while your partner sees the old woman. You both have a different
reality in your heads, although both have the same stimulation.
Transferring this to a performance would mean
that you as the magician see only the old woman (you know the trick like an old
hat) while the spectator sees only the young woman. More specifically, while
you draw an old woman, the spectator sees only a young woman. He orders the
stimulations differently and forms another reality in his head. The difficulty
for the magician is in order to draw a stable picture of the young woman the
lines must be drawn very carefully. Each small error lets the picture flip
over. The flashing of a palmed coin or thumbtip, the slipping of a double card,
or simply wrong timing are enough to break the illusion or prevent it from
"jelling." Richard Gregory describes this very clearly from the point
of view of the lay spectator and the Indian Rope Trick:
".
. . and I virtually saw it all happening although the action was
hidden—that the hollow rope rose by being filled with compressed air.
Then a pole was pushed up from below the stage, and the conjuror's assistant
climbed up. When he descended, the pole was withdrawn but the tube-rope
remained vertical, kept up by the compressed air (. .
.) When one has an adequate running model of the hidden mechanisms of the
trick, the performance looks ridiculous."
See: Richard L. Gregory Odd Perceptions,
Routledge, London 1986..
It isn't easy to pull the right
"strings" so that the audience experiences the "magic"
inherent in an illusion. We help him only by the construction of this
perception. The advantage of the constructive view is that we throw a positive
light on our deeds. We don't misdirect, but we direct. We don't hide, but we
lead the audience on the "magic road" as Tamariz calls it. The above mentioned biophysicist, Heinz von Foerster, an active
magician in his youth, said:
"A lady floats in the air. The usual
argument is something like this: aha—these magicians try to direct my
attention away, try to confuse my thinking so that I don't observe what they
are really doing. In fact, the whole magic consists of inviting you to create a
world of yourself, creating a new world in which ladies are floating, in which
elephants keep disappearing (. . .) Magic is not a question
of distracting you, of any kind of a gimmick, rather a way of making you
attentive to a particular reality you're creating. Magic is the strategy of
constructivism."
Susanne Freund, Heinz von Fšrster—A
Portrait, ORF 1992..
We take the audience on a trip, watch out that
they don't think of anything stupid and accompany them to an abyss. In order to
reach the other side, they must construct their own bridge. We don't tell them
that the discussed perceptive mechanisms (and a few more) help them automatically.
At the end, when he stands on the other side, the bridge that he passed over
has long since collapsed, and he wonders how he managed to arrive there.
The moment that the spectator realizes he has
reached a point that, according to his conscious perception, he should not be
(because he can't see a bridge) he has reached the "magical" moment.
When the effect succeeds, this is always bound with a feeling that is very
special and can only be evoked by a magic performance. Tamariz describes this
very pictorially in The Magic Way:
"And on the wings of our imagination, and
of fantasy, we cross together through the mirror of the moon and bathe
ourselves in the rainbow, and paint ourselves in its colors, as we live and
enjoy the spell of the Magical Effect."
The
Magic Way, Tamariz, 1988
As magicians, we consciously call for this
"Moment of Experience." At the moment of astonishment, we indirectly
make visible the limitations of the perception in the heads of the audience. We
must, at the same time, be careful that the way back has been obliterated so
the spectator doesn't, with "joined powers," discover the illusion. A
high aim because it's difficult to construct and perform routines so that the
audience cannot find the solution by working backward (see the performances of
Juan Tamariz in The Magic Way). When in the moment of the effect, the
limitations of the perceptive mechanisms become visible and when one takes Paul
Klee's comment "Art doesn't reproduce the visual but makes visible,"
then magic in this sense is an art. Since we are caught within the natural
borders of perception and carry them around with us unnoticed in our daily
lives. As magicians we are able to make these borders visible in a most playful
way. In an ironic sense Richard Gregory is probably right when he writes at the
end of his explanations about perception mechanisms:
"Perhaps most people view the world as one
single magic trick."
How fortunate for magicians that most people
don't notice this!