IN the last issue of this magazine, we covered some of the
basic
methods concerning the detection of biodynamic signals of a
biodynamic character. A brief history of the work of L. George Lawrence was examined along with some ractical alications of biodynamic signal detection. !ince the writing of art one in this series, new and exciting information in regard to the resent work and the works of L. George Lawrence has been discovered. "!#$ has recently ac%uired atent documents, e%uiment, and an unublished manuscrit entitled, Galactic Life Unveiled - The
Phenomenon of Biological Communication Between Advanced Life in Space and Its Subliminal ffects on Te!!est!ial "an , by L. George Lawrence. &xamination of these materials uncovered many startling facts about the real work of 'r. Lawrence, and confirmed many assumtions we had based on our own emirical findings. Galactic Life Unveiled is a comlete thesis by 'r. Lawrence based on () years of remote biological sensing *#"!+ field studies and interstellar communications. e are currently in the rocess of ublishing this rare book which should be available by sring of (--). Methods of Biodynamic Signal Translation he lant resonse detector or signal rocessing translator detailed in /'etecting "iodynamic !ignals/ reresents only a fraction of the e%uiment used in the disclosure of biodynamic signals. 'r. Lawrence utilized a system which included a telescoe for sighting, a biodetector assembly containing biological transducers, electronic signal conversion e%uiment, &0 artifact detection e%uiment, and a video attachment for the roduction of biograms. In the eighty age atent document entitled /0ethods and #eceiver for "iological 'ata ransort/, 'r. Lawrence cites five different methods of signal rocessing translators as follows1
(+ Bridge Method 2 "iological semiconductors exhibiting electrical resistance changes due to external signal imingement may be arranged in a classic heatstone bridge arrangement *see schematic in revious issue+. 3+ Capacitance
Method2
"iological
semiconductors
exressing variations of caacitance during stimulus events may be embodied to function as a fre%uency2control element in an oscillator of the $0 tye. #ead2out may then be secured by means of a fre%uency counter or e%ually suited device. 4igh 53(6imedance or otical devices are used to sense given iezoelectric henomena accomanying caacitive reactions. 7+ Electrostatic
Method2
"iological
semiconductors
which are electrostatically active *active charge ac%uisition and deletion+ as a result of local excitation and the resence of
external biodynamic signal events may be read out by means of a charge2couled device *88'+ or on hotograhic film. 9+ Optical Method 2 "iological semiconductors evidencing otical roerties of a rimary *luminescence+ or secondary *transarency alterations+ tye during signal incidence may be read out by means of hotoelectric devices and "ragg cells. :+ Self-Potential Method2 "iological semiconductors exressing changes in electrical self2otentials due to signal incidence, may be amlified by non2loading high imedance devices such as electrometers. As we can see, there are a variety of means by which we may obtain and translate signals of a biodynamic character in biological semiconductors. It must be remembered, however, that biological materials exhibit characteristic actions of their own due to normal living cell function. It is the sensitization or excitation duty either as a service of the rocessing method or induced searately which will susend these functions to secure diagnostic control
over
natural
and
inter2communicatively
induced 5336resonses of living cells. In our exeriments, methods (, 3, and :, offer the most continuously successful rocedure of biodynamic signal rocurement, and are also the most cost effective. he reeated success of this instrumentation may be rimarily due to the combinative sensitizing;receiving nature of the ac%uiring method.
Lawrence
$esea!ch, v.3-, n.9 *=uly > August (-)7+
Image Acquisition and Biograms &arly on in the #"! exeriments, 'r. Lawrence develoed a means by which biodynamic signals could be translated into video images. Although he soke of using 88' technology as an ideal, he favored the most basic biological data dislay techni%ue of using facsimile recording. his system simly in?ects the electrical signals roduced by the biological semiconductors into a tye of A0 modulator. his modulates a given fre%uency band in such a manner so that varying amlitudes are a recise reflection of the modulating direct current roduct which can then be rendered into facsimile images. In our exeriments, we have utilized the same rotocols with greater flexibility regarding image resolution and ac%uisition.
In the first system we used to roduce biogram, the signal rocessing translator
software uses a mathematical $ast $ourier ransform *$$+ in erforming the fre%uency analysis. $$s are usually secified by the number of inut data oints used in each calculation. $or a samling rate of $ *cs+, an N inut oint $$ will roduce a fre%uency analysis over a fre%uency range of $;3. !ignal amlitude will be calculated at N;3 fre%uency increments in this range. he software rovides both narrowband and broadband rocessing otions. Narrowband rocessing
roduces a dislay
5376
of high fre%uency resolution which resolves the individual harmonics of the audio samle. "roadband rocessing broadens the fre%uency resonse of the $$ and roduces a dislay which smoothes over the individual harmonics to show broad areas of intensity. o simlify, the software ackage samles the inut, erforms an $$, and grahs the outut in the form of a 7' time2 fre%uency lot or sectrogram, where one axis is time, the second is fre%uency, and the vertical axis is the signal level at the secific time and fre%uency. hese "iograms were finally extracted from the comlex modulated ortions of the emergent sectrograhic image. hen very small sections of the image 2 little more than a few microseconds in duration 2 were enlarged to an aroriate viewing magnification. hese comleted "iograms could later be rendered into video resentations in a frame2by2frame se%uence. hile this system is not the ultimate in "iogram ac%uisition *mainly due to its deendence on the linear time constraints of the received signals+, it resents secific imaging of the erceived biodynamic modulations. Dne of the ma?or advantages of this system is that the A0 modulated biodynamic signals can be recorded and stored on analog or digital media to be later layed back for image rocessing.
he most difficult task for the researcher lies not in the e%uiment setu, but in the interretration of the ac%uired images. !ome images will reveal distinct imressions which need little translation, but many seem fragmented and are robably simle frames in an evolving comlex eretuity. Dne may discern a likeness of these images to those obtained by 'r. #uth 'rown in the use of her #adiovision instrument, the 'e la arr camera ictures, or the eidetic emulsions of Gerry Eassilatos. It was 'r. Lawrence
53C6
that its
recetion is in the form of whole images+, and it roagates in a longitudinal *time indeendent+ fashion, the rior systems of instant frame ac%uisition would be ideal. 8harge2couled device *88'+ technology while romising, is exensive and rovides a somewhat distorted biodynamic image resolution. @hotograhic film techni%ues, while rocuring the highest resolution images, are time consuming and relatively unmanageable in most field situations. ork is currently in rogress to modify and develo similar systems in con?unction with resent technology.
emote Biological Sensing and adionics ading through much of the technical data concerning biodynamic signal ac%uisition, one may lose sight of the real imortance of this exciting borderland technology. his is the
science of receiving living biodynamic information at a distance. Df course, we already have an examle of such a technology in radionics, a %ualitative science which not only ossesses the ability to receive living energy, but may also transmit living energy over great distances. ith the remote biological sensing system, we have no similar means of tuning or transmitting as in radionic systems, but it does ossess the ability to receive atternate living information which through its electronic interface resents us with an added %uantitative element to the %ualitative study, and may be used in con?unction with radionic systems. It offers another means of verification in biodynamic information analysis, and can be used in connection with the more sub?ective use of endulums and stick lates. #esearchers working in the field of #adionics have long sought an agency of /automated detection/ of radionic energy which could be directly incororated into their instruments, and several such examles exist today. he treatment instruments of #uth 'rown, for examle, included a small microammeter which would give indications when a atient was connected to the instrument via the footlates and robe. A later examle would be the /#AF23/ radionics instrument of =. Gallimore. his system disensed with the stick late altogether, and utilized a very sensitive G!# *galvanic skin resistance+ circuit with a microammeter wich would, when connected to the oerator, give secific indications while tuning. he #AF23 was designed for use in agricultural work where human oerators would determine, via the resonse indications of the G!#, secific radionic atterns while tuning the instrument. In recent 53)6exeriments *see /he "orderland &xerimenter, 7rd tr, "orderlands+ such a system has been used successfully while relacing the human oerator with a lant, allowing the lant to determine individual radionic /rates/. 0any modern instruments
are now including such automated detection devices in their construction. he alications of a remote biological sensing system are not strictly limited to living energy verification exeriments. 'r. Lawrence accidentally discovered that living biodynamic signals could be received from articular locations in sace, and imlied that we may be constantly receiving directions or instructions of an eidetic nature from an intelligent source outside our own solar system. hese exeriments of 'r. Lawrence, and our own, will be detailed in ucoming issues of "orderlands. !ield Tests and Biodynamic Signal Acquisition L. George Lawrence sent much of his time in isolated desert locations erforming remote biological sensing oerations. 0any arts of the desert are free from electromagnetic interference which can comlicate biodynamic signal interretation, so it is an ideal lace to erform exeriments in remote biological sensing. As we have already discussed, 'r. Lawrence
rocessing amlifier and meter rovide rimary, unmodulated monitoring of the incoming signals. Initially, 'r. Lawrence conducted his field exeriments with the goal of obtaining signals from living systems such as =oshua trees. 4e would simly in?ect a remeasured amount of '8 electricity into the tree by remote control while training the sights of his field e%uiment containing the biological transducers directly on the sub?ect tree. As the tree began to resond to the current, the biological transducers would simultaneously react to the 536irritation exerienced by the tree. Increasing the distance from the sub?ect *u to several miles+ roved no obstacle to the recetion of signals with no decrease in signal intensity. ith these many inaugural tests, 'r. Lawrence was able to erfect his system of the recetion of biodynamic signals.
he #"! field e%uiment in current use at "!#$ is nearly identical to 'r. Lawrence
those interested in essential and related information on our toic, references, atent sources, and an extensive bibliograhy of the works of L. George Lawrence are included here.
Continue "ith #$etecting Biodynamic Signals# %Part III&
eferences (.
3.
Galactic Life Unveiled - The Phenomenon of Biological Communication Between Advanced Life in Space and Its Subliminal ffects on Te!!est!ial "an, by L. George Lawrence. Fnublished 0s. o be ublished late sring (--), by "!#$. 5Now available in our standard xerograhic format1 H"B7, %Galactic Life Unveiled%J6 /0ethods and #eceiver for "iological 'ata ransort,/ L. George Lawrence. Abandoned atent, (-(.
7.
/8inema 3BBB1 he uest for &xtraterrestrial Eideo,/ L. George Lawrence, lect!onics and Technolog& Toda&, 0arch;Aril (--3.
9.
/Interstellar 8ommunications !ignals,/ L. George Lawrence, &cola Institute "ulletin )3;CA, #erinted in #ou!nal of Bo!de!land $esea!ch, v.3-, n.9 *=uly > August (-)7+. H'ull-te(tJ
:.
/Are e #eceiving "iological !ignals from Duter !aceK,/ L. George Lawrence, Popula! lect!onics, Aril (--(. H'ull-te(tJ
C.
/he !tarland Galactic ransmission heatre,/ L. George Lawrence. Fnublished.
).
/"iological Image ransmission,/ L. George Lawrence, (--. Fnublished. 'iterature and Patents
(. 3. 7. 9. :. C.
).
.
Cha!ge and 'ield ffects in Bios&stems, by .=. Aston, Abacus @ress, urnbridge, F (-9, . 9-(29-. Hhtt1;;amzn.to;(sNhsJ lect!oph&siological "ethods in Biological $esea!ch, by =. "ures, Academic @ress, N.M., (-C). Hhtt1;;amzn.to;EmrNvEJ )!ganic Semiconducto!s, by $. Gutmann and L.&. Lyons, iley, N.M., (-C). Hhtt1;;amzn.to;Emr=0@J /"iosensors,/ by 8.#. Lowe, T!ends in Biotechnolog&, &lsevier, Amsterdam, 317, (-9, . :-2C:. Biosenso!s* 'undamentals and Applications, by A.$.@. urner, Dxford Fniv. @ress, Dxford, F, (-). Hhtt1;;amzn.to;Emry#rJ /!ensor 4aving @iezoelectric 8rystal for 0icrogravimetric Immunoassays,/ F.!. @atent 9,)7:,-BC, G.=. "astiaans, Aril :, (-. Hhtts1;;www.google.com;atents;F!9)7:-BCJ /Immunoassays $or Antigens,/ F. !. @atent 9,393,B-C, Dliveira, #.=. and !.$. !ilver, 'ecember 7B, (-B. Hhtts1;;www.google.com;atents;F!9393B-CJ /!andwich Immunoassay Fsing @iezoelectric Dscillator,/ F.!. @atent, 9,7(9,3(, .. #ice, $ebruary -, (-3. Hhtts1;;www.google.com;atents;F!97(93(J
-.
Biosenso!s and Bioelect!onics, Eol (3, No. 9, (--). Hhtt1;;www.sciencedirect.com;science;?ournal;B-:C:CC7;(3;9J Bi(liography of ') *eorge 'a"rence he bibliograhy of L. George Lawrence
