Anatoly AKIMOV : Torsion Field Generators -- Rejuvenation,
improved germination, & structural changes in metal; articles
& patents


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**Anatoly AKIMOV**  
  
**Torsion Field Generators**


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[**YouTube : Akimov Lecture**](#youtube)[**Inst. of Quantum Genetics :
Rejuvenation**](#Rejuvenation)[**RU2008111912 : The method of
the uncontacted control of the ripple effects on the
body's age characteristics...**](#RU2008111912)[**Akimov, et al. : Models of polarized
states of the physical vacuum and torsion fields**](#Models)[**Inoan, et al. : Influence of
torsion field on arabidopsis thaliana seeds germination**](#arabidopsis)[**Akimov Torsion
Field Generator**](#AkimovTorsionFieldGenerator)[**US6549805 : Torsion Diagnostic
System...**](#US6549805)[**RU2151204 : Steel Structural
Characteristics Correction Method**](#RU2151204)[**RU2107105 : Method of Correction
of Microstructure of metal Casting Alloys**](#RU2107105)[**SU1748662 : Method of Correction
of Structural Characteristics of material and Device
Thereof**](#SU1748662)[**US20070287881 : Destressing
system, apparatus, and method therefor**](#US20070287881_)

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[**https://www.youtube.com/watch?v=7LYsVXLRLJY**](https://www.youtube.com/watch?v=7LYsVXLRLJY)  
Lecture of brilliant Russian scholar, academician of the ACADEMY
of NATURAL SCIENCES, Akimova A.e., in which he talks about the
torsion fields.  
  
Akimov A. E. studied models of physical vacuum, applied problems
of torsion fields and technologies on new physical principles.  
  


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[**http://wavegenetics.org/en/portfolio-view/akimov-torsionnyie-polya/**](http://wavegenetics.org/en/portfolio-view/akimov-torsionnyie-polya/)

**INSTITUTE OF QUANTUM GENETICS**

+7 (925) 022-67-37  

**Rejuvenation**

   
All want to quickly become young. But do not forget, the process
of rejuvenation, running the programme us the spectra of the
placenta, the cord blood of   
newborns and children's photo,  
  
THERE CAN BE NO FASTER AGEING PROCESS.  
  
Although this phenomenon is not linear, and there are exceptions
...  
  
So, We've had three patients about 60 and for the 70 years. They
returned the menstrual cycle after a year of use-matrices by their
children's photo. A month is a clear marker for the young State of
the organism.  
  
Another important point: I often write, for example a listening to
already 10 days, and there is no effect. A>>. Answer. Our methods
are not the magic wand magic wand and not apples from children's
fairy tales-waved, ate and order. Was young and beautiful. No,
This long work with faith and positive attitude.   
  
Lying on the couch, nothing will. Quick positive effects are.
Rare, but there are also. In extreme conditions of patients. In
the final stages of cancer 4th degree. Or a hemorrhage in the
brain, coupled with paralysis.  
  
Our research and practice of the application of the principles of
Lingvistiko-wave Genetics are in line with the priority work of
molecular biology and genetics, Russian Academy of Sciences. See.
video: Meeting of the Council for science and education,
20.12.2013.. Moreover, our results in this area substantially
ahead of all the, that is received in the "classical" Genetics so
far. No one in the world is not yet able to program stem cells,
Since the methods used are based on an understanding of genes as a
purely physical structures. And this is the error. Genes can
function at a level of physical fields, as the quantum equivalent
of ourselves. It predicted at the beginning of the last century
our scientist A.g. Gurvich. We have confirmed this hypothesis and
use wave genes in practice, treatment, inhibition of aging and
rejuvenate people.  
  
All matrices are unique because you are individual order.  
  


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**RU2008111912**  
**The method of the uncontacted control of the ripple effects
on the body's age characteristics (halting aging and
longevity) and the device for its enjoyment  
[ [PDF](RU2008111912.pdf) ]**

  
The method of contactless control of the wave action on the
inhibition of aging and prolongation of the life of the organism,
regeneration of organs and tissues by modulation by the donor of
laser electromagnetic radiation and SHEI carrying metabolic
information with the subsequent introduction of this information
into the body, leading to corrective changes in its metabolism. !!
2. Method according to claim 1, characterized in that the acceptor
(s) is placed at different distances both on the beam axis and
outside it for receiving the control genetic-metabolic information
from the donor (s). 3. The method according to claim 1,
characterized in that the exposure of the scavenger (s) is
performed by the SHEI, which is modulated by the donor (s) to
alter the acceptor (s) metabolism, resulting in organ regeneration
and inhibition of aging. 4. A device including a donor (s) on the
optical axis of the laser radiation, characterized in that the
electromagnetic radiation of the laser is modulated by the wave
information program of the donor (s) when radiation is directed
through it to the perceived organism or its organ.  
  
5. The device according to claim 4, characterized in that the wave
information program of the donor (s) is automatically formed by
complex modulated electromagnetic signals - carriers of
genetic-metabolic information of laser and information-related
SHEI. 6. The device of claim 4, characterized in that a donor (s)
is placed on the axis of laser radiation from a helium-neon laser
between two plane-parallel glasses. 7. The device according to
claim 4, characterized in that it reflects a portion of the laser
beam that has passed through the donor and is modulated in a
complicated manner, is returned back to the laser cavity. 


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 **<https://link.springer.com/article/10.1007/BF00895770>DOI: 10.1007/BF00895770  
Russian Physics Journal, March 1992, Volume 35, Issue 3, pp
214a222**

**Models of polarized states of the physical
vacuum and torsion fields**  
**A. E. AkimovV. Ya. Tarasenko**

 **Abstract**A model is proposed of the physical vacuum, taking into
account the existence of fields generated by classical spins or
angular momenta of rotation.  



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[**http://journals.usamvcluj.ro/index.php/agricultura/article/download/10248/8664**](http://journals.usamvcluj.ro/index.php/agricultura/article/download/10248/8664)**Agricultura a Stiinta si practica no. 1-
2(89-90)/2014 Agriculture - Science and Practice**  

**Influence of torsion field
on arabidopsis thaliana seeds germination**  

****Inoan Simona Laura, H. Criveanu****

  
University of Agricultural Sciences and Veterinary Medicine,
Faculty of Horticulture  
400372, 3-5 Manastur Street, Cluj-Napoca, Romania;
laurainoan@yahoo.com  
  
**Abstract.**   
Arabidopsis thaliana seeds were exposed to left and right
torsion field for 30, 60 and 90 minutes. The field was
generated using the Comfort-7, a device that besides axial and
radial components of axion field has also an azimuth
component. After exposure the seeds were evaluated for energy
and capacity of germination. Comparing the results obtained
for seeds exposed to left and right torsion field and
unexposed seeds, the influence of torsion fields improved the
energy of germination by an overall difference of 36.6% and
39.33%. For the seeds exposed to left torsion field, the
higher the time of exposure, the greater results were
obtained; the energy of germination increased by 14% at 60
minutes and 28.33% for 90 minutes exposure comparing to the 30
minutes variant.  
  
**INTRODUCTION**  
Torsion field theory is rooted in the discoveries and ideas
formulated by Einstein's colleague, Eli Cartan, who in 1913
first used the term torsion force referring to its twisting
motion, at the same time establishing clearly the momentum
density spin angular fields generated concept (Akimov A.E.,
1997). As the electromagnetic field is produced by electric
charge and the gravitational field by mass, rotation or spin
of a mass generates torsion field. All these fields have
effects on long distances. The term torsion may be defined as
a variable which describes the rotation. Torsion field theory
supporters scientists confirms that the interaction of spin -
spin can be transmitted by, or through space like
electromagnetic waves, except, however, that this does not
possess energy and mass but only information. There are
generators of torsion fields, electrical installations, the
use of which allows us to modify the properties of material
objects, such as liquids, metals and alloys. Explaining the
nature of the torsion field, scientists have concluded that
depending on the direction of rotation the torsion fields can
be right or left. They have shown also that the right fields
are beneficial to humans because they improve the fluidity of
all environments, increase the conductivity of cell membranes
and by increasing the fluidity they reduce the chance of blood
clots, there is an improvement of metabolic processes, an
improvement of human overall homeostasis (www.torser.com). In
turn, the left fields have deleterious influence on humans.
What is interesting is that just left torsion fields
predominate if not all, then most electronic devices around
us. Starting from this point, the main purpose of the carried
out research was to check if torsion field action can affect
the germination of Arabidopsis thaliana seeds.  
  
Arabidopsis thaliana is an annual plant belonging to
Brassicaceae family and a very common plant used for research
in plant biology and genetics. The small genome, completely
sequenced, makes it a model organism and generated a series of
large scale Agricultura a Stiinta si practica no. 1-
2(89-90)/2014 Agriculture - Science and Practice projects
aimed at discovering the functions of the 25.000 genes
identified in Arabidopsis thaliana (Bevan and Walsh, 2005).  
  
**MATERIAL AND METHOD**  
The research was carried out on Col-0 line Arabidopsis
thaliana seeds received from the Institute for Plant Biology
Szeged, Hungary. To generate torsion field, Comfort-7 was
used, a device that has both axial and radial components of
the axion field and an azimuth component. The device consists
of four sections: the power supply, where a variable
alternating current voltage is applied, two stator sections
and a pulsed relay section (www.ussdiscovery.com). Spin field
generator is shown in Fig.1 and consists of a rotating ferrite
hollow cylinder (1) whose axis of rotation (3) coincides with
the main axis of symmetry of the cylinder. In the cylinder are
inserted, in the form of an oblique comb, four permanent
magnets (2). The cylinder can be in the form of either a flat
ring or a tube. Seeds were arranged in variants, each variant
with three replications of 100 seeds.  
  
The variants were exposed to left and right torsion field
action and another one remained unexposed representing the
control variant. For each torsion field three exposure times
were studied, T1 = 30 minutes, T2 = 60 minutes and T3 = 90
minutes, in order to determine whether the duration of
exposure to the torsion field action has an influence on seeds
germination and on the future plant growth. After the
Arabidopsis thaliana seeds were exposed to the torsion filed
produced by Comfort-7 generator, they were placed in Linhardt
type germination dishes to determine the germination capacity
and energy of germination (Fig. 2).  
  
During the entire germination process conditions of humidity,
light intensity and temperature were stable and favorable to
the process, with 30% relative humidity and 23 0 C.  
  
**RESULTS AND DISCUSSION**  
The first seeds began to germinate at two days after their
placing into germination dishes and until the sixth day the
maximum percentage of seeds were germinated for all 
variants. The energy of germination (%) varied from one
variant to another based on the Fig. 2 Linhardt type
germination dish with  
Arabidopsis thaliana seeds (original)   
  
**Fig.1 The diagram for the spin-field generator (source
www.spinfield.idhost.kz -Alexander A. Shpilman)**

![akimov torsion
              field generator](10248a.JPG)

  
Science and Practice torsion field type action on which they
have been subjected to and depending of the time of exposure
(Table 1).  
  
**Table 1****Torsion field effect on the average energy of
germination (%) of Arabidopsis thaliana seeds**

**![table1](10248t1.JPG)**

  
Using analysis of variance for the processing and
interpretation of statistical data obtained after germination,
the following results were drawn relevant:  
To highlight the differences regarding the speed of
germination, between seeds exposed to the torsion field action
and witness seeds, comparison of the results of the three
variants was performed. The influence of torsion field factor
on the start of seeds germination was one positively
stimulating. Between variants represented by the seeds that
were not exposed to torsion field (C1), considered the control
version, and seeds subjected to the action of left torsion
field (C2) and right torsion field (C3), there were extremely
significant difference according to Duncan significance test
(Table 2).  
  
**Table 2****Influence of torsion field factor on germination
process** 

**![table2](10248t2.JPG)**

  
In the case of left torsion field, exposure time has a direct
effect on the speed of germination. The difference between the
first exposure time T1 = 30 minutes considered as witness in
this comparison, and exposure time T2 = 60 minutes, the
difference is highly significant. Extremely significant
difference was observed between T1 and T3 = 90 minutes (Table
3).  
  
**Table 3****Exposure time influence on seeds exposed to left
torsion field action**

![table3](10248t3.JPG)

  
**CONCLUSIONS**  
The effect of torsion fields proved to be stimulating for the
germination process of Arabidopsis thaliana seeds and can be
successfully used in the future to improve this process.  
  
The seeds under the influence of torsion fields, both left and
right, had an increased energy of germination comparing to the
unexposed seeds, the improved germination ranged between 29
and 55% based on time of exposure.  
  
For the seeds exposed to left torsion field, the time of
exposure was an effective factor to the improvement of
germination the differences increased along with time exposure
and they were very significant, according to the results of
statistical calculations performed.  
  
**REFERENCES**  
1. Akimov, A.E., G.I. Shipov. (1997). Torsion Fields and Their
Experimental Manifestation. New Energy News, pp.11-14.  
2. Bevan, M., Walsh, S. (2005). The Arabidopsis Genome: A
foundation for plant research. Cold Spring Harbor Laboratory
Press, New York.  
3.
http://www.torser.com/en/scientific\_base/torsion\_fields/torsion\_fields\_base\_Univers/default.aspx,
Accessed April 25, 2014.  
4. http://www.ussdiscovery.com/torsion\_field\_generator.htm
Accesed April 30, 2014;  
5. http://spinfield.idhost.kz/ALMANACH/N3\_95/S4\_1a.htm,
Accessed April 30, 2014.

  


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[**http://www.hologrammatrix.com**](http://www.hologrammatrix.com)

**Akimov Torsion
Field Generator**

  
The Akimov generator using own radiator removes the membrane
between parallel worlds and opens the portals to the parallel
worlds. The portal remains active for several days after turning
off the generator.  The portal parameters depend on the
frequency spectrum supplied to the radiator. If two Akimov
generators with the same spectra are switched on in various places
this has to make a teleportation tunnel through which radio waves
can pass in both directions.  
   
The Akimov torsion generator generates left or right torsion
field, modulated by various signals. It is possible to use this
generator in various spheres such as information transfer, room
cleaning, the changes of metals properties, charging of water and
others.  
  

![Akimov torsion field generator1](akimovelectrotorsiongener.JPG)  
  
![Akimov torsion field generator2](akimovmp3.JPG)  
  
![Akimov torsion field generator3](wave2ak.PNG)

  
**Maintenance manual (extract).**  
   
The generator has two connectors. One of them is used for
operating voltage (12V DC) supplied from power supply or battery.
The second one is for the signal input from the signal generator
or mp3 player with the sound recorded.   
  
The Akimov generator begins to receive the signal started about 1
V range. The sound signal supplied to the circuit of the torsion
generator amplifies up to the supply voltage and then transfers to
the radiation source. The radiator is made as a conical condenser
which is made using a copper conductor, wound in a spiral. This
construction allows turning of the magnetic field of the coil
perpendicularly to the magnetic field of the magnet which is
located in front of the radiator.  
  
There are two switches of the generator.  
  
The first is for switching on and switching on the generator. The
second one is for changing of the polarity of the torsion field,
so the generator creates right or left torsion field.  
  
Applications: water charging, influence upon plants, mineral
products searching, the torsion field connection investigations.   
  
After using the generator it is necessary to make a depolarization
of the environment where it is located.  
  
A phantom remains for a long time after operating of the generator
so it is necessary to switch on the device into the opposite
polarity mode to deactivate the phantom presence.  
  
The supply of the generator must be positive in the center of the
plug; the negative part of supply must be located on the cabinet
of the generator.  
  


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**US6549805**  
**THE TORSION DIAGNOSTIC SYSTEM UTILIZING NONINVASIVE
BIOFEEDBACK SIGNALS BETWEEN THE OPERATOR, THE PATIENT AND THE
CENTRAL PROCESSING AND TELEMETRY UNIT**

  
A biofeedback diagnostic system includes a central processing and
telemetry unit and a triggering sensor. The central processing
unit in turn includes a situation-generating block for producing a
series of stimuli and transmitting them in parallel to both a
patient and an operator of the system via a dual peripheral
device. The stimuli can be of magnetic, audio, visual, or other
nature. The triggering sensor is designed to remotely acquire the
patient's feedback to the transmitted stimuli and send a digital
signal back to the central unit. Two biofeedback loops are formed:
between the central unit, the patient, and the triggering sensor;
and between the central unit, the patient, and the operator, who
is interpreting the test results without involving the conscious
reaction of the patient.; The triggering sensor includes a noise
generator to detect the patient's brainwaves and a detector
channel equipped with a logoperiodic multi-turn spiral antenna to
further enhance its sensitivity. To improve the patient's
intuitive response, an optoelectronic element is placed of the
patient's forehead and illuminated with a laser light at a
frequency equal to that of the patient's brainwaves theta-rhythm.
To isolate the torsion component of the laser light, a cavity
resonator is employed with a volumetric chamber having a size
being some multiple of the transmission frequency of about 1.45
GHz.  
  
**[0028] FIG. 1 is a general block-diagram of the diagnostic
system of the present invention, and****[0029] FIG. 2 is a general block-diagram of the triggering
sensor of the diagnostic system.**

**![US6549805a](us2003069513a.JPG)![US6549805b](us2003069513b.JPG)**

  
**Interruptions**  
1  1.66  Dark Maroon  DO  
2  2.49  Red  RE  
3  3.32  Orange  MI  
4  4.15  Yellow  FA  
5  4.56  Green  FA-Dies  
6  4.98  Light Blue  SOL  
7  5.81  Blue  LA  
8  6.64  Violet  SI  
9  7.47  Dark Violet  DO  
  
[0047] Table 1 presents one example of various stimuli to be
generated by the CPT unit 10 of the diagnostic system of the
present invention. The moments in time when each stimuli sequence
begins are all coordinated with each other and with the initiation
of the triggering sensor and cadistor so that the operator and the
patient receive the stimuli and both loops of biofeedback are
formed.  
  


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**RU2151204****STEEL STRUCTURAL CHARACTERISTICS CORRECTION METHOD**

  
SUBSTANCE: method involves treating steel melt till solid
crystallization phase by torsion radiation of spectrum of at least
three characteristic frequencies. Such method may be used for
manufacture of cast parts, as well as for production of billets
which may be used for further conversions. EFFECT: wider range of
changes in physico-mechanical characteristics and improved
structure of steel.  
  
The invention relates to the field of metallurgy, in particular to
the production of steels (ferrous alloys based on iron with a
carbon content of not more than 2.14%), as well as alloy steels,
and can be used for the manufacture of both cast parts and for
casting blanks for Use in subsequent metallurgical operations.  
  
There are known the possibilities of correcting the structural
characteristics of various materials by exposing them to torsional
radiation at the characteristic frequency.  
  
Thus, a method is known for correcting the structural
characteristics of materials, including metals, including metal
treatment with torsion radiation at the characteristic frequency.  
  
The method allows to change the properties of metals in order to
obtain their given physicomechanical characteristics.  
  
In this method, the treatment of chemically pure non-ferrous
metals, such as, for example, tin or copper, is described as
examples. The treatment is performed by torsion radiation at one
separate characteristic frequency. For example, for copper after
treatment with torsion radiation with frequencies of 6 and 100 Hz,
the structure of the ingot shows an orderly microporosity, the
size of which varies with the characteristic frequency of the
torsion radiation source. It is not known from the indicated
technical solution about the possibility of changing the
structural characteristics of steel by the torsion field, as well
as the possibility of changing the physicomechanical
characteristics of materials due to the effect of torsion
radiation with several characteristic frequencies at the same
time. The design of the device intended for carrying out the
method, although it is capable of generating torsion radiation
with several frequencies, but this torsion source serves both for
the direct determination of the values ??of the characteristic
frequencies by their search, and for studying the structural
changes introduced into the materials under the action of the
torsion field on Identified individual characteristic frequencies.  
  
The closest technical solution is a method for correcting the
structural characteristics of steel, including processing the
steel melt until the formation of its solid crystallization phase
by torsion.  
  
In this method, a structural reorganization of the steel taken in
an amount of up to 200 kg was detected when it was exposed to
torsion radiation from a torsion generator consuming 10 mW of
electricity. However, the limitation of this method is the
insufficiently high range of changes in the physicomechanical
properties of steel.  
  
The problem solved by the invention is an increase in the range of
changes in the physico-mechanical properties of steel, and an
improvement in the structure of steel.  
  
The technical result that can be obtained by carrying out the
invention is to increase the strength, yield strength, elongation,
relative contraction, impact toughness by decreasing the relative
content of ferrite, increasing the dispersity and uniform
distribution of non-metallic inclusions, reducing the average
grain size and obtaining equilibrium Forms.  
  
In order to achieve the above-mentioned object with the attainment
of said technical result, in a known method for correcting the
structural characteristics of steel, including treating the steel
melt prior to the formation of its solid torsion-phase
crystallization phase, the melt processing of the steel is
performed by torsion radiation with a spectrum of at least three
Characteristic frequencies.  
  
Additional embodiments of the method are possible in which it is
expedient that: each of said characteristic frequencies be
suitably selected in one of the intervals: 1 Hz to 20 MHz and / or
20.1 MHz to 200 MHz and / or 200.1 MHz to 2 GHz And / or 2.1 GHz -
200 GHz; - at least two of these characteristic frequencies were
simultaneously selected in one of the intervals: 1 Hz-20 MHz or
20.1 MHz-200 MHz or 200.1 MHz-2 GHz or 2.1 GHz-200 GHz.  
  
Due to the effect of torsion radiation on the melt, which
simultaneously includes several characteristic frequencies in its
spectrum, it is possible to form a homogeneous structure and
certain grain sizes, which results in an improvement in the
complex of physicomechanical properties (strength, yield stress,
elongation, relative narrowing, Viscosity) of cast steel parts and
blanks used for further metallurgical operations.  
  
These advantages, as well as the features of the present
invention, are explained by the best embodiments of the method for
various steel grades.  
  
The figure shows the functional diagram of the stand for torsion
treatment of steel melt.  
  
As a result of the action of external torsion radiation on the
melt, the spin state of a system of free atoms in the melt
changes. In this state, atoms experience mutual attraction through
spin-torsion interactions. Due to this mutual attraction, the
melt, as a spin system, becomes internally stable. As a result,
the structure of the casting grains for steel after
crystallization becomes more uniform, the shape of the grains is
more balanced, and the non-metallic inclusions are evenly
distributed throughout the casting volume. Internal stability of
the ingot after crystallization leads to minimization or complete
absence of macrodefects (cracks, pores, etc.). All these results
combine to improve the mechanical properties of the steel, which
can be illustrated by the examples below.  
  
As studies have shown, in the case of steel processing, the use of
a mono-frequency in the torsion generator as a signal does not
lead to significant satisfactory results, since only one of any
melt components has a change in structure. Under the action of
mono-frequency or strengthen the influence on the overall
structure of the ingot of this component, or weaken. In addition,
in the melt there is a spread in the values ??of the natural
frequencies of the oscillations of atoms of one chemical element
or of the same type of molecules of chemical compounds, which is
associated with an uneven distribution of the energy of thermal
motion. As a result of the experiments it was established that the
achievement of a more efficient structure change during torsion
treatment of a melt is feasible in the case of applying a spectrum
of certain characteristic frequencies for a torsion generator.  
  
For the experiments, an induction melting unit UPI-0.5-3.0-440
produced by "Reltec", Ekaterinburg, consisting of an induction
melting furnace IPP-0.5 and a semiconductor frequency converter
PVG-3-440.  
  
Technical characteristics of the furnace IPP-0.5: Capacity of the
furnace 0,5 kg Power of the feeding converter 3 kW Power of the
furnace 2,7 kW Number of phases of the supply network 1 Number of
phases of the loop circuit 1 Frequency of the mains current 50 Hz
Current frequency of the loop 440 kHz Nominal voltage Power supply
220 V Rated voltage on the inductor 900 V For each steel grade, 10
control and prototypes weighing 0.15 kg were manufactured.
Castings after melting were heat treated (normalization at 920oC
and tempering). The chemical composition of steels 35 L, 45 L, 20
GFL and 20 GL is given in Table. 1.  
  
Mechanical tests were carried out on cylindrical samples, carved
from castings, obtained as a result of experimental and control
melting. The average values from the results of mechanical tests
of control and prototypes are given in the tables for each grade
of steel. In all experiments, the torsion beam device (source) was
located 1 m from the crucible of the induction furnace. The effect
of torsion radiation on the melt was carried out with
predetermined components of the line spectrum of the
characteristic frequencies prior to the start of casting, and this
treatment processed the melt. For example, one of the generators
described in [1] or [2] can be used as a source of torsion
radiation.  
  

![](ru2151204.JPG)

![RU2151204a](ru2151204a.JPG)  
  
![RU2151204b](ru2151204b.JPG)  
  
![RU2151204c](ru2151204c.JPG)  
  
![RU2151204d](ru2151204d.JPG)

  
Torsion radiation treatment was carried out in accordance with the
functional scheme of the stand for torsion treatment of steel melt
(Fig.1), where: 1 - torsion generator; 2 - radiating antenna of
the torsion generator; 3 - reference radio frequency generators
f1, f2, ..., fk; 4 - induction furnace; 5 - high-frequency block
of induction furnace; 6 - power supply network; 7 - inductor; 8 -
crucible.  
  
It is clear that, in contrast to the described functional scheme,
steel melt processing can also be performed by torsion radiation
from individual torsion generators 1 with its radiating antennas
2, with the radiation of each torsion generator 1 having its
reference frequency from its reference oscillator 3, and these
emissions in The same time is processed by the melt in the
crucible 8. However, such a functional scheme allows to obtain the
same technical result, but only complicates the design. In
addition, functional schemes are possible with the conversion of
the reference frequency, its multiplication or division, which
does not affect the essence of the claimed method. A feature of
the method is the treatment of a steel melt with torsion radiation
containing simultaneously at least three characteristic
frequencies from a wide frequency range.  
  
To achieve the required physicomechanical properties of the alloys
(Fig.1), the torsion radiation with a spectrum consisting
simultaneously of several characteristic frequencies from the
torsion generator 1 is applied to the melt in the period before
the change in its aggregate state. As a result of the action of
torsion radiation on the melt in the crucible 8, the spin
structure of the material changes, which leads to changes in the
material properties shown in Table. 2-5. Characteristic
frequencies are determined experimentally, for example, by
examining the entire frequency range and choosing from it those
characteristic frequencies that best satisfy the stated goal of
the experiment and the required properties of the steel. When a
pre-determined optimal spectrum of torsion frequencies is used,
the spin structure induced in the melt forms a stable system.
Torsion radiation creates torsion generator 1 and is formed due to
the supply of radio signals to it at frequencies {fl, f2, ..., fk}
from the reference generators 3 exciting certain characteristic
frequencies.  
  
The spectrum of characteristic impact frequencies for various
materials can theoretically be in a very wide range from 1 Hz to
200 GHz. The frequency spectrum is a characteristic parameter for
each steel. For steels of different brands, the corresponding
components of the characteristic frequencies of the entire
frequency spectrum are determined, which, according to studies,
can lie in the intervals: 1 interval: 1 Hz - 20 MHz; 2 interval:
20.1 MHz - 200 MHz; 3 interval: 200.1 MHz - 2 GHz; 4 interval: 2.1
GHz - 200 GHz, and in accordance with the specific purpose of
processing spectral components in some intervals may be absent.  
  
It is a feature of the present invention that torsional radiation
with certain characteristic frequencies in each individual
interval mentioned is selected for treating the melt of steel, and
practice shows that in most cases it is expedient to select a line
spectrum. In addition, studies have shown that a given correction
of steel parameters can be obtained when each of said
characteristic frequencies is suitably selected in one of the
intervals: 1 Hz to 20 MHz; 20.1 MHz - 200 MHz; 200.1 MHz - 2 GHz;
2.1 GHz - 200 GHz. Additionally, at least two of these
characteristic frequencies can be simultaneously selected in one
of the intervals: 1 Hz-20 MHz or 20.1 MHz-200 MHz or 200.1 MHz-2
GHz or 2.1 GHz-200 GHz.  
  
Characteristic frequencies for specific chemical compositions of
steels can lie, for example, on the edges of various frequency
bands of intervals, in addition, in a number of situations it is
necessary to form broadband noise rather than narrowband
characteristic frequencies on specific frequency bands of
intervals. For each particular impurity composition, the formation
of the structure at the grain level, for example, their grinding,
depends on the correct choice of the combination of the exposure
time and the spectrum of the characteristic frequencies. At the
same time, the changes in the crystal lattice depend mainly on the
spectrum of the characteristic frequencies and, to a lesser
extent, on the time of the action.  
  
In particular, torsion radiation with characteristic frequencies
of 10.5 Hz, 3 MHz, 50 MHz, 400 MHz, 1.3 GHz, and 20 GHz was used
to treat the melt of 35 L steel and 45 L steel.  
  
The duration of the torsion action on the melt is determined by
the requirements for the parameters of the resulting metal and can
range from 1 millisecond to 1 hour. In this case, the lower bound
of the exposure time is determined by the minimum required
specific (per unit volume) spin melt polarization (polarization
with respect to the classical spin). The maximum time of the
exposure interval is determined by saturation in the spin
polarization of the composition of the entire volume of the
material.  
  
As shown by practical studies, when choosing frequencies from the
frequency interval of less than 1 Hz, there is no significant
change in the physico-mechanical properties of the steels. In
turn, the use of frequencies from an interval above 200 GHz is
economically impractical.  
  
As a result of the experiments, samples with structural and
mechanical characteristics were obtained: Experiment 1.  
  
Steel 35 L (see Table. 2).  
Experience 2.  
  
Steel 45 L (see Table. 3).  
Experience 3.  
  
Steel 20 HFP (see Table. 4) Experience 4.  
  
Steel 20 GL (see Table. 5).  
  
As a result of the treatment of melts with torsional radiation
simultaneously with several characteristic frequencies, the
following main results were obtained: for steel 45, an increase in
the yield stress st by 10.2%, a time limit of s s of 8.3%, grain
size decreased by 1 point, cementite from lamellar became
granular-lamellar; For steel 35 L - experiment 1: an increase in
the yield stress st by 7.9%, a time limit of ss in 4.8%, the grain
size decreased by 1 point, cementite from the lamellar became
granular-lamellar; Experiment 2: an increase in the yield stress
st by 13.7%, a time limit of s s of 10.6%, the grain size
decreased by 2 points, the cementite from the lamellar became
granular-lamellar; For steel 20 HFL, an increase in the yield
strength of st by 7.4%, a time limit of s of 9.8%. The grain size
decreased by 1 point, cementite from the lamellar becomes
granular-lamellar; For steel 20 GL - an increase in the yield
stress st by 8.7%, the limit of the time resistance s in 9.2%, the
grain size decreased by 2 points, the cementite from the lamellar
becomes granular-lamellar; When processing with torsion radiation
using mono-frequency alone, rather than previously known methods
for treating chemically pure non-ferrous metals or steels, as
studies have shown for these steel grades, with some change in the
structure (in particular, the average grain size), there is no
appreciable change in the mechanical properties of steels (Table.  
  
From a comparison of control and experimental samples, it can be
seen that as a result of the application of the torsion radiation
treatment of the melt, the following changes in the characteristic
frequencies have occurred: a decrease in the grain size by 1-2
points; Instead of the lamellar form, granular (globular)
cementite predominates; The size of globules of cementite is 1-3
Aum; Perlite is located along the boundaries of ferrite grains. In
addition, the grains become more rounded. Nonmetallic inclusions
are distributed more evenly, and the dispersity of nonmetallic
inclusions increases. In the experimental samples, the number of
nonmetallic inclusions along the grain boundaries averages about
45%, while in the control samples, about 75%. As a result, the
yield strength and ultimate strength of the steel increase.  
  
Thus, when tungsten radiation is processed by a melt of steel with
several characteristic frequencies, the improvement in mechanical
properties is achieved by reducing the grain sizes to 8-9 points
(while in the control samples of grain 7-8 points), more
equilibrium forms of grains, increasing the dispersion and more
uniform distribution of nonmetallic inclusions.  
  
The most successful way to correct the structural characteristics
of steel can be used in the metallurgical industry to produce
steels with given physical and mechanical properties and with the
improvement of their structure.  
  
Sources of information 1. Patent of the USSR N 1748662, G 01 N
22/00, H 05 C 3/00, H 03 B 28/00, publ. 15.07.92 2. Akimov AE,
Finogeev VP "Experimental   
manifestation of torsion fields and torsional technologies". Ed.
"NTC Informtekhnika", Moscow, 1996, p. 68h  
  


---

  

**RU2107105**  
**METHOD OF CORRECTION OF MICROSTRUCTURE OF METAL CASTING
ALLOYS**

  
FIELD: metallurgy, more specifically, methods for correction of
microstructure in production of aluminium-base alloys with high
mechanical and physical properties. SUBSTANCE: method consists in
that in course of its melting and/or crystallization, alloy is
exposed to torsion field with radiation frequency within the range
from medium to extremely high ones. EFFECT: higher mechanical and
physical properties of alloy of aluminium-silicon system due to
reduced sizes of silicon crystals by 10 times.   
  
The invention relates to the creation of alloys with increased
physical and mechanical properties due to the correction of the
microstructure of the metal in the melting and crystallization
process.  
  
There are known methods of changing the microstructure of alloys
that affect the increase in their physicomechanical properties, by
modifying various components in the melting process. In
particular, a method is known for modifying the aluminum-silicon
system by sodium and strontium eutectic aluminum alloy   
  
However, the use of methods for modifying alloys in metallurgical
production by other elements creates technological, economic and
environmental problems.  
  
A method for correcting the structure of the characteristics of
materials is known [2], which consists in the action of a torsion
field on the material.   
  
Examples of exposure to this field with a radiation frequency of 6
and 1000 Hz on copper and tin melts during their crystallization
have shown the possibility of changing the microstructure of the
metal and increasing its mechanical properties. Thus, the
microstructure of copper is obtained by ultradispersed, amorphous,
and the hardness of tin is increased by 1.5 times.  
  
The disadvantage of the known correction method is the fact that
under the influence of torsion radiation in the above frequency
range on the liquid metal, there is an insignificant ordering of
the nuclear spins of the atoms of the individual components of the
alloy, which has little effect on the change in the microstructure
of the alloy and the increase in its physico-mechanical
properties.  
  
The object of the invention is to increase the physical and
mechanical properties of metal casting alloys, preferably aluminum
alloys.  
  
The task is solved due to the fact that the alloy during its
melting and / or / crystallization is affected by a torsion field
with a radiation frequency in the ranges from medium to extremely
high frequencies. These frequency bands are determined from the
theoretical prerequisites of the greatest influence of torsion
radiation on the ordering of the atoms of the alloy components due
to the action of the spin moments of the atomic nuclei with an
external torsion field and are confirmed experimentally. The
positive result of the action on the alloy by the torsion field,
both in the melting and crystallization process, and only during
melting or crystallization is determined experimentally.  
  
The carried out investigations of the aluminum-based alloy
additionally showed that after the treatment of the alloy with a
torsion field, there is a decrease in the electrical resistance of
the metal.  
  

![](ru2107105.JPG)

  
Example. The aluminum-based eutectic alloy with a calculated
silicon content of 12% by weight was melted in an induction
furnace at 800 A deg C, followed by pouring the metal into a container
(chill) heated to 300 A deg C. Weight of melting: 2 kg. Two ingots
with a diameter of 50 mm and a height of 115 mm were cast from
each melting. Ten ingots were cast in total, one of which was
control and was irradiated with a torsion field with a frequency
of 100 Hz, the remaining ingots were exposed to a torsion field
with frequencies in the declared ranges. The effect of the torsion
field was made with the help of broadband generators similar in
design to the generator given in the information source [2]. The
time of action of the torsion field on the alloy during its
melting and / or crystallization depends on the chemical
composition of the alloy, the mass of the liquid metal or ingot,
the duration of crystallization, and the like. In this particular
example, the exposure time to the alloy in the melting unit was 15
minutes and during the crystallization process it was 10 minutes.  
  
To determine the physical and mechanical properties of the alloy,
standard samples were cut from each ingot, tested for strength,
plasticity, toughness, electrical conductivity, and microstructure
studies of the alloy. The parameters of the effect on the alloy by
the torsion field and the result of the tests are given in the
table.  
  
An analysis of the results of the tests shows that the effect on
the alloy of the torsion field in the claimed frequency ranges
makes it possible to substantially increase its physico-mechanical
characteristics in comparison with the similar effect by 20%, the
ductility has been increased almost twofold, the impact resistance
has increased 1.3 times, the specific The electrical resistance
decreased by 11%. The achieved improvement in physical and
mechanical properties is due to a decrease in the silicon crystals
in the microstructure of the aluminum alloy by almost 10 times.  
  
The implementation of the invention opens wide opportunities for
the production of cast alloys with increased physical and
mechanical properties without using traditional methods to improve
the properties of alloys by metallurgical modification.  
  


---

  

**SU1748662****METHOD OF CORRECTION OF STRUCTURAL CHARACTERISTICS OF
MATERIAL AND DEVICE THEREOF**

  

![SU1748662a](su1748662a.JPG)  ![SU1748662b](su1748662b.JPG)  
  
![SU1748662c](su1748662c.JPG)  ![SU1748662d](su1748662d.JPG)   
  
![SU1748662e](su1748662e.JPG)  
  
![SU1748662f](su1748662f.JPG)  ![SU1748662g](su1748662g.JPG)   
  
![SU1748662h](su1748662h.JPG) ![SU1748662i](su1748662i.JPG)  
  
![SU1748662j](su1748662j.JPG)  
  


---

**US20070287881**  
**Destressing system, apparatus, and method therefor**

 **Abstract**A device, system, apparatus, and method are disclosed for
reducing stress in an individual by creating an enhanced
informational spin field environment substantially surrounding
the individual. Such informational spin field environment is
at least partially derived from one or more dynamically
produced informational spin fields wherein electromagnetic
components associated with producing one or more of such
dynamically produced informational spin fields are blocked
from propagating therewith, such one or more dynamically
produced informational spin fields being then conducted
without accompanying electromagnetic signals to the
environment substantially surrounding the individual.

**BACKGROUND****1. Field of the Invention**  
This invention relates to a method, apparatus, and system for
reducing stress in an individual.  
  
**2. Background of the Invention**  
The increasing complexity and population density of our society
seems to be increasingly conducive to the creation of stress in
the population. There has appeared, therefore, a growing need to
identify more effective means of alleviating stress, and as a
result a variety of new therapies and technologies for dealing
with stress have surfaced over the past century.  
  
Stress is viewed as the cause of many forms of unhappiness in
people, such as irritability, depression, anger, emotional
instability, withdrawal, restlessness, anxiety and frustration,
and dysfunction in all living beings. The link between stress and
health is well known. The Journal of Occupational and
Environmental Medicine observes that health care expenditures are
nearly 50% greater for workers who report high levels of stress.
Medical symptoms widely attributed to stress include increased
heart rate and blood pressure, headache, nausea, indigestion, and
insomnia. In fact, the onslaught of disease more generally is
increasingly being related to stress. The American Institute of
Stress, founded in 1978 by such notables as Linus Pauling, Alvin
Toffler, Herbert Benson, and numerous other prominent scientists
and physicians, currently describes stress as "America's No. 1
health problem." In answer to the question as to how stress can
cause so many diseases, the Institute states, "many of these
effects are due to increased sympathetic nervous system activity."  
  
It is well known that stress can be relieved in humans by rest,
and by resorting to natural environments such as lakes, seashores,
mountains, gardens, and forests. It is also well known that spas,
soft lights and certain types of sound or music can relieve
stress. In some cases light and color have been observed to have
benefits with respect to both stress alleviation and healing.
Spectro-Chrome, a colored light therapy introduced in 1920 by
Dinshah Ghadiali, developed an impressive array of successes in
healing a wide range of diseases over a thirty year period. Sound
healing CDs have been produced by Andrew Weil, M.D., founder of
the Program in Integrative Medicine at the University of Arizona,
and Mitchell Gaynor, M.D., founder and president of Gaynor
Integrative Oncology in New York City.  
  
A device invented and patented by Barry McNew (U.S. Patent No.
6,544,165) uses a combination of music and light to accomplish
stress reduction and healing. An individual lies in a horizontal
cabinet designed to resonate with sound corresponding to a B minor
(C flat minor) chord. Successful clinical results for this device
are described in the Proceedings of the First Interdisciplinary
International Conference on the Science of Whole Person Healing.
McNew's device is specifically described as being directed at
balancing the sympathetic and parasympathetic elements of the
autonomic nervous system. McNew's international patent
application, published under the Patent Cooperation Treaty (WO
2005/058144 & PCT/US2004/042451), describes the use of indicia
such as involuntary eye or foot movements as references for the
operator in adjusting sound and light inputs to the device to
accomplish balancing the environment within the device to achieve
the desired effect. Destressing is specifically claimed as an
attribute of the device, with supporting evidence being
accumulated on numerous subjects using HRV monitoring before and
after exposure to the device. A typical exposure of an individual
in the device is described as one hour at a session.  
  
The past two decades have seen an increasing recognition by
scientists of the existence of a new fundamental field in physics
beyond the long recognized electrical, magnetic, gravitational,
and strong and weak nuclear attraction fields, namely, the
informational field (IF), with characteristics unique as compared
with the classical fields. An example of an informational field is
shown in the conservation of twin photons in entanglement
experiments, where the transfer of information necessary to
conserve spin can happen without energetic properties.  
  
This more newly recognized field has been described by other names
as well, such as torsion field, spin field, and informational spin
field. The seminal work in understanding and demonstrating the
reality of informational fields was done in the former Soviet
Union by Russian physicist Anatoly E. Akimov, a coinventor of the
present invention, and Russian theoretical physicist Gennady I.
Shipov, both of the International Institute of Theoretical and
Applied Physics of the Russian Academy of Natural Sciences. A
summary of the theory and numerous technologies created as a
result of this discovery appears in Dr. Akimov's paper delivered
in Moscow in 2000, entitled, Horizons of XXI Century Science and
Technologies. A description of the mathematical basis further
elaborating and supporting the theory is described in Dr. Shipov's
book, A Theory of Physical Vacuum-A New Paradigm, published in
Russian in 1993, and in English in 1998.  
  
In the experimental work with informational spin fields (ISFs),
ISFs were found to have different properties than known classical
fields. For example, they do not decrease with distance, as all of
the other known fields do, according to the inverse square law.
ISFs have a spatial structure corresponding to axial symmetry.
Objects with like (left-oriented or right-oriented) spins attract,
unlike objects with like electrical charges, which repel. ISFs are
capable of spin-polarizing space, such that even when a source of
an ISF is removed, the space where the field was tends to retain
its ISF-influenced state for a period of time.  
  
Informational spin fields have the ability to affect matter under
certain circumstances, especially in materials undergoing a phase
change, and tend to influence the alignment of electron, nuclear,
and atomic spins. This fact was verified by experiments carried
out in the Soviet Union using the Mossbauer Effect. In this
effect, the only known interaction with the material under
investigation is through spin, and the ISF created by devices
designed by Anatoly Akimov did affect the materials. Thus, it was
proven that these informational fields relate to spin, which is
why the term "spin" is being included in the name of these
informational fields described herein.  
  
It is presently postulated by some scientists that ISFs carry
information, and can impart that information to matter in the form
of phase information associated with varying degrees in the
precession of spins. Experiments by Dr. Akimov and others show
that ISFs can, under certain circumstances, affect crystal
structure and molecular structure, and consequently physical
properties, in materials.  
  
Informational spin fields are known to be generated in numerous
ways. Statically generated ISFs occur inherently with physical
geometry. For example, stationary objects, such as spheres, cones,
cylinders, and tetrahedrons, all generate static ISFs. The
intensity of static ISFs increases with specific ratios in the
geometry of the object, such as, for example, the phi ratio of
approximately 1.618, as well as with the increasing size of the
object.  
  
Dynamically generated ISFs are produced by bodies with angular
motion, for example, rotating spheres and nuclear and atomic
particles. Dynamically generated ISFs are produced by
electromagnetic radiation as well, such as by light and by
rotating magnetic fields. An example of an ISF created when
rotating a magnet about an axis is illustrated in a device
presently produced in Kazakhstan and marketed internationally by
Alexander A. Shpilman. Dynamically generated ISFs can also be
produced by combinations of geometry and changing electromagnetic
fields. Soviet patent No. 1748662 patenting such a device together
with its use in modifying the properties of materials was issued
in 1992 with priority since 1990 to Anatoly Akimov et al.  
  
The existence of biofields surrounding living beings has been
established by scientists over the past several decades. Valerie
Hunt, a Professor Emeritus of UCLA, was able use the patterns in
electromyograph signals to consistently correlate patterns in the
human biofield observed by individuals who could directly perceive
them. The results of her 25 years of research and clinical studies
demonstrating these results were presented in 1989 in her book,
Infinite Mind. More recently, Konstantin Korotkov, Professor of
Physics at St. Petersburg State Technical University in Russia,
introduced a commercial device using a Gas Discharge Visualization
(GDV) technique (Kirlian method), and is also able to correlate
parameters measured by that device with those patterns observed by
individuals who could directly perceive the human biofield. The
GDV device outputs have successfully correlated with the real time
introduction of stimulation to human subjects experiencing aromas,
physical injury, and other stimuli. Biofields themselves appear to
be informational spin fields, based upon research observations of
Dr. Anatoly Akimov correlating images of biofields observed by
individuals who could directly perceive them, with their direct
perceptions of the outputs of dynamic ISF generators.  
  
**BRIEF SUMMARY OF THE INVENTION**  
The present invention mitigates stress in individuals and improves
the efficiency of stress alleviation afforded by other available
environments and techniques. The present invention provides a
device, system, apparatus and method for reducing stress in an
individual by creating an enhanced informational spin field
environment substantially surrounding the individual. The term
"informational spin field" or "ISF," as used herein, refers to a
field also commonly known as a torsion field.  
  
In embodiments of the present invention, an apparatus for
destressing is provided that is configured to temporarily
accommodate an individual, preferably such that the individual can
assume a resting position. The apparatus is configured with a
series of elements whose geometrical arrangement corresponds to a
predetermined pattern. In one example, the apparatus comprises a
support structure configured to act as a bed and two end
structures joined to and orthogonal to the bed. In one embodiment
of the present invention, the end structures each comprise
multiple layers of electrically insulating material, such as wood.
In embodiments of the present invention, a pattern of metallic
tape, such as copper, is laminated between each wood layers
comprising each end structure. In one embodiment of the present
invention, the pattern of the copper tape comprises a six-pointed
star geometry comprised of two superposed equilateral triangles,
also know as a Star of David. Preferably, the patterns are
arranged opposite each other such that each apex of a star pattern
can be connected to a corresponding apex by a conductive member
that is mutually orthogonal to both end structures. In one
embodiment of the present invention, each end structure comprises
a trilayer assemblage of wood layers, in which the middle layer
includes a metallic tape pattern affixed thereto.  
  
In one embodiment of the present invention, the end members are
joined to each other by a series of six metallic tubes that are
substantially orthogonal to each of the end members. Preferably,
the orthogonal metallic tubes are mutually arranged to each
interconnect a point of a metallic Star of David that is laminated
between outer and inner boards of an end structure with a
corresponding point in a similar structure on the opposite end
member. The laminated Star of David pattern may be affixed to a
middle board of trilayer structure, or alternatively may be at the
interface of an inner and outer board of a bilayer end structure.
Preferably, six metallic tubes are arranged to interconnect all
six apices of a metallic Star pattern located in a first end
structure with a corresponding six apices in a metallic Star
pattern located in the opposite end structure to the first end
structure. Accordingly, an individual resting on a bed disposed
between the end structures lies within a hexagonal prism whose
long edges parallel to the cylinder axis are defined by the
metallic pipes.  
  
In embodiments of the present invention, the apparatus for
destressing further includes a hexagonal projector located in an
upper portion of the apparatus and configured with a series of six
cones. Preferably, the hexagonal projector is configured to slide
in a direction parallel to the bed structure. Preferably, the
destressing apparatus also includes a ball radiator that includes
a small metallic sphere that is configured to slide in a direction
parallel to that of the hexagonal projector.  
  
In accordance with the above-described elements, a static
informational spin field environment can be provided in a spatial
region designed to accommodate individuals of varying size within
the destressing apparatus. Once substantially inside a region
corresponding to the hexagonal prism, the static ISF environment
created by the destressing apparatus efficiently interacts with
the biofield of the individual, such that a destressing process is
initiated.  
  
In other embodiments of the present invention, the disclosed
device, system, apparatus and method provide an informational spin
field environment substantially surrounding an individual which is
at least partially derived from one or more dynamically produced
informational spin fields, wherein electromagnetic components
associated with producing one or more of such dynamically produced
informational spin fields have first been substantially separated
therefrom, such one or more dynamically produced informational
spin fields being then conducted to the environment substantially
surrounding the individual. The term "dynamically produced
informational spin field," as used herein, refers to an ISF that
is produced at least in part from the time-dependent variation of
an entity, such as a varying magnetically-induced spin field,
electromagnetic signal, electromagnetic current, or
electromagnetic radiation.  
  
In embodiments of the present invention, an apparatus is
configured to establish an ISF environment in a region configured
to accommodate a resting individual, wherein the ISF environment
comprises a dynamically produced informational spin field
resulting predominantly or in whole from inputs from a magnetic,
electric, or electromagnetic source. In other embodiments of the
present invention, the ISF environment is created by a combination
of elements configured to generate static ISFs together with
sources that serve to generate one or more dynamic ISFs, such as
electromagnetic, magnetic, or electrical signals.  
  
The present invention provides a system for alleviating or
reducing stress in an individual comprising an informational spin
field environment substantially surrounding an individual, which
is at least partially derived from one or more dynamically
produced informational spin fields, wherein electromagnetic
components associated with producing one or more of such
dynamically produced informational spin fields have first been
substantially blocked from propagating with the informational spin
field produced therefrom, such one or more dynamically produced
informational spin fields being then conducted without any
accompanying electromagnetic field to the environment
substantially surrounding the individual.  
  
The present invention also provides a method for alleviating or
reducing stress in an individual, comprising providing an
informational spin field environment substantially surrounding
such individual, which is at least partially derived from one or
more dynamically produced informational spin fields, wherein
electromagnetic components associated with producing one or more
of such dynamically produced informational spin fields have first
been substantially separated blocked from propagating with the
informational spin field produced therefrom, such one or more
dynamically produced informational spin fields being then
conducted without any accompanying electromagnetic field to the
environment substantially surrounding the individual.  
  
In one embodiment of the present invention, the dynamically
produced informational spin field source utilizes an
electromagnetic signal to generate an informational spin field,
wherein the electromagnetic signal itself is substantially
separated from the informational spin field produced therefrom,
said informational spin field produced therefrom being then
conducted to the environment substantially surrounding the
individual. In one embodiment of the present invention, the
dynamic informational spin field source utilizes an
electromagnetic signal derived from a musical sound input to
generate an informational spin field, wherein the electromagnetic
signal itself is substantially blocked from propagating with the
informational spin field produced therefrom, said informational
spin field produced therefrom being then conducted without any
accompanying electromagnetic field to the environment
substantially surrounding the individual.  
  
In one embodiment of the present invention, the dynamic
informational spin field source utilizes an electrical signal from
a compact disk (CD) or magnetic tape player to generate an
informational spin field, wherein the electromagnetic components
of the electrical signal itself are substantially blocked from
propagating along with the informational spin field produced
therefrom, wherein the informational spin field produced therefrom
is conducted to the environment substantially surrounding the
individual without accompanying electromagnetic radiation or
electric signals.  
  
In one embodiment of the present invention, the informational spin
field environment is at least partially derived from one or more
light sources wherein the electromagnetic components of the light
emitted therefrom are substantially blocked from propagating with
the informational spin field produced by the light, said
informational spin field being then conducted without accompanying
light to the environment substantially surrounding the individual.  
  
In one embodiment of the present invention, means are provided to
modify and/or adjust the informational spin field environment in
either composition or intensity or both so as to be made
harmonious for an individual substantially surrounded by such
environment. In one embodiment, the informational spin field of
the present invention is modified and/or adjusted in either
composition or intensity or both in response to one or more
autonomic responses of the individual substantially surrounded by
said informational spin field environment so as to make it
harmonious for said individual.  
  
In one embodiment of the present invention, the informational spin
field environment is partially derived from one or more statically
generated informational spin fields.  
  
In one embodiment of the present invention, means are provided to
cause the primary localization of the information spin field
environment within the vicinity of the individual.  
  
In one embodiment of the present invention, either music or light
is additionally provided to the individual directly in order to
provide an aesthetic benefit.  
  
The present invention offers the potential of improved efficiency
as compared to means of achieving stress reduction by the
practices of the prior art. Significantly positive results are
observable in 15 to 30 minutes exposure to the informational spin
field environment of the present invention. In a society in which
the time to deal with one's own needs is frequently scarce, this
advantage of the present invention is very important. Moreover,
this feature offers the possibility for commercial employers to
provide the benefit of such a device to employees in the work
environment to improve morale and productivity, since the economic
return in terms of increased worker efficiency does not have to be
very large to justify perhaps only a 15-minute break exposure to
the environment of the present invention.  
  
While not wishing to be bound by any particular theory, it is
believed that all destressing environments owe their effects to
the presence of ISFs. Unlike the case with music and light healing
environments, in which the inputs to such environments are
acoustic and electromagnetic, any ISF intensity of such
environments must be limited to lower levels because of potential
discomfort or even harm to an individual at high levels of sound
or light exposure. By virtue of the ability to prevent
electromagnetic and acoustic signals from propagating in the
environment surrounding an individual, the present invention
provides a means to achieve higher ISF levels in the immediate
physical surroundings of an individual without the need to incur
high levels of electromagnetic radiation or acoustic signals in
the same physical surroundings. This facilitates optimizing the
destressing effect within a minimum of time without introducing
unwanted or negative side effects of excessive electromagnetic or
acoustic energy near the individual. Moreover, acoustic or
electromagnetic components can in themselves create unwanted
interactions in certain instances. The feature of the present
invention of minimizing or eliminating any acoustic inputs and
filtering out electromagnetic components from ISF inputs to the
environment substantially surrounding the individual permits the
creation of effects on the individual that are solely positive,
and therefore adds to the efficiency of achieving the destressing
result.  
  
Unlike certain therapies, such as spas, hot tubs and saunas, which
produce relaxation and stress alleviation at the expense of
creating lethargy, individuals exposed to the informational spin
field environment of the present invention report feeling
energized, yet relaxed.  
  
**BRIEF DESCRIPTION OF THE DRAWINGS**  
In order that the invention will be readily understood, a more
particular description of the invention will be rendered by
reference to specific embodiments that are illustrated in the
appended drawings. Understanding that these drawings depict only
typical embodiments of the invention and are not therefore to be
considered limiting of its scope, the invention will be described
and explained with additional specificity and detail through the
use of the accompanying figures, in which:  
**FIG. 1 depicts one embodiment of an apparatus in accordance
with the present invention, in which an individual is situated
in a reclining position appropriate to its use;****FIG. 2a is a schematic perspective view of a system for
destressing, in accordance with an embodiment of the present
invention;****FIG. 2b is a schematic diagram of a perspective view of a
hexagonal prism region defined by longitudinal members, in
accordance with one embodiment of the present invention;****FIG. 2c is a schematic diagram of a front view and side
view of an end structure of the system of FIG. 2a, in accordance
with one embodiment of the present invention;****FIG. 2d is a schematic diagram of an exploded view of the
end structure of FIG. 2c, in accordance with one embodiment of
the present invention;****FIG. 2e is a schematic diagram that illustrates an
exemplary hexagonal metallic tape pattern and collector of the
middle panel of the end structure of FIG. 2c, in accordance with
an embodiment of the present invention;****FIG. 2f is a schematic diagram that illustrates the
opposite side of the panel shown in FIG. 2e, showing details of
the collector, according to an embodiment of the present
invention;****FIG. 2g is a schematic diagram that illustrates details of
a collector star plate, in accordance with one embodiment of the
present invention;****FIG. 2h is a schematic diagram of a side view of the
destressing system of FIG. 2a, showing the collector in relation
to the system;****FIG. 2i is a schematic diagram that depicts details of an
inner panel of the end structure of FIG. 2c, in accordance with
an embodiment of the present invention;****FIG. 2j is a schematic diagram that depicts a side view of
an end structure of FIG. 2c, showing carriage bolt locations, in
accordance with an embodiment of the present invention;****FIG. 2k is a schematic perspective view of a system for
destressing, in accordance with another embodiment of the
present invention;****FIG. 2l is a schematic illustration that depicts elements
of a system for destressing in accordance with an embodiment of
the present invention;****FIG. 2m is a schematic illustration that depicts elements
of a system for destressing in accordance with an embodiment of
the present invention;****FIG. 3 is a schematic diagram that illustrates details of
an end structure outer panel, in accordance with one embodiment
of the present invention;****FIG. 4 is a schematic diagram that shows the configuration
and dimensions of the two inner end panels of the system
illustrated in FIG. 2k, with the copper tape shown in FIG. 4
applied to one side of each of the two inner end panels on the
faces respectively away from the individual as they would
recline within the apparatus, and with the slot shown situated
on the edge of the respective inner end panel that would be on
the reclining individual's left, permitting one copper tube on
that side to be removed to permit convenient ingress and egress
of the individual from the apparatus, according to an embodiment
of the present invention;****FIG. 5 is a schematic diagram of an assembly drawing for a
bed of the system illustrated in FIG. 2a, upon which the
individual is shown reclining in FIG. 1;****FIG. 6 is a schematic diagram of an assembly drawing for a
top assembly configured for use in the system illustrated in
FIG. 2a;****FIG. 7a is a schematic diagram of an assembly drawing for a
foot assembly configured for use with the apparatus depicted in
FIG. 2a, according to an embodiment of the present invention;****FIG. 7b is a schematic diagram of an assembly drawing for a
foot assembly configured for use with the apparatus depicted in
FIG. 2k, according to another embodiment of the present
invention;****FIG. 8a is a schematic diagram of an assembly drawing of an
exemplary dynamic ISF generator component configured for use
with the apparatus depicted in FIG. 2a, according to an
embodiment of the present invention;****FIG. 8b is a schematic diagram of an assembly drawing of
another exemplary dynamic ISF generator component configured for
use with the apparatus depicted in FIG. 2k, according to an
embodiment of the present invention;****FIG. 9 is a schematic diagram of a diagram showing detail
of electrical connections for the capacitor component of the ISF
generators shown in FIGS. 8a and 8b, according to an embodiment
of the present invention;****FIG. 10 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the copper cone
component of the ISF generators of FIGS. 8a and 8b, according to
an embodiment of the present invention;****FIG. 11 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the bottom Teflon(TM)
cone mount component of the ISF generator of FIGS. 8a and 8b,
according to an embodiment of the present invention;****FIG. 12 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the top Teflon(TM)
cone mount component of the ISF generator of FIGS. 8a and 8b,
according to an embodiment of the present invention;****FIG. 13 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the ring magnet
component of the ISF generator of FIGS. 8a and 8b, according to
an embodiment of the present invention;****FIG. 14 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the bronze Teflon(TM)
capacitor component of the ISF generator of FIGS. 8a and 8b,
according to an embodiment of the present invention;****FIG. 15 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of a metal housing
component of the ISF generator of FIG. 8b, according to an
embodiment of the present invention;****FIG. 16 is a schematic diagram of an assembly drawing of an
exemplary fiber coupler assembly component configured for use
generally with the system depicted in FIG. 27a, according to an
embodiment of the present invention;****FIG. 17 is a schematic diagram showing an exemplary
configuration and exemplary dimensions of the insulator cone
components of the fiber coupler assembly of FIG. 16, according
to an embodiment of the present invention;****FIG. 18a is a schematic diagram of an assembly drawing in
cross-section of an exemplary lamp ISF generator assembly of the
system depicted in FIG. 27a, according to an embodiment of the
present invention;****FIG. 18b is a schematic diagram of a perspective view, top
view, side view, and bottom view of the lamp reflector component
of FIG. 18a, according to an embodiment of the present
invention;****FIG. 18cis a schematic diagram of perspective views and a
side view of the lamp reflector and lamp box of the exemplary
lamp ISF generator assembly of FIG. 18a, according to an
embodiment of the present invention;****FIG. 19 is a schematic diagram of an assembly drawing of a
hexagonal projector base structure, in accordance with one
embodiment of the present invention;****FIG. 20a is a schematic diagram of an assembly drawing
showing an exemplary configuration and exemplary dimensions of
an exemplary ISF projector comprising a copper cone assembly, in
accordance with an embodiment of the present invention;****FIG. 20b illustrates an example of a copper or phosphor
bronze cone, arranged in accordance with one embodiment of the
present invention;****FIG. 21a is a schematic diagram of an assembly drawing of
an exemplary hexagonal cone projector configured for use in the
apparatus depicted in FIGS. 2a and 27a, according to an
embodiment of the present invention;****FIG. 21b is a schematic diagram of a hexagonal distributor
component of the apparatus of FIG. 21a, according to an
embodiment of the present invention;****FIG. 21c is a schematic diagram of an assembly drawing of a
housing for the apparatus of FIG. 21a, according to an
embodiment of the present invention;****FIG. 21d is a schematic diagram of an assembly drawing of a
cover for the apparatus of FIG. 21a, according to an embodiment
of the present invention;****FIG. 22a is a schematic diagram of a ball radiator assembly
in accordance with an embodiment of the present invention;****FIG. 22b is a schematic diagram of the configuration of a
ball radiator assembly, infrared (IR) camera, IR light source,
and hexagonal projector assembly in an apparatus, such as that
depicted in FIG. 1, in accordance with an embodiment of the
present invention;****FIG. 23 is a schematic depiction of a ball radiator
assembly in accordance with an embodiment of the present
invention;****FIG. 24 is a schematic diagram that shows exemplary details
of the hexagonal projector, infrared (IR) camera, IR light
source, ball ISF radiator assembly, and mattress components with
respect to their relative positions in the apparatus depicted in
FIG. 2k, in accordance with an embodiment of the present
invention;****FIG. 25 is a schematic diagram of an assembly drawing of an
exemplary distribution assembly of the apparatus depicted in
FIG. 21a, according to an embodiment of the present invention;****FIG. 26 is a schematic diagram that details exemplary
connections between two copper panels of the foot assembly of
FIG. 7b, the distribution assembly of FIG. 25, and the copper
tape of FIG. 4 at its junctions with the copper tubes, according
to an embodiment of the present invention;****FIG. 27a is a circuit diagram of exemplary connections and
electromagnetic currents and their resulting ISF flows that are
being input into a destressing apparatus, in accordance with an
embodiment of the present invention;****FIG. 27b illustrates a wiring diagram for a system used to
supply a signal derived from a music player to an ISF generator
such as that shown in the embodiments of FIGS. 8a and 8b,
according to an embodiment of the present invention;**  
  
![US20070287881a](US2007287881a.JPG) **![US20070287881b](US2007287881b.JPG)**

**![US20070287881c](US2007287881c.JPG) ![US20070287881d](US2007287881d.JPG) ![US20070287881e](US2007287881e.JPG) ![US20070287881f](US2007287881f.JPG) ![US20070287881g](US2007287881g.JPG) ![US20070287881h](US2007287881h.JPG) ![US20070287881i](US2007287881i.JPG) ![US20070287881j](US2007287881j.JPG) ![US20070287881k](US2007287881k.JPG) ![US20070287881l](US2007287881L.JPG) ![US20070287881m](US2007287881m.JPG) ![US20070287881n](US2007287881n.JPG) ![US20070287881o](US2007287881o.JPG) ![US20070287881p](US2007287881p.JPG) ![US20070287881q](US2007287881q.JPG) ![US20070287881r](US2007287881r.JPG) ![US20070287881s](US2007287881s.JPG) ![US20070287881t](US2007287881t.JPG) ![US20070287881u](US2007287881u.JPG) ![US20070287881v](US2007287881v.JPG) ![US20070287881w](US2007287881w.JPG) ![US20070287881x](US2007287881x.JPG) ![US20070287881y](US2007287881y.JPG) ![US20070287881z](US2007287881z.JPG) ![US20070287881z2](US2007287881z2.JPG) ![US20070287881z3](US2007287881z3.JPG) ![US20070287881z4](US2007287881z4.JPG) ![US20070287881z5](US2007287881z5.JPG)  ![US20070287881z7](US2007287881z7.JPG) ![US20070287881z8](US2007287881z8.JPG)**

  
**DETAILED DESCRIPTION OF THE INVENTION**  
While not wishing to be bound by any particular theory, it appears
that the device, system, apparatus and method of the present
invention results in an ISF flow that circulates in the
informational spin field environment substantially surrounding an
individual. Such flow does not appear to require direct contact
with the individual substantially within such environment in order
to occur. For example, although a foot paddle is provided in one
embodiment of the present invention depicted in FIG. 1, contact of
the individual with the foot paddle does not appear to be
required, although the flows appear somewhat more intensive when
contact of the feet with the paddles is employed, with or without
socks, as reported by individuals experiencing the environment,
based on their perceptions.  
  
One aspect of the device, system, apparatus and method of the
present invention provides means for enhancing an informational
spin field environment substantially surrounding the individual.
Biofields themselves appear to be informational spin fields
surrounding all living beings. The present invention reduces
stress in an individual by creating an enhanced informational spin
field environment substantially surrounding the individual. This
facilitates the process in which an individual changes his or her
own biofield in a manner that serves to reduce stress.  
  
In particular, in an embodiment of the device, system, apparatus
and method of the present invention, the dynamic ISF input or
inputs are provided in a manner in which they are harmonious to
the individual at the time of the individual's presence
substantially within the enhanced informational spin field
environment.  
  
FIG. 1 depicts one embodiment of an apparatus in accordance with
the present invention. In that embodiment, copper tubes and copper
tape are provided in a geometric configuration that localizes an
ISF environment substantially surrounding the individual within
the main support assembly thereof.  
  
FIG. 2a is a schematic perspective view of a system 400 for
destressing, in accordance with an embodiment of the present
invention. System 400 includes a bed 402 that is affixed at each
end to end members 404 and 406.  
  
As depicted in FIG. 2d, end members 404 and 406 each comprise a
trilayer structure, 404a, 404b, 404c and 406a, 406b, 406c
respectively, which preferably comprises a wood-based material.
Sandwiched between outer layer 404a (or 406a) and inner layer 404c
(or 406c) is a layer 406b that preferably includes a wood
substrate to which is affixed a star pattern 408, preferably
comprising metallic tape such as copper tape (e.g., [1/2] inch
wide and 0.0015 inches thick, with self-adhesive). Star pattern
408 comprises a pair of overlapping and oppositely facing
triangles each approximately equilateral and arranged so that the
six corners of the overlapping triangles form the points of a
regular hexagon having equal sides. Such a star pattern is
commonly referred to as a Star of David pattern. In the example
shown, each of the six star apices 410 is connected to a
longitudinal member (tube) 412 (see FIG. 2a) that in turn connects
that apex with a corresponding apex in the opposite star pattern.
The longitudinal members are designed to conduct ISF fields and
can comprise a solid metal, insulator, or other material.
Longitudinal members 412, also referred to as tubes, may be, for
example, solid bars, hollow cylinders, or cylinders containing
solid inserts. Preferably, each tube 412 comprises an outer metal
tube (not separately shown), such as copper and further includes a
supporting wooden dowel (not shown) within the metal tube. The
tubes 412 are arranged to be substantially orthogonal to the
planes of end members 404 and 406. Thus, tubes 412 are mutually
arranged in a hexagonal array as viewed along the axis of the
tubes. This arrangement serves to define a larger hexagonal prism
space 414, as illustrated in FIG. 2b. The base edges 415 of the
prism space are defined by connecting adjacent star apices 410 and
are all identical in length. The length of the prism space is
equivalent to the physical separation of opposing star surfaces
whose apices are the points of each prism base. The height and
relative lateral position of bed 402 is configured such that an
individual lying on bed 402 is substantially or wholly within the
space defined by prism space 414, as illustrated in FIG. 2a.  
  
The metallic tubes 412, together with metallic tape patterns 408
are configured to establish and direct an ISF environment
particularly within the region defined by prism space 414,
although ISFs can extend into the region outside of prism space
414. In one embodiment of the present invention, the metallic tube
length between opposing star surfaces embedded within members 404
and 406 is 88 inches.  
  
FIG. 2c illustrates details of end structure 404, in accordance
with one embodiment of the present invention. In one embodiment of
the present invention, each of layers 404a, 404b, and 404c have
the shape of a hexagon, save for protrusion 404d on the top
portion of 404c. Layer 404c also has an opening that accommodates
cone structure 404e (discussed further below) that is configured
to direct ISFs into the foot area of an individual lying on bed
402. End structure 406 is preferably configured substantially the
same as end structure 404, except that cone structure 404e is not
present in end structure 406.  
  
FIG. 2e illustrates details of a star shaped metallic tape pattern
408 and collector 416, in accordance with an embodiment of the
present invention. Star pattern 408 is affixed to panel 404b on a
surface that is inwardly disposed toward the region where an
individual lies on bed 402. Collector 416 comprises cone structure
404e and star plate 418, depicted more clearly in FIG. 2f. Cone
404e is configured to couple to a foot panel or foot paddles,
described in more detail with respect to FIGS. 7a and 7b. Cone
404e is affixed to star plate 418, which in turn is affixed to
radial pattern 420. As depicted in FIG. 2f, pattern 420 is affixed
to the side of panel 404b opposite to that which star pattern 408
is affixed, and preferably comprises metallic tape similar to or
the same as that used for star pattern 408. Thus, collector 416
serves to collect ISF fields that are distributed along metallic
tubes 412 and direct them to cone 404e, which itself is configured
to couple to foot panels or foot paddles to direct fields into the
lower extremities of an individual lying on bed 402.  
  
In one embodiment of the present invention, the distance from
opposite points on hexagonal panels 404a, 404b, and 404c is 42
inches, the length of a vertical panel side is 22 inches, the
length of non-vertical panel sides is 21 inches, the distance
between next nearest neighboring apices in star pattern 408 (i.e.,
the distance between two vertices of one of the two large
triangles that make up the star pattern) is 33 inches, and the
width of panels 404a, 404b, and 404c is 37 inches. The 33''
alternate point to point dimension of the stars, as well as the
88'' dimension between opposing star surfaces are preferred
dimensions.  
  
FIG. 2g illustrates details of collector star plate 418, in
accordance with one embodiment of the present invention. Star
plate 418 preferably comprises a regular hexagon whose sides each
define the base of a phi ratio triangle. In one example, the base
of the phi ratio triangle is 0.92 inches, the height is 0.66
inches, and the metal thickness is 0.005 inches (e.g., annealed
copper sheet). Holes (e.g., approximately 1/16 inch in diameter)
are provided about 0.375 inches from each triangle apex to provide
openings for a fastener (not shown) to fasten the plate to members
of radial pattern 420.  
  
As depicted in FIG. 2h, collector 416 is disposed above bed 402
and in the center of hexagonal prism 414. Also shown in FIG. 2h is
projector 422 which is configured to project ISFs from a top
region of apparatus 402 (see also FIG. 2a), as discussed below
with respect to FIGS. 21a-d. FIG. 2h also shows how the metallic
tape connects to the six tubes. In one embodiment, the tubes are
copper tubes, the ends of which are disposed in copper cap sockets
(e.g., 1 inch copper sweat caps) whose bases are secured (e.g.,
riveted) to the middle panel (e.g., panel 404b) of the end
structure.  
  
FIG. 2i depicts details of inner panel 404c in accordance with an
embodiment of the present invention. As shown, panel 404c is
configured with six 1.25 inch diameter holes to accommodate metal
tubes 412. Panel 404c also includes a central hole having a 2.125
inch diameter that is used to clamp cone structure 404e to star
plate 418 when panels 404c and 404b are joined together. Panel
404c also includes a slot to one of the six 1.25 inch diameter
holes so that a tube 412 can be removed and replaced, to permit
ingress and egress by an individual.  
  
FIG. 2j depicts details of an outer panel, which can be outer
panel 404a or 406a, in accordance with one embodiment of the
present invention. Preferably, a pattern of four carriage bolt
holes is provided in a lower portion of panel 404a to allow
bolting to bed 402, discussed further below with respect to FIG.
5, while a pattern of two bolt holes is provided in a top portion
of panel 404c for fastening to a top assembly 424 (see FIG. 2a),
discussed further below with respect to FIG. 6.  
  
FIG. 5 illustrates details of bed 402, in accordance with one
embodiment of the present invention. Bed 402 includes feet 402a
and horizontal member 402b. Bed 402 is supported by cross braces
402c and long braces 402d. Bed 402 is configured to be flush with
the inner panels 404c and 406c when assembled into system 400.
Accordingly, end structures 404 and 406 are supported by feet
402a, as illustrated in FIG. 2a and 2j. The outer cross braces
402c bolt to the end structures via the carriage bolt locations
shown in FIG. 2j. Bed 402 can be made of, for example, birch
plywood. Although bed 402 is shown as containing legs, as an
alternative, the bed could be supported by the end members, as
shown for bed 202 of FIG. 2k.  
  
FIG. 6 illustrates further details of top assembly 424, in
accordance with one embodiment of the present invention. Assembly
424 includes top surface 424a, cross braces 424b, and side pieces
424c. In one embodiment, as shown in FIG. 22b, side pieces 424c
each include an aluminum track 424d that acts to guide projector
422 in a horizontal plane.  
  
FIGS. 7a illustrates a foot assembly 440 that can be coupled to
collector 416, in accordance with one embodiment of the present
invention. Foot assembly 440 comprises a pair of foot paddles 442
that preferably include a silver sheet on front surface 444. Feet
can be secured to the paddles with fasteners 446 (e.g., a strap
with a hook and loop fastener). Cord 448, disposed on the back of
foot assembly 440, couples paddles 442 to a collector, such as
collector 416 illustrated above. Referring again to FIG. 2a,
paddles 442 are configured so that an ISF established along
metallic tubes 412 can be conducted to the lower extremity region
of an individual in bed 402.  
  
As illustrated in FIG. 2a, and further in FIG. 21a, system 400
also includes a hexagonal assembly (projector) 422, which can be
used to provide an ISF environment inside structure 402. In one
embodiment of the present invention illustrated in FIG. 21a,
hexagonal projector 422 is configured with a series of six
cylindrical cones 422a, preferably mutually arranged so that their
cone axes all converge upon a point. Preferably, cones 422a are
phi ratio cones in which the ratio of base to height is about
1.618. In one embodiment, illustrated in FIG. 2a, the hexagonal
assembly 422 is configured such that the axes of all cones
converge at a point (not shown) above bed 402. In embodiments of
the present invention, discussed further below, hexagonal
projector 422 is slidable in the longitudinal direction of tubes
412, such that the convergence point can be positioned above a
specific region, such as the heart chakra of an individual resting
on bed 402. The arrangement of cones 422a is such that the base of
each cone is downwardly disposed (closer to bed 402) with respect
to the cone apex. Accordingly, any static ISF generated within the
interior of a cone 422 and projected downwardly toward an
individual lying below, is a left handed ISF. As illustrated
further in FIG. 21b, distribution assembly 422b is disposed along
the central axis of hexagonal projector 422 and comprises a
hexagonal star plate 422c the same as or similar to collector
plate 418 of FIG. 2g. Star plate 422c is coupled through wires
422d to each of the six outer cones 422a. Cylindrical cone 422e is
clamped to star plate 422c using gasket 422f, which is affixed to
a main body of projector 422 using a series of three bolt holes.
Gasket 422f holds cone 422e down, centered on star plate 422c. In
one embodiment, the main body is made of masonite, gasket 422f is
birch plywood, and the bolts and nuts are nylon. FIG. 25,
discussed further below, presents an alternative distribution
assembly 340a, in accordance with a further embodiment of the
present invention.  
  
As illustrated in FIG. 21c, hexagonal projector 422 can include a
side housing 422g and top plate 422h designed to impart an outer
appearance of a simple hexagonal prism shape to projector 422 when
assembled.  
  
In one configuration of the present invention illustrated in FIG.
21d, projector 422 includes a carriage assembly 422i, which
includes a top plate portion 422j and chassis portion 422k.
Chassis portion 422k is configured with a set of eight wheels
422l, which are designed to couple to an aluminum rail provided in
a top assembly between the two end structures, as described above.
Accordingly, projector 422 can be suspended from a top assembly
424 moved in a horizontal direction above bed 402 to position the
projector as desired. Moreover, the axis of hexagonal projector is
preferably orthogonal to the axis of tubes 412. Projector 422 is
thereby configured to project a statically derived ISF into the
region where an individual is located when the individual is lying
on bed 402. As discussed further below, cone 422e is configured
with a wire coupled to its apex that can be used to conduct
dynamically generated ISFs to projector 422.  
  
In another embodiment of the present invention, a ball radiator
structure 450 is also provided in destressing apparatus 400, as
illustrated in FIG. 22a. Ball radiator device 450 preferably
includes a cylinder 452 (e.g., PVC tube) that contains a metallic
sphere such as copper/silver alloy or copper (e.g., [5/8] inch
diameter copper ball), which is also slidably moveable in a plane
parallel to that of tube 412, using a top portion 454 (e.g., a
wooden box made from [1/4] inch birch plywood) provided with a
cylindrical through hole as shown in FIG. 2a. As shown, cylinder
452 is pivotally mounted to top portion 454. Accordingly, ball
radiator 450 can be positioned over and adjusted for an
individual, for example, focusing the ball radiator 450 on the
"third eye" chakra in the region of the forehead, as illustrated
in FIG. 22b. A static ISF generated on the outside of the sphere
defined by the ball irradiator 450 is a right handed ISF. As
discussed further below, ball radiator 450 is configured with a
wire 456 (e.g., 16 gauge multi-strand coiled copper speaker wire)
that can be used to conduct dynamically generated ISFs to radiator
450. Wire 456 can be connected through a gold-plated copper butt
terminal to a wire inside cylinder 452 (e.g., a 10 gauge single
strand copper wire) that is brazed (e.g., with 72% silver and 28%
copper alloy braze) to the side of the metallic sphere.  
  
FIG. 2k is a schematic perspective view of a system 200 for
destressing, in accordance with another embodiment of the present
invention. System 200 includes a bed 202 that is affixed at each
end to end members 204 and 206. In this embodiment, end members
204 and 206 each comprise a bilayer structure, 204a, 204b, and
206a, 206b, respectively, which preferably comprises a wood-based
material.  
  
Sandwiched between each bilayer structure is a star pattern 208,
preferably comprising conductive tape arranged to form a Star of
David-type geometry, using a metallic tape such as copper tape.
Similar to star pattern 408, star pattern 208 comprises apices
210, as also illustrated in FIG. 4. Each star apex is connected to
a tube 212 that in turn connects that apex with a corresponding
apex in the opposite star pattern. Preferably, each tube 212
comprises an outer metal tube (not separately shown), such as
copper and further includes a supporting wooden dowel (not shown)
within the metal tube. The tubes 212 are arranged to be
substantially orthogonal to the planes of end members 204 and 206.
Thus, tubes 212 are mutually arranged in a hexagonal array as
viewed along the axis of the tubes. This arrangement serves to
define a larger hexagonal prism space 414, as illustrated in FIG.
2b. The base edges 415 of the prism space are defined by
connecting adjacent star apices 210. The length of the prism space
is equivalent to the length of the tubes 212. The height and
relative lateral position of bed 202 is configured such that an
individual lying on bed 202 is substantially or wholly within the
space defined by prism space 414, as illustrated in FIG. 4.  
  
The metallic tubes 212, together with metallic tape patterns 208
are configured to establish and direct an ISF environment
particularly within the region defined by prism space 414,
although ISFs can extend into the region outside of prism space
414.  
  
FIG. 3 illustrates details of an end structure outer panel 204a,
in accordance with one embodiment of the present invention. As
shown, panel 204a comprises a beveled top and flat base.  
  
FIG. 7b illustrates back and front views of a foot assembly 222
that is provided over an opposite portion of bed 202 as compared
to the location of ball radiator 220 (see FIG. 2k), in accordance
with one embodiment of the present invention. In one embodiment of
the present invention, foot assembly 222 comprises a
[3/4]''\*15''\*33'' Luan surface finished plywood foot panel 222a
supported by two 4''\*15'' braces 222b and a 4''\*33'' bottom panel
222c. Copper panels 223 are made of 6''\*13.5'' copper sheets,
where each panel is offset about 1.5 inches from the center of
panel 222a, where each copper panel is designed to rest against
the feet of an individual lying on bed 202. In accordance with one
embodiment of the present invention, illustrated in FIG. 26,
metallic tubes 212 are coupled to the foot assembly 222 using a
concentrator 224. Collector 224 preferably is similar to or
substantially the same as collector 416 and comprises a metal
having a base that is shaped in a hexagonal star pattern whose
apices 225 are each coupled to a metallic tube 212 using 16 gauge
multi-strand copper wire, which is soldered to copper tape located
between panels, such as panels 204a, 204b. The copper wire is fed
to the copper tape through holes 204c provided in the panels (see
FIG. 3). Concentrator 224 also includes a conical structure 226
whose apex is contacted by a 16 gauge multi-strand wire that feeds
through holes provided in inner and outer panels 204b, 204a and
leads to a foot assembly, such as foot assembly 222, shown in FIG.
7. A copper wire is fed through assembly 222 from front to back
and is soldered to each of the foot panels 223, as shown. Copper
foot panels 223 are preferably nailed to plywood foot panel 222a
using four copper nails placed at the corners of each panel. Thus,
concentrator 224 is configured to concentrate ISF fields from
tubes 212 to the apex of cone 226 and to direct the ISF to the
region of the foot panels 223.  
  
The metallic tubes 212, together with metallic tape patterns 208
are configured to establish and direct an ISF environment
particularly within the region defined by prism space 414.  
  
System 200 also includes a hexagonal assembly (projector) 216,
which can be used to provide an ISF environment inside structure
202. In one embodiment of the present invention, hexagonal
assembly 216 is configured with a series of six cylindrical cones
218, as illustrated further in FIGS. 19 and 20. Preferably,
projector 216 is configured similarly to projector 422 such that
the cones are mutually arranged so that their cone axes all
converge upon a point. Preferably, cones 218 are phi ratio cones
in which the ratio of base to height is about 1.618. In one
embodiment, illustrated in FIG. 2a, the hexagonal assembly 216 is
configured such that the axes of all cones converge at a point
(not shown) above bed 202. In embodiments of the present
invention, discussed further below, hexagonal assembly 216 is
slidable along a tube 212, such that the convergence point can be
positioned above a specific region of an individual resting on bed
202, such as the heart chakra region. The arrangement of cones 218
is such that the base of each cone is downwardly disposed (closer
to bed 202) with respect to the cone apex.  
  
In an embodiment of the present invention, a ball radiator
structure 220 is also provided in destressing apparatus 200, as
further illustrated in FIG. 23. Ball radiator 220 is preferably a
metallic sphere such as copper silver alloy or copper, which is
also slidably moveable in a plane parallel to that of tube 212.
Accordingly, ball radiator 220 can be positioned over an
individual, such as above the "third eye" chakra in the region of
the forehead. A static ISF generated on the outside of the sphere
defined by the ball irradiator 220 is a right handed ISF.  
  
In accordance with the above-described elements of system 200,
static ISFs can be distributed and projected within one or more
areas of a spatial region that accommodates an individual on bed
202, such that the ISFs interact with the individual to produce a
destressing effect.  
  
FIG. 21 is a schematic illustration that depicts elements of a
system 230 for destressing in accordance with additional
embodiments of the present invention. System 230 is designed to
accommodate an individual in a structure 232 for a period of time
to facilitate destressing of the individual. In an embodiment of
the present invention, structure 232 includes bed 402, end members
404 and 408, and metallic tubes 412 and star patterns 408, as
shown with respect to FIG. 2a. Alternatively, structure 232
includes bed 202, end members 204, 206, tubes 212 and star
patterns 208, arranged substantially as shown and described above
with respect to FIG. 2k. Structure 230 also preferably includes a
hexagonal collector, such as collector 224 or 416 that is coupled
to a foot assembly such as assembly 222 or 440. Thus, structure
232 is configured to conduct and distribute ISFs within a region
that accommodates an individual in a reclined position. In a
preferred embodiment of the present invention, structure 232 is
horizontally elongated and bed 202 is horizontal such that the
individual is optimally accommodated in a reclined position on bed
202. Alternatively however, as one of ordinary skill in the art
would appreciate, the structure could be adapted for other
orientations, such as to accommodate an individual who is
standing.  
  
System 230 includes an electromagnetic source 234 that can be used
as an input for generating ISF inputs. As discussed in detail
below, electromagnetic source 234 may include electrical or
electromagnetic outputs from a music source, such as a CD,
audiotape, and the like. Alternatively, electromagnetic source 234
may include an SCR controller or similar device that can control a
light source, such as a lamp.  
  
Electromagnetic or electrical signals from electrical source 234
are conducted to dynamic ISF generator 236. ISF generator 236 is
configured to receive the electromagnetic or electrical input from
electrical source 234, which can be used as an input to cause ISF
production by dynamic ISF generator 236. In a preferred
embodiment, both electromagnetic source 234 and dynamic ISF
generator 236 are located in a region external to structure 232.  
  
System 230 is also configured such that the electrical or
electromagnetic signals received from electromagnetic source 234
are substantially blocked or attenuated from propagating into the
immediate environment of an individual in structure 232.  
  
An information spin field generated by ISF generator 236 is
conducted along ISF conductor 238 to ISF projector system 240. ISF
conductor 238 can comprise, for example, an electrical conductor,
such as a metal. Alternatively, ISF conductor 238 can comprise an
insulator material, such as an optical fiber. In embodiments of
the present invention, system 230 further includes an attenuator
(or coupler) 242 that acts to conduct ISF into structure 232,
while preventing electromagnetic or electric signals from
propagating from ISF generator 236 to ISF projector system 240. In
other embodiments, however, an attenuator 242 separate from the
ISF generator 236 need not be included. This is because the ISF
generator 236 is preferably configured to prevent electromagnetic
or electric signals from propagating to projector system 240, as
discussed further below. Thus, electromagnetic or electrical
signals that are used as inputs to ISF generator 236 or are
byproducts of ISF generator 236 during its operation, are
substantially blocked from propagating into areas such as areas A,
B, and C of structure 232.  
  
As discussed further below, ISF projector system 240 may be
configured to distribute dynamically created (and statically
created) ISFs from multiple positions toward the vicinity of the
individual, or alternatively, may be configured as a relatively
localized single source that radiates ISF in the vicinity of the
individual during a destressing session. ISF projector system 240
may comprise a plurality of separate ISF projectors (as depicted,
for example as 240a and 240b), that comprise similar or different
features, and are directed at different regions near an
individual, as discussed in detail in the discussion to follow.
For example, an individual ISF projector might include a series of
identical structures, such as cones that are mutually arranged
according to a predetermined geometry within the ISF projector.
Alternatively, an ISF projector system might include two or more
ISF projectors that differ in structure and materials, and are
interconnected with different elements, such as different ISF
generators. The term "ISF projector," as used herein, refers to an
object or system that provides or directs an ISF or set of ISFs
within a desired region, for example, in a region of a destressing
structure than can accommodate an individual. As depicted in FIG.
2c, projector 240 is located within structure 232, but need not be
located within such a chamber.  
  
A set of dynamically generated ISFs is provided by projector
system 240 in a manner that enhances the destressing of an
individual located within structure 232. Accordingly, the
individual resting in structure 232 receives the benefit of an ISF
environment purposively created from sources that can create
harmonious ISFs without any unwanted or deleterious effects
associated with the electromagnetic or electric sources associated
with generation of ISFs themselves. In preferred embodiments of
the present invention discussed further below, projector system
240 comprises a ball radiator and hexagonal assembly (each
discussed previously). Projector system 240 thus may comprise
components that are configured to project both statically
generated and dynamically generated ISFs in the region of
structure 232 surrounding an individual.  
  
As described further below, in some embodiments of the present
invention, a dynamic ISF generator can be switched from generating
right handed ISFs to generating left handed ISFs. Additionally, as
noted above, different elements of system 230, such as the ball
radiator and hexagonal cone assembly produce either left handed or
right handed static ISFs. When dynamic ISF generators are
employed, the ISF environment thus established in the environment
of the individual in structure 232 results from a combination of
dynamically generated ISFs as well as statically generated ISFs,
whose intensity and handedness may differ. In embodiments of the
present invention in which a source for dynamic ISF generation is
employed, the intensity of the dynamically derived ISF tends to be
such that the dynamically derived ISF exercises a dominant effect
on the ISF environment established in the vicinity of the
reclining individual, such as regions A, B, and C.  
  
Referring again to FIG. 21, system 230 further includes monitor
244, which can be used to monitor the response of an individual
during a destressing session, which can aid in tuning the ISF
input during a destressing session or adjusting ISF inputs for
future sessions. This is useful so that the energetic input used
to generate ISFs can be tailored to the individual to optimize the
destressing effect for that individual.  
  
FIG. 2m is a schematic illustration that depicts the
interconnection of elements of a system 460 for destressing in
accordance with another embodiment of the present invention. Solid
lines show flow of electromagnetic currents and dashed lines show
ISF flows. System 460 includes main assembly 462 that contains bed
464 and hexagonal projector 466 and ball radiator 468 located
above bed 464. CD player 470 is configured to play, for example
audio CDs that output an electronic signal to receiver 472, which
outputs a signal to high voltage amplifier 474. Amplifier 474 in
turn, outputs a signal to dynamic ISF generator 476, examples of
which are described further below with respect to FIGS. 8a and 8b.
ISF generator 476 is connected to fiber coupler 478 that is
designed to block electric and electromagnetic signals from
propagating to assembly 462. Fiber coupler 478 is connected to
distribution box 480, that may include a distributor such as
distribution assembly 422b depicted in FIG. 21b. Distribution
assembly is configured to receive ISFs generated by ISF generator
476 and distribute them within hexagonal projector 466.
Accordingly, dynamic ISFs produced from inputs derived from CD
player 470 are projected within assembly 462 by hexagonal
projector 466. In addition, ball radiator 468 is configured to
receive ISFs generated by the action of SCR 482 which outputs a
signal that controls the intensity of light in lamp module 484.
The light generated in lamp module 484 is collected and blocked
from leaving the lamp module, as described further with respect to
FIGS. 18a-18c. ISFs produced by lamp module 484, on the other
hand, are conducted to ball radiator 468 and projected into
assembly 462. As described further below with respect to FIG. 27a
and 27b, the ISF environment created within an assembly, such as
assembly 462 can be used to facilitate destressing.  
  
In one embodiment of the present invention generally depicted in
FIG. 1 and more particularly in FIG. 27a herein, destressing is
accomplished by using an electromagnetic signal comprising
frequency information derived from music as an input to a dynamic
ISF generator. This is accomplished in that particular embodiment
by using the output signal from a CD player as input to a high
voltage amplifier of a type typically employed for powering
piezoelectric transducers, with the output of the amplifier
feeding as an input to the dynamic ISF generator. Alternatively,
either a live music or recorded music source converted to an
electromagnetic signal provided by an audiotape player, radio,
computer storage device, television, or similar device can be
employed. Moreover, other harmonious informational sources, such
as the sound of ocean waves and wind, can be employed as inputs to
one or more ISF generators providing input to the environment of
the present invention in a similar fashion. In the case where
music is used as the informational basis for the dynamic ISF input
to the device, system, apparatus, and method of the present
invention, the music upon which such signal is based can be
selected as being of a type harmonious to the individual. Examples
of music used in such an embodiment are shown in Table 1 below.  
  
**TABLE 1****Artist  Album Title  Publisher**  
2002  Wings  Real Music  
Merlin's Magic  The Heart of Reiki  Inner Worlds Music  
Merlin's Magic  Angel Symphony of  Inner Worlds Music  
  Love and Light  
Aeoliah  Angel Love  Oreade Music  
Erin Jacobsen  Feather on the  Serenity Music  
  Breath of God  
Chuck Wild  Liquid Mind IV  Real Music  
Angie Bemiss  Recovery  James Schaller  
Steve Halpern  Gift of the Angels  Inner Peace Music  
Merlin's Magic  Light Reiki Touch  Inner Worlds Music  
W. A. Mozart  Classical Relaxation  Direct Source  
  with Ocean Sound  Special Products  
Gerald Jay Markoe  Celestial Mozart  Astro Music  
Merlin's Magic  Chakra Meditation  Inner Worlds Music  
  Music  
Merlin's Magic  Healing Harmony  Inner Worlds Music  
Deuter  Reiki's Hands of Light  New Earth Record  
  
While not wishing to be bound by any particular theory, it is
believed that the above music examples have combinations of tones
and patterns which create geometric effects which are particularly
harmonious when employed in the present invention. A relationship
between music and geometry has been observed by Princeton
University Theorist and composer Dmitri Tymoczko, among others,
who published some of his findings to that effect in The journal
Science in 2006.  
  
As a practical matter in choosing music that has harmonious
properties desirable for use in connection with the present
invention, it has been observed that certain individuals have an
ability to perceive that the music has suitably harmonious
properties by listening to the music with headphones apart from
any presence of such individuals in the apparatus of the present
invention. When they are thus listening and the proper harmonious
characteristics are present in the music, such individuals
perceive a feeling of vibration or tingling that pervades their
whole body that is unique to the types of music that are desirable
for use as ISF informational sources for use in connection with
the present invention. This represents a method employed to choose
music employed in the apparatus of the present invention. All of
the CD music albums listed in Table 1 were chosen by this means
and exhibit such characteristics. By contrast, most music, even
though it may be pleasant to listen to, lacks such a property.  
  
FIG. 27a is a schematic illustration that includes a circuit
diagram of components of a system 270 for destressing, in
accordance with one embodiment of the present invention. The
circuit arrangement illustrated can be implemented in a physical
apparatus similar to that depicted in FIG. 1. Solid lines show
flow of electromagnetic currents and dotted lines show ISF flows.
In accordance with embodiments of the present invention, a source
of information, such as a signal from a CD player or from a light
source, is conducted to an ISF generator, which can comprise a
cone. The ISF generator then locally generates an ISF, which is
distributed in the environment of a chamber that can accommodate a
person.  
  
In the embodiment depicted in FIG. 27a, an information source
comprises a CD player 272. The electrical signal from the music
information played by CD player 272 is conducted over conductive
wire, such as coaxial leads 274 through a sound amplifier 276 to a
high power amplifier device 278, which, in one embodiment, is
configured to produce an output voltage not exceeding 120 volts
when the gain is at maximum. The output of the high voltage
amplifier device 278 thus contains information related to the
music contained in the CD.  
  
A switch 280 regulates conduction of an electromagnetic signal
from amplifier 278 to ISF generator 282. ISF generator 282 can
comprise a conical structure, as described further below with
respect to FIG. 8.  
  
In the embodiment depicted in FIG. 27a, ISF conductor 284
comprises a fiber optical coupler 286 (described further below
with respect to FIG. 16) and multi-strand conductive wire 288.
ISFs generated from ISF generator 282 are conducted to ISF
projector 290, which comprises a hexagonal distribution assembly
340 that may be disposed within main assembly structure 292. A
series of six projection points 294 are arranged at tips of cones
arranged in a hexagonal array that is disposed directly over bed
296. Accordingly, ISFs can be provided in a region of structure
292 that is designed to accommodate a reclining individual. In
this manner, the individual is encompassed in an ISF environment
that is provided by projector 290, which receives the ISF from ISF
generator 282, which in turn receives an electrical signal based
on the music played by CD player 272.  
  
Accordingly, the ISF environment that surrounds an individual in
structure 292 is derived at least in part from the information
provided by CD player 272. Additionally, as described further
below, ISF conductor 284 and fiber coupler 286 are configured to
minimize or eliminate electrical and electromagnetic signals
derived from the output of CD player 272, such that the individual
in structure 292 is subject to an ISF environment substantially
stripped of any electromagnetic or electric signals used to help
generate the ISF environment. If a metallic material is used to
form a conductive wire 288, copper or noble metals are preferably
used to form the wire. In some embodiments, instead of a
multistrand wire 288, an ISF conductor can comprise an insulator
such as an optical fiber.  
  
Another source of harmonious informational input for use in
connection with ISF generators of the present invention is light.
Such a source can also be provided in the embodiment of the
present invention depicted in FIG. 1, and detailed in FIGS. 18a-c,
24, and 27a. FIG. 27a depicts an information source 300 that
includes an SCR (silicon controlled rectifier) controller 302 and
lamp module 304. SCR 302 acts as an electrical source that is
configured to provide a power source to lamp 306 without the AC
voltage variation from the line supply. Lamp 306, in turn, acts to
generate radiation that is collected at cone 308. The ISFs
generated from cone 308 (or combined ISF) are conducted by ISF
conductor 310 to ISF projector 312, which is a ball radiator in
the embodiment depicted in FIG. 27a. Ball radiator 312, in turn,
provides an ISF environment directly in the vicinity of an
individual reclining on bed 296. Thus, a light source can be used
to generate a harmonious ISF environment in structure 292. In a
preferred embodiment of the present invention, ball radiator 312
and hexagonal assembly 290 act in concert with a hexagonal array
of metallic tubes (not shown in FIG. 27a, but described above with
respect to FIG. 2a) to produce an ISF environment that combines
dynamically produced and statically produced ISFs that interact
with an individual in structure 292 to produce a destressing
effect.  
  
In one embodiment of the present invention, means are provided for
determining that the enhanced ISF environment is harmonious to the
individual at the time of the individual's presence substantially
within the enhanced informational spin field environment. Such a
means is provided in the embodiment of the present invention
depicted in FIG. 1. It has been observed that an individual who is
substantially surrounded by the ISF environment of the present
invention exhibits autonomic responses that can be visibly
interpreted by an operator. A sensor whose output is directed to a
computer programmed to interpret visual data, can also be used to
determine whether the environment is harmonious to the individual
when present within such ISF environment. Among such autonomic
responses are various involuntary eye movements, the most common
example of which is blinking of the eyes at a rate much more rapid
than normal, which tend to largely cease when the environment is
fully harmonious. Such autonomic responses described herein are
similar in kind and character to those reported in the published
PCT patent application of McNew (WO 2005/058144 and
PCT/US2004/042451), observed in the combined sound and light
environment described therein. It has been discovered that the
phenomenon of such responses are present in the ISF environment of
the present invention as well, even in the absence of both light
and sound within such environment, and can be can be employed as a
means of cueing the adjustment of the ISF environment of the
present invention with regard to either its intensity,
informational content, or both, to assure the presence of a
harmonious ISF environment for the individual within said
environment.  
  
In a preferred embodiment of the present invention, a gain knob
configured to adjust voltage of the output electromagnetic signal
from the high voltage amplifier to the ISF generator may be
adjusted downward from its initial setting to eliminate
involuntary eye movement on the part of the individual subject if
such eye movement is being exhibited either at the commencement of
or during a destressing session. If involuntarily eye movement
persists, the hexagonal projector may be moved toward the feet of
the subject, lowering the overall frequency of the ISF within the
destressing apparatus. If involuntary eye movement still persists,
this is an indication that the subject has made as much change to
their ISF as can be comfortably accommodated at the time of the
session, and the session is then terminated by removing the
individual from the destressing device.  
  
**Exemplary Implementations of Components of a System for
Reducing Stress**  
In the discussion to follow, details of exemplary components of a
system for destressing are provided. Such components are merely
exemplary to provide a better understanding of the operation of
the invention, and should not be considered as limiting the scope
of the present invention in any way.  
  
**ISF Generators**  
One embodiment of a dynamic ISF generator of the present invention
is illustrated in FIG. 8a.  
  
FIG. 8a illustrates a cross-sectional, top, and bottom view of ISF
generator 500 that includes cone 502 and an assembly of phosphor
bronze and Teflon(TM) sheets and a ring magnet. A pair of
Teflon(TM)/bronze capacitors 506, 508 is concentrically arranged
such that a ring magnet 504 is concentrically disposed between the
concentric coiled capacitor plates. When a changing voltage is
applied to the inner and outer bronze plates 506, 508, the
magnetic moments within magnet 504 (the electron spin
polarizations of the ferrite ceramic ring magnet) are changing
dynamically. This change in spin polarization creates a
dynamically changing magnetic field. This dynamically changing
magnetic field generates an ISF. This dynamic ISF couples into the
static ISF created by the copper cone 502 itself, whose base is
affixed to the base 510. The dynamic and static ISF are then
broadcast out of cone 502 and follow a copper wire and optical
fiber conduction path. In a preferred embodiment of the present
invention, as illustrated in FIG. 13, the polarity of the ring
magnet 504 is arranged such that the poles are arranged along the
axis of the ring and cone, and the north pole is facing up toward
cone 502. In one embodiment of the present invention, ring magnet
504 comprises a ferrite ceramic ring type five, with magnetic
field strength of about 4000 Gauss. As shown in FIG. 8a, cone 502
is held down by a top square plate and sandwiched between the top
square plate and bottom square plate by, for example, nylon bolts
through the top and bottom plates.  
  
In accordance with another embodiment of the present invention,
FIG. 8b illustrates a cross-sectional view of another ISF
generator 320 that includes an assembly of bronze and Teflon(TM)
sheets and ring magnets. The embodiment depicted in FIG. 8b
differs from that shown in FIG. 8a primarily in that the magnet
and capacitors in the former are contained within an enclosure
330. Similar to ISF generator 500, a pair of Teflon(TM)/bronze
capacitors 322, 324 is concentrically arranged such that a ring
magnet 326 is concentrically disposed between the concentric
capacitor plates. When a changing voltage is applied to the inner
and outer bronze plates 322, 324, the magnetic moments within
magnet 326 (the electron spin polarizations of the ferrite ceramic
ring magnet) are changing dynamically. This change in spin
polarization creates a dynamically changing magnetic field. This
dynamically changing magnetic field generates an ISF. This dynamic
ISF couples into the static ISF created by the copper cone 328
itself, whose base is affixed to the outside of a housing 330 that
houses the magnet capacitor assembly. An example of housing 330 is
shown in FIG. 15.  
  
The dynamic and static ISF are then broadcast out of cone 328 and
follow a copper wire and optical fiber conduction path. In a
preferred embodiment of the present invention, the polarity of the
ring magnet 326 is arranged such that the poles are arranged along
the axis of the ring and cone, and the north pole is facing up
toward cone 328. In one embodiment of the present invention, ring
magnet 326 comprises a ferrite ceramic ring type five, with
magnetic strength of about 4000 Gauss.  
  
Preferably, the dynamic ISF field generated by generator 320 or
500 is a right handed field, which can be controlled by choice of
polarity of the input signal to generator 320, as illustrated in
FIG. 9.  
  
FIG. 14 illustrates details of capacitors 322 (506), 324 (508)
according to an embodiment of the present invention. In this
embodiment, capacitors 322 and 324 each comprise three concentric
layers of Teflon(TM)/bronze formed from a single continuous
Teflon(TM)/bronze bilayer. The Teflon(TM) layer is on the outside.
Each layer of the bronze sheet is preferably isolated from the
previous and next layer. In one embodiment, the Teflon(TM) and
bronze layers of a single layer of the capacitor are each about
0.005 inches thick. A wire (e.g., 16 gauge 8 inch multi-strand
copper speaker wire) is soldered to the inner layer of capacitor
322 and the outside layer of capacitor 324.  
  
Referring again to FIGS. 8a and 8b, the width of capacitors 506
(322) and 508 (324) along the axis of the capacitors and cone is
about twice the thickness of the magnet 504 (326).  
  
FIG. 10 illustrates details of a copper cone structure, which can
represent, for example, cone 502 of ISF generator 500. An
exemplary base diameter is about 60 mm while the height is about
37.1 mm. In one embodiment of the present invention six similarly
shaped copper cones are used to form the hexagonal projector
described above, as well as cones in a fiber coupler and lamp
assembly described below. In the latter cases, an exemplary base
diameter is about 101.6 mm and height is about 62.8 mm. Finally, a
similar cone structure having diameter of about 63 mm and height
of about 39.0 mm is used for a collector assembly connected to a
foot assembly described above as well for a distributor assembly
connected to the hexagonal projector described previously.
Preferably, all such cones are 99.99% oxygen free copper cones.  
  
FIGS. 11 and 12 illustrate bottom and top mounts 520 and 522
(e.g., square plates) that are used to fasten cone 502 of FIG. 8a
to the underlying magnet/capacitor assembly. Similarly, respective
bottom and top mounts 333 and 331 are used to fasten cone 328 to
housing 330, as illustrated in FIG. 8b.  
  
Once assembled, ISF generators depicted in FIGS. 8a and 8b are
configured to produce ISFs that can be conducted from the apex of
the respective cone element to an ISF projector, without
conducting substantial electromagnetic radiation therewith. For
example, the cones are not electrically coupled through an
electrical conductor to the magnet/capacitor assembly. Thus, the
ISF generators themselves act as filters preventing
electromagnetic radiation from propagating along a path between
ISF generator and ISF projector. However, as mentioned above, a
decoupler can be provided in the path between an ISF generator and
ISF projector to ensure that little or no electromagnetic
radiation propagates between the ISF generator and ISF projector.  
  
FIG. 27b illustrates a wiring diagram for a system used to supply
a signal derived from a music player to an ISF generator such as
shown in the embodiments of FIGS. 8a and 8b. In one configuration
of the invention, high voltage amplifier 510, which contains DC
offset control 512 and DC polarity control 514, is contained
within main enclosure 516 of the high voltage amplifier.
Potentiometer 518 is used for gain control but DC polarity and
offset is preset and generally not varied by an operator of high
voltage amplifier 510, which is used to control inputs to an ISF
generator 500. Enclosure 516 is preferably provided with a
plurality of vent holes to allow cooling during operation of the
high voltage amplifier. FIG. 27b also shows receiver 276 and 12V
transformer 517a, 6V transformer 517b, and 3V transformer 517c,
dual instrumentation amplifier 519, each coupled to the receiver
276 and console 516 as shown.  
  
In one embodiment of the present invention, the electromagnetic
signal inputs coming from the high voltage amplifier are based
upon the original musical input from a CD or other music player,
as illustrated in FIG. 27a. These signal inputs are attached to
the capacitors, and therefore are the source of the changing
voltage on the capacitors, which in turn causes the magnetic field
to dynamically change in a magnet of an ISF generator, such as
magnet 326. Alternatively, high voltage signals in the form of
single frequencies, such as from a signal generator, can also be
used in the ISF generator of the present invention. The ISF
generator itself is useful in various embodiments of the present
invention. There is no limit to the frequency of the input, so any
signal from a frequency generator from small fractions of a Hertz
to Gigahertz frequencies have been shown to work for generating
ISFs. Frequencies in the visible light range have also shown to
work in the ISF generator of the present invention. Thus, there
appears to be no limitation with respect to potential frequency
inputs and resulting ISF outputs.  
  
FIGS. 18a-c illustrate further details of lamp module 304
discussed above with respect to FIG. 27a. As previously noted,
lamp 306 can receive input from an SCR controller 302 to rectify
the alternating current input, and, if desired, control operation
of lamp 306. In one embodiment, an SCR controller is utilized as a
dimmer to lamp 306, which comprises a 40-watt incandescent light
bulb to allow simultaneous variation in both the frequency output
range (and therefore informational output) and intensity of the
light from the bulb. In the presently preferred embodiment of the
present invention, the dimmer switch is employed as a rectifier
and is set to its maximum output level, without further
adjustments. A hexagonal reflector 310, illustrated in more detail
in FIG. 18b, is provided to surround lamp 306 and to generate a
static ISF in addition to the dynamic ISF produced by the light
from lamp 306 itself. Hexagonal reflector preferably comprises a
support structure to which inwardly facing mirrored surfaces are
joined on the interior of faces of a hollow prism structure shown.
Reflector 310 includes six steeply inclined trapezoid mirrors 310a
and one horizontal hexagonal mirror 310b provided with a central
hole As illustrated in FIG. 18c, reflector 310 may be joined to or
rest on a base 311, which forms a base of module 304. As
illustrated, an enclosure 313 is joined to the inwardly-facing
side of base 311. Enclosure 313 is configured to allow light to
impinge on cone 308 only on the inside surface of cone 308. The
combined static and dynamically generated ISF is collected into
cone 308, which also restricts the visible light from being
emitted from module 304. In one embodiment of the present
invention, the ISF created in module 304 is conducted through a
single strand copper wire that is brazed into the tip of cone 308
using a 72% silver/28% copper alloy. The ISF is conducted to a
copper ball radiator (shown in FIG. 23 and discussed further
below). In the embodiment of the present invention depicted in
FIG. 1, a multicolored 40-watt light bulb called "The Amazing
Rainbow Light," available from Special F/X Lighting Inc.,
Hurricane, Utah 84737, is used as the light source, providing
particular variations in the ISF output of the light ISF generator
as the SCR input to the bulb is adjusted.  
  
**ISF Conductors**  
ISF conductors useful in the present invention include metals,
such as copper, silver, gold, and other noble metals, but
preferably should not be (although can be) base metals, such as
tin or lead due to their potential distortion of an ISF during
conduction. Glass can also be employed as an effective ISF
conductor. In one embodiment, 12-gauge multi-strand copper speaker
wire can be employed to conduct the ISF from the ISF generators to
and from the fiber coupler assembly 286, and from there to the
hexagonal projector 290 (see FIG. 27a), as well as from the lamp
ISF generator assembly to the ball radiator (element 312 of FIG.
27a). The same type of wire can be used to connect the copper tape
from its junctions with the copper tubes with the distribution
assembly shown in FIG. 21a, and from the distribution assembly to
the copper panels of the footplate assemblies shown in FIGS. 7a
and 7b. If solder is employed at any point in the ISF conductance
means, copper, silver, gold, or other noble metal alloys are
preferred, preferably (although not necessarily) free of base
metals such as, for example, lead or tin. In one embodiment of the
present invention, machined copper and copper sheet can be
variously used for cones in the ISF conductance path, as depicted
generally in FIG. 10. Copper tubes and copper tape employed in
embodiments of the present invention and described above are also
part of an ISF conductance path, although the latter elements are
not connected directly to dynamic ISF generators. In embodiments
of the present invention, optical fiber, such as, for example,
quartz or other glass, or (less desirably) acrylic fiber can be
used as ISF conductor.  
  
**Attenuators**  
In one embodiment of the present invention, a fiber coupler
assembly is provided, as shown in more detail in FIGS. 16 and 27a.
FIG. 16 illustrates a side view of fiber coupler 286, in
accordance with one embodiment of the present invention. The fiber
coupler acts to transmit ISFs, which are being conducted to a
projector, while blocking the transmission of electrical or
electromagnetic signals. The fiber coupler also acts to couple
ISFs into and out of the cones along conductor 288. In FIG. 16, a
pair of couplers 286a, 286b is separated by takeup spool 287. In
one embodiment of the present invention, couplers 286a and 286b
comprise double cones having a phi ratio geometries. The effect of
fiber coupler 286 is to transition the ISF conductance from copper
wire to optical fiber and back to copper wire between an ISF
generator (see element 282 of FIG. 27a) and an ISF projector (see
the hexagonal projector 290 of FIG. 27a). The purpose of this
transition is to provide a positive filter blocking any
electromagnetic elements' ability to flow through the ISF circuit.
Light cannot be conducted through the copper conductors and
electricity and magnetism cannot be conducted through the optical
fiber conductors. Only ISFs, therefore, are conducted from the ISF
generator to an ISF projector such as the hexagonal projector 290
of FIG. 27a. As illustrated in FIG. 16, a metallic wire leads from
an ISF generator (FIG. 27a, element 282) into coupler 286a. Any
electrical signal entering into coupler 286a is prevented from
flowing further due to the insulating nature of optical fiber 289,
which is preferably glass or an insulating polymer. Although
optical fiber 289 can transmit electromagnetic radiation such as
light, any light entering coupler 286b is prevented from further
propagation, because the light does not propagate along metallic
wire 286c leading from 286b to a projector. Thus, any ISF
generated by an ISF generator and leaving coupler 286 is conducted
toward a projector without the presence of an accompanying
electromagnetic signal or electrical potential.  
  
In the embodiment illustrated in FIG. 16, each coupler 286a, 286b
comprises a pair of opposed cone structures joined at the base to
a common mount. Preferably, the bases of each pair of cones are
mutually aligned with each other as viewed down the axis of the
cone. Cones 286d are preferably copper cones, while cones 286e can
comprise an insulator such as polyester, as shown in FIG. 17. In
one embodiment of the present invention, a plywood box (not shown)
is placed around coupler 286, with the interior of the box painted
flat black.  
  
In one embodiment, cones 286e are polyester and have glass fiber
wound 11 turns at a 6 mm pitch as represented in FIG. 16. The
direction of the turns is clockwise on the input side, when viewed
from the cone's apex and wound counterclockwise, again viewed from
the apex of the cone, on the output side. The cones of FIG. 16 can
be mounted to plywood such that the copper and fiber wound cones
are aligned with each other. The input and output pairs of cones
are mounted on a common base for convenience. The fiber is, for
example, 50 micron optical fiber. The takeup spool is, for
example, a vertical, hollow, plastic spool, 1[1/2] inches in
diameter and 1[1/2] inches high, taking up excess of five meter
long optical quality glass fiber. The wire 286c can be 10 gauge 4
inch single strand copper wire brazed using 72% silver and 28%
copper alloy, with approximately [1/4] inch of the wire extending
into the cone.  
  
**ISF Projectors**  
In one embodiment of the present invention, the ISF output from at
least one ISF generator is conducted into the ISF environment of
the present invention substantially surrounding the individual by
means of one or more arrays of copper cones arranged in a
hexagonal projector. As discussed above, in one preferred
embodiment illustrated in FIG. 21a, an ISF projector 422
(hexagonal assembly) comprises six conical radiators 422a that are
employed in a hexagonal array focused upon the vicinity of the
center of the heart chakra (approximately the center of the
breastbone) of the individual within the ISF environment of the
present invention. Cones 422a are preferably objects having hollow
geometries, such as, for example, hollow cones having a base to
height ratio of phi, approximately 1.618.  
  
FIG. 20b illustrates an example of a copper or phosphor bronze
cone 422a, arranged in accordance with one embodiment of the
present invention. Cone 422a comprises an approximately 0.005''
thick sheet that is formed into an approximately 61.8\*100 mm cone
having an approximately 2 mm hole at the apex that accommodates a
wire, such as a solid 10 gauge wire, such as copper wire. A length
of about 5 mm of copper wire is inserted into the hole and brazed
with a low melting point material, such as copper/silver 72%/28%
eutectic alloy at an end 423. The joining can be performed using
for example a silver/copper alloy described above, which is
applied at the end of the wire, after which the wire is soldered
to the cone 422a, and the 2 mm hole is sealed. The unbrazed end of
copper wire can then be joined to another device, such as a
distributor.  
  
The arrangement of cones 422a is such that their bases are facing
downwardly when the assembly is affixed in a structure, such as
structure 400. As described above, the axes of the cones all
preferably converge upon a point below the array that can serve to
project dynamically created and statically created ISFs in a
region in the vicinity of the heart chakra of an individual lying
in structure 400, as illustrated in FIG. 2a.  
  
ISF projector 422 can also include a distribution assembly 422b
(340), an embodiment of which is illustrated in FIGS. 21a and 27a.
In the embodiment of the present invention depicted in FIG. 27a,
distribution assembly 340 is connected to conductor 284 and
receives a dynamically generated ISF from generator 282. As
further illustrated in FIG. 21b, distribution assembly 422b
comprises a metallic star shaped base 422c affixed to a metallic
cone, in which the apices of the star point to the points of the
hexagonal top plate. Conductor 284 is coupled to the apex of cone
422e. Attached to each point of star shaped base 422c are wires
422d that each lead to an individual cone 422a, depicted in FIG.
21a. Accordingly, the dynamic ISF received from ISF generator 282
is distributed to each cone on assembly 340.  
  
In one embodiment of the present invention depicted in more detail
in FIG. 24, a hexagonal projector 216 is configured to slide in a
horizontal direction along tube 212, which is an uppermost tube of
an array of tubes connecting end members 206 within structure 200.
Accordingly, the position of hexagonal assembly 216 can be
adjusted according to an individual's size, so that it can be
maintained over the heart chakra or other area of individuals of
varying height. The centers of bases of cones 218 are located on a
common plane that is about 27.0'' above bed 202.  
  
FIG. 23 illustrates details of a ball radiator ISF projector 312,
according to one embodiment of the present invention. Ball
radiator 312 comprises a copper ball 314 located at the end of a
multi-strand wire 316. In one embodiment, the diameter of the
copper ball 314 is about [5/8] inch. As discussed previously, ball
radiator 312 is connected to an ISF source that employs a light
source. Ball radiator 312 is mechanically coupled to hollow tube
318 so that the position of copper ball 314 can move along a
horizontal direction when hollow tube 318, which is configured to
slide along copper tube 212, is moved. Thus, ball radiator 312 can
be adjusted to remain in the same relative position with respect
to the head of individuals of varying height.  
  
**Individual Monitoring Equipment**  
In one embodiment of the present invention, a video camera is
provided to furnish observational input of the individual to an
operator (via a monitor) or to a computer, for manual or automated
employment, respectively, in adjusting the ISF inputs to the
environment to achieve harmony and therefore maximize stress
alleviation for the individual substantially within the ISF
environment. If no visible light is present within the
environment, either a passive infrared-sensitive video camera of
sufficient resolution or an IR video camera and an IR light
positioned, for example, as shown in FIGS. 2a and 2k, may be
provided for such purpose. Also located in structure 200 (400) are
IR light source 215 (427) and IR camera 217 (425). Light source
215 can provide sufficient illumination inside structure 200 so
that IR detector can detect images of objects within structure
200, including details of an individual reclining in structure
200. IR light source 215 is configured to produce radiation of
frequency and intensity to cause minimal disturbance to an
individual in structure 200. Accordingly, the individual can be
observed during exposure to the ambient ISF environment without
undue disturbance. In other embodiments of the present invention,
other sensors may alternatively be substituted for a video camera
as aids in adjusting the ISF inputs to the ISF environment of the
present invention to assure that it is harmonious for the
individual.  
  
Monitoring of individuals, such as observation of eye movements is
helpful in ascertaining an appropriate duration of destressing
session. When a dynamically created ISF is provided to an
individual, a destressing process may begin to take place over a
short period of time, for example ten to twenty minutes. The
destressing may be associated with reconfiguring of the
individual's own biofield, such that the individual experiences
conscious sensations, such as a feeling of relaxation. Autonomic
responses such as involuntary eye movement are believed to be an
indication that the adjustment taking place in response to the ISF
is no longer comfortable. As discussed above, this may be due to
an inharmonious ISF environment usually because the intensity of
the ISF is too high. However, such autonomic responses observed
after a period of time may indicate that the individual is no
longer able to accommodate further biofield readjustment
comfortably during that session. Thus, a residence time of
individuals in the destressing system can be adjusted according to
observed indicators, such as involuntary eye movement. The
intensity of the ISF projected toward an individual can be lowered
by adjusting a high voltage electromagnetic signal input to a
dynamic ISF generator.  
  
**Other Hardware**  
In one embodiment of the present invention, an audio speaker or
set of speakers is provided that is coupled to a music source,
such as source 272 in FIG. 27. The audio speaker receives an
electrical signal from an amplifier and, at the option of the
individual subject, can project audible music into the environment
of such individual located in system 200. The music corresponds to
the same electrical input sent to an ISF generator, such as
generator 282, which electrical signal is then blocked from
propagating toward the individual along the ISF conduction path.
The electrical input into the speaker or set of speakers is
transformed into sound by transducers in the speakers.
Accordingly, very little, if any, electrical or electromagnetic
energy is transmitted from the speakers toward the individual.
Preferably, the set of speakers is located outside of the region
containing the individual and the ISF projectors.  
  
The present invention offers potential of improved efficiency as
compared to means of achieving stress reduction by practices of
the prior art. Significantly positive results are observable in a
15 to 30 minute exposure to the informational spin filed
environment of the present invention. Individuals experiencing the
ISF environment of the present invention typically report feeling
a sense of stress reduction, revitalization and wellness. In
addition, they often report subsequent healings apparently as a
result of being destressed.  
  
While not wishing to be bound by any particular theory, it is
believed that consciousness effects facilitated by the environment
created within the apparatus of the present invention precipitate
the destressing results experienced by individuals spending one or
more sessions therein. The following is a non-binding explanation
of how and why this is believed to occur.  
  
The human biofield is an ISF whose information content is
comprised of ideas or thought forms derived from both the waking
(or rational) and subconscious levels of consciousness or
awareness. Information inputs to this field from the rational
level occur continually as thought and emotion occurs within that
level of consciousness, creating content that tends to be
transient, except to the extent adopted by the subconscious as
part of its evolving self-identity and belief systems. Information
inputs to the biofield from the subconscious level tend to be more
long term in their tenure in the field, representing fundamental
attitudes and convictions adopted by the subconscious concerning
the individual's self-identity and worldview. Stress in an
individual occurs as a result of: a) negative experiences which
are not resolved and are adopted as part of an individual's
self-identity as beliefs of having been somehow injured, and b)
the exposure of an individual to fears and ideas of limitation
about themselves which they do not reject but to which they have
come to believe themselves to be subject, and accept as part of
their self-identity. Such adopted negative aspects of identity
(stress) are then reflected on an extended basis in the ISF that
is the biofield of the individual as disharmonious information
content.  
  
The biofield is the medium by which the consciousness of an
individual communicates with and directs the cellular and
biophysical activity that creates and maintains the individual's
physical presence. When disharmonious information content (stress)
appears in the biofield on other than a transient basis, it
becomes part of the instructions that direct the creation and
maintenance of the individual's physical body, and becomes
manifested as physical disharmony in the form of disease and
dysfunction. Disease and dysfunction can be seen, therefore, as
the efforts of one level of consciousness (the subconscious)
trying (by means of physically manifested disharmony) to get the
attention of another level of consciousness (the waking, or
rational, level), to get it to recognize and resolve (heal, or
discharge) a corruption of the harmony of the individual's
self-identity.  
  
When one enters the very powerful and harmonious ISF existing
within the environment of the present invention, the subconscious
of the individual becomes instantly aware of that field, as well
as its greater degree of harmony as compared with the field that
the individual has himself or herself created. This awareness
causes a response in the individual in which the level of their
subconscious then connects with the level of their superconscious
(the highest level of their awareness, which is omniscient), in
order to try to understand what is occurring. During that
connection, the subconscious becomes aware of the specific
elements of disharmony that it has adopted into the biofield which
it has created, and begins to eliminate those disharmonies issue
by issue, resulting in the de-stressing of the individual. As
stress disappears from the field of the individual over a series
of destressing sessions, they naturally progressively resume a
more harmonious physical and mental state, as their innate
self-healing mechanisms operate unimpeded by accumulated stress.  
  
Various therapies involving the direct use of light, color and
sound on individuals have found a need to vary the frequency
inputs specifically to needs of the individual at the particular
time of treatment in order to be effective or beneficial. While
indeed it is possible to input frequencies of information tailored
to address the current needs of a specific individual using the
present invention, it is believed to be unnecessary. In the
preferred embodiment of the present invention, only the intensity
of the field is typically being adjusted, so as not to overwhelm
the individual and so as to be of sufficient intensity to
facilitate the consciousness connections above described. The
music and light frequency inputs chosen are universal. (For
example, any of the music sources listed in Table 1 can accomplish
the facilitating environment of the present invention.) A key
aspect of this modality of the present invention is that the need
to choose or structure specific individualized informational
inputs is absent: the informational changes necessary to destress
the individual are coming directly from within themselves from
their highest level of consciousness, which is omniscient and
therefore incapable of harming them by introducing inappropriate
inputs. Essentially, the present invention creates a facilitating
environment where the individual is progressively "remembering"
their perfect state devoid of the accumulation of disharmonious
experiences and limitations, progressively jettisoning aspects of
self-image that do not fit harmoniously. This is often one of the
goals of meditators, namely to silence their lower levels of
awareness and connect with their highest levels of awareness to
become more aware of harmony. Indeed, it has been observed by
individuals experienced in regular meditation that being in the
environment of the present invention is "like meditating with the
static removed," and that following even a single session in the
harmonious ISF environment of the present invention that achieving
meditative states thereafter seems easier than before.  
  
There are numerous modalities for healing that operate by
introducing various types of informational intervention and/or
programming of the individual. These inevitably require
receptivity and willingness to accept such informational changes
on the part of the recipient. Some of these modalities operate at
the level of the subconscious and some directly at the level of
the human biofield, to eliminate or otherwise compensate for
informational influences that have their origins in stress. These
include hypnotherapy, acupuncture, qigong, pranic healing, Reiki,
and homeopathy. All of these rely to some degree on the skill of
the practitioner in either diagnosis, treatment or both, and in
certain circumstances may present various potentials for either
ineffectiveness or perceived harm to the individual if the
informational inputs are inappropriate to the need.  
  
A preferred embodiment of the present invention comprises a method
for achieving destressing of an individual without any necessity
for diagnosis or treatment by a practitioner. Such method
comprises placing an individual in an environment into which both
statically derived and dynamically derived ISF elements are
present, from which the electromagnetic components have been
removed from at least one such dynamic ISF element.  
  
One example of such a preferred embodiment can be accomplished in
the apparatus described above. An individual lies on the mattress
of the bed for typically a 20 minute session, during which time a
dynamic ISF derived from a musical source with appropriate
harmonious characteristics (such as, for example, one of those
illustrated in Table 1) is provided in addition to one or more
static ISFs. Such dynamic source is adjusted downward in intensity
if necessary to assure that no involuntary eye movement is being
exhibited by the individual within the apparatus. The subject will
often afterward report perceptions of tingling or other sensations
in the body, and perhaps colors and/or visions observed mentally.
Upon emerging from the session feelings of renewal and
revitalization are commonly reported. Subsequent observations of
later healings are often reported as well, believed to be the
result of destressing. Occasionally increased abilities are later
reported to be manifesting, such as the ability to perceive ISFs
visually as colors, spontaneous receiving of correct but
previously unknown information, premonitions, and increased
awareness.  
  
A characteristic of the ISF that is the human biofield is that it
has both right handed and left handed elements, and circulates
within and surrounding an individual's physical body.
Disharmonious information contained in the biofield manifests as
blockages in the normal flow of the ISF. The science of
acupuncture is directed at the intervention at acupoints to
attempt to unblock such flow blockages. Disharmonious information
contained in the biofield also manifests as imbalance in the
parasympathetic and sympathetic elements of the autonomic nervous
system. In connection with the present invention, it is postulated
that the progressive abandonment of negative elements of
self-identity by the subconscious as a result of connecting with
the superconscious in the ISF environment of the present invention
appears to result in the removal of blockages to the ISF flow of
the individual's biofield. The ISF of the present invention is
itself observed (by those who can either feel them or perceive
them visually) to circulate more or less along the longitudinal
axis of the hexagonal prism space, radially out at the bulkhead at
one end, and back along the copper tubes to the other bulkhead,
then radially inward and then back through the middle of the prism
space along its longitudinal axis. This circulation appears to
occur despite no means being deliberately introduced to cause such
circulating flow. The ISF flow has been observed to vary in
direction (from head to feet of the individual, or vice versa)
with different individuals, but has been perceived to be
harmonious.  
  
The destressing device of the present invention is preferably
located in a quiet setting. A typical procedure for conducting a
destressing session in the apparatus of the present invention is
as follows:  
  
The operator turns on power to the main electronic console,
including the lamp ISF generator assembly, CD player, infrared
camera, video monitor, and infrared light (if needed-ambient room
lighting may be sufficient to not require the IR light for the
camera). A CD music recording such as one of the albums described
in FIG. 1 is placed in the CD player. The client individual
removes shoes, metal, jewelry and eyeglasses to the extent
feasible. The removable copper tube (entrance tube) on the side of
the destressing device is removed by the operator, and the
hexagonal projector is slid to the far left extreme of its travel
within the hexagonal prism space of the destressing device. The
ball radiator assembly is slid to the extreme right of its travel
within the space. The client individual then enters the prism
space, lying on their back with their head to the right, their
feet to the left, and their arms at their sides with their body
substantially aligned in the direction of the axis of the prism
space. One or more pillows and/or a blanket may be provided for
the comfort of the individual. The ball radiator is then slid to
the left and positioned so that the copper ball is above the
vicinity of the "third eye" chakra (the middle of the forehead
region an inch or so above the eyebrows) of the individual. The
hexagonal projector is slid to the right and positioned such that
its center is above the vicinity of the heart chakra
(approximately the middle of the breastbone) of the individual.
The two foot paddles are strapped to the bottoms of the
individual's feet using the Nylon(R) hook and loop straps attached
to them. The entrance tube is then replaced into the destressing
device.  
  
The individual is offered the choice of hearing the music from
which the ISF will be derived or not. If the individual elects to
hear it, a switch is enabled which will route the electromagnetic
audio signal from the CD player to small speakers located in the
upper right quadrant of the destressing device, above the prism
space, in addition to the signal still being conducted to the ISF
generator. (An adjustable volume control for the speakers is
located on the right bulkhead of the destressing unit at the edge
of the prism space within reach of the individual.) The operator
then pushes the "play" button of the CD player, activating its
electromagnetic audio signal output. The "gain" knob which
controls the ISF strength of the output of the hexagonal projector
is set by the operator at a value of "3" as marked by its dial.
The switch at the panel of the electronic console which activates
the high voltage amplifier (main "field switch") is then turned on
by the operator, empowering the ISF generator and its output which
feeds the fiber coupler and hexagonal projector.  
  
The operator then looks at the video monitor screen to determine
whether the ISF field strength within the destressing device is
too strong for the individual within, an affirmative indication
being demonstrated by involuntary eye movement of the individual,
such as rapid blinking of the eyes. If such eye movement is
observed, the operator promptly reduces the gain until the
individual's involuntary eye movement response is eliminated. If
the involuntary eye movement persists regardless of the gain
setting being at its minimum, the session is promptly ended by
flipping off the field switch, detaching the foot paddles, sliding
the hexagonal projector and ball radiator back to their extreme
positions, removing the entrance tube, and assisting the
individual's egress from the prism space, and then replacing the
entrance tube in the destressing unit. (While the entrance tube is
removed from its normal registry with the geometry of the prism
space, the ISF within the prism space is less coherent. A property
of ISFs is that they increasingly condition space to their
informational properties as a function of time; therefore the
entrance tube is stored in its regular geometric position in order
so as not to condition the prism space somewhat incoherently.) The
typical explanation for a prompt termination to the destressing
session would be that the individual is still processing physical
change fallout from a recent improvement to their biofield, and
therefore is subconsciously signaling the need for more time to
elapse before attempting more improvement to their field so as to
not overwhelm their body with the activity of physical change.  
  
Normal time scheduled between destressing sessions would be at
least a week; however, critically ill individuals tend to process
change faster and are often scheduled at four day intervals.
Assuming no involuntary eye movement is observed and therefore
that the session is not terminated immediately, the operator then
promptly mentally asks for the protection of the individual from
any outside negative mental influence, mentally sends
unconditional love to the individual, and mentally expresses
gratitude for what is occurring in the session. The individual
will typically remain within the destressing unit for a total of
twenty minutes in a single session, with the operator checking the
monitor for involuntary eye movement every five minutes or so to
determine whether the session should be terminated sooner than
twenty minutes, in which case at the end of the session the
termination procedure is as previously described. The operator
asks for any perceptions of the individual during the session
(sensations, experiences, observations). If several sessions occur
over a few weeks with no perceptions reported by the individual as
occurring during the sessions and no subsequent benefits are being
noticed in wellbeing or capabilities, the gain setting will be
progressively increased by the operator from session to session in
0.5 increments until effects are beginning to be perceived by the
individual. Following a session, the operator advises the
individual to drink plenty of water for at least the four days
following the session in order to allow detoxing and bodily repair
processes that tend to follow as a result of destressing to
operate unimpeded by lack of hydration.  
  
**Parts Specifications and Assembly Instructions for an Exemplary
Destressing System**  
The discussion to follow makes reference to tables and figures
that provide descriptions of exemplary components (e.g.,
electronic parts), materials, and assembly details associated with
manufacturing an embodiment of the present invention. The
discussion is presented within the context of the embodiment of
FIG. 2k, and the referenced "main assembly" refers to the system
generally depicted in FIG. 2k. The ISF generator described below
corresponds to the embodiment depicted in FIG. 8b, while the ball
radiator corresponds to the embodiment depicted in FIG. 23.
Notably, many of the steps listed below for construction of the
main assembly depicted in FIG. 2k can be employed for construction
of the system depicted in FIG. 2a. Similarly, the ISF generator
depicted in FIG. 8a can be constructed according to many of the
steps listed below, with the understanding that the latter
embodiment does not employ an aluminum housing to contain the
magnet/capacitor assembly. In addition, apparatus that include
combinations of the components described above are within the
scope of this invention. For example, a main assembly constructed
according to the steps below could incorporate an ISF generator
built in accordance with the embodiment disclosed in FIG. 8a and a
ball radiator disclosed in FIG. 22a. Thus, notwithstanding the
discussion below with respect to the embodiment of FIG. 2k, one of
ordinary skill in the art would appreciate that similar assembly
methods could be applied to other embodiments.  
  
**TABLE 2**  
**CD Player**  
  
**TABLE 3****Sound Amplifier**  
  
**TABLE 4**  
**High Voltage Amplifier**  
**MECHANICAL**  
Front Panel Controls:  Gain adjust; DC Polarity selector
(+,  0, -); DC offset adjust  
Rear Panel Controls:  On/off switch; Line voltage selector  
Terminals:  BNC for Input (ground referenced); safety
shrouded banana jacks for high voltage  output terminals
(ground referenced)  
Weight:  6.4 kg (14 lbs)  
Dimensions:  12'' (305 mm) long \* 12'' (305 mm)  deep \*
5'' (127 mm) high  
4. Copper tubing: Schedule 40 copper pipe such as used in
plumbing.  
5. Copper tape: 3/16'' such as used in stain glass.  
6. SCR dimmer: Such as available at any hardware store.  
7. Lamp socket: Such as available at any hardware store.  
8. Copper sheets: Annealed copper sheets 0.005'' thick.  
9. Bronze sheets: Phosphor bronze sheets 0.005'' thick.  
10. Ball Radiator: Metal ball. 99.9% copper, solid, 0.631''
diameter.  
  
**TABLE 5****IR Camera** **TABLE 6**  
**IR Camera Power Supply**  
**TABLE 7**  
**IR Light Source**  
**TABLE 8**  
**TV Monitor**  
15. Type of Optical Fiber: UV/VIS High OH content fused silica
core and cladding. These are a stepped index, multimode fiber with
a core diameter of 250 um. Has a polymer buffer on for protection.
Fiber ends are not polished. Numerical Aperture: 0.22+/-0.02.  
  
**Exemplary Methods for Building the Assemblies**  
  
The discussion below provides exemplary methods for assembling
components of a system for destressing in accordance with
embodiments of the present invention. To aid in understanding,
reference is made to the Figures.  
  
1. Magnet and Cone ISF Generator  
  
To construct an ISF generator, reference is made to FIGS. 8b, 9,
10, 11, 12, 13, 14, and 15.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. As illustrated in FIG. 14 and FIG. 8b, cut the Bronze and
Teflon(TM) sheets so that they are 2 times the width of the magnet
and can be wound 3 times around the magnet. One set is for the
outside of the magnet, the other for the inside. Then, layer the
bronze and Teflon(TM) sheets such that the Teflon(TM) is layer
between the bronze and also insulates the bronze from the magnet.  
  
2. FIG. 9 illustrates connecting of wires to the outer capacitor,
which is done by cutting back the Teflon(TM) sheet on the outside
of this capacitor and exposing a small area of bronze sheet. To
connect to the inner capacitor, the same technique applies, but in
addition a small v shaped cut needs to be made on the outer
capacitor since, as seen in the ISF assembly drawing, there is no
room between the top of the capacitors and the ISF housing (part
12 in FIG. 15). A one MegaOhm resistor is placed across the
inputs. An input voltage of up to 150 V can be supplied, where a
positive bias produces a right handed ISF and negative bias
produces a left handed ISF.  
  
3. A bulk head BNC connector is mounted to the side wall of the
aluminum housing (FIG. 15). The aluminum housing can be sheet
metal or purchased from an electronic supply catalog. A SPST
toggle switch is mounted next to the BNC connector.  
  
4. A 1 Mega Ohm resistor is soldered across the inputs to the ISF
generator, typically in between input connector and the wire
soldered to the inner and outer capacitors.  
  
5. The outside diameter of the ring magnet should match the
diameter of the copper cone above, as illustrated in FIG. 8b. In
FIG. 13, exemplary magnet dimensions include a 8.4 mm thickness, a
60 mm inner diameter design to couple to a 60 mm cone and a 29 mm
inner diameter.  
  
6. A Teflon(TM) sheet is inserted between the top of the
capacitors and the ISF housing as well as between the bottom of
the capacitors and the aluminum plate underneath.  
  
7. As illustrated in FIGS. 8b, 11, and 12 a copper cone 328 is
mounted to the top of the ISF housing with the top and bottom
Teflon(TM) mounts, 331 and 333, respectively. In one embodiment,
the cone is about 37 mm\*60 mm. Teflon(TM) screws are used to
attach mounts 331, 333 to the ISF housing (see FIG. 8). Bottom
mount 333 is each a 2 mm thick 84 mm\*84 mm square gasket having a
56 mm diameter circular hole in the center and four 1.6 mm
diameter through holes for fasteners spaced 70 mm apart. Top mount
331 has similar dimensions as bottom mount 333, except that the
gasket thickness is 6 mm and the circular hole is beveled at a 51
degree angle, such that the diameter decreases from 60 mm at the
bottom of gasket 331 to 48 mm at the top of gasket 331.  
  
8. As illustrated in FIG. 10, copper cone 328 can comprise a 1-2
mm thick sheet of 99.99% oxygen free copper formed into a cone
whose base diameter is 60 mm, and having a tapped hole configured
to accommodate a 1.5 mm or 1/16'' thread screw.  
  
9. Either a copper or bronze screw, or solder, can be used to
attach a wire to the top of the copper ISF cone 328.  
  
10. A switch can be inserted on either the + or - input lines so
that the ISF can be switched off independent of the other
equipment (see FIG. 8).  
  
11. An aluminum base 325 is used to mount the magnet 326. The
aluminum base 325 is supported by four Teflon(TM) standoffs
located in the corners. A fiber or Teflon(TM) washer is used to
center the magnet 329. The distance between the aluminum base and
top of the housing 330 is twice the thickness of magnet 326.  
  
2. Fiber Coupler  
  
To construct a fiber coupler (also termed coupler), reference is
made to FIGS. 16, 17, 20.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Provide an appropriate length of fiber: A 10M long strand of
fiber is preferably used.  
  
2. After using the specification in FIG. 17 to create the
insulator cones, wind 9 turns in an 8 mm pitch spiral, starting at
0.188'' from the base of the original cone. This offset from the
base of the cone is due to the fiber board which is glued to the
base of the cone for mounting and strength. Insulator cone 291
comprises a 62.8 mm\*101.6 mm cone as shown.  
  
3. Direction of windings: In Assembly 06 drawing (FIG. 16), the
input is on the left and the output is on the right. The
directions of the windings, when looking down on the apex of the
input fiber cone is clockwise and it is counter clockwise on the
output cone.  
  
4. Two 61.8\*100 mm copper cones of 0.005'' thick copper are built.
As illustrated in FIG. 16, the two copper cones are each mounted
so that the axis of the two input and the two output cones are
aligned. The distance between the base of the input copper cone
and the input fiber cone is 3/16''. There is no requirement for
the distance between the pair of input and the output cones 286a,
286b. In this drawing they are set 8'' apart for convenience and
the extra fiber is wound around a small spool 287 that is disposed
between cone pairs 286a, 286b. The takeup spool 287 is a vertical
hollow insulator tube having a 1.5'' diameter and height, and
having four turns of fiber in the example shown in FIG. 16.  
  
5. The cones are mounted on a polymer foam board, such as a
5''\*5'' board.  
  
3. Distribution Box  
  
To construct a distribution box, reference is made to FIG. 25.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Using an annealed copper sheet of about 0.005'' thickness cut
out a hexagon pattern having an inner hexagon portion of about
1.84'' distance between opposed sides, with triangular tips
extending 0.66'' outwardly from each hexagonal side, as shown in
Part 16-01 of FIG. 25. The pyramid shapes that extend from the
periphery are not separate but are integral to the whole base
plate 342.  
  
2. Cut a piece out of the annealed copper sheet so that a cone 344
having the dimensions shown in Part 16-02 of FIG. 25 can be made.
Use solder along the outside seam to form the cone, which has
dimensions of about 1'' in height and 1.62'' in diameter.  
  
3. Mount the cone 344 in the center of the base 342, as shown in
the bottom left of FIG. 25, and use solder to tack down the edges
of cone 344 in 6 places.  
  
4. Soldered an input wire to the tip of the cone 344 in the manner
shown in Part 06 (FIG. 20).  
  
5. Solder 6 output wires to the tips of the hexagon pattern.  
  
6. Mount the distribution assembly 340a in a suitable non-metal
housing.  
  
4. Hexagonal Projector  
  
To construct a hexagonal projector, reference is made to FIGS. 19,
20, and 21a, respectively.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Cut part 15-02 to 07 from polymer foam board (see FIG. 19).  
  
2. Cut part 15-01 from the same material (see FIG. 19).  
  
3. Assemble these pieces as shown in FIG. 19. Hot glue or any
other bonding material can be used to affix parts 15-01 to 15-07
together. Once assembled, the face of every piece forms a 30
degree angle with respect to the bottom plane, as shown in FIG.
20a.  
  
4. Once parts 15-01 to 15-07 are assembled, two slots are cut on
opposite tips of the hexagon assembly, as shown in the bottom left
of FIG. 19.  
  
5. Assemble 6 copper cones 218 (the term "copper cones 218" also
is meant to include phosphor bronze cones, unless otherwise
indicated) in the manner shown in the drawing for Part 06 (FIG.
20a). Use solder on the outside seam of the cones.  
  
6. Mount the wires in the manner shown in FIG. 20.  
  
7. Mount the 6 cones 218 in the center of the six faces of the
hexagon structure 216.  
  
5. Lamp Assembly  
  
To construct a lamp assembly, reference is made to FIGS. 18b.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Cut 6 pieces of mirrored glass according to the specifications
for parts 14-02 to 14-07 (FIG. 18b).  
  
2. Cut a piece in the shape of element 310b (FIG. 18b).  
  
3. Core drill a 1.125'' hole into element 310b (FIG. 18b).  
  
4. Assemble parts to form reflector structure 310 (FIG. 18).
Mirrored surfaces of the mirrored glass face toward the inside the
resulting structure 310. Any manner of techniques can be used to
assemble these pieces but nothing should touch the inside surfaces
of this assembly 310. Copper foil tape can be used on the outside
surfaces to hold the assembly together and then a wooden box can
be made to secure the whole assembly.  
  
5. Build a copper cone 218 as specified in Par 17-02 of FIG. 10.  
  
6. Mount this cone in a plywood frame supporting the lamp housing
and connect to a wire to form ISF generator 304 as shown in
Assembly 03 (FIG. 18a). The opening of the cone should remain open
to the interior of the reflector without obstruction.  
  
6. Ball Radiator Assembly  
  
To construct a ball radiator assembly, reference is made to
assembly Drawing 08, which is contained in FIG. 23.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Using a copper ball 314 of about 0.625'' diameter solder 16
gauge wire to it of sufficient length so that it can be connected
to the copper cone in the Lamp Assembly described above.  
  
2. Cut a piece of wood 317 that is 6'' long by 1.5'' wide by
0.75'' thick.  
  
3. Cut a 30 degree angle with the long side being 6'' and short
side being 3''.  
  
4. Cut a 1'' ID PVC tube 318 in the manner shown in the FIG. 23.  
  
5. Mount the wooden piece to the PVC pipe, preferable with screws.  
  
6. Use screws to mount a 9'' long [3/8]'' diameter dowl 319 to the
bottom of the wooden mount.  
  
7. Attach a wire 316, preferably 16 gauge multi-strand wire, with
copper ball 314, to the wooden dowel 319 with wire ties.  
  
7. Main Assembly  
  
To construct a main assembly, reference is made to FIGS. 2k, 3, 4,
5, 6, 7b, 2, 24 and 26, respectively. Further detailed description
of respective parts is also provided below.  
  
In one embodiment of the present invention, the following
exemplary steps are performed:  
  
1. Cut 6 1'' diameter copper piping 212 to 88'' in length, as
illustrated in FIG. 2a.  
  
2. Use copper foil tape to outline the pattern 208, as shown in
FIG. 4. The hole diameter for a pattern of hexagonal through holes
cut through an inner end member (204b of FIG. 4) is preferably
about 1.125.'' Copper foil tape is preferably folded at its ends
that form the star apices, such that the foil tape is folded into
the 1.125'' diameter holes, in order to endure good contact with
copper tubes 212 when the end of the tubes are placed into the
holes. The junctions 204d of copper tape are preferably solder
together, as illustrated in FIG. 4.  
  
3. On an inner panel 204b for the bottom, solder 6 16 gauge wires
to the tips 210 of the hexagon pattern.  
  
4. Sandwich the inner and outer panels together, as illustrated in
FIG. 2a. As illustrated in FIG. 3, make sure that an outer panel
204a having 6 wire feedthrough holes (204c, in the example shown
in FIG. 3), is joined together with an inner panel (see panel
204b, FIG. 4) that has six wires soldered to the apices 210 copper
foil hexagon pattern. The configuration described in steps 3-5 can
be applied to both end members 204 and 206.  
  
5. As illustrated in FIGS. 3 and 4, a 0.188'' diameter feed
through hole is also provided in the center of the hexagonal
patterns in panel 204a and 204b only, which provides for a wire
connection to a foot panel.  
  
6. Mount a bed 402 (see FIG. 5) to one of the panels 204, 206
using carriage bolts. Bed 402 preferably comprises a [3/4] Luaun
Surface finished plywood board, about 33''\*86.5.'' The plywood
board is supported by a series of three wood cross braces 402c
about 1.5''\*9.5''\*19.75'' illustrated in FIG. 5. In addition, two
10''\*86.5'' lengthwise braces 402d are used to support bed 202.
The braces can be secured to bed 402 by 1.25'' deck screws spaced
at 6'' intervals. In the embodiment of the present invention
illustrated in FIG. 4, each end member has a height of about
53.64.'' The bottom side dimension is about 39.17'' and the top
portion is beveled so that its width is about 13.188'' and the
side edges have a height of about 46.64.'' The bed is mounted
about 17.50'' above the bottom of board 204, which is above the
line described by a pair of lower holes 210 that are 12.625''
above the lower surface of the end member.  
  
7. Then the six copper tubes 212 are inserted into a first inside
panel 204b or 206b. The outer four tubes are located 3'' from the
front and back edges of the end member. The pair of upper holes is
located 32.375'' above the lower surface of the end member, while
the topmost hole is located 41.25'' above the lower surface.
Accordingly, the center wire feedthrough is located about 2''
above the bed 202. As illustrated in FIG. 4, a slot 204e is
provided on panel 204b so that one copper tube 212 disposed to the
outside of panel 204b can be removed, thus promoting easy entry
and egress to bed 402. Using the second of the inner-outer panels
206b, 204b align the 6 copper tubes 212 with the holes in the
second panel, and mount the bed 202 using the appropriate carriage
bolts.  
  
8. Prepare a top assembly 424 comprising a top panel 424a about
12.75''\*87.5'' as shown in FIG. 6. Support the top assembly using
two 1.5''\*3.5''\*12.75'' cross braces 424b and two
0.75''\*3.5''\*86.5'' face strips 424cc, the latter preferably made
from 0.75'' Luaun Surface Finished Plywood. Mount the top assembly
424 (see FIG. 6) to the support comprising bed 402 (also shown as
202 in FIG. 2k) and end panels 204, 206, and fasten assembly 424
in place using 0.375'' diameter carriage bolt holes provided in
end members 204, 206, as illustrated in FIGS. 2k and 3.  
  
9. As illustrated in FIGS. 24 and 26, place the hexagon assembly
216 on the top copper tube 212, making sure that the copper tube
212 fits well inside the two notches 216a (see FIG. 19) cut into
the two ends of this assembly. In one embodiment, the hexagonal
assembly support structure 216b comprises a set of 0.188'' thick
polymer foam board pieces. The notches 216a are formed by cutting
adjacent portions from abutting pieces of the hexagonal assembly
to form 3.5''\*1.125'' notches, as illustrated in FIG. 19. Use a
suitable material to build a box 219 between the top of the
hexagon assembly and the bottom of the top assembly 424, as
illustrated in FIGS. 24 and 26. A Teflon(TM) sheet is then
inserted between this box structure 219 and the Top assembly to
reduce friction. The box structure 219 acts to keep assembly 216
parallel to bed 402. The hexagon assembly 216 can be enclosed with
a suitable housing. Once complete, this hexagon assembly 216
should slide back and forth along the top copper tube 212 with
ease, but the hexagon assembly 216 must remain parallel with the
bed 402. Make sure that the center of the cones 218 in the hexagon
assembly are about 27'' above the bed 402.  
  
10. As illustrated in FIG. 23, a slot is cut in PVC tubing 318 to
fit around the copper tubing 212. The ball radiator 312 is mounted
by snapping the slotted PVC 318 over the top copper tube 212
between the hexagon assembly and the headboard.  
  
11. Mount the IR camera 217 on the top assembly as shown in FIGS.
2k and 24. The IR camera is adjusted so that the head of an
individual lying on foam mattress 203 is viewable on a monitor.  
  
12. Mount the IR light source 215 with a suitable gooseneck mount
as shown in FIGS. 2a and 24. The angle of light source 215 is
adjusted to illuminate the head of an individual lying on mattress
203.  
  
8. Setting up the Electronic Hardware  
  
Below is an exemplary list of hardware used to generate electronic
signals, and generate ISFs.  
  
Parts list:  
  
1. Philips CD player or any comparable CD player. See exemplary
specification details above.  
  
2. Yamaha or any comparable Sound Amplifier/Stereo receiver with
greater than 30 W per channel of amplifier output. See exemplary
specification details above.  
  
3. Piezo Systems Linear Amplifier or any comparable High Voltage
amplifier capable of taking a 10 V peak-to-peak signal in and
outputting a minimum of 120V but not greater than 200V signal. The
Piezo Systems Amplifier has a Bias offset which is necessary in
this device. See exemplary specification details above.  
  
4. ISF Generator: See construction details above.  
  
5. Fiber Coupler: See construction details above.  
  
6. Distribution Assembly: See construction details above.  
  
7. Main Assembly with Hexagon projector and Ball Radiator Assembly
are already installed.  
  
8. SCR Lamp dimmer.  
  
9. Lamp Module: See construction details above. Lamp ISF Generator
illustrated in FIG. 18.  
  
9. Connecting the Hardware  
  
Below is an exemplary set of steps for connecting various hardware
elements of a destressing apparatus, constructed in accordance
with an embodiment of the present invention.  
  
1. Referring again to FIG. 27a, connect the outputs of a CD player
272 to the Aux (or other comparable inputs) of the sound amplifier
276 using a standard phono jack cable 274.  
  
2. Take a standard coax cable with BNC connectors that can be
bought at any electronics store and cut one of the ends off. Take
16-gauge speaker wire and solder it to the core wire and another
wire to the shielding. Connect the core wire to the positive
speaker terminal and the shield wire to the negative speaker
terminal (either right or left channel). Connect the other end
with the BNC connector and attach it to the male BNC input
connector on the front panel of the high voltage amplifier 278.  
  
3. Take a length of coax wire with BNC connectors that is long
enough to go from the high voltage amplifier 278 to the ISF
generator 282, which is placed close to the main assembly. Cut one
of the BNC connectors off and attach banana plugs to the positive
and negative wires and insert the banana plugs into the positive
and negative output terminals on the front panel of the high
voltage amplifier 278. Take the other BNC connector and connect it
to the female BNC connector on the ISF generator 282.  
  
4. Connect the switch 280 on the ISF generator terminal between
the negative end of the bulk head BNC connector and the outside
bronze/Teflon(TM) capacitor 324 (FIG. 8b). Make sure that the
positive input of the bulk head BNC connector is connected to the
inner bronze/Teflon(TM) capacitor. Use appropriate solder to make
both connections.  
  
5. Referring again to FIG. 8b, take a 16 gauge multi-strand wire
and connect it to the tip of the copper cone 328 on the ISF
generator. This can be done by either soldering the wire to the
tip of the cone 328 or by solder a ring connector to the wire and
using the appropriate screw to tighten the ring connector to the
tip of the cone. The other end of this wire is connected to the
input of the fiber coupler assembly 286 (FIG. 27a). It is possible
to use a male and female connector in the wire between the ISF
generator and the fiber coupler, but any connector used must not
have lead based solder. Copper connectors with no solder are
preferable, but nickel plated connectors will also work. It can be
seen from FIG. 16 that the input and output wire of the fiber
coupler 286 are attached to the tip of the copper cones in the
manner shown in FIG. 16.  
  
6. Referring again to FIG. 27a, use the same 16 gauge wire to make
a connection from the output of the fiber coupler 286 to the input
of the distribution assembly 340. The input wire of the
distribution assembly is connected to the tip of the cone in this
assembly. Again, wire attachment is done in the same manner as
shown in the drawing for FIG. 16. The 6 output wires are soldered
to the 6 tips of the base of the distribution assembly. Each of
these 6 wires is connected to one of the cones on the hexagon
projector 290, as depicted in FIG. 27a.  
  
7. The connections for the lamp assembly 304 are made as follows.
A 110V power supply cord is connected to the lamp socket base.
This cord is then plugged into the output of the SCR dimmer
control.  
  
8. Referring again to FIG. 2k, the video output plug from the IR
camera 217 is connected to video input of any TV purchase for this
device. The IR camera as specified comes with a separate
transformer for DC power.  
  
10. Setting Up and Optimizing the Electronics  
  
Below is an exemplary set of steps for setting up and optimizing
the electronic components of a destressing system, according to
one embodiment of the present invention.  
  
1. Insert a CD into the CD player 272.  
  
2. Use an oscilloscope to measure the speaker output of the sound
amplifier 276. Adjust the volume control until the speaker output
has a median value of 5 V peak-to-peak and should not exceed 10 V
peak-to-peak during any portion of the music.  
  
3. Before turning on the high voltage (HV) amplifier 278, turn the
gain to minimum. Hook up the ISF generator 282 to the HV amplifier
278. Make sure the switch 280 on the ISF generator is off. Use an
oscilloscope to measure the output of the HV amplifier. Set the
Bias Polarity to positive. Adjust the Bias offset so that there is
a positive 150 V bias. Now turn up the gain and make sure that at
no point during does the signal go below zero volts DC. If this
does happen, the more Bias offset needs to be applied. Once the
bias set, turn the gain back down and this part of the electronics
is ready.  
  
4. Plug the IR camera supply into a power strip. Once this is
turned on, turn the IR light 215 on and the system is ready to be
optimize to the person in the resting in the device.  
  
5. Plug the SCR into the same power strip as the IR camera. As
power switch on the front panel of the SCR is used to turn it on.  
  
The foregoing disclosure of the preferred embodiments of the
present invention has been presented for purposes of illustration
and description. It is not intended to be exhaustive or to limit
the invention to the precise forms disclosed. Many variations and
modifications of the embodiments described herein will be apparent
to one of ordinary skill in the art in light of the above
disclosure. The scope of the invention is to be defined only by
the claims appended hereto, and by their equivalents. For example,
although embodiments of the invention disclosed above focus on
apparatus in which an individual is accommodated in a reclined
position, apparatus in which the end members are arranged so that
the longitudinal members are vertical and the individual is
upright during destressing are within the scope of the invention.
Additionally, component or apparatus dimensions discussed in the
text or indicated in the Figures are merely exemplary and not
meant to limit the scope of the invention.  
  
Further, in describing representative embodiments of the present
invention, the specification may have presented the method and/or
process of the present invention as a particular sequence of
steps. However, to the extent that the method or process does not
rely on the particular order of steps set forth herein, the method
or process should not be limited to the particular sequence of
steps described. As one of ordinary skill in the art would
appreciate, other sequences of steps may be possible. Therefore,
the particular order of the steps set forth in the specification
should not be construed as limitations on the claims. In addition,
the claims directed to the method and/or process of the present
invention should not be limited to the performance of their steps
in the order written, and one skilled in the art can readily
appreciate that the sequences may be varied and still remain
within the spirit and scope of the present invention.  
  


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