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Patent No. 4902274
Multiple afferent sensory stimulation
device (Gleeson, III , Feb 20, 1990)
Abstract
An improved multiple afferent sensory stimulation device is provided to receive a prerecorded tape program upon which the audio stimulation and control signals for the visual stimulation of a subject person's eyes and ears is provided, the invention consisting of a reproducing device to emit the audio and visual control signals on separate channels, the audio stimulation proceeding to earphones worn by the subject person, and the visual stimulation control signals processed electronically. This electronic processing includes amplifiers receiving the electronic signals for amplification, means to convert the AC signals to stretched out positive pulses, and means to utilize the stretched pulses to turn on and turn off the visual stimulation components of the invention. Visual stimulation components utilized may be electrofluorescent lights or incandescent bulbs placed directly in front of the subject person's eyes. Various different schemes of audio and visual sensory stimulation are suggested for achieving a mental and physical affect upon the subject person.
Notes:
BACKGROUND
OF THE INVENTION
1. Field of the Invention
The field of the invention is devices which simultaneously provide visual and
audio stimulus to a person wearing a set of earphones and goggles with light
stimulus in the front of the goggles.
2. Description of Related Art
Researchers have discovered that through the use of visual and audio stimulus,
certain reactions may be induced into a person such as relaxation, altered states
of consciousness, and increase of the brain's functional intelligence. Such
an application of stimuli to a subject person and the reaction obtained is termed
"multiple afferent sensory stimulation" or MASS.
These effects are produced through different combinations of visual and audio
stimulus at different frequencies and in different rhythms. A total of four
separate stimuli are available for energizing, one for each eye and for each
ear, and such energizing may take many varied forms. The visual stimulus, if
considering only one single color entity, such as an incandescent lamp, may
have its brightness continually increased or decreased, may take the form of
pulsed brief flashes of light which in turn can vary in brightness, or may be
patterns over time or brillance formed with the pulses of light. For example,
the pulses could be evenly spaced and of the same time width for one lamp brightness,
or the lamp brightness could be increasing or decreasing by changing the pulse
duty cycle. Further, the visual stimulus for each eye need not be the same.
The mode of operation of the audio stimulus can have many of the characteristics
of the visual stimulus, such as pulsed tone, although, and perhaps preferably,
music or pink noise may be substituted for a tone or combination of tones. The
volume of the audio sounds can be increasing or decreasing, can consist of chopped
sounds which again may be increasing or decreasing in intensity, and the duty
cycle may be changed, i.e., the portion of the time that a sound is present
compared to one complete cycle of sound present and not present.
Again, each sound stimulus for each ear need not be the same either.
Machines varying the visual and audio stimulus discussed above have been developed
in the prior art.
It is reported that the human brain has basic frequencies at which it operates
and which have been observed by recording equipment such as an electroencephalograph
(EEG). These so called "brain waves" generally fall into four classifications
in accordance with their frequency rate, namely Beta, Alpha, Theta, and Delta.
Beta waves occur during a person's awake time and occupies a frequency spectrum
of between approximately 12 and 30 Hz. (cycles per second). Generally, the higher
the frequency, the more intense the mental activity. Alpha waves occur during
relaxation and during that twilight state just before sleep. Alpha waves occupy
the frequency spectrum of approximately 8 to 12 Hz. Theta waves represents the
frequency spectrum between 4 and 8 Hz and generally reflect brain activity during
sleep or deep meditation. Lastly, Delta waves occur during times of deepest
sleep and are generally in the range of 1 to 4 Hz.
It has been determined by researchers, such as Dr. George Corges, that a person's
brain can be persuaded to operate in any of these four frequency spectrums by
the application of visual and audio stimuli supplied in a desired frequency
spectrum. The person's brain activity tends to "synchronize" with the frequency
rate of the applied stimulus for certain defined stimulus.
By slaving the visual stimulus, such as repetitive blinking lights, with the
audio stimulus, such as repetitive tones, a person will soon find their brain
wave frequency, and thus mental activity, synchronizing to the applied visual
or audio stimulus.
Obviously, various alternating modes of applied stimulus are possible by alternating
between the left and right side eyes and ears in one or more of the sixteen
possible combinations from no stimulus present on all four receptors (left and
right eyes, left and right ears) to stimulus for all four receptors. In addition,
the pattern of the stimulus can be varied as eluded to above.
Of course, some combinations of stimulus will result in less reaction of the
person while other combinations of stimulus will result in a profound reaction.
Further, while it would be apparent that a scheme of application of structured
visual and audio stimulus to a person would produce the best or desired reaction,
yet it is possible to achieve desirable reactions by utilizing as the audio
stimulus what is commonly termed "pink noise", which is a variation of "white
noise". White noise is random electrical noise that exists in electronic circuits
due to electron shot and thermal noise defined as having constant energy per
unit band waves and independent of any central frequency of a band. The name
is taken from the analogous definition of white light, which is the combination
of light of all colors in the light spectrum. Pink noise is white noise having
the special characteristics that its intensity is inversely proportional to
its frequency over a specified range. In pink noise, equal power is dissipated
into a constant resistance in any octave band width in that range. Pink noise
when heard, can have a very soothing effect, much like the sounds of ocean surf.
All of the stimulus, both visual and audio, with its variations, can be pre-programmed
upon magnetic tape and then, through properly designed equipment, be presented
to a person to achieve the desired mental and physical effects.
Accordingly, it would be useful to have a device adapted to take information
pre-recorded on such a medium as magnetic tape, to decipher it through electronic
circuits, and deliver the resultant electronic signals to generators of visual
and audio stimulation surrounding a subject person.
SUMMARY OF THE INVENTION
The invention relates to an improved multiple afferent sensory stimulation device
receiving on prerecorded tape, a series of electronic signals which, after processing,
control the placement of visual or sound stimulus before a subjeCt person's
eyes and ears.
In the preferred embodiment, one tape recorder with four playback heads is utilized
with a prerecorded four channel tape. Upon two of the channels of the tape are
recorded the audio signals such as pink noise or music which are to be heard
by the subject, one channel for the left ear and a second channel for the right
ear. One audio channel does not necessarily have the same recorded program as
the other, although it may. The other two channels of the prerecorded tape contain
the electrical control signals which regulate the visual stimulus presented
to each of the subject's eyes, one channel for the left eye and one channel
for the right eye.
In an alternate embodiment, two tape recorders with two separate prerecorded
tapes are utilized, one tape recorder presenting the two audio channel outputs
and the other tape recorder presenting the two electrical control signal outputs.
If desired, the two tape recorders may be slaved to each other so that the audio
portion is in synchronization with the visual stimulation control signals or,
if pink noise is recorded on the two audio channels of the prerecorded tape,
it may not be necessary or desirable to synchronize the prerecorded tapes. This
would most likely be the situation for a relaxation mode where the sound of
surf is to be played in the earphones while a relaxing pattern of visual stimulus
is presented in accordance with control signals on the prerecorded tape.
The electronic circuitry which receives the electrical output of each channel
of visual stimulation control signals from the tape recorder is identical to
the other channel and, the electronic circuitry receiving the electrical output
from the tape recorder for each audio channel connected to the left and right
headsets is also identical.
The visual stimulation electrical control signals eminating from the first and
second output channels on the tape recorder or playback device are first directed
to a visual processing circuit means having firstly a buffer amplifier receiving
the AC component of the signal after it has been DC isolated from the tape recorder
and a fixed DC bias added at its entrance to the buffer operational amplifier
input. The buffer amplifier is in a feedback mode to regulate gain in order
that a sufficiently large signal is available for processing. The electrical
control signals, as received from the tape recorder channels, nominally comprises
2 kHz sine wave bursts of signal upon each line.
The output of the buffer amplifier, normally 6 volts peak to peak, is directed
to a second DC isolation capacitor and then the negative going portion of the
signal below approximately zero volts DC is shunted to ground through a negative
clamping diode. The positive going portions of the 2 kHz signal burst passes
a forward biased rectifying diode which acts much like a half-wave rectifier
to charge a capacitor in a pulse stretching circuit to form a positive pulse
having a width equal to the total number of positive going sine wave portions
in the 2 kHz burst of control signal. Amplitude of the resultant signal is approximately
5 volts relative to ground.
The control signal, now looking somewhat like the positive portion of a square
wave or elongated pulse, is directed to the gate of a turn on-turn off field
effect transistor which turns on hard upon receipt of the signal and stays on
throughout the duration of the signal. The drain of the field effect transistor
is then directed to the visual display circuit. In the event an incandescent
light bulb is utilized, the 9 volt power source is directed through the light
bulb and through the FET drain to its source and onto ground. If an electrofluorescent
light is utilized, the 9 volt source is fed to one side of a DC/AC power inverter
with the output of the power inverter directed to the field effect transistor
drain with the FET's source grounded.
The visual stimulation means is placed in front of the subject person's eye,
usually taking the form of being encapsulated in the eye lenses of a pair of
goggles. When utilizing an incandescent bulb, the lenses of the goggles are
opaque and may be termed blinders. The bulb is placed immediately inside each
blinder in order that the subject person see nothing except light emitted from
the bulb. In the case utilizing the electrofluorescent lights, the electrofluorescent
lights are the blinders, and the output of the previously described DC/AC power
inverter is directed to these blinders and application of voltage turns the
electrofluorescent lights on. During the absence of the control signal, the
electrofluorescent lights darken and the subject person sees the dark blinder,
i.e., no light at all.
An audio circuit means consisting of an earphone receives the audio stimulation
signals from the playback device's third and fourth outputs to supply the audio
stimulation to the subject person.
It is an object of the subject invention to provide a device for processing
signals from prerecorded tapes to provide multiple afferent sensory stimulation
of the auditory and visual senses.
It is another object of the subject invention to provide a multiple afferent
sensory device which processes auditory and visual stimuli for separate audio
and visual stimulus.
It is another object of the subject invention to provide a multiple afferent
device which receives encoded signals from prerecorded tapes so that the auditory
and visual stimulation devices may be separately controlled.
Other objects of the invention will in part be obvious and will in part appear
hereinafter. The invention accordingly comprises the apparatus comprising the
construction, combination of elements, and arrangement of parts which are exemplified
in the following detailed disclosure and the scope of the invention which will
be indicated in the claims.
BRIEF DESCRIPTION OF THE DRAWINGS
For further understanding of the nature and objects of the subject invention,
reference should be had to the following detailed description taken in connection
with the accompanying drawings wherein:
FIG. 1 is a schematic diagram of the subject invention;
FIG. 2 is a partial schematic diagram of an alternate embodiment of the subject
invention; and
FIG. 3 is a front view of a subject person wearing the earphones and goggles
receiving the audio and the visual stimuli.
In various views, like index numbers refer to like elements.
DETAILED DESCRIPTION OF THE PREFERRED
EMBODIMENT
Referring firstly to FIG. 1, a complete schematic diagram is shown of the invention
which permits sensory stimulation of the visual and audio senses of a subject
person, the stimulus in each of the subject person's ears or eyes capable of
being provided separately or together in all conceivable combinations. For example,
one ear could be stimulated with sound without stimulating the other ear or
visually stimulating either of the left or right eyes. The possible combination
from no stimulus to any stimulus receptor (eyes or ears) to all four receptors
receiving stimulus is 16.
Further, the combinations of stimulation is further increased because the light
stimulation can be in combination of different brightnesses, or its brightness
may be varied, either becoming more bright, or going less bright. Similarly,
the audio stimulation can be at any volume, from very soft to very loud, or
like the visual stimuli, may be increasing in volume or may be decreasing in
volume. Further, both the audio and the visual stimulus can be pulsed in innumerable
combinations. It is apparent that there is practically an unlimited number of
combinations in which the four sensory organs may be stimulated.
Such sensory stimulation is accomplished by the circuit shown in FIG. 1. Proceeding
from the top left to right, at the far upper left is the playback device 12
such as a magnetic tape playback recorder or other machine which utilizes a
prerecorded four channel tape with encoded data on two channels and audio on
two channels, the visual stimulation control electrical signals emitted on the
first two channel outputs, a left or first channel output 1 and a right or second
channel output 2 and the audio stimulation signals emitted on the second two
channel outputs, namely left or third channel output 3 and right or fourth channel
output 4. The tape has been pre-programmed with the desired visual control signals,
comprising a 2 kHz sine wave which may consist of bursts of signal which in
itself may be repeating, such as at a 10 cycle rate, or the 2 kHz sine wave
may be continuous for relatively long periods of time.
Any DC component on the output electrical control signal of channel 1 of playback
recorder 12 is directed to the visual processing circuit means and firstly isolates
the inventive circuit by first DC isolation capacitor C2 and thus only the AC
component of the signal is passed. Thereafter, the output signal of channel
1 is dc biased by means of connection to the common point of a voltage divider
network made up of resistors R2 and R13, the other end of resistor R2 attached
to the source of DC power with the other end of resistor R13 grounded. The AC
signal received from channel 1, now raised above zero volts by its fixed DC
bias, an amount of approximately a positive 4.5 volts, is fed into the positive
input of buffer operational amplifier A1. Buffer amplifier A1 is connected in
a feedback mode with its gain set by the ratio of resistor R8 over R7. A gain
of about 10 is desired. Further, the negative input to buffer amplifier A1 is
also grounded through resistor R7 and capacitor C5 which provides a DC reference
voltage of about 4.5 volts.
The output of buffer amplifier A1 consists of a 2 kHz sine wave having an amplitude
of about 6 volts peak-to-peak. The output signal is then DC isolated from the
remainder of the circuitry by in-line second DC isolation capacitor C9. Resistor
R5 connected to capacitor C9 is grounded and provides an essentially constant
load to the output of buffer amplifier A1 in order that the voltage at the junction
of capacitor C9 and resistor R5 will approach ground when no input signal is
present at the input to buffer amplifier A1. The signal is negatively clipped
by reverse biased negative grounding diode CR6 which grounds all negative portions
of the signal greater than the drop across the diode, nominally 0.6 volts or
so.
Continuing, the output signal from channel 1, which is now substantially all
positive going and consisting of the positive wave forms of the sine wave, now
passes through forward biased rectifying diode CR7 (acting like a half-wave
rectifier) to the pulse stretching circuit to charge capacitor C10, one lead
of capacitor C10 being grounded. At this point, the gap or space between the
positive going portions of the sine wave are filled in by the charge stored
previously on capacitor C10, which charge is also slowly being continuously
drained by bleed resistor R9 to ground. The net effect is that the signal at
this point has been changed from a sine wave to a positive going elongated pulse
having a width as wide as the number of sine wave cycles contained in the burst
of the two kHz electrical control signal. When the control signal amplitude
goes to zero, capacitor C10 will then start to drain through resistor R9 to
form the falling or trailing edge of the positive going pulse.
The signal at this point is fed to the gate of Q1, a turn off-turn on field
effect transistor (FET), to control the current through the transistor. The
FET is a very high input impedance device and accordingly draws extremely little
gate current from the signal. Upon Q1 being triggered, it closes the circuit
between its drain and its source, the source being grounded. The drain of the
FET is operably connected to the positive DC voltage which is the power supply
voltage for the invention, nominally 9 volts DC.
In the visual display circuit means, when the visual stimulus control signals
are to operate electrofluorescent lights placed immediately in front the subject
person's eyes working as blinders in a pair of goggles, power inverter T1 is
utilized with the electrofluorescent lights. In the embodiment shown in FIG.
1, the input voltage to power inverter T1 is connected between the drain of
the transistor Q1 and the DC power supply, nominally 9 volts.
The electrofluorescent light is shown by the circle and nomenclature LEC1 in
FIG. 1 and is caused to fluoresce by an AC current of nominally 110 volts. Accordingly
then, power inverter T1, which is a commercially packaged unit, is a DC to AC
power convertor stepping up 9 volt DC to 110 volt AC at a frequency of 400 hKz.
For a continuously operating electrofluorescent light, an alternating current,
preferably at 400 hz, is supplied by power inverter T1. To provide such a source
of continuous alternating current from T1, the burst of 2 kHz cycle programmed
on the prerecorded tape and appearing on channel 1 would need be continuous.
Then, when it is desired in the operation of the device that the electrofluorescent
light LEC1 should not fluoresce, the control signal is absent from channel 1.
Obviously, pulsing of electrofluorescent light LEC1 is accomplished by pulsing
bursts of electrical control signals.
The components and connecting of circuitry shown in FIG. 1 which receive the
electrical control signal from channel 2 of playback device 12 is identical
to channel 1 and the circuitry similarly operates. Accordingly, discussion of
this circuit would be the same as the above discussion of the circuit receiving
the signal from channel 1 and for that reason is omitted.
An alternate embodiment of the invention is shown in FIG. 2 where the power
inverters T1 and T2 and the electrofluorescent lights LEC1 and LEC2 of the visual
display circuit means have been removed and incandescent bulbs or lights 23
and 25 respectively substituted. So long as current is flowing through the field
effect transistors Q1 and Q2, incandescent bulbs 23 and 25 will light. Alternately,
pulsed signals may power bulbs 23 and 25 if desired. Further, brightness or
dimness of the bulb may be controlled by pulsed electrical control signals having
a repitition rate above the eye's discerning level but having a duty cycle such
that the amount of time that current is flowing through the filament of the
bulb is varied to achieve the desired resultant effect.
The balance of the schematic in FIG. 1 not previously discussed concerns the
audio stimulation signals outputted from playback device 12, namely through
output channels 3 and 4. These channels output audio sounds pre-programmed upon
the third and fourth channels of the prerecorded tape to the audio circuit means
consisting of a left and right headset earphone worn by the subject person.
In FIG. 1, the output from channel 3 is directed to the left earphone 26, and
the output of channel 4 from playback device 12 is directed to the right earphone
28.
Referring now to FIG. 3, a front view of a subject person utilizing the apparatus
of the invention is detailed. Firstly, left and right earphones 26 and 28 respectively
of headset 30 are shown mounted upon the head of the subject person 32. The
headset is preferably spring loaded in the band connected to the two earphones
so as to hold each earphone to the ear, each earphone utilizing elastic cushions
13 and 15 situated between the earphone and the ear so as to provide comfort
to the subject person and to keep out extraneous sounds from interfering with
the programmed audio sounds heard by the subject person 32. Situated proximate
each of the subject person's eyes are a pair of goggles 34 which contain individual
opaque blinders, left opaque blinder 36 and right opaque blinder 38, each separated
from the other and light protected in order that no outside light enter the
subject person's eyes.
In the preferred embodiment, left opaque blinder 36 and right opaque blinder
38 comprise the electrofluorescent lights LEC1 and LEC2 respectively. These
lights, which are shaped as lenses for placement in a pair of goggles, are dark
when not being excited by an AC electrical signal. In the alternative, opaque
blinders 36 and 38 may have attached to them bulbs 23 and 25 respecitvely wherein
the portion of the bulb containing the filament protrudes through the opaque
blinders so that the light emitted from the bulb may be seen by the subject
person. The bulbs are light sealed around the blinders.
Thus, the subject person 32 shown in the diagram of FIG. 3 has two inputs of
audio stimulation and two inputs of visual stimulation, each separated from
the other and each capable of being separately energized with an appropriate
sound or control signal.
Since, as mentioned above, the visual stimuli presented can be either a very
soft, dim light, or a very bright light, or a light increasing in brightness
or a light decreasing in brightness, together with the light on or off with
respect to real time, i.e., a series of light pulses over time in a coded group
of light pulses, or as a continuous light, the visual stimulation obtained is
an average of the actual number of pulses present to energize the light. A series
of closely spaced pulses having a repetition greater than 60 Hz powering a lamp,
for example, would appear to the subject person as a light constantly on. Similarly,
if the on pulses are initially widely separated and then become closer spaced
and are at a repetition rate greater than 60 Hz, the light will appear to a
subject person as increasing in brightness. Certainly the inverse is true, from
pulses which are closely spaced to pulses which are spaced further apart with
respect to time will cause the light to appear to have reduced its intensity
over a period of time. If the light utilized is an incandescent bulb, it will
take some period of time before the blub emits light from the time that the
electrical pulse is received as the filament must heat up to the point of becoming
incandescent. Plus, in the case of incandescent lights, the filament tends to
stay hot and emit light for a period after the pulse has passed. Thus, the incandescent
bulbs may be made to have its light energy waning, or increasing, or pulsing,
when all that is happening is the spacing of strings of electrical pulses.
Further, it is obvious that light emitting diodes (LED's) may be used in place
of incandescent bulbs or electrofluorescent lights with modifications of the
electronic circuitry all within the current state of the art.
Obviously then, a pulse width modulation can be used as the procedure for producing
the visual stimuli control pulses.
In the preferred embodiment, the elements described in FIG. 1 comprise the following
commercially available electronic circuits: amplifiers A1 and A2 are National
Semiconductor LM741; transistors Q1 and Q2 are field effect transistors VN0610L
manufactured by Siliconix, all diodes are 1N3600, and left and right electrofluorescent
lights LEC1 and LEC2 are electroluminescent lights 0434 manufactured by Loctite
Luminescent Systems, Inc. Lastly, power inverters T1 and T2 are Model No. BKL09-3-1
manufactured by ERG Inc.
TABLE I. ______________________________________ Resistors Capacitors Ohms uf
______________________________________ R2 100k C2 10 R4 100k C3 10 R5 3k C5
10 R7 10k C6 10 R8 100k C9 1 R9 5k C10 10 R10 10k C11 1 R11 100k C12 10 R12
5k R13 100k R16 3k R18 100k ______________________________________
While a preferred embodiment and three
alternate embodiments have been shown and described, it will be understood that
there is no intent to limit the invention by such disclosure, but rather it
is intended to cover all modifications and alternate constructions falling within
the spirit and the scope of the invention as defined in the appended claims.