Subj:	RE: oscillation neuroprocessing model


Work in progress:

Correlational Opponent-Processing: A Unifying Principle
by
Ronald C. Blue and Wanda Eileen Hatcher Blue
Lehigh Carbon Community College
4525 Education Park Drive
Schnecksville, PA 18078-2598
USA
e-mail x011@Lehigh.edu.us

Copyright 1995
All Rights Reserved

Permission granted to duplicate for non-profit educational or research
purposes.

Abstract:

The correlational opponent-processing theory is a neuro homeostasis
integration psychological immune theory that would connect phenomena
such as sensation, perception, movement, habituation, memory,
representations, learning, cognition, personality, psychopathology,
paradoxical integration, emotion, and evolution of the mind under a
unified theory.

Perception/learning/cognition may be viewed as an effort to assimilate
and accommodate all experience into neuro-energy-efficient
eigenfunction equivalence or quasi-holographic correlational opponent-
processing recordings.

Stimuli causes brain wave modulations which interact with carrier or
reference wavelets.  This interaction creates a quasi-holographic
stimulus wavelet.  The opponent-process creates an opposing quasi-
holographic memory wavelet.  Through this process the correlations or
associations of experience are encoded to memory.  Every wavelet,
regardless of source or type, triggers an opposing wavelet.  The
function of the opposing wavelet or feedback is to diminish the
intensity of neural processing.  A wavelet potential is stored or hard
wired as long-term potentiation opponent-processes in nerve cells and
the interconnections between nerve cells.  The wavelets are quasi-
holographic and allow recovery of information due to the interaction of
reference carrier wavelets and stimuli, thought, motor movement, and
emotional arousal.

Outline:
       Discussion
       Neuro Net
       Quasi-holographic wavelets
       Habituation/immunization
       Memory
       Representations, copies or models
       Learning/Cognition
       Personality
       Sensations and Perceptions
       Movement
       Emotion
       Evolution
       Tools
       Implications
       Conclusion and applications from COP theory
            Discorrelation
            Education
            Biophysical
            Intelligence
            Defense Mechanisms
            Brain damage
            Creativity
            Brain Tape
            Computer Model
            Conclusion
       Bibliography
       Acknowledgments

Discussion:

A system is a mixture of component parts that when united together
produce results that are greater than any individual part.  According
to Solomon (1980) opponent-process is a basic biological system that
may be viewed as starting from a baseline state or equilibrium.
Activation of an A process automatically activates an opposite or
opposing process B.  The equation then can be stated as the absolute
value of A process minus B process which creates a resultant.  The
resultant can be an observable behavior.  "Every experiment generated
by the model has failed to refute the model, even though the
experiments have been designed to be capable of doing so.  ... The
opponent-processing theory is quite encompassing".

A simple illustration of correlation opponent-processing can be
accomplished with the following procedure:  take your fists and put
your fists together side by side; press them firmly together for one
minute; since the fist are touching each other and you have made the
pressure equal, the situation is correlated; the balance illustrates
correlation opponent-processing.  Allison Graves (1994) provided
a more interesting illustration of correlational opponent-processing.
Now pull your fists apart and place them about one inch next to each
other.  You will notice that your fists seems to be attracted toward
each other like a magnet!

A wave is an oscillation with a specific number of cycles per second.
You can observe a wave by tying a rope to a wall and modulating the
lose end up and down.  If your timing and energy is perfect the wave
will bounce back from the wall as an inversion wave.  A wavelet can be
made with many individual ropes vibrating at different frequencies and
time cycles.  To see the wavelet as a unified phenomenon the ropes must
all be tied together.  Another illustration of a wavelet can be
experienced by observing what happens when a rock is thrown into water.
The wave pattern is the structure that determines the wavelet.  The
water is just one of many physical systems that possess the
characteristic of allowing wavelets to propagate through them.  What is
true of physical systems should be true of biological and psychological
systems.

Look at a color television set.  Look carefully at the screen with a
magnifying lens.  You will see blue, green, and red dots.  The dots go
on and off.  The dots symbolically represent nerve cells firing.  Take
the television set apart.  You will see transistors, resistors,
capacitors, and integrated circuits.  These symbolically represent
nerve cells.  When you back up from the television screen you will
observe a picture.  The picture originates from a television
electromagnetic wave.  This symbolically represents information encoded
into a memory wavelet.

The correlational opponent-processing (COP) theory would accept that
all learning and memory is associative, correlational, energy-
efficient, integrative, cognitive, eigenfunction equivalence, quasi-
holographic and the result of information processing.  Memory is
created as a correlational pattern of opponent-processing consisting of
firing and inhibition of individual nerve cells.  This means the major
goal of the brain is to form the smallest number of correlational
firings of nerve cells to external and internal stimuli (Bower, 1992;
Bower, 1994 & Southwell, 1994).  Why nerve cells form correlations at
first may seem to be mysterious and connected to learning or biology.
But now it appears the correlations are due to the results of natural
principles that have more to due with the mathematics and physics of
oscillators and synchronization phenomenon (Strogatz and Stewart,
1993) and (Peterson, 1995).  In addition the reason why this is the
goal is due to the mathematical way the data or experiences have been
packed or compressed as a mental equation or eigenfunction equivalence
that allows for the recovery of that information.  Another reason why
this is the goal is due to the way complex systems adapt through self-
organization.  Such systems exhibit subcritical, critical, and
supercritical phenomenon.  For example, if one pours sand into one
location it builds ups and collapses at different levels of intensity.
A subcritical period would be a stable region of the sand getting
larger and larger without collapse.  A small collapses would be a
critical event.  A large reorganization of the sand would be
supercritical phenomenon.  This means that the brain is using a
universal adaptive principle of existing on the edge of order and
randomness (Ruthen, 1993) & (Pendick, 1993).  New cognitions are due to
consequences created by randomness, chaos, and major catastrophic
reorganization resulting in new integrations.  These new cognitions
allow for selective advantages for adapting to and understanding the
environment.  Support for catastrophic reorganization is suggested in
the stagewise cognitive development of children reported by Maas and
Molenaar (1992).

Neuro Net:

Neuro netters are developing and experimenting with computer programs
to simulate neural activity.  To us the most exciting results have been
generated with a program call EXIN.  Jonathan A. Marshall and Richard
K. Alley (1993) reported that EXIN (excitatory + inhibitory) network
self-organized by using inhibitory and excitatory learning rules with
two parallel opponent channels or chains.  This program successfully
learned depth relations from occlusion event.

Lisman and Idiart (1995) successful modeled short-term memories with
oscillatory subcycles, thusly proving that information can be
encoded into oscillations.  Interestly, in order to get the model to
work, a feedback inhibition oscillation loop had to built into the
model.  The work suggest that the brain uses a high frequency cycle
with low-frequency subcycles to encode memory.

Quasi-holographic wavelets:

Wavelet theory (Cipra, 1990) and quantum chaos with eigenfunction
equivalence (Peterson, 1995) appears promising to help explain how
information is formed and retrieved.  Wavelet theory is an advancement
over fourier analysis of the sine and cosine functions of brain
oscillating patterns.  Wavelet analysis allows one to separate the
individual wave components and the start/stop cycle of each wave in the
wavelet.  An eigenfunction equivalence or quasi-holographic mental
wavelet, by analogy, is like the mean and standard deviation of normal
data.  A mental wavelet predicts the present, variations, the future,
and the past.  The past that is predicted is not necessarily the one
that actually occurred and the future that is predicted may never
occur.  Wavelet theory and quantum chaos with eigenfunction equivalence
may provide a way to understand how the brain packs so much data into a
schema, idea, model, belief or theory.  Wavelets of learned activity
should produce constructive interference (high neural activity) and
destructive interference (low neural activity).  The situation is
complicated by superposition of information.  It will be extremely
difficult to observe directly neurowavelets and their actions.  The
fact that something can not be observed directly does not mean we
should ignore the possibilities of the model.  Almost every
neurobiologist knows that the brain is the organ of the mind and that
it generates wave functions from a simple sine wave, reverberation of
Hebbian precise interspike-interval patterns, to complex sub-milisecond
waves that allows for energy efficient coincidence detection (Softky,
1993).

Waves propagate throught many types of mediums.  The rules of
nature that apply to wave activity should be similar to the rules of
neural wave transmission.  Steinblock et al. (1995) research on
determining the best pathway in a chemical maze through high
speed photography of the changing colors illustrates the concept.  Wave
systems typically consist of waves traveling at constanct velocities
that interact with one another.  Sometimes this interaction will lead
to annihilation of other waves.  Gurney (1995) reports that the idea
of using diffusion equations and wave models for neural theory has been
suggested by Jack Cowan for self-organising nets, Alan Turing for
morphogenesis in biological systems, H.  Haken for synergetics, and
Swindale for similarity between zebra stripes and occular dominance
columns.

Further support for neural modulation and correlation being a major
characteristic of neural processing is suggested by Vaadia et al
(1995).  Neurons associate fast and influence correlated firing in
functional groups.

Wolf Singer's research revealed a correlated synchronous neural firing
to the same visual object with a oscillating wave of 40 hertz
(Barinaga, 1990).  Singer thinks that the oscillations may provide the
answer to the question on how neurons pool information.  Thoughts occur
in real time and may be thought of as occurring in 40 hertz cycles.
Nerve cells have this time frame when setting their configurations.
This does not mean that this is the only special frequency in the
nervous system.

Traditionally we have thought that nerve impulses are best represented
in an on/off system.  With the concept of a wave, the model may be
thought of neurotransmitters acting as vectors.  For example, the
hearing system does not process left/right frequency modulations.  We
would suggest that there may be structural reasons for this.  Wavelets
may use vectors of left/right, forward/backward, and some +/- system to
represent time.  Such procedures should be useful for encoding data
into neural wavelets.  If this speculation is true then this would
suggest that special regions of the brain would interact with these
modulations.  Therefore, some areas that are uni-directional should
exist and would not necessarily contradict COP theory.  Take a bucket
of water that is viberating with a cork in it and you will notice that
the cork will move to a stable region in the water.  High neural
firings in particular areas of the brain does not necessarily mean that
this is the location of that memory function.

Greg J. Stuart and Bert Sakmann (1994) found back-propagation in
neurons that provide a rapid retrograde signal that may assist the
neurons in its computational efforts.  These reverse oscillations are
likely to have significant importance to COP theory.  It is possible
that the vesicles that store the neurotransmitters have a charge and
are sensitive to the oscillations in the nerves electrical field.  It
is possible that the harmonics of these oscillations would be specific
to a neurotransmitter and result in high physical activity ultimately
resulting in the release of the neurotransmitter in response to
sub-milisecond electrical field oscilations.

It has been suggested that apical dendrite is a specialized recipient
of feedback information coming from higher cortical areas (Yuste, etc.,
1994).  This could be an opponent process.

According to Peter Laudrup (1994) "The way I see neurotransmitters (in
a brain that processes waves more than serial information) is that
release of a neurotransmitter and the acceptance postsynaptically will
lead to a change of _one_ of the waves dimensions.  If the wave is a
vector/multidimensional matrix each neuron will represent a dimension.
However, I think so much biochemical evidence point to the action
potential as an on/off process, that the components of the wave
dimensions have to be considered binary.  On the other hand, you could
consider some of the protein neurotransmitters, that have no direct
action but is thought to diffuse to a wide area from the point of
release and thereby effect a lot of neurons by modulating their
threshold for action potential as vector transmitters."

Dennis McClain-Furmanski (1994) made the following suggestions and
comments.  The intraneuronal microtubules may be the physical storage
space of the oppositional signal.  Both Stuart Hameroff and Roger
Penrose have done intensive work looking at these structures.  The COP
model is certainly less esoteric than their model.


David Southwell (1994) position is that "resonances" in "Columnar Array
Networks" consisting of interconnected columar complex assemblage of
50,000 neurons running through out the cortical layers becomes the
functional unit of intelligent processing of stimulation.  While
there may be a difference in the terminology, Southwell's insight of
resonnance and the necessity of energy efficiency is at a fundamental
level similar to ours.

Heanue, Bashaw, & Hesselink (1994) have developed a volume holographic
computer storage system which use a reference hologram to retrieve the
stored data.  We would suggest that the correlated synchronous firing
revealed by Singer is used as a reference quasi-holographic wavelet for
the brain.  Klimesch (1995) reported that alpha frequency is associated
with retrival of semantic long term memory and theta oscillations are
associated with retrival of episodic short term memory demands.  These
could be reference freqencies.


According R. Tim Coslet (1995) when viewing a hologram with a different
laser frequency than the one used to take the picture the image
produced results in a change in size proportional to the change in
wavelength between the two light sources.  Neural quasi-hologram should
produce variation and deviations from the original memory in a gaussian
distribution.  This would result from the recovery of memories with
different oscillating neural frequencies.

Theios and Amrhein (1989) research suggest that "a stimulus is a
stimulus is a stimulus, independent of its ... mode".  This puzzling
result suggests that a quasi-holographic neurowavelet is created by
brain wave modulations created by stimuli and the interactions or
correlation of current experience and changes in neuroconnections from
long-term potentiation due to past experience.

Ghislaine Dehaene-Lambertz and Stanislas Dehaene (1994) research on
speech sounds and changes in babies brains suggest a mirror image of
the stimulus wavelet.  This mirror image is in our opinion a memory
wavelet.  Since a wavelet is an average, the standard 3 modulation
pattern for event-related potential (ERP) is interpreted to represent
an approximation of the average wavelet for the stimulus "ba".  The
surprise stimulus "ga" is followed by a inversion ERP.  This inversion
is interpreted as a memory wavelet for "ba" + not.  If this pattern can
be replicated it would suggest support for correlational opponent-
processing theory.

Habituation/immunization:

Habituation can be viewed as the product of correlational opponent-
processing.  Stimuli are habituated when neuronal patterns have been
correlated to a lower level of neural firings.  It is likely that
stimuli create a unique stimuli wavelet and that habituation is the
antiwavelet or memory wavelet.  This means that internal mental
representations or wavelets now act as a filter to reduce or control
neural firings for similar situations in the future.  An idea then acts
as if it had immunized the learner to the stimuli in the environment.
The concept of a filter is supported by the use of a hologram in
optical astronomy (Borra, 1994) and LaBerge & Brown (1989) research on
attention.  "Habituation induces a specific change in the processing of
...  information rather than a general reduction in responsivity"
(Condor & Weinberger, 1991).  Habituation then means that wavelets,
stimuli, schemas, ideas, models, concepts, beliefs and theories have
been learned and no longer create a high arousal state.  Psychological
immunization to the environment has occurred and this state allows for
the selective perception of discrepancies to the stimulus complex.
Learned stimuli now function as background to see new stimuli.  We are
built to conserve old ideas and focused to understand the unusual by
the correlational opponent-processes.  In a meta-analysis of 54
experiments on how memory is influenced by expectations, Stangor and
McMillan (1992) reported that incongruent stimuli were more likely to
be remembered than congruent stimuli.

The brain would be constantly searching for the fewest neural pathways
to understand environmental stimuli.  According to Bernard W. Balleine
and Ian S. Curthoys (1991) the "hippocampal activity is sensitive to
event contingencies ...." Commonly used neural pathways would be over-
fired (habituated) and cause the brain to use other neural pathways
resulting in the random jumps in intellectual understandings.  These
jumps may occur in 40 hertz cycles (Barinaga, 1990).  Mild jumping out
of one's comfort zone would be stimulating.  Any significant jump would
require extra effort to use the correlational opponent-processing
systems to habituate the jump.  Significant stimulus jumps may explain
humor or abnormal behavior like psychopaths, multiple personalities,
drug addiction and thrill seeking.



Memory:

Memory is any way of storing and representing information.  The brain
has many ways of doing this.  In the past it was suggested that memory
is best understood as changes in RNA molecules in nerve cells due to
learning.  This idea does not generate much interest or support today.
We would suggest if the idea returns that what is important would be
the location and interconnection of RNA molecules, if they are in fact
connected with memory.  It should be clear that memory is a complex
issue and many approaches are giving us true information but the
information has not been linked together in a way that allow us to
understand.

While not the first, the research by Richard Tsien of Stanford and
Charles Stevens (1990) of the Salk Institute shows that nerve cells
create a long-term potentiation of a change in the probability of
firing or inhibition when stimuli are associated with the firing of two
other nerve cells.  According to Tsien and Stevens, glutamate may be
the main neurotransmitter substance responsible for this change
resulting in associative learning.  Glutamate is released in the
receptor neuron when stimuli are pair- bonded or connected with each
other from the firing of two other nerve cells.  The probability of
firing or inhibition of firing of a nerve cell ranges from 0 to 1.  In
other words, nerve cells have a permanent change in response to
environmental stimulation.  Since learning would require thousands of
nerve cells working together in their firing or inhibition patterns,
one may view these patterns as learned correlational relationships
between stimuli.  The actual storing of the eigenfunction equivalence
or mathematical relationship is expressed as a structural change
relative to other nerve cells and a change in the probability of
firing.  One may view these structural changes as the changes of
chemicals on photographic film.  We would suggest that they are quasi-
holograms of memory.  Computers have been programmed to create
holograms, of any visual rotation, from a limited set of information
(Peterson, 1992) .  The brain is probably using similar procedures in
creating quasi-holographic wavelets.  COP theory strongly suggests that
a mechanism must be present to force some nerve cells to die or pull
back neural connections to store wavelets.  If this is true then
chemicals that kill nerve cells may increase learning.  It is likely
that nerves are instructed to grow to preserve or repair a learned
association.  These tendencies could result in diseases.

Correlations are the encodings of associations and cooperativity
between neurons.  A neural mechanism for opponent-processing is
suggested by Robert A. Zalutsky and Roger A. Nicoll's (1990) work on
associational-commissural fibers and mossy fibers of dentate granule
cells.  "Much of the interest in LTP (long-term potentiation) has been
fueled by its tantalizing phenomenological similarity to memory.  ...
in assoc-com pathway the CA3 pyramidal cell integrates its various
inputs and controls the potentiation of active inputs, in mossy fiber
LTP the presynaptic dentate granule cell would make the analogous
computation, transform it into spiking frequency, and thus control the
occurrence of LTP."  These two types of cells use significantly
different procedures for creating long-term potentiation.  These
differences may be opponent-processing.  Opponent-processing may be due
to the difference in neural firings that occur from the
interhemispheric competition and specialization of functions (Kennison
& McFarland, 1989).

Jean-Pierre Changeux (1993) research on the firing patterns at the
synapse reveals a three-phase change in probability of firing.
This suggests that opponent-processes started in nerve cells and later
developed into global opponent-processing.  Synapse exists in three
states, the closed or resting state, the closed or desensitized state,
and the open or active state.  Neurotransmitter receptors by altering
their states can change the probability of neurotransmission.  Changeux
believes this response could participate in learning.  Opponent-
processing may require three different nerve mechanisms.  According to
Holloway (1992) the three main or elite neurotransmitters are ATP,
acetylcholine, and glutamate.  Long-term potentiation may be due to
nitric oxide, arachidonic acid, and carbon monoxide.

The learner must be viewed as an active processor of information and
trying to integrate his current experience with his old experiences
(Mayer, 1992).  COP theory of data analysis and storage is one of a
working memory.  The working memory's goal is to correlate all data.
Data that is correlated is strengthened.  Data that has low
correlations is slowly erased.  The hypermnesia and reminiscence
phenomenon problem raised by Payne (1987) could be explained as a
consolidation of wavelets.  Correlations may be positive or negative.
The brain may work more effectively with positive correlations.  For
example, children have difficulty with lies not being real, pretending
not being real, movies not being real, and the concept of not or
negation.  Tell a child not to do something and they will often do what
you told them not to do.  Even college students often miss questions on
tests with the word NOT in them.  This should mean that repression and
undoing are active neural processes, not passive processes.  For
further readings on the changed perception of the importance of working
memory the reader is referred to Alan Baddeley's (1992) article on
Working Memory.

According to Nestor A. Schmajuk and James J. Dicarlo (1991) "Sensory
representations compete among themselves for a limited-capacity short-
term memory (STM) that is reflected in a long-term memory storage.  The
STM regulation hypothesis, which proposes that the hippocampus controls
incentive motivation, self-excitation, and competition among sensory
representations thereby regulating the contents of a limited capacity
STM."

The ability to recognize slight changes in the stimulus complex is
influenced by our attention.  We are limited in how many stimuli we can
respond to at any one time.  PET scans demonstrate that cognitive
control of visual processing occurs (Corbetta , et al., 1990).
Focusing attention is important for the effectiveness of the working
memory or mediator.  It is our theories, schemas and ideas that focus
our attention.  The neural pathways are dependent on biological wiring,
the hard wiring from experience, and the disconnection and random
growth of neural connections from new learning experiences and neural
decay.

Horgan (1993) has reported that all areas of brain functioning seem to
be highly specialized with fragmentation in intellectual task and
experience.  This fragmentation has led to the realization that there
must be a supreme integrator.  The thalamus is suggested as the
supreme integrator from the analysis of the neuropathological findings
in the brain of Karen Ann Quinlan (Kinney & etc, 1994).  COP theory
would predict that neural networks are organized in a triad system as a
minimum by having an advocate, a protagonist, and a mediator; or white,
black, and gray; or on, off, and gatekeeper or integrator.  The
constant dialogue between these systems creates new knowledge and
balance.  These neural networks would be specialized organizations of
knowledge acting as brokers of information and gate keepers.  New
stimuli would be analyzed by the gatekeeper as to applications to
current intellectual problems.  This alertness to stimuli and focusing
on critical observations is used to support or refute a key concept.
The question then becomes can the new experience be explained by the
rotation, compression, or change of the concept.  If the new stimulus
fits the predictions of the wavelet it is not added to the wavelet.  If
the information is slightly off the average the information is added to
the wavelet.  If the information is significantly different it is
summed under a new wavelet as an exception to the rule.  The mediator
is a neural device that brings together the elements or data required
to generate a new idea.  The brain is automatically structured into an
applied knowledge area and a pure or theoretical area.  In many ways
the mind is the battleground between idealism and pragmatism.  Ideas
are schemas created by random correlations.  We act as if these ideas
are real.  Psychologist Daniel T. Gilbert of the University of Texas
states that "Much recent research converges on a single point people
are credulous creatures who find it very easy to believe and very
difficult to doubt ....  Inquiring minds not only want to know; they
also tend to believe, at least initially, what they read and hear"
(Bower, 1991).  Superstitious behavior illustrates the concept of the
realness of ideas.  It is the usefulness (goodness-of-fit) or lack of
usefulness of ideas that creates tension with other ideas that generate
intellectual growth and emotional conflict.

COP theory suggests that there are no memories that have not been
reworked.  It also suggests that any stimulation of the brain and the
apparent memories created by that stimulation must be made consistent
with previous experiences.  Therefore, the memories stimulated may be
rebuilt memories instead of actual memories or predicted estimates of
the future.  Transfer is the correlational connection of schemas to new
situations.  Schemas may cross-connect from the reworking of old
memories and random connections.  Habituation of old firings is the key
reason for new random firings created by increased sensitization to new
random stimuli that are discrepant to old stimuli.

Representations, copies or models:

One may visually recognize a multiple regression correlational
relationship as a star formed by drawing an individual correlation as a
spoke of a star.  Such stars are easily recognized by untrained
individuals as unique.  The brain is probably using a similar method
since three dimensional firing associations have been recorded with PET
scans or positron emission tomography (Bower, 1990).

It has been reported in the literature that an attractive face is
really a face that is mathematically determined to be average by a
computer (Langlois & Roggmann, 1990).  This means that for all face
stimuli that we are exposed to we constantly compare the new face to a
mathematic model of that average.  If the new face is highly correlated
to our mental model or mental copy we respond to it in a positive way
and state that the face is pleasing.  COP theory would say that all
schemas, ideas, models, beliefs or theories are mathematically
determined to be average and expressed as a wavelet by our experiences.
Just as a model airplane is made of parts our mental models or schemata
are made up of mental parts.  These parts are correlated to our mental
models, mental copies, or representations and can be used to make other
models.  Models can be grouped together to make more complex models or
theories.  All models and parts are independent and connected at the
same time.  Remember it is possible to write complex computer programs
with only 255 numbers in a chip.  The numbers are the parts that can be
assembled into models of reality.  People with learning difficulties
may be missing key parts or processes for building the models necessary
for the learning process.  Not all parts are necessary to recognize a
model plane as a plane, but there are critical parts that are
necessary.  Habituation of a stimulus complex followed by the
presentation of a new stimulus (key part) may be all that is necessary
to establish the elements required for learning.  The brain is
structured to compare new stimuli with old schemas.  If the stimuli is
discrepant we focus our attention and create a new schema.

It is our conceptualization of events that allows us to observe new
relationships not previously apparent.  The reader is directed to
McCloskey's (1983) concept of mental models for supporting evidence.
COP theory would stress that all humans are highly theoretical.  Each
person's theories are their perceptions or interpretations of reality.
It would be difficult to impossible to take head-on another's theory.
A new theory must be discovered slowly to overcome a strong counter
theory unless the new theory matches in with one's old theories.
Presenting the advantages and disadvantages of each theory would help
integrate both and create a relaxed synthesis.


Learning/Cognition:

A new activity requires a new neuronal environment.  Strong resistance
should be observed to new experiences.  Resistance could be experienced
as anxiety, fear, anger and paradoxically excitement according to the
opponent-processing theory of emotion.  The speed of opponent-
processing or diffusion of ideas should help determine whether new
stimuli are anxiety evoking or exciting.  The faster the response time
for habituation, the more intelligent the person will be.  We are
biologically wired to be anxious to significant changes in the stimulus
complex.  If a person is intelligent or worldly they can habituate to a
new situation faster.  This changes what should have been anxiety
provoking to an exciting stimulus, interesting stimulus, or even a
boring stimulus.  If large amounts of information and experience have
been habituated, a person would then be alert to small changes in the
stimulus complex.  Prior knowledge then alerts a person to new
knowledge and speeds up its acquisition.  Almost anyone could become
superior in an area of knowledge that they are actively trying to
understand and master.

An important goal of learning is the assimilation and accommodation of
new stimuli with organized correlational schema formed by our
individual experiences.  Theories that put large quantities of
empirical data into a nice package would be neurologically energy
efficient.  Low energy usage should cause the release of pleasure
chemicals or neurotransmitters, possibly carbon monoxide, to lock in
the memory and cause one to feel pleased.  This suggests that we have a
comfort zone for looking for new empirical experiences to confirm our
theories.  The normal zone or comfort zone of individuals would vary
according to their biological makeup and correlated experiences.  The
range of variability in brain wave fluctuations would influence data
storage and retrieval.  Sensitivity or responsiveness to stimuli would
be biologically and experientially vectored.  The characteristic of the
person's biological thermostat would define the comfort zone.
Individual difference in thermostats are illustrated by novelty
preference, shyness phenomenon and stimulus seeking personalities.

Meaning of material has long been recognized as important to and
enhancing learning (Reed, 1938).  COP theory would stress discrepancies
and the meaning of information.  Meaning would occur as a process of
reworking of old memories.  Histories (all data or experiences from the
past) are not as important as the geschichte (theories or ideas created
by clustered data).  Memories would be constantly changed to make sense
of one's current situation.  Parents may report one child having
musical ability when both of their children are musically inclined.
The parent's theory that one is musically inclined and the other is
athletic causes the selective reworking of memories and perceptions to
adjust the data for consistency.  COP theory would use the concept of
perceptual set to support the working of correlational opponent-
processing.  The research on the events of wording regarding a car
accident supports this position.  The word crash generates higher
estimated speeds when compared to the words fender bender (Loftus &
Palmer, 1974).

New learning is dependent on prior learning and randomness.  New
learning requires development time, inventive cognitive dialogue,
integration, or opponent-processing.  Neal Stolar et al (1989) suggest
that "unexpected stimuli activate certain hippocampal and
cingulate cortical neurons.  This activity in turn suppresses or
`limits' the firing of limbic thalamic neurons ... in relation to
stimuli classified as unexpected or expected on the basis of their
incidence or `probability'."

Peter J. Lang et al (1990) research findings suggest support for
COP theory.  Their findings are that "Emotions are organized
biphasically, as appetitive or aversive (defensive).  Reflexes with the
same valence as an ongoing emotional state are augmented; mismatched
reflexes are inhibited."   The COP theory is supportive of Piaget's
theory of cognitive development.  The organization principle and schema
are neural correlations to the stimulus complex.  Adaptation
(assimilation and accommodation) can be viewed as opponent-processes.
COP theory would stress that the research on what children can not do
cognitively hides their greatest strength.  Children are scientists and
philosophers.  Children are theoretical even as babies, but at a more
primitive level.  Cognitive behavior follows the pathway of stimulus,
schema review of stimulus, novelty, habituation, and schema production
and consolidation.

Personality:

The rational-emotive theory of emotions (Ellis, 1962) uses antecedent
events.  Beliefs about these events lead to consequences.  The COP
theory would say the antecedent events are stimuli, the beliefs are the
opponent-processing of correlational stimuli, and the consequences are
the educated guesses, trends, and vector analysis translated into
action.  The opponent-process is really one of active-reactive neural
networks.   Beliefs are neural arrangements created by previous choices
and negotiations with other neural networks.  Beliefs are local
conditions that represent investment decisions created by past
conflicts and political processes occurring at a neural level.  Beliefs
are entrenched integrated neural compatibilities, strategies,
configurations, frames of reference, styles of utilization, points of
view, and momentum of one's past.  Cognitive data has extremely strong
emotive power.  This is illustrated with the concepts of musts and
shoulds in Ellis' theory.  Cognitive data is an original construction
of people.  People's shoulds become strong desires, goals and
necessities that for them may be non-negotiable.   The consequence of
belief is the result of multiple correlational analysis, voting of
networks, or conflict between sponsor-regulator neurons that vector us
to a course of action.  The consequences lead to cognitive dissonance
or tension that must be reduced by correlational opponent-processing
and creation of new beliefs to stabilize or adapt the neural firing
patterns.

The incorporation of an erroneous belief into one's schema is
paradoxical integration.  In order to accept tension arousing stimuli
and achieve homeostasis between existing memories we may fit erroneous
beliefs into our cognitive schema by distorting information.
Distortions cause conscious or unconscious tensions that may result in
coping strategies in the form of maladaptive behaviors or faulty
cognitions.  These frequently lead to self-defeating behavior patterns.
Psychopathology can be understood as a paradoxical integration.  Some
examples may be learned helplessness, paranoia, multiple personalities,
dependence, defense mechanisms, aggressiveness, classical conditioning,
and autoimmune diseases.  A belief is dangerous in that it may limit
our ability to see contradictory information.  We may feel compelled to
force others into our beliefs.  Their acceptance of our viewpoints
allows us to relax our vigilance that we may be wrong or that some
other opinion may be correct.  A belief that integrates most
experiences may ultimately win out because it is more energy
efficient.  That is why a false belief is a paradoxical integration.
The tension is not at its lowest level, causing a search for possible
new integrations.  Approaching others for psychotherapy is like saying
our paradoxical integrations are not working and we want to reduce our
psychological tension.

The old saying that people always take the easiest way out for
themselves is supported by COP theory.  What is easiest is determined
by the biological and experiential make up of an individual.
Guastello's (1984) use of catastrophe theory to explain the opponent-
process of drug addiction and work performance illustrates that the
easy way out is psychological and can be vectored in unexpected
outcomes.  Chaos and feedback are useful in understanding how the brain
functions.

COP theory suggests that memories are state dependent.  Each person is
constantly a different person.  Brain chemistry and neuron firings vary
over time.  Data is stored for the actual neuronal environment at the
time it was experienced.  Data retrieval is dependent on the neuronal
environment.  It would be difficult to impossible to recall information
that is stored in significantly different neuronal environments.
Therefore, a person will remember happy things when they are happy and
sad things when they are sad (Johnson & Magaro, 1987).  When you are
speaking Spanish you are a Spanish person and when you are speaking
English you are an English person (Psychology Today, 1987).  Different
personalities for each language within the same person may be
interpreted to support COP theory.

Genetic differences and interaction with the environment would create
different cognitive and emotive styles, strategies and reactions to the
environment.  Lee (1977) proposed using the metaphor of colors to
describe and understand the various typologies of love.  Using a Q sort
test of 1,500 card and factor analysis the research supported the
theory.  The concept of a temperament thermostat represented by a color
band continuum may be useful for illustrating the COP functions of
personality.  Red would be representative of anger or a hyper-arousal
state; pink would represent irritation, discomfort or moderate
excitation; green would represent a comfort zone, contentment or mild
excitation and grey would represent hypo-arousal, boredom or
depression.  The width and normal position of each color band would
vary due to biology and experience.  Recovery time to the green band
also would be dependent on biology and experience.  These color bands
represent a continuum of gradually intensifying shades within each
color band.

Abnormal personalities could be due, in part, to emotional thermostats
that are set at points off center or to portions of color band that are
abnormally large or small.  A well-adjusted person would have a well
proportioned, centered emotional thermostat.

The COP theory is really an immune theory of learning where the goal is
to achieve balance or homeostasis to environmental stimuli.  Major
stimulus changes or discrepancies in the stimulus complex would
represent danger and require immediate immune responses.  Phobias could
be eliminated with flooding to activate the immune functions of COP
theory if the person is willing to give up their phobia.  Systematic
desensitization could do the same thing at a slower rate.  Any
procedure that allows the brain to control or explain things to itself,
and thereby reduce tension, should help.

Sensations and Perceptions:

Paradoxical integration is illustrated with the Thunberg thermal grill
illusion.  Using alternating tubes of warm and cold water to generate
contradictory stimulation individuals report intense pain.  Craig and
Bushnell (1994) suggest that the integration in the thalamic region of
the brain best explains this illusion.  The integration result from the
joining of two unmasked simple models of central disinhibition.  COP
theory suggests that the firing of individual nerve cells would create
a unique wave function for a particular sensory system and experience.
These sensory systems then create waves or wavelets.  A wave generator
for warm and a wave generator for cold with increasing signals up to a
maximum signal strength.  In the integrative systems of the brain these
wavelets would result in producing an integrative opponent-processing
wavelet.  This wavelet created by interaction results in the perception
of pain.

Paradoxical integration is illustrated with taste.  By cooling the
tongue with ice, sweets will taste less sweet (Frankmann & Green,
1988).  The chemical explaination is that sweets when cold cause the
nerve cells to fire at a slower rate resulting in perceived less sweet
tast.  We would suggest correlational opponent-processing may be a
better explaination.

Saccharin, an artificial sweetener, tastes both sweet and bitter.  The
psychological report of people vary on the taste of accharin.  Caffeine
is a bitter tasting stimulant.  After exposure to caffeine, the
saccharin taste is increased for both sweet and bitter.  Yet, caffeine
has no effect on sweets and their taste (Schiffman, Diaz, & Beeker,
1986).  This suggest an opponent-processing system of sweet-bitter and
paradoxical integration.  Bartoshuk (1993) research suggest opponent-
processing.  When one side of the tongue has been paralyzed sweets will
taste sweeter to the other side.  Bartoshuk (1994) reported that
miracle berries will cause acids to taste both sweet and sour.  The
explanation was believed to be peripheral.  The glycoprotein on the
miraculin molecule was believed to directly stimulate sweet receptors.
Now that a central explanation has been proposed by correlational
opponent-processing Bartoshuk reported that she really liked the
explanation.  Using a gestalt pattern and correlational opponent
process the miraculin which is practically tasteless might produce
neural wavelet patterns what are unnoticed in the brain.  This would
produce opponent memory reverberating wavelets.  When the stimulus of
acid (vinegar) is added to the miraculin wavelet it causes a frequency
modulation that is read as very sweet and sour.  This would be like phi
phenomenon and the gestalt of perception.

The system of olfaction has been difficult to study.  Paradoxical
integration is illustrated through "olfactory compensation" first
reported by Zwaardemaker in 1900 in which two odors will cancel each
other out and block perception (Richardson & Zucco, 1989).  COP theory
may be able to direct research in this difficult area.

According to Gutin, Oliwenstein, and Mestel (1993), world wide there
are only 200 serious investigators pursing the auditory system.  There
work has significant impact on the thousands of others who study
psychological, neurological, and physiological aspects of the auditory
system.  The hearing nerve system consist of about 16,000 hair cells
and their cilia in four parallel rows, one inner and three outer rows.
(Note: four moments suffice to create a Pearson system (Cacioppo &
Dorfman, 1987)).  Each hair cell is connected to about 100 bristles or
stereocilia.  The hair cells are arranged in a row according to height.
Strand like structures called tip links join each stereocilium to its
tallest neighbor.  This linkage allows for nerve stimulation only in
the direction of front or back.  This then allows for the correlational
encoding of nerve stimulation.  The opponent process we believe comes
from the nerve cells coming from the brain to the auditory nerves.
According to Gutin et al. (1993) the number of connections coming from
the brain to the auditory nerves is significantly higher than the
auditory nerves going to the brain.  According to Drennan (1995) there
are ~1,800 efferent connections from the brain to the cochlea and there
are over 30,000 afferent nerves from the cochlea to the brain (temporal
lobe) this contradicts Gutin et al. (1993) report.

In addition according to Drennan (1995) there are four rows of hair
cells, three inner and one outer.  The hair cells provide the base for
the cilia.  There are ~12,000 outer hair cells in each row.  A row
would be make up of 100-150 stereocilia in 6 or 7 rows of sterocilia
shaped in a W or V pattern.  There are ~3,500 inner hair cells which
each have 40-60 cilia shaped in a U pattern in 2 or 4 rows.  Longer
cilia are near the base of the U, V, or W and the shorter cilia are
near the inside.  Longer cilia are in the apical turn of the basilar
membrane and the shorter cilia are in the basal turn.  The cells fire
only when pulled in one direction.  Thusly, the cilia act as a
rectifier only transmitting on the positive side of the acoustic wave.

According to John M. Price (1994) the nervous system works both ways.
This ultimately results in nerve cells responding to 2,000 Hz in the
right ear eventually affecting the firings of the 2,000 Hz portion of
the opposite cochlea.  Tinnitus a ringing in the ear can actually
produce sound (otoacoustic emmissions) that others can hear also.

Since sound is a wave function, wavelet theory seems to be a natural
for explaining sound analysis.  Stimuli wavelets are produced by sound.
The opponent-process produces wavelets to control and integrate new
stimuli wavelets produced by the environment.  Since the auditory
system may be the simplest example of correlational opponent process,
systematic study of the auditory system may suggest other research
avenues and strategies for other sensory systems.

The opponent-process theory of color vision (Beck, Hope, & Rosenfeld,
1983; Leibovic, 1990) suggests that color perception is due to three
types of cone nerve cells that send information to bipolar nerve cells
resulting in seeing a particular color.  A nerve would have two states,
on for a color and off for another color, for example; nerves for
blue/yellow, red/green and white/black (rod).  This information when
jointly presented to bipolar cells from other cones would produce all
the colors that we see.  This means that red light turns on one type of
cone and inhibits another type of cone from firing.  This opponent-
process then is interpreted to mean that the stimulus was red.  Purple
is made up of red and blue.  Cones for red and cones for blue are turn
on or inhibited.  The opponent-process then is interpreted to mean the
color purple.  It is likely that some cones are pure types for red,
blue, green with no off meaning.  This would help the opponent-process
of interpreting the perception.

Paradoxical integration is observed with color constancy.  A color is
maintained even under different lighting conditions if not to extreme.
The visual principles of closure, figure and ground, similarity,
simplicity, and whole being greater than its parts also illustrate
paradoxical integration.  Optical illusions illustrate paradoxical
integration.  Examples are reversal of figure and ground, negative
after image, Muller-Lyer illusion, visual aftereffects, and phi
phenomenon.  Problems raised by Blake (1989) regarding binocular
rivalry like suppression having no retarded effect on the growth of the
threshold elevation aftereffect, the spatial frequency shift
aftereffect, the tilt aftereffect, and motion aftereffect suggest the
strength of wavelets.

Paradoxical integration is observed in binocular depth reversals.
According to Deutsch and Ramachandran (1990) when pictures are inverted
in a stereoscope people report that the perceived depth reverses.  This
is not always true since faces seem to be resistant to reversals.  We
should see a hollow face but instead we see a normal face.  While this
phenomenon can be reduced by changing texture clues and binocular
disparity clues, the position of COP theory is a cognitive
interpretation.  The wavelets or schemas for faces are used to
generalize the current stimulus of an "inverted face" to a normal face.
However, when sufficient information is supplied to counteract the
prediction from the wavelet, reversal occurs.  Reversals may support
the position that for every schema or wavelet there has to be an
opposite schema or wavelet.  We are hopeful this may be a useful way to
test COP theory.  Reversed responses were reported by Jin (1992) as
a revision of the law of initial value.  The law of initial value would
state that the initial strength of a stimulus would determine its
strength and resistance to change to a memory in the future.  This
implies a baseline rate for future comparisons.  However, Jin states
that the law of initial value should be revised.  The revision is that
the higher the initial value of a stimulus the greater the likelihood
that a reversed response would be observed.  This reversal supports in
our opinion reverse wavelets or correlational opponent processing.

Very-large-scale integration (VLSI) electronic circuits for computer
vision algorithms have been developed with the strategy for minimizing
the energy or functional cost (Harris, Koch, & Luo, 1990).  This use of
a priori constraints, stochastic algorithms , and probability
distributions for detecting discontinuities for computer vision systems
has led to successes for the electronic industry.  These same a priori
constraints of minimizing the usage of neuroenergy and the use of
probability distributions from wavelets when forming neural firing
patterns have lead to human beings.

Movement:

Bullock & Glossberg (1988) research on movement revealed that "Opponent
interactions regulate ... agonist and antoganist muscle groups.  This
system generated synchronous movements across synergetic muscles by
automatically compensating for the different total contractions that
each muscle group must undergo."  This suggests the use of movement
wavelets to predict and correct the movement systems before it is
possible to do so.

Emotion:

The opponent-process theory of motivation (Solomon & Corbit, 1974)
demonstrates paradoxical integration.  The goal is to maintain
equilibrium in emotion and motivation.  Events force us out of our
balance.  The body tries to force us back to the balance by releasing
opposing chemicals.  Events change and the chemicals that were released
are still in the blood stream.  This causes an opposite emotional
effect.  For example if you are about to jump out of an airplane strong
fear and anxiety are aroused.  The body does not want you to be afraid
or nervous so it releases pleasure chemicals at high levels to try to
balance the negative emotions.  Suddenly the parachute opens and you
are safe.  The pleasure chemicals are still in your blood stream so
they cause you to experience a strong positive feeling like having a
shot of heroin.  These opponent-processes explain addictive behaviors.

The phenomenon of drug addiction, drug withdrawal, and drug tolerance
fits the opponent-processing theory well.  The correlational aspect is
illustrated with the research on drug tolerance being connected with
the environment (Poulos & Cappell, 1991) .  A low drug dose when
connected to a change in the environment can result in a new high or
even death.

Evolution:

Houde and Ender (1990) research on male color patterns and female
mating preference may be interpreted to support COP theory.  Male
guppies (Poecilia reticulata) vary in number and size of orange dots.
Females use the orange dots to create a schema or wavelet for sex
recognition.  A wavelet is an average.  Females prefer males who have
average or above average dots.  Orange dots make the males easy to see
for predators so this results in an opponent-process of reducing the
number of orange dot fish that survive.  Sexual preference from wavelet
modulations keeps the dots higher.  Reproductive success and survival
to have offsprings is the driving force of evolution.  Any genetic
trait or behavior that increases reproductive success and survival of
offsprings will be selected into the gene pool for a species.  Behavior
is a quicker way to adapt to the environment than changing the gene
code to adapt.  Behavior often creates significant advantages by
exploiting new ecological niches.  Through natural selection the
biology of the organism further adapts the offspring to use these
behaviors more effectively.  Evolution works on the available gene
codes and the successes of the past.  Many of the biological systems
are redundant and modifications of previous successes.  Homeostasis is
a major adaptation.  We drink water when we are thirsty.  We eat when
we are hungry.  Our sex drive, curiosity and aggression results in
offsprings.  Learning is a faster way to adapt to the environment than
biology.  Knowledge can be transferred by experience and observation to
offsprings thereby giving them a selective advantage.  COP theory
reflects evolution.  Habituation is homeostasis to the stimulus
environment.  Homeostasis conserves energy.  A wavelet is a statement
of balance and memory of experiences that is energy efficient.  The
brain will configure itself to almost any type of environment thereby
enhancing survival.  No real new system is being used in opponent-
process since it describes a large range of behaviors and biological
systems.  This means that learning is simply a modification of basic
biological processes.  Opponent-process allows for rapid adaptation to
complex biological requirements.  Learning is an extension of this
adaptation.  Chaos, order, and catastrophe processes when applied to
learning have created new and powerful successes.  We are the heirs in
this long chain of successes and events.

COP theory would predict that some birds that fly together should have
correlated wing beats.  A lot of group behavior in animals that are
synchronized illustrates correlational opponent-processing.  The
vacillation phenomenon in approach-avoidance problems illustrates
correlational opponent-processing.

COP theory would accept that animals can think, know, and be aware
through the mental models or mental copies that they generate from
their experiences of the environment.  The difference between animals
and humans is not that extreme, both are creating and using symbolic
representations of reality.  We believe that animals should be given
the respect, appreciation, and fair treatment they deserve since we now
must view them as being more human.

Tools:

Without the reductionist strategy the necessary empirical facts could
not have been revealed allowing for a synthesis into COP theory.  A
great danger of COP theory is a return to a pure mentalist model.
Mentalist views must have reasonable empirical evidence.  If mentalist
models will encourage research then we will make progress.  The tools
that will allow for a support of mentalist positions are computerized
axial tomography, positron emission tomography, magnetic resonance
imaging, BEAM recordings, SQUID recordings, neural netting,
bioneurology, and wavelet analysis,

Implications:

Piaget's position that mental thought is symbolic and a process of
assimilation and accommodation is sported by COP theory.  The current
use of concrete teaching is supported if the theory is stated first.
Even babies are theoretical.  Piaget's theory suggests that this would
come later.  While the theories of children are not acceptable to us
and their theories will change with time to the adult position, one can
not be lulled into a position that children are simple, concrete
oriented creatures.  Even the mentally retarded are interested in the
reasons why things are the way they are.

Freud's concept of the unconscious influencing behavior would be
supported by COP theory.  This comes as a complete surprise and forces
us to reexamine the psychoanalytic position.

Experience and associations that support or refute a theoretical
position is what we must strive to build in children and adults.
Reward is not necessary for learning.  However rewards are useful to
motivate a person to start the process of learning .

Conclusion and applications from COP theory:

Discorrelation:

What happens when habituation, integration, or paradoxical integration
fail?  Discorrelation.  Discorrelation may be due to genetic causes,
brain damage, traumatic experiences, wavelet constructive interference
or wavelet destructive interference.

The pathology of stuttering may be used to illustrate the concept.
Marek Roland-Mieszkowski (1994) has developed an electronic device to
prevent discorrelation which is 90% effective in stopping stuttering
with no training.  Stutterers who sing with a group do not stutter.
Stutterers who become deaf do not stutter.  Ear plugs will help reduce
stuttering.  It is likely that wavelet constructive interference due to
feedback loops to the speech centers, cause chaos in the speech
processing systems.  Jamming, blocking, or modifying feedback will
reduce discorrelation.

According to Eric Wasserman (1995) magnetic stimulation of CNS/PNS can
produce motor evoked potential in hand muscles that close to normal
nerve stimulation.  This occurs from repetitive magnetic stimulation of
the motor cortex at about 10 Hz.  The firing results from
hypersynchrony of firing in the corticospinal system.

Education:

Educational information has to be presented in many different ways for
correlations to form that may lead to intellectual understandings or
new inventions.  Information should be presented to increase
intellectual tension to form new conceptualizations.  The tension
cannot be overwhelming resulting in the student using escape as their
method of staying in their comfort zone.  There are many thermostats or
comfort zones for different cognitive functions.  A knowledge zone
really is just an area of knowledge that has been habituated due to
exposure and biologically based abilities.  COP theory suggests
revealing the object, principle, or theory first then providing as many
experiences and approaches involving as many of the senses as
possible.  Remember that the brain is calculating a mathematical
average to represent or classify phenomena as a wavelet or wave
function. To the mind everything is a theory that is used to filter
future stimuli and thusly refute or confirm the theory.  A cup does not
exist as a concrete object, but as a theory called cups.  Huge amounts
of cross-connecting data are stored under the mental program called
cup.  This data is stored in a wavelet or a compressed mathematical
statement almost as a single internal stimulus that allows the brain to
unpack the data for review.  The goal of education would then be to
teach theories and examples of those theories.

The next goal of education would be to facilitate the synthesis of
ideas.  Each idea could be presented as a thesis or antithesis.  The
goal would be to integrate contradictory ideas into a synthesis.  Pro
and con exercises with a resolution of a synthesis would be the second
major goal of education.


Biophysical:

The neural firings should reduce to a low level after a correlation has
been formed.  Glutamate may increase learning.  Intelligence may be
viewed as the speed of habituation to a new stimulus complex.  Exposure
to new information increases the speed of habituation.

Intelligence:

All data experienced by a person are constantly reevaluated in light of
new random correlations.  Therefore intelligence or IQ can be increased
by more education or exposure.  A wise person may be the one who
possesses the most consistent correlations.  Machines are capable of
intelligent responses to controlled situations.  Procedures are
currently being explored to increase intelligent responses to
uncontrolled situations (Wang, 1994).

Defense Mechanisms:

Defense mechanisms may be viewed as learned neural correlated opponent-
processing used to keep a person in their comfort zone.  The neural
patterns would act as a filter to stimuli and actions.

Brain Damage:

Under normal conditions it is accepted that mature neurons do not
divide.  Correlational opponent-processing demands that neurons not
divide or connect up randomly.  Therefore this natural system restricts
repair through cell division and connection in the central nervous
system.

The correlational encoding of memories creates a quasi-holographic
template.  A laser produced hologram on a holographic 35mm. slide can
be destroyed with scissors yet a laser beam will still retrieve all the
stored information.  Human quasi-holographic memories would force the
brain to grow new nerve connections (not cell division) after brain
damage that would allow the old correlational memories to be expressed
or recovered.  This means that the brain should be very elastic and
capable of good recovery from tremendous damage.  Nerve growth factor
hormone and epidermal growth factor hormone may allow for rapid
reconnections and rebuilding of neural pathways for old correlated
memories.  The damaged areas currently are not 100% repaired because
cell division is blocked.

Creativity:

Everyone is creative to some degree.  COP theory stresses alertness to
new answers for old problems.  Creativity should be enhanced by playing
around with random connections of ideas.  Games like list as many ways
as possible that you can use a brick without duplicating usage may
enhance creativity.

Brain Tape:

If the quasi-holographic correlational opponent-processing theory is
correct, many will speculate on the possibility of using the brain's
biomagnetic currents to external stimuli to record peoples' memories in
another medium.  The Futurist (May-June 1992) suggested that
significant brain damage could be repaired by forcing the brain to
repair itself through the use of stimuli to create the identical brain
readings that were recorded before damage.  It was also suggested that
knowledge and experience transfer may be possible using the same
procedure.

While it may be possible to create global response potentials equal to
the global recorded potential of neural wiring at some future time, it
is unlikely to result in detailed actual memory transfer to oneself or
to others because it would violate the uncertainty principle.  A global
recorded potential could speed up learning, however.

Computer model:

If the model is correct then it might give insight into the building of
a computer that could duplicate the human mind.  A chip to do this
would be similar to a water pressure value that must be equal on both
sides to allow both sides of the feed lines (dendrites) to release
water from the main line (axon).  A more complete model may include
field effect transistors connected to charge coupling devices.  By
analogy, data output from a VCR camera may be similar to data output
from the mind.  The changes on the VCR tape may be thought of as blocks
or packets of information that can be recovered to see the recorded
images.  The computer model would require the constant effort to
compress the data stored on tape to smaller and smaller sets of
equations that could be used to recover all of the meaningful
information that has been encoded.  Since the brain is a confederacy of
many minds, these minds are negotiating issues, like a Delphi group, in
order to reach consensus or homeostasis.  Someday it may be possible to
transfer completely a person's memories to a computer.  As biological
existence ends as a possibility mankind may continue as memories in a
super computer.  Such memories may be transferable as a potential at
some future time
to others.

Conclusion:

Many systems in science behave as correlational opponent-processes.
This statement may be saying little or it could vector our
experimentation.  Only time will tell if it has any long range value,
since the history of science is one of correlational opponent-
processing or thesis, antithesis and synthesis.

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                   Acknowledgments

The following individual are recognized for their assistance, advice,
time, and encouragement.

Dr. Albert Ellis, Nils Hovik, Peter Karch, Robi Polikar, Margaret
McMenamin, Betty Yawney, Holly Morris, Wayne Nelson, Ralph Sell,
Richard Shollenberger, Althea Hatcher, Misha Beierlein, Heinz Beck,
Oliver Sparrow, Glen Appleby, Andrea Chen, Doug Craigen, Harry R.
Erwin, Leszek Balla, Christian Holscher, Sharon Allen, Marianne
Ciotti
*n*